method of informing an enodeb the transmit power state of a user equipment in a mobile communication

专利摘要:
METHOD FOR INFORMING AN ENODEB THE TRANSMISSION POWER STATE OF A USER EQUIPMENT IN A MOBILE COMMUNICATION SYSTEM USING 5-CARRIER AGGREGATION COMPONENT AND USER EQUIPMENT TO INFORM AN ENODEB THE TRANSMISSION POWER STATE OF A USER EQUIPMENT A MOBILE COMMUNICATION SYSTEM USING COMPONENT CARRIER AGGREGATION. The invention relates to methods for informing an eNodeB of the transmit power state of a user equipment in a mobile communication system using component carrier (CC) aggregation. Furthermore, the invention is also related to the implementation of these methods by hardware and their implementations in software. The invention proposes procedures that allow the eNodeB to recognize the power usage state of a UE in a communication system using carrier aggregation. The UE indicates to the eNodeB when the UE is close to using its total maximum UE transmit power, or when it has exceeded it. This is achieved by the UE including indicator(s) and/or new MAC CES to one or more protocol data units transmitted on the respective component carriers within a single sub-frame (...).
公开号:BR112012010022B1
申请号:R112012010022-0
申请日:2010-10-20
公开日:2021-05-04
发明作者:Joachim Lohr；Christian Wengerter；Martin Feuersanger
申请人:Sun Patent Trust；
IPC主号:

专利说明:

FIELD OF THE INVENTION
The invention is related to methods for informing an eNodeB of the transmit power state of a user equipment in a mobile communication system using component carrier aggregation. Furthermore, the invention is also related to the implementation/performance of these methods in/by hardware, i.e. apparatuses, and their implementation in software. The invention further relates to the definition of power margin reports per UE and per component carrier and their signaling by means of MAC control elements. TECHNICAL HISTORY LONG TERM EVOLUTION (LTE)
Third generation (3G) mobile systems based on WCDMA radio access technology are being developed on a large scale around the world. One step in improving or evolving this technology involves the introduction of High-Speed Downlink Packet Access (HSDPA) and an enhanced uplink, also called High-Speed Downlink Packet Access (HSDPA). HSUPA - "High Speed Uplink Packet Access"), providing a radio access technology that is highly competitive.
To be prepared to further increase user demands and be competitive against new radio access technologies, 3GPP has introduced a new mobile communication system which is called Long Term Evolution (LTE). LTE is designed to meet the carrier's needs for high-speed data and media transport, as well as high-capacity voice support for the next decade. The ability to provide high bitrates is a key measure for LTE.
The work item (WI) specification in Long Term Evolution (LTE) called Evolved UMTS Terrestrial Radio Access (UTRA) and UMTS Terrestrial Radio 10 Access Network (UTRAN) is about to be finalized as Version 8 (LTE See . 8). The LTE system represents efficient packet-based radio access and radio access networks that provide completely IP-based functionality with low latency and low cost. In LTE, scalable multicast bandwidths are specified, such as 1.4, 3.0, 5.0, 10.0, 15.0 and 20.0 MHz, to achieve flexible system deployment using a given spectrum. On the downlink, radio access based on Orthogonal Frequency Division Multiplexing (OFDM) was adopted because of its inherent immunity to multipath interference (MPI) due to a low symbol rate using a prefix cyclic (CP - "cyclic prefix"), and its affinity with different transmission bandwidths. Radio access based on multiple access to 25 single-carrier frequency division multiple access (SC-FDMA) was adopted in the uplink, as providing a wide coverage area was prioritized over the improvement in the peak data rate, considering the restricted power margin of the user equipment (UE - "User Equipment"). Many key packet radio access techniques are employed, including multiple input, multiple output (MIMO) channel transmission techniques, and a highly efficient control signaling framework is achieved in LTE Ver. 8/9. LTE ARCHITECTURE
The general architecture is shown in Figure 1, and a more detailed representation of the E-UTRAN architecture is given in Figure 2. E-UTRAN consists of eNodeB, providing the E-UTRA user plane protocol terminations (PDCP/RLC /MAC/PHY) and control plane (RRC) towards the user equipment (UE). The eNodeB (eNB) hosts the Physical (PHY - "Physical"), Media Access Control (MAC - "Medium Access Control"), Radio Link Control (RLC), and Packet Control Protocol layers (PDCD - "Packet Data Control Protocol") which include user-plane header encryption compression functionality. It also provides Radio Resource Control (RRC) functionality corresponding to the control plane. It performs various functions including radio resource management, admission control, scheduling, negotiated uplink QoS enforcement, cell information transmission, encrypting/decrypting user plane packet headers. The eNodeBs are interconnected with each other through the X2 interface. eNodeBs are also connected through an SI interface to the EPC (Evolved Packet Core), more specifically to the MME (Mobility Management Entity) through the Sl-MMe and the service portal (SGW - "Serving Gateway") through the Sl -U. The SI interface supports a many-to-many relationship between MMEs/Service Portals and eNodeBs. The SGW routes and forwards user data packets, while also acting as the mobility anchor for the user plane during deliveries between eNodeBs and as the mobility anchor between LTE and other 3GPP technologies (terminating the S4 interface and relaying traffic between 2G/3G and PDN GW systems) . For idle state user equipment, the SGW terminates the downlink data path and triggers paging when downlink data arrives for the user equipment. It manages and stores user equipment contexts, eg IP bearer service parameters, internal network routing information. It also replicates user traffic in case of legal interception.
MME is the key control node for the LTE access network. She is responsible for tracing and paging user equipment in idle mode, including retransmissions. It is involved in the bearer activation/deactivation process and is also responsible for choosing the SGW for a user equipment at the initial link and at the time of intra-LTE delivery, involving Core Network (CN) relocation. It is responsible for authenticating the user (interacting with the HSS) The Non-Access Stratum (NAS) signaling terminates at the MME and is also responsible for generating and allocating temporary identities to user equipment. It checks user equipment authorization to camp on the Public Land Mobile Network (PLMN) and imposes user equipment roaming restrictions. The MME is the endpoint on the network to encrypt/protect the integrity for NAS signals and controls the management of security keys. Legal signaling intercepts are also supported by the MME. The MME also provides the control plane function for mobility between LTE and 2G/3G access networks with the S3 interface terminating at the MME from the SGSN. MME also terminates the S6a interface towards the home HSS to perform user equipment roaming. i I QOS CONTROL
Efficient Quality of Service (QoS) support is seen as a basic requirement by operators for LTE. To enable the best-in-class user experience while on the other hand optimizing the utilization of network resources, enhanced QoS support should be an integral part of the new system.
Aspects of QoS support are currently being discussed within 3GPP working groups. 10 Essentially, the QoS design for System Architecture Evolution (SAE)/LTE is based on the QoS design of the current UMTS system reflected in 3GPP TR 25.814, "Physical aspects for evolved Universal Terrestrial Radio Access (UTRA)", v.7.1.0 (available at http://www.3gpp.org and incorporated herein by reference). The aggregated SAE Bearer Service architecture is illustrated in Figure 5. The definition of a bearer service as given in 3GPP TR 25.814 may additionally be applicable:
"A bearer service includes all aspects 20 to enable the provision of a contracted QoS. These aspects are, among others, control signaling, user plane transport and QoS management functionality."
In the new SAE/LTE architecture, the following 25 new bearers were defined: the SAE Bearer service between the mobile terminal (User Equipment - UE) and the service portal, the SAE radio bearer at the radio access network interface between the mobile terminal and the eNodeB, as well as the SAE Access Bearer between the eNodeB and the service portal.
The SAE Bearer Service provides: - aggregation with respect to QoS of IP end-to-end service flows; - IP header compression (and provision of UE related information); - User Plane (UP) encryption (and provision of UE related information) ; - if priority handling of end-to-end service signaling packets is required, an SAE Bearer Service can be added to the standard IP service; providing mapping/multiplexing of information to the UE; 10 - provision of accepted QoS information to the UE.
The SAE Radio Bearer Service provides: - transport of SAE Bearer Service data units between the eNodeB and the UE according to the required QoS; - connection of the SAE Radio Carrier Service to the respective SAE Carrier Service.
The SAE Access Bearer service provides: - transport of SAE Bearer Service data units between service portal and eNodeB, according to the required QoS; providing aggregated QoS description of the SAE Carrier Service towards the eNodeB; - connect the SAE Access Bearer Service to the respective SAE Bearer Service.
In 3GPP TR 25814, a one-to-one mapping between an SAE Bearer and an SAE Radio Bearer. In addition, there is a one-to-one mapping between a radio bearer (RB) and a logical channel. From this definition, it is concluded that an SAE Bearer, that is, the SAE Radio Bearer and the SAE Access Bearer, is the level of granularity for QoS control in a SAE/LTE access system. Packet flows mapped to the same SAE Bearer receive the same treatment.
For LTE, there will be two different types of SAE bearer: the standard SAE bearer, with a standard QoS profile, which is configured during initial access, and the dedicated SAE bearer (SAE bearers may also be called SAE bearer services) , which is set 5 for services that require a QoS profile that is different from the default.
The default SAE bearer is an "always on" SAE bearer that can be used immediately after transitioning from LTE_IDLE to LTE_ACTIVE state. It carries all 10 flows that have not been signaled a Traffic Flow Template (TFT). The Traffic Flow Model is used by the service portal to discriminate between different user loads. The Traffic Flow Model incorporates packet filters such as QoS.
Using packet filters, the service portal maps incoming data to the correct Packet Data Protocol Context (PDP). For the SAE bearer, several service data streams can be multiplexed. Unlike standard SAE Bearers, Dedicated SAE Bearers are designed to support identified services in a dedicated manner, typically to provide a guaranteed bit rate. Dedicated SAE carriers are established by the service portal based on the QoS information received in Policy and Charging Control (PCC) rules from the evolved packet core when a new service is requested. A dedicated SAE bearer is associated with packet filters, where filters only match certain packets. A standard SAE bearer is associated with 30 "match all" packet filters for uplink and downlink. For uplink control, the services portal builds the Traffic Flow Model filters for the dedicated SAE bearers. The UE maps r I F I * I service data flows to the correct bearer, based on the Traffic Flow Model, which was signaled during bearer establishment. As for the standard SAE Carrier, also for the ; Dedicated SAE bearer, multiple service data streams can be multiplexed.
The SAE bearer QoS Profile is signaled by the service portal to the eNodeB during the bearer configuration procedure. This profile is then used by the eNodeB to derive a set of 10 Layer 2 QoS parameters, which will determine the QoS control over the air interface. Layer 2 QoS parameters are sent to the scheduling functionality. The parameters included in the QoS profile signaled on the SI interface from the service portal to the eNodeB are currently being discussed. Most likely, the following QoS profile parameters are signaled for each SAE bearer: Traffic Control Priority, Maximum Bit Rate, Guaranteed Bit Rate. In addition, the service portal signals the eNodeB the Priority of Allocation and Retention for every 20 users during initial access. LTE UPLINK ACCESS SCHEME
For uplink transmission, a power efficient user terminal transmission is required to maximize coverage. Single-carrier transmission combined with FDMA (Frequency Division Multiple Access) with dynamic bandwidth allocation was chosen as the evolved UTRA uplink transmission scheme. The main reason for the preference for single-carrier transmission is the low peak-to-average power ratio (PAPR) compared to Orthogonal Frequency Division (OFDMA) signals Multiple Access), and the corresponding improved power amplification efficiency and the best assumed coverage (higher data rates for a given terminal peak power). During each time slot, the eNodeB assigns users a unique time/frequency feature to transmit user data, thus ensuring intracellular orthogonality 5 . An orthogonal access on the uplink promises improved spectral efficiency by eliminating intracellular interference. Interferences due to multipath propagation are controlled at the base station (eNodeB), aided by the insertion of a cyclic prefix into the transmitted signal.
The basic physical resource used for data transmission consists of a frequency resource of BWgrant size over a period of time, for example a 0.5 ms subframe, over which bits of information are mapped. It should be noted that a sub-frame, also called the transmission time interval (TTI), is the shortest time interval for transmitting user data. It is, however, possible to assign a BWgrant frequency resource over a longer period of time than one TTI to a user per 20 sub-frame concatenation.
The frequency resource can be in either a localized or distributed spectrum, as illustrated in Figures 3 and 4. As can be seen in Figure 3, a localized single carrier is characterized by the transmitted signal having a continuous spectrum that occupies a part of the spectrum total available. Different symbol rates (corresponding to different data rates) of the transmitted signal imply different bandwidths of a localized single-carrier signal.
On the other hand, as shown in Figure 4, the single distributed carrier is characterized by the transmitted signal having a discontinuous ("comb-shaped") spectrum that is distributed over the system bandwidth. Note that although the distributed single-carrier signal is distributed over the system bandwidth, the total amount of spectrum occupied is essentially the same as that of the localized single-carrier. Also, for a higher/lower symbol rate, the number of "comb fingers" is increased/decreased, while the "bandwidth" of each "comb finger" remains the same.
At first glance, the spectrum in Figure 4 may give the impression of a multi-carrier signal, where each comb finger corresponds to a "sub-carrier". However, from the time domain signal generation of a distributed single-carrier signal, it should be clear that what is being generated is a true single-carrier signal with a low peak-to-average power ratio. The key difference between a distributed single-carrier signal versus a multi-carrier signal, such as, for example, OFDM (Orthogonal Frequency Division Multiplex), is that, in the first case, each "sub-carrier" or "comb finger" does not carries a single modulation symbol. Instead, each "comb finger" carries information about all modulation symbols. This creates a dependency between different comb fingers that leads to low PAPR characteristics. It is the same dependency between the "comb fingers" that leads to a need for equalization, unless the channel is frequency non-selective over the entire transmission bandwidth. In contrast, for OFDM, equalization is not necessary as long as the channel is frequency non-selective over the sub-carrier bandwidth.
Distributed broadcast can provide greater frequency diversity gain than spot broadcast, while spot broadcast more easily allows channel dependent scheduling. Note that in many cases the scheduling decision may decide to give all the bandwidth to a single user equipment to achieve high data rates. LTE UPLINK SCHEDULE SCHEME
The uplink scheme allows both scheduled, ie eNodeB-controlled, and contention-based access. In the case of scheduled access, user equipment is allocated a certain frequency resource for a certain time (ie a time/frequency resource) for uplink data transmission. However, some time/frequency resources may be allocated for contention-based access. Within these time/frequency resources, user equipment can transmit without being first scheduled. A situation where the user equipment is making contention-based access is, for example, random access, that is, when the user equipment is performing the initial access to a cell or to request uplink resources.
For scheduled access, eNodeB's scheduled assigns a user a unique frequency/time resource for uplink data transmission. More specifically, the scheduler determines - which user devices are allowed to transmit; - which physical channel resources (frequency), Transport Format (Transport Block Size (TBS) and Modulation Coding Scheme (MCS) to be used by the mobile terminal for transmission
The allocation information is signaled to the user equipment through a scheduling grant, sent on the so-called L1/L2 control channel. For simplicity, this downlink channel is called the "uplink grant channel" below.
A schedule grant message (also called a resource assignment in this document) contains at least information which part of the frequency band the user equipment is authorized to use, the grant validity period, and the transport format that the user equipment must use for the next uplink transmission. The shortest validity period is a subframe. Additional information may also be included in the grant message, depending on the scheme selected.
Only "per user equipment" leases are used to grant the right to transmit on the UL-SCH Uplink Shared Channel (ie, there are no "per user equipment per RB" leases). Therefore, the user equipment needs to distribute the allocated resources among the radio bearers according to the same rules, which will be explained in detail in the next section.
Unlike HSUPA, there is no transport format selection based on user equipment. The base station (eNodeB) decides the transport format based on some information, for example, reported scheduling information and QoS information, and the user equipment must follow the selected transport format. In HSUPA, the 25 eNodeB assigns the maximum uplink resource and the user equipment therefore selects the current transport format for the data transmissions.
Uplink data transmissions are only allowed to use the time-frequency resources 30 assigned to the user equipment through the scheduling grant. If user equipment does not have a valid lease, it is not authorized to transmit any uplink data. Unlike HSUPA, where each user equipment is always allocated a dedicated channel, there is only one uplink data channel shared by multiple users (UL-SCH) for data transmissions.
To request resources, the user equipment transmits a resource request message to the eNodeB. This resource request message could, for example, contain information about the buffer state, the power state of the user equipment and some information related to Quality of Service (QoS). This information, which will be called scheduling information, allows the eNodeB to make an appropriate resource allocation. Throughout the document, it is assumed that the buffer state is reported for a group of radio bearers. Of course, other settings for the buffer status report are also possible. Since radio resource scheduling is the most important function in a shared channel access network to determine Quality of Service, there are a number of requirements that must be met by the uplink scheduling scheme for the
LTE to enable efficient QoS control (see 3GPP RAN WG#2 Tdoc. R2-R2-062606, "QoS operator requirements/use cases for sharing the same bearer services", by T-Mobile, NTT DoCoMo, Vodafone, Orange, KPN; available at http://www.3gpp.org/ and incorporated herein by reference): - Starvation of low priority services should be avoided
Clear QoS differentiation for radio carriers/services must be supported by scheduling scheme - Uplink notification must allow fine-grained buffer reporting (eg, by radio bearer or by radio bearer group) to allow the eNodeB scheduler identify for which Carrier/service
Radio data must be sent. - It should be possible to make clear QoS differentiation between services from different users - It should be possible to provide a minimum bit rate of 5 per radio bearer ■- As can be seen from the list above, an essential aspect of the scheduling scheme LTE is to provide mechanisms with which the operator can control the partitioning of its aggregate cellular capacity between radio bearers of different QoS classes. The QoS class of a radio bearer is identified by the QoS profile of the corresponding SAE bearer signaled to from the eNodeB service portal as described above. An operator can then allocate a certain amount of its aggregate cellular capacity to the aggregate traffic associated with radio bearers of a certain QoS class.
The main purpose of employing this class-based approach is to be able to differentiate the handling of packets depending on the QoS class they belong to.
For example, as the load on the cell increases, it should be possible for an operator to control this by throttling traffic belonging to a low priority QoS class. At this stage, high priority traffic can additionally experience a low load situation, since the resources added to this traffic are sufficient to serve it. This should be possible in both the uplink and downlink directions.
One benefit of employing this approach is that it gives the operator full control of the policies that govern bandwidth partitioning. For example, an operator policy could be to, even at extreme loads, avoid starvation of traffic belonging to its lowest priority QoS class. The prevention of low priority traffic starvation is one of the main requirements for the uplink scheduling scheme in LTE. In the current UMTS Version 6 (HSUPA) scheduling mechanism, the absolute prioritization scheme can lead to low priority 5 application starvation. E-TFC selection ("Enhanced Transport Format Combination selection") is made according to absolute logical channel priorities, ie high priority data transmission is maximized, which means that 10 low priority data is possibly starved by high priority data. To avoid starvation, the eNodeB scheduler must have a means to control which radio bearers a user equipment transmits data from. This mainly influences the design and use of 15 scheduling grants transmitted on the L1/L2 control channel on the downlink. In the following, details of the uplink rate control procedure in LTE will be outlined. MEDIUM ACCESS CONTROL (MAC - "MEDIUM ACCESS CONTROL") AND MAC CONTROL ELEMENTS
The MAC layer is the lowest sublayer in the Layer 2 architecture of the LTE radio protocol stack (see 3GPP TS 36.321, "Medium Access Control (MAC) protocol specification", version 8.7.0, in particular sections 4.2, 4.3 , 5.4.3 and 6, available at http//www.3gpp.org and incorporated herein in its entirety by reference). The connection to the physical layer below is through transport channels, and the connection to the RLC layer above is through logical channels. The MAC layer performs multiplexing and demultiplexing between logical channels and transport channels. The MAC layer on the transmit side 30 (in the following examples the user equipment) builds MAC PDUs, also called transport blocks, from MAC SDUs received over logical channels, and the MAC layer on the receive side retrieves the MAC SDUs of MAC PDUs received over transport channels.
In the multiplexing and demultiplexing entity, data from several logical channels can be (de)multiplexed into/from a transport channel. The multiplexing entity generates MAC PDUs from MAC SDUs when radio resources are available for a retransmission. This process includes prioritizing the logical channel data to decide how much data and which 10 channels should be included in each MAC PDU. Please note that the process of generating MAC PDUs at user equipment is also referred to as logical channel prioritization (LCP) in 3GPP terminology.
The demultiplexing entity reassembles 15 MAC SDUs from MAC PDUs and distributes them to the appropriate RLC entities. In addition, for peer-to-peer connection between MAC layers, control messages called 'MAC control elements' can be included in the MAC PDU.
A MAC PDU primarily consists of the header 20 and the MAC payload (see 3GPP TS 36.321, section 6). The MAC header is additionally composed of MAC sub-headers, while the MAC payload is composed of MAC control elements, MAC SDUs, and padding. Each MAC subheader consists of a Logical Channel ID (LCID 25 "Logical Channel ID"} and a Length field (L "Length") The LCID indicates whether the corresponding part of the MAC payload is a MAC control element , and otherwise which logical channel the MAC SDU belongs to. The L field indicates the size of the MAC SDU or related MAC control element 30. As already mentioned above, MAC control elements are used for peer signaling MAC-level -to-peer, including BSR reporting and information delivery of the UE power available in the uplink, and in the downlink DRX commands and time forward commands. For each type of MAC control element, one LCID special is allocated. An example for a MAC PDU is shown in Figure 6. POWER CONTROL
Uplink transmitter power control in a mobile communication system serves the purpose of balancing the need for sufficient transmit power per bit to achieve the required QoS against the need to minimize interference to other system users and maximize the life of the system. user equipment battery. In achieving this, the uplink power control must adapt to the characteristics of the radio propagation channel, including path losses, shading and fast fading, as well as overcoming interference from other users 15 within the same cell and in neighboring cells. The idea of classic uplink PC schemes is that all users are received with the same SINR, which is known as full compensation. As an alternative, 3GPP adopted the use of Fractional Power Control (FPC) for LTE Ver. 8/9. This new functionality makes users with high path loss operate at a lower SINR requirement, so they are likely to generate less interference to neighboring cells.
The power control scheme provided in LTE Ver. 8/9 employs a combination of open-loop and closed-loop control. One mode of operation involves defining a coarse operating point for the transmission power density spectrum by open-loop means based on the path loss estimate. Faster operations can then be applied around the open loop operating point by the closed loop power control. This controls interference and adjusts power settings to suit channel conditions, including fast fading.
With this combination of mechanisms, the power control scheme in LTE Ver.8/9 provides support for more than one operation. It can be seen as a 5-tool kit for different power control strategies depending on the implementation situation, system load and operator preference.
Detailed power control formulas are specified in LTE Ver. 8/9 for Physical Uplink Shared Channel (PUSCH), Physical Uplink Control Channel (PUCCH) and Sound Reference Signals (SRS) in section 5.1 in 3GPP TS 36.213, "Physical layer procedures", version 8.8.0, available at http://www.3gpp.org and incorporated herein by reference. The formula for each of these 15 uplink signals follows the same basic principles; in all cases they can be considered as the sum of two main terms; an operating point derived from semi-static parameters signaled by the eNodeB, and an updated dynamic shift from sub-frame to sub-frame.
The basic open-loop operating point for transmit power per resource block depends on a number of factors, including intercellular interference and cell load. It can be further divided into two components, a semi-static base level Po, additionally comprising a common power level for all user equipment in the cell (measured in dBm) and a UE-specific offset, and a compensation component of path loss in open loop. The dynamic displacement portion of the power block per resource can be further divided into two components, an MCS dependent component and explicit Transmitter Power Control (TPC) commands.
The MCS dependent component (denoted in the LTE specifications as Δπ, where TF stands for "Transport Format") allows the transmitted power per resource block to be adapted according to the transmitted information data rate .
The other component of dynamic shift is the UE-specific TPC commands. These can operate in two different modes: cumulative TPC commands (available for PUSCH, PUCCH and SRS) and absolute TPC commands (available only for PUSCH). For PUSCH, switching between these two modes is semi-statically configured for each UE via RRC signaling - i.e. the mode cannot be changed dynamically. With cumulative TPC commands, each TPC command signals a power step relative to the previous level. Uplink transmitter power control in a mobile communication system serves the purpose of balancing the need for sufficient transmitter power to achieve the required QoS against the need to minimize interference to other users of the system and maximize the battery life of the equipment. user.
In achieving this, the uplink power control has to adapt to the characteristics of the radio propagation channel, including path loss, shading and fast fading, as well as overcoming interference from other users within the same cell and in neighboring cells.
The UE PPUSCH transmit power [dBm] setting for PUSCH transmission in reference subframe i is defined by (see section 5.1.1.1 of 3GPP TS 36.213): ^PUSCH (z) — min{PC!vIAX, 10 log10 (A/PUSCH(Z)) + ^O_PUSCH 0) + α(j) ■ PL + ΔTF(Z) + /(/)} 30 Equation 1 - /'ruAY is the maximum UE transmit power chosen by UE in a given band (see below) ; MPUSCH is the number of physical resource blocks (PRBs). The more PRBs that are allocated, the more uplink transmit power is allocated. - Po PUSHU) indicates the base transmission power signaled by the RRC. For semi-persistent scheduling (SPS) and dynamic scheduling, this is the sum of a nominal component specific to the Po cell N0MrNAL PUSCH (7) and [-126,...,24] and a specific component to the UE ^O.UE.PUSCH0 ) and [ 127,..., 9th] For the RACH 3 message: Preamble transmit power offset - a denotes a cell-specific parameter (which is transmitted in system information). This parameter indicates how much loss per PL path is compensated, α = 1 means that the signal level received at the eNodeB is the same, regardless of the position of the user equipment. For SPS and dynamic scheduling, a e {0, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9.1}, and for the case of Message Rach 3, a(j) = l. PL is the path loss derived in user equipment based on the measurement of the Reference Signal Received Power (RSRP) and the signaled Reference Signal transmit power (RS - "Reference Signal") . PL can be defined as PL = reference signal strength - higher layer filtered RSRP. - ΔrF is a modulation of a coding scheme (transport format) dependent on power shift. /(z) is a function of the closed-loop power control commands signaled from the eNodeB to the UE. represents the accumulation, in case of cumulative TPC commands. It is set in the higher layers whether closed-loop commands are cumulative relative or absolute. For cumulative TPC commands, two sets of power degree values are provided: (-1.1) dB for DCI 3A format and (-1.0+1,+3) dB for DCI 3 format. of values that can be signaled by absolute TPC commands is (-4,-1,1,4) dB, indicated by DCI 3 format. POWER MARGIN NOTIFICATION
To assist the eNodeB in scheduling uplink transmission resources to different user equipment in an appropriate manner, it is important that the user equipment can report its power margin to the eNodeB.
The eNodeB can use power margin reports to determine how much more uplink bandwidth per sub-frame a user equipment is capable of utilizing. This helps to avoid allocating uplink transmission resources to user equipment that is unable to utilize them to avoid wasting resources.
The range of the power margin report is +40 to -23 dB (see 3GPP TS 3 6.133, "Requirements for support of radio resource management", version 8.7.0, section 9.1.8.4, available at http//www. 3gpp.org and incorporated in its entirety herein by reference). The negative part of the band allows the user equipment to signal to the eNodeB the extent to which it has received a UL grant which would require more transmit power than the UE has available. This would allow the eNodeB to reduce the size of a subsequent grant, thus freeing up transmission resources to allocate to other UEs.
A power margin report can only be sent on sub-bands where a UE has a UL grant. The report is related to the bus-frame on which it is sent. A number of criteria are defined to trigger a power margin report. These include: - A significant change in estimated path loss since the last power margin report - More than one configured time has passed since the previous power margin report - More than a configured number of meshed TPC commands closed were implemented by the EU
eNodeB can configure parameters to control each of these triggers depending on the system load and the requirements of its scheduling algorithm. To be more specific, the RRC controls power margin notification by setting the two periodic timersPHR-Timer and prohibitPHR-Timer, and signaling dl-PathlossChange which sets the measured downlink path loss change to trigger a margin report. power.
The power margin report is sent as a MAC control element. It consists of a single octet where the highest two bits are reserved and the lowest six bits represent the dB values mentioned above in steps of 1 dB. The MAC control element structure is shown in Figure 7.
The UE power margin PH [dB] valid for sub-frame i is defined by (see section 5.1.1.2 of 3GPP TS 36.213) : PH& ~ PcMAX {10 • log10 (M PUSCH (z)) + PQ_PUSCH ( ) + «(y) -PL + TF (i) + /(z)} Equation 2
The power margin is rounded to the nearest value in the range of [40; -23] dB, with steps of 1 dB. PCMAX is the total maximum UE transmit power (or total maximum transmit power of the user equipment) and is a value chosen by the user equipment in the given range of ^CMAX LE CMAX H based on the following restrictions: _ ^CMAX_L < CMAX < CMAX _H _ CMAX _L = ~ ' PpowerClass ~ MPR — AMPR ~ ATC _ PcMAX _H — mi 11(7/^^ ' PPowerClass ) PEMAX θ ° value signaled by the network and ATC, MPR and AMPR ( also called A-MPR - "Additional Maximum Power Reduction" are specified in 3GPP TS 36.101, "Evolved Universal Terrestrial Radio Access (E-UTRA) ; User equipment (UE) radio transmission and reception" , version 8.7.0, section 6.2, available at http//www.3gpp.org and incorporated herein by reference.
MPR is a power reduction value, the so-called Maximum Power Reduction, used to control the Adjacent Channel Leakage Power Ratio (ACLR) associated with the various modulation schemes and the width of transmission band. An adjacent channel can be, for example, another Evolved Universal Terrestrial Radio Access (E-UTRA) channel or a UTRA channel. The maximum allowable power reduction (MPR) is also defined in 3GPP TS 36.101. It differs depending on channel bandwidth and modulation scheme. User equipment derating may be less than this maximum allowable power derating (MPR) value. 0 3GPP specifies an MPR test which verifies that the maximum transmit power of a user equipment is greater than or equal to the rated maximum total transmit power minus the MPR while still meeting ACLR requirements.
As indicated above, MPR is the Maximum Additional Power Reduction. It is band specific and is applied when configured by the network.
As can be seen from the explanations above, PCMAX is specific to UE implementation and thus not known by eNodeB. Figure 25 shows exemplary situations for a UE transmit power state and corresponding power margin. On the left side of Figure 25, the user equipment is not limited (positive PHR), while on the right side of Figure 25, a negative power margin is implying a power limitation to the user equipment. Please note that PCMAX L< PCMAX < min(P£A^,PPowerClass). where the lower limit PCMAX L ® is typically primarily dependent on the maximum power reduction MPR and the additional maximum power reduction AMPR , ie, PCMAX _L = Ppowerciass ~ MPR ~ AMPR . ADDITIONAL ADVANCES FOR LTE (LTE-A)
The frequency spectrum for IMT-Advanced was decided at the World Radiocommunication Conference 2007 (WRC-07). Although the overall frequency spectrum for IMT-Advanced has been decided, the available frequency bandwidth is different according to each region or country. Following the decision regarding the delineation of the available frequency spectrum, however, the standardization of a radio interface started in the 3rd Generation Partnership Project (3GPP) . At the 39th 3GPP TSG RAN meeting, the Study Item description in "Further Advancements for E-UTRA (LTE-Advanced)" was approved. The study item covers technology components to be considered for the evolution of E-UTRA, eg meeting the requirements of IMT-Advanced. Two major technological components, which are currently under consideration for LTE-A, are described below. Carrier aggregation in LTE-S for higher bandwidth support
In carrier aggregation, two or more component carriers (component carriers) are aggregated to support higher transmission bandwidths up to 100 MHz. All component carriers can be configured to be LTE Ver. 8/9 compatible, at least when the aggregate numbers of component carriers on the uplink and downlink are the same. Not all component carriers 10 aggregated by a user equipment may necessarily be Ver. 8/9 compatible.
A user equipment can simultaneously receive or transmit one or more component carriers depending on its capabilities. A LTE-A Ver. 10 user equipment with receive and/or transmit capabilities for carrier aggregation can simultaneously receive and/or transmit on multiple component carriers, while an LTE Ver. 8/9 user equipment can receive and transmit on a single component carrier only, as long as the component carrier structure follows Ver. 8/9 specifications.
Carrier aggregation is supported for both contiguous and non-contiguous component carriers, with each component carrier limited to a maximum of 110 Blocks of 25 Resources in the frequency domain using Ver. 8/9 numerology. It is possible to configure a user equipment to aggregate a different number of component carriers originating from the same eNodeB and possibly different uplink and downlink bandwidths: - The number of component downlink carriers that can be configured depends on the capacity of downlink aggregation of user equipment; - The number of uplink component carriers that can be configured depends on the uplink aggregation capability of a user equipment;
It is not possible to configure a user equipment with more uplink component carriers than downlink component carriers;
In typical TDD implementations, the number of component carriers and the bandwidth of each component carrier in uplink and downlink is the same.
Component carriers originating from the same eNodeB need not provide the same coverage. The spacing between center frequencies of contiguously aggregated component carriers must be a multiple of 300 kHz. This is to be compatible with the Ver.8/9 frequency sweep while preserving orthogonality of the 15 kHz spacing subcarriers. Depending on the aggregation situation, the n x 300 kHz spacing can be facilitated by inserting a low number of unused subcarriers between contiguous component carriers.
The nature of multi-carrier aggregation is only exposed up to the MAC layer. For both uplink and downlink, there is a required HARQ entity in MAC for each aggregated component carrier. There is (in the absence of SU-MIMO - "Single User Multiple Input Multiple Output" - for uplink) at least one transport block per component carrier. A transport block and its potential HARQ retransmissions need to be mapped onto the same component carrier. The Layer 2 structure with carrier aggregation enabled is shown in Figure 19 and Figure 20 for the downlink and uplink, respectively.
When carrier aggregation is configured, the user equipment only has one RRC connection to the network. At RRC connection establishment/reestablishment, a cell provides the security input (one ECGI, one PCI and one ARFCN) and non-access strata mobility information (eg TAI), similarly to LTE Ver. 8/9. After RRC connection establishment/reestablishment, the component carrier corresponding to that cell is called Primary Cell (PCell). There is always one and only one downlink PCell (DL PCell) and one uplink PCell (UL PCell) configured per user equipment in connected mode. Within the configured set of 10 component carriers, other cells are referred to as Secondary Cells (SCells) . The characteristics of downlink and uplink PCells are:
Uplink PCell is used for transmitting Layer 1 uplink control information Downlink PCell cannot be disabled Reset is enabled when Downlink PCell goes through Rayleigh Fading (RLF), not when downlink SCells pass by RLF Downlink PCell may change with delivery 20 - Non-access stratum information is taken from downlink PCell.
Reconfiguration, addition and removal of component carriers can be performed by RRC. In intra-LTE delivery, the RRC may also add, remove, or reconfigure 25 component carriers for use in the target cell. When adding a new component carrier, dedicated RRs signaling is used to send system information from the component carriers, which is required for component carrier transmission/reception (analogously to LTE Ver. 8/9 for delivery).
When carrier aggregation is configured, a user equipment can be scheduled across multiple component carriers simultaneously, however, at most one random access procedure must be performed at any one time. Scheduling across carriers allows the Physical Downlink Control Channel (PDCCH) of one component carrier to schedule resources on another component carrier. For this purpose, a component carrier identification field (CIF) is introduced in the respective Downlink Control Information (DCI) formats. A connection between component uplink and downlink carriers allows identification of the component uplink carrier for which the lease applies when there is no inter-carrier scheduling. The connection of component downlink carriers to component uplink carriers does not necessarily need to be one by one. In other words, more than one downlink component carrier can connect to the same uplink component carrier. At the same time, a component downlink carrier can only connect to a component uplink carrier. THE (DIS) ACTIVATION OF A COMPONENT CARRIER AND A DRX OPERATION
In carrier aggregation, whenever a user equipment is configured with only one component carrier, discontinuous reception (DRX) of LTE 25 Ver. 8/9 applies. In other cases, the same DRX operation applies to all configured and activated cells, respectively component carriers (ie identical active time for PDCCH monitoring). When in active time, any component carrier can always schedule a Physical Downlink Shared Channel (PDSCH) 30 on any other configured and activated component carrier (additional restrictions are free for study).
To allow reasonable user equipment battery consumption when aggregation is configured, a component carrier enable/disable mechanism for downlink SCells is introduced (ie enable/disable does not apply to PCell). When a downlink SCell is not active, the user equipment does not need to receive the corresponding PDCCH or PDSCH, nor does it need to perform CQI measurements (CQI stands for "Channel Quality Indicator"). Conversely, when a downlink SCell is active, the user equipment must receive the PDSCH and PDCCH (if present), and is expected to be able to perform CQI measurements. In the uplink, however, a user equipment is always required to be able to PUSCH any configured uplink component carriers when scheduled on the corresponding PDCCH (i.e., there is no explicit activation of uplink component carriers).
Other activation/deactivation mechanism details for SCells are: - Explicit activation of downlink SCells is done by MAC signaling; - Explicit disabling of downlink SCells is done by MAC signaling; - Implicit disabling of downlink SCells is also possible;
Downlink SCells can be enabled and disabled individually, and a single enable/disable command can enable/disable a subset of the configured downlink SCells; SCells added to the set of configured component carriers are initially "disabled".
UPLINK POWER CONTROL FOR CARRIER AGGREGATION Although most of the details of the uplink power control algorithm for the carrier aggregation case are still open or under discussion in the 3GPP working groups, the general agreement is that the LTE-A Ver. 10 supports component carrier specific uplink power control, ie there will be an independent power control loop for each uplink component carrier configured for user equipment. In addition, it was decided that the power margin should be reported by component carrier. In the case of power limitation, i.e. the UE transmit power is exceeding the total maximum UE transmit power, the following power scaling is applied.
For power scaling, PUCCH power must be prioritized and the remaining power can be used for PUSCH (ie, PUSCH power is first reduced, perhaps to zero). Additionally, a PUSCH with uplink control information (UCI) is prioritized over PUSCH without UCI. Additionally, equal power scaling for PUSCH transmissions without UCI is considered.
As each component carrier can be assumed to have its own power control loop and each transport block on each component carrier is transmitted with an individually defined power for the component carrier, power margin notification 25 must be performed per carrier component. Since carrier aggregation can be seen as a multiplication of several LTE Ver. 8/9 carriers (components), it can be assumed that the power margin notification on the individual component carriers will also reuse the 30 margin notification procedures power output of LTE Ver. 8/9.
Thus, each user equipment transmits power margin reports for each component carrier on that component carrier. This means that each component carrier that has an uplink transmission on a specific sub-frame could also transmit a power margin report, provided conditions 5 for sending such a report are met.
Power margin notification as known by LTE Ver.8/9 is controlled, respectively triggered on each component carrier (employing different timers). Applying this concept to the individual component carriers of a system using carrier aggregation, this means that it almost never happens that, within a subframe, each component carrier with an uplink transmission is transmitting a power margin report. Thus, even if the timers 15 related to power margin notification (the periodicPHR timer and the prohibitPHR timer) are set to the same values for all component carriers, synchronous power margin reports on all component carriers within a sub -frame will only happen 20 by chance. Figure 10 shows exemplary power margin reporting in an LTE-A system, assuming that LTE 8/9 power margin reporting is applied to each of the three exemplary component carriers (CoCal to 25 CoCa3). In Tlr there is an uplink assignment on all three component carriers and an uplink transport block, respectively MAC PDU, including a power margin report for the respective component carrier, is sent on each component carrier. Since there is a 30 power margin report per component carrier (per DC) for each component carrier, the eNodeB is informed of the power state of the user equipment. Furthermore, the respective timers periodicPHR-Timer and prohibitPHR-
Timers are reset for each component carrier. For CoCal and CoCa3 component carriers, it is assumed that, after the expiration of the periodicPHR-Timer, there is no uplink allocation in the next sub-frame, so that no power margin reports can be sent immediately. Thus, in T2l the user equipment transmits a block PDU/Transport MAC with a power margin report only on the CoCal component carrier. As there is only one resource assignment on the CoCal component carrier, the eNodeB can again conclude regarding the power state of the user equipment from the DC power margin report in T2.
However, in T3, T4 and T5, only some transport blocks/PDUs of the component carriers within a sub-frame carry a power margin report. In relation to the power margin report on the CoCa3 component carrier in T5. It is assumed that a path loss change on the CoCa3 component carrier triggers the power margin report, but at the time of the path loss change, none of the component carriers have uplink transmissions (ie, component carriers CoCal and CoCa2 ) have a power margin report included. Therefore, T3, T4 and T5r the eNodeB is not aware of the actual transmit power spent on uplink transmissions within the respective sub-frames.
In addition, in LTE Ver. 10 within the scope of carrier aggregation, there are two maximum power limits, a maximum total UE transmit power PCNMAX θ a maximum transmit power specific to carrier PCMACC component • ° 3GPP working group RAN4 has already indicated that both the maximum (nominal) transmission power per PCNMAX user equipment and the specific transmission power of the maximum (nominal) component carrier PCMAC,C must be the same, regardless of the number of supported carriers, in order not to affect the connection budget of a user equipment capable of carrier aggregation in single carrier mode of operation.
Unlike LTE Ver. 8/9, in LTE-A Ver. 10, the user equipment must also handle simultaneous PUSCH - PUCCH transmission, scheduling in multiple groups, and simultaneous transmission on multiple component carriers, which requires higher values of MPR and also cause a higher variation of MPR values compared to 3GPP Ver. 8/9.
It should be noted that the eNodeB does not have knowledge of the power reduction applied by the user equipment on each component carrier, as the actual power reduction depends on the type of allocation, the standardized MPR value and also the implementation of the user equipment . Therefore, the eNodeB does not know the component carrier-specific maximum transmit power relative to which the user equipment calculates the power margin. In LTE Ver. 8/9, for example, the maximum transmit power of PCNMAX user equipment may be within a certain range as described above ( PCMAX_L~ p < p ) £CMAX rCMAX _H ' •
Due to the reduction in the maximum transmit power specific to the PCMAC,C > component carrier which is not known by the eNodeB as explained above, the eNodeB cannot really know how close a user equipment is operating to its total maximum transmit power PCNMAX • Therefore, there may be situations where the user equipment is exceeding the maximum transmit power of the full PCNMAX user equipment, which would therefore require power scaling. Figure 26 shows an exemplary situation, where the user equipment has limited power, that is, applying power scaling on the 5 component carriers CC#1 and CC#2 configured in the uplink.
Although user equipment is power limited, component carrier-specific power margin reports, per LTE definitions, indicate a sufficiently large power margin. SUMMARY OF THE INVENTION
An object of the invention is to propose procedures that allow the eNodeB to recognize the power usage status of a user equipment in a mobile communication system using carrier aggregation.
The object is resolved by the matter of independent claims. Advantageous realizations are subject to the dependent claims.
A first aspect of the invention is to allow user equipment to indicate to the eNodeB when it is potentially power-limited or power-limited, that is, when it is close to using its full maximum UE transmit power (also called "user equipment total maximum transmit power", "user equipment total maximum UE transmit power 25", or "user equipment total maximum UE transmit power" below) or the resource allocations and eNodeB power control commands would require using a transmit power that exceeds the total maximum transmit power 30 of the user equipment.
In accordance with this first aspect of the invention and in accordance with a first exemplary implementation, the user equipment uses an indicator in the MAC protocol data units (MAC PDUs ("Protocol Data Units") of each sub-frame to signal to the eNodeB if the user equipment has applied power scaling to the transmission (of the MAC PDUs) within the respective sub-frame. The indicator(s) can be, for example, included in one or more MAC sub-headers of the MAC PDUs.
In an enhancement to the first exemplary implementation, an indicator is provided for each configured component carrier (or alternatively for each active component carrier) on the uplink so as to allow indication of power scaling usage for individual component carriers on the uplink. For example, this can be accomplished by multiplexing respective indicators 15 to MAC PDUs transmitted by the user equipment on the respectively configured (or alternatively active) component carriers on the uplink, so that the indicator can be associated with the configured (or alternatively active) component carrier in which it is broadcast.
If the user equipment power state indication must be done before the user equipment actually reaches its full maximum UE transmit power, a threshold value (eg a certain percentage) could be set relative to the power of 25 total maximum UE transmission, which, when exceeded, triggers the user equipment to set an indicator. In this case, when set, the indicator would indicate to the eNodeB that the user equipment is close to using the full maximum UE transmit power (ie, has exceeded the threshold value). In addition, this indicator may be signaled for each individually configured uplink component carrier, and may, for example, be included in one or more MAC subheads of MAC PDUs.
Still in accordance with the first aspect and according to another second exemplary implementation, if the user equipment needs to apply power scaling to a transmission of MAC PDUs in a given subframe, the user equipment is transmitting in that subframe a power margin report for each configured (or alternatively active) uplink component carrier (also referred to herein as power margin per component carrier report) along with an indicator that 10 is the power margin report(s) per component carrier are triggered by the estimated transmit power required to transmit MAC PDUs within the given sub-frame exceeding the total maximum transmit power of the user equipment (alternatively, the indicator could also be interpreted as an indication of the scaling of power having been applied to transmissions within the given sub-frame by the user equipment due to and this event).
Thus, in this second exemplary implementation, when the transmit power required for a transmission of MAC PDUs by component uplink carriers within the respective sub-frame exceeds a total maximum transmit power of the user equipment, a power margin report per aperiodic component carrier for 25 all configured (or active) uplink component carriers is triggered and sent by the user equipment. The trigger indication for component carrier power margin reports can be, for example, included in a MAC subheader of a MAC PDU carrying a component carrier power margin report in a MAC control element.
This second exemplary implementation can also be modified so as to signal an indication of the user equipment power state if before the user equipment actually reaches its full maximum UE transmit power. Again, a threshold value (eg a certain percentage) could be set in relation to the total maximum UE transmit power, which, when exceeded, triggers the user equipment to send a power margin report for each component carrier. of uplink.
In addition, a power margin report for each configured (or alternatively active) uplink component carrier may optionally be sent along with an indication that the respective power margin report has been triggered, exceeding the total maximum transmit power of the equipment. user name or a threshold relating thereto. For example, such an indication could be comprised in a MAC subheader of a MAC control element transmitting a power margin report to an uplink component carrier of the user equipment.
According to a third exemplary additional implementation, in accordance with the first aspect of the invention, the user equipment is indicating to the eNodeB the amount of power reduction applied to the maximum transmit power of a component carrier.
Alternatively, instead of power reduction, the maximum transmit power of each configured uplink component carrier (after applying specific power reduction to the component carrier) could be signaled to the eNodeB.
The amount of power reduction can be, for example, signaled by configured uplink component carrier or by active uplink component carrier.
In a further example, the amount of power reduction applied to the maximum transmit power of a component carrier is signaled along with a power margin report for each uplink component carrier configured to the eNodeB.
User equipment power state information may be signaled in the form of one or more MAC control elements that are comprised * within the MAC PDU(s) of a given sub-frame. In addition, the signaled power state information allows the 10 eNodeB to derive the power state for each user equipment that is signaling its power state information. The eNodeB scheduler can, for example, take into account the power state of the respective user equipment in its dynamic and/or semi-persistent resource allocations to the respective user equipment.
In a fourth exemplary implementation in accordance with the first aspect of the invention, a user equipment is enabled to indicate to the eNodeB 20 when it is potentially becoming power limited or is power limited by defining a new MAC control element that is inserted by the user equipment in one or more protocol data units _ transmitted by respective component (assigned) carriers within a single sub-frame that is providing the eNodeB with a corresponding indication.
Furthermore, together with the indication that the user equipment is approaching its total maximum UE transmit power, the control element 30 inserted into the protocol data units can additionally indicate a power margin per user equipment (per UE ) . For example, the user equipment power margin indicates the transmit power not used by the user equipment when transmitting the protocol data units (including the MAC control element) within the sub-frame relating to the transmit power of Total maximum EU of user equipment.
The MAC control element can be inserted into the protocol data units of a sub-frame. For example, the MAC control element can be inserted into one of the protocol data units transmitted by the user equipment within the sub-frame or all protocol data units transmitted by the user equipment within the sub-frame.
In another fifth exemplary implementation and in accordance with the first aspect of the invention, the object is solved by the user equipment sending power margin reports per component carrier for all assigned component carriers within a single subframe when the user equipment is potentially becoming power-limited or power-limited, that is, when it is close to using its maximum UE transmit power, or eNodeB's resource allocations and power control commands require the use of a transmit power exceeding the total maximum UE transmit power of the user equipment.
Another second aspect of the invention is to suggest a definition for a power margin per component carrier when reporting the power margin in a mobile communication system using carrier aggregation on the uplink. According to an exemplary definition, the power margin per component carrier of a configured (or alternatively active) uplink component carrier is defined as the difference between the maximum transmit power of the configured uplink component carrier and the transmit power of uplink used.
The uplink transmit power used is the power used (or emitted) by the user equipment for transmitting MAC PDUs within the given sub-frame. The uplink transmit power used may also be called transmitted PUSCH power. The uplink transmit power used is therefore considering the power sizing (if applied to the transmission). Therefore, the transmit power used may be different from the estimated transmit power, which is the transmit power required for a transmission of MAC PDUs by component uplink carriers within the respective sub-frame as a result of the control formula of power.
Alternatively, a configured uplink component carrier power margin can be defined as the difference between the configured uplink component carrier maximum transmit power and an estimated PUSCH power. The PUSCH power is, for example, calculated by the power control formula for the respective component carrier.
In addition, the maximum transmit power of the component uplink carrier (configured) can take into account a power reduction due to simultaneous transmissions by other component uplink carriers in the sub-frame. Optionally, power margin reports are sent to active uplink component carriers of user equipment only.
The power margin per component carrier according to the second aspect of the invention may be provided in the form of a power margin per component carrier report. Power margin reporting per component carrier is, for example, signaled in the form of a MAC control element within a MAC PDU. As mentioned above, the MAC control element carrying the power margin per component carrier report can be associated with a MAC sub-header in a MAC PDU header section that can be further employed to indicate that the power margin per component carrier is triggered by a user equipment power-limited situation, requiring power scaling.
In all aspects of the invention and also in all embodiments and exemplary implementations described herein, the user equipment may optionally report only by configured component carriers that are active, which may be called active component carriers (i.e., indicators, reports power margin, etc., can only be signaled by active component carriers only). This can be, for example, advantageous if the configuration and (de)activation of component uplink carriers of a user equipment can be controlled separately.
One embodiment of the invention relates to a method for informing an eNodeB the transmit power state of a user equipment in a mobile communication system using component carrier aggregation. This method comprises the following steps performed by the user equipment for each sub-frame where the user equipment performs a transmission on the uplink. The user equipment determines whether an estimated transmit power required for a transmission of MAC protocol data units 30 by the component carriers within the respective sub-frame will exceed a total maximum transmit power of the user equipment. If so, the user equipment performs a transmission power power sizing to reduce the transmission power required for the transmission of MAC protocol data units so that it is no longer exceeding the total maximum transmission power of the equipment. and transmits the MAC protocol data units to the eNodeB within the respective sub-frame. The transmitted MAC protocol data units comprise an indicator which indicates to the eNodeB whether power scaling has been performed by the user equipment by transmitting the MAC protocol data units in the respective sub-frame.
The indicator can, for example, be comprised within a MAC header of at least one of the MAC protocol data units. For example, the indicator may be a flag within one or more of the MAC sub-headers of a respective MAC header comprised in the at least one MAC protocol data unit.
Furthermore, in a more advanced exemplary embodiment of the invention, power scaling can be performed for each individually configured uplink component carrier. For each uplink component carrier on which a MAC protocol data unit is transmitted, at least one MAC protocol data unit transmitted by the respective uplink component carrier comprises an indicator that indicates to the eNodeB whether the power scaling has been applied to transmission on the respective uplink component carrier within the subframe.
Another embodiment of the invention provides an additional method 30 for informing an eNodeB of the transmit power state of a user equipment in a mobile communication system using component carrier aggregation. In accordance with this realization, a user equipment determines whether an estimated transmit power required for the transmission of MAC protocol data units on component uplink carriers within the respective sub-frame will exceed a total equipment maximum transmit power. of user. If this is the case, the user equipment performs a transmit power power sizing to reduce the transmit power required for the transmission of MAC protocol data units such that it is no longer exceeding the total maximum transmit power of the user equipment, and additionally triggers the generation of a power margin report for each configured uplink component carrier of the user equipment. The user equipment transmits the MAC protocol data units to the eNodeB within the respective sub-frame along with a power margin report for each configured uplink component carrier of the user equipment and an indication of the power margin reports, having been triggered by the transmit power required for transmitting MAC protocol data units on the uplink component carrier exceeding the total maximum transmit power of the user equipment.
Furthermore, the user equipment may optionally additionally determine, in response to the trigger, a power margin report for each configured uplink component carrier of the user equipment, wherein the power margin for a configured uplink component carrier is defined as the difference between the maximum transmit power of the configured uplink component carrier and the used uplink transmit power. Thus, this definition of the power margin considers the power margin.
Alternatively, or in addition thereto, the user equipment may determine, in response to the trigger, a power margin report for each configured uplink component carrier of the user equipment, wherein the power margin of a component carrier. Configured uplink is defined as the difference between the maximum transmit power of the configured uplink component carrier and the estimated uplink transmit power of the respective component carrier.
Therefore, this alternative definition of power margin 10 is not considering power sizing. Optionally, the power margin according to both of the above definitions can be determined by the user equipment for each configured uplink component carrier and can be provided to the eNodeB within a power margin report.
In a further exemplary embodiment of the method, the power reduction applied to the maximum transmit power of a configured uplink component carrier that is determined by the user equipment considers 20 transmissions on other configured uplink component carriers of the user equipment within the sub- frame.
In addition, according to another exemplary realization, the indication of the power margin reports that are triggered by the estimated transmission power that exceeds the total maximum transmission power of the user equipment is provided by defining a signaling in a MAC subheader for a MAC control element carrying at least one of the power margin reports. For example, a MAC subheader could be included in a MAC protocol data unit header section to which the MAC control element is multiplexed for each MAC control element comprising a respective power margin report. A signaling in the MAC subheader indicates that the power margin report within the MAC control element has been triggered by the estimated transmit power required for a transmission of MAC protocol data units on 5 component uplink carriers within the respective subframe exceeding the total maximum transmit power of the user equipment.
In another exemplary embodiment, an additional method for informing an eNodeB of the transmit power state 10 of a user equipment in a mobile communication system using component carrier aggregation. Optionally, this method can be performed for each subframe where the user equipment performs an uplink transmission. According to the method, the user equipment 15 determines whether an estimated transmission power required for a transmission of MAC protocol data units on component uplink carriers within the respective subframe will exceed a total maximum transmission power of the user equipment. user. If this is the case, the user equipment performs a transmit power power sizing to reduce the transmit power required for the transmission of MAC protocol data units such that it is not exceeding a total maximum transmit power of the equipment, and transmits the MAC protocol data units to the eNodeB within the respective sub-frame. The transmitted MAC protocol data units comprise at least one MAC control element indicating the amount of power reduction applied to the maximum transmit power of the user equipment for the configured uplink component carriers.
Alternatively, the user equipment could signal the maximum transmit power of the user equipment for the configured uplink component carriers, which may, however, imply more signaling overhead than signaling the amount of power reduction at the same level of granularity.
Optionally, MAC control elements indicating the amount of power reduction for configured uplink component carriers could be included in MAC PDUs within a sub-frame only if the estimated transmit power required for a transmission 10 units MAC protocol data on the component uplink carriers within the respective sub-frame will exceed the total maximum transmit power of the user equipment, that is, if the user equipment is to apply power scaling.
In a more detailed exemplary realization of this method, it can be assumed that power scaling has been performed for each individually configured uplink component carrier. For each uplink component carrier on which a MAC protocol data unit 20 is transmitted, at least one MAC protocol data unit transmitted on the respective uplink component carrier comprises a MAC control element indicating the amount of reduction of power applied to the maximum transmit power of the respective uplink component carriers.
According to a further exemplary embodiment of the invention, in case the estimated transmission power required for the transmission of MAC protocol data units by the component uplink carriers within the respective sub-frame exceeds the total maximum transmission power of the equipment user equipment, the user equipment additionally generates a power margin report for each configured uplink component carrier and transmits the power margin reports together with the MAC protocol data units including the MAC control element for reporting the power reduction to the eNodeB.
According to another exemplary embodiment of the invention, the user equipment signals the reduction of . power and a power margin report for the respective J respective uplink component carrier configured in response to (de)activating a component uplink carrier or in response to a predetermined change in the amount of power reduction applied to the power of maximum transmission for an uplink component carrier.
In another embodiment of the invention, the format of the MAC control element signaling the amount of power reduction is identified by a predetermined logical channel identifier defined by MAC control elements signaling the amount of power reduction, or an identifier of predetermined logical channel defined by MAC control elements signaling a power margin report and one or more signals included in the MAC subheader of a MAC control element.
The different exemplary embodiments of the method for informing an eNodeB the transmit power state of a user equipment may - according to another embodiment of the invention - comprise the steps of receiving by the user equipment at least one allocation of uplink resources , wherein each uplink resource assignment is allocating resources for transmitting at least one of the MAC protocol data units on one of the multiple component carriers to the user equipment, and generating for each received uplink resource assignment at least one of the protocol data units of
MAC for retransmission of the respective assigned component carrier. Each unit of MAC protocol data is transmitted over one of the corresponding component carriers according to one of the received resource allocations 5 (please note that, in case MIMO is used, two MAC PDUs can be transmitted over one uplink component carrier on which resources have been granted to the user equipment). The generation of the protocol data units can be, for example, carried out by executing a logical channel prioritization procedure.
In accordance with the second aspect of the invention and in accordance with another exemplary embodiment of the invention, a MAC control element for transmission from a user equipment to the eNodeB in a mobile communication system using component carrier aggregation is provided. . According to this embodiment, the MAC control element comprises a power margin report for a configured uplink component carrier which reports the difference between the maximum transmit power of the uplink component carrier and a transmitted PUSCH power (or the uplink transmission power used).
In an example, the transmitted power PUSCH PPUSCH,c(z) of sub-frame i is defined by 25 P puscH,c(z) = PSF. • min{PCMAX1C > 1 θ 1st C^PUSCH.C (0) + ^0_PUSCH,c (j) + 0) • PLC + ΔTF c (0 + fc I where PSFC is the applied power scaling factor to the respective configured uplink component carrier c.
Furthermore, in another exemplary embodiment of the invention, the MAC control element may further comprise a configured uplink component carrier power margin report that reports the difference between the maximum transmit power of the configured uplink component carrier and a estimated PUSCH power (or estimated uplink transmit power on the respective component carrier).
Still in accordance with the second aspect of the invention and in accordance with an alternative exemplary embodiment of the invention, another MAC control element for transmission from a user equipment to an eNodeB in a mobile communication system using component carrier aggregation is provided. . This MAC control element comprises a configured uplink component carrier power margin report which reports the difference between the maximum transmit power of the configured uplink component carrier and an estimated PUSCH power.
In both realizations of the MAC control element, the maximum transmit power of the configured uplink component carrier considers a power reduction due to transmissions on other configured uplink component carriers of the user equipment.
Another exemplary embodiment of the invention relates to a MAC protocol data unit for transmission from a user equipment to an eNodeB in a mobile communication system using component carrier aggregation. The MAC protocol data unit comprises a MAC control element including a power margin report according to one of the different embodiments described here and a MAC sub-header. The MAC subheader comprises an indicator, which, when set, indicates to the eNodeB that the power margin report has been triggered by the transmission power required for a transmission of MAC protocol data units on component uplink carriers exceeding power maximum transmission rate of the user equipment.
Furthermore, the invention is also related to the realization of methods to inform an eNodeB the transmission power status of a user equipment in hardware and/or by means of software modules. Therefore, another embodiment of the invention relates to a user equipment for informing the eNodeB the transmit power state of a user equipment in a mobile communication system using component carrier aggregation. The user equipment comprises a determining section which determines whether an estimated transmit power required for the transmission of MAC protocol data units on the uplink component carriers within the respective sub-frame will exceed a total maximum transmit power of the user equipment. In addition, the user equipment comprises a power control section that performs a power sizing of the transmission power to reduce the transmission power required for transmission of MAC protocol data units such that it is no longer exceeding the total maximum transmit power of the user equipment, and a transmit section for transmitting the MAC protocol data units to the eNodeB 25 within the respective sub-frame. The transmitted MAC protocol data units comprise an indicator which indicates to the eNodeB whether power scaling has been performed by the user equipment to transmit the MAC protocol data units in the respective sub-frame.
Another exemplary embodiment provides a user equipment for informing an eNodeB the transmit power state of a user equipment in a mobile communication system using component carrier aggregation. The user equipment comprises a determination section adapted to determine whether a transmission power required for a transmission of MAC protocol data units on component uplink carriers within the respective sub-frame will exceed a total maximum transmit power of the equipment. and trigger the generation of a power margin report for each configured uplink component carrier of a user equipment, and additionally a power control section adapted to perform a power scaling of the transmit power to reduce the transmit power required for the transmission of MAC protocol data units such that it is no longer exceeding the total maximum transmit power of the user equipment. Furthermore, the user equipment includes a transmission section adapted to transmit the MAC protocol data units to the eNodeB within the respective sub-frame along with a power margin report for each configured uplink component carrier of the user equipment and an indication of the power margin reports being triggered by the transmit power required for a transmission of MAC protocol data units on component uplink carriers 25 exceeding the maximum transmit power of the user equipment.
In an embodiment of the invention, the user equipment comprises a determination section adapted to determine whether an estimated transmission power required for a transmission of MAC protocol data units on the component uplink carriers within the respective sub-frame will exceed a total maximum transmit power of the user equipment, and a power control section adapted to perform a power sizing of the transmit power to reduce the transmit power required for the transmission of MAC protocol data units such that it does not is further exceeding the total maximum transmit power of the user equipment, and additionally a transmission section adapted to transmit the MAC protocol data units to the eNodeB within the respective sub-frame. The transmitted MAC protocol data units comprise at least one MAC control element indicating the amount of power reduction applied to the maximum transmit power of the user equipment for the configured uplink component carriers.
Furthermore, according to another embodiment of the invention, the user equipment is adapted to carry out the steps of the methods for informing an eNodeB the transmit power state of a user equipment according to one of the various embodiments described herein.
Another embodiment of the invention provides a computer readable medium 20 storing instructions which, when executed by a user equipment processor, cause the user equipment to report to an eNodeB the transmit power state of a user equipment for each sub-frame where the to be transmitted by the user equipment transmits on the uplink within a mobile communication system using component carrier aggregation, determining whether an estimated transmission power required for a transmission of MAC protocol data units in the component uplink carriers within 30 of the respective sub-frame will exceed a maximum transmit power of the user equipment, and, if so, perform a power scaling of the transmit power to reduce the transmit power required for the transmission of the units of MAC protocol data such that it is no longer exceeding the transmit power Maximum total user equipment, and transmit the MAC protocol data units to the eNodeB within the respective sub-frame. The transmitted MAC protocol data units comprise an indicator which indicates to the eNodeB whether power scaling has been performed by the user equipment to transmit the MAC protocol data units in the respective sub-frame.
A computer-readable medium of another embodiment of the invention is storing instructions which, when executed by a user equipment processor, cause the user equipment to report to an eNodeB the transmit power state of a user equipment in a mobile communication system using component carrier aggregation, determining whether an estimated transmit power required for a transmission of MAC protocol data units on uplink component carriers within the respective sub-frame will exceed a total equipment maximum transmit power and, if so, perform a transmission power power sizing to reduce the transmission power required for the transmission of MAC protocol data units such that it is no longer exceeding the total maximum transmission power of the user, and trigger the generation of a power margin report for each p. configured uplink component carrier of the user equipment, and transmit the MAC protocol data units to the eNodeB within the respective sub-frame along with a power margin report for each configured component uplink carrier of the user equipment and an indication of power margin reports having been triggered by the transmit power required for a transmission of MAC protocol data units on uplink component carriers exceeding the total maximum transmit power of the user equipment.
According to a further embodiment of the invention, a computer-readable medium storing instructions is provided. The instructions, when executed by a user equipment processor, cause the user equipment to inform an eNodeB the transmit power state of a user equipment for each sub-frame where the data to be transmitted by the user equipment does an uplink transmission within a mobile communication system using component carrier aggregation, determining whether an estimated transmission power required for a transmission of MAC protocol data units on component uplink carriers within the respective sub-frame will exceed one total maximum transmission power of a user equipment, and if so, perform a transmission power power sizing to reduce the transmission power required for the transmission of MAC protocol data units such that it is no longer exceeding the power total maximum transmission rate of the user equipment, and transmit the data units of p. MAC rotocol to the eNodeB within the respective subframe, wherein the transmitted MAC protocol data units comprise at least one MAC control element indicating the amount of power reduction applied to the maximum transmit power of the user equipment for the carriers configured uplink components.
Additionally, according to another embodiment of the invention, the computer-readable medium may additionally store instructions which, when executed, cause the user equipment to perform the steps of methods to inform an eNodeB of the transmit power state of an equipment. according to one of the various realizations described here.
Another embodiment of the invention related to the first aspect of the invention provides a method for informing an eNodeB the power state of a user equipment in a mobile communication system using component carrier aggregation. The user equipment determines whether an estimated transmit power required to transmit 10 units of protocol data on respective component carriers within a sub-frame will exceed a threshold value relative to a total maximum UE transmit power of the user equipment . If the threshold value is exceeded, the user equipment multiplexes the MAC control element to the protocol data units and transmits the protocol data units including the MAC control element to the eNodeB within the sub-frame. The MAC control element indicates to the eNodeB that the transmit power expended by the user equipment to transmit the protocol data units generated in the uplink has exceeded the threshold value, i.e. it is reporting the power margin per user equipment . The threshold value can be, for example, defined as a percentage of the maximum the user equipment is allowed to use.
According to a further embodiment of the invention, the MAC control element provides the eNodeB with a power margin per user equipment relative to all uplink protocol data units transmitted in the sub-30 frame. For example, in a 3GPP-based communication system such as LTE-Advanced, the power margin per user equipment could take into account all transmissions on a shared physical uplink channel (PUSCH) and a control channel. physical uplink (PUCCH) within the sub-frame.
In another embodiment of the invention, at least one uplink resource assignment is received, wherein each uplink resource assignment is allocating resources for the transmission of one of the protocol data units on one of the multiple component carriers to the user equipment . For each uplink resource assignment received, a protocol data unit is generated for transmission 10 on the respective assigned component carrier. Each unit of protocol data is transmitted over one of the corresponding component carriers according to one of the received resource assignments.
According to another embodiment of the invention, generating 15 for each received uplink resource assignment a protocol data unit comprises said multiplexing the MAC control element to at least one of said protocol data units. In a further embodiment of the invention, the MAC control element is multiplexed to 20 one of the protocol data units or to each of the protocol data units. Protocol data units can be, for example, generated by performing a joint logical channel prioritization procedure.
According to an advantageous embodiment of the invention, the component carriers each have a priority, and the MAC control element is multiplexed to the protocol data unit to be transmitted on the highest priority component carrier for which a resource allocation has been received.
In an alternative embodiment of the invention, the component carriers have a priority each, and the MAC control element is multiplexed to the protocol data unit to be transmitted on the component carrier achieving the lowest block error rate, having the highest margin of power or having the best channel quality, and for which an allocation of resources per received.
With respect to a further embodiment of the invention, the estimated transmission power is estimated based on . resource assignments for the protocol data units to be transmitted in the sub-frame and in the state of w a function of transmit power.
According to a further embodiment of the invention, radio resource signaling is received by the eNodeB indicating such threshold value as a percentage of the maximum that the user equipment is authorized to use. The threshold value is set according to the indicated percentage.
Another embodiment of the invention provides another alternative method for informing an eNodeB the power state of a user equipment in a mobile communication system using component carrier aggregation. Protocol data units are transmitted in each of a predetermined number of successive sub-frames (monitoring period) from the user equipment to the eNodeB. In the user equipment, a MAC control element is multiplexed to the protocol data units of the last subframe of said predetermined number of successive subframes transmitted by the user equipment, if one of the following conditions is fulfilled: * - the transmission power required to transmit the protocol data units in each of the successive sub-frames exceeds a threshold value relating to the maximum total UE transmit power of the user equipment, or 30 - the transmission power required to transmit protocol data units in a sub-group of sub-frames of said successive sub-frames exceeds a threshold value relating to the total maximum UE transmission power of the user equipment, or - the average transmission power required to transmit the units of protocol data in said successive sub-frames exceeds a threshold value relating to the total maximum UE transmit power of the user equipment. -1 / The MAC control element thus indicates to the eNodeB that the respective condition has been met.
In a further embodiment of the invention, the number of sub-frames in said sub-group is configured by the RRC control signaling received in the user equipment from the eNodeB or is pre-defined.
According to another embodiment of the invention, a MAC control element for transmission from a user equipment to an eNodeB in a mobile communication system using component carrier aggregation is provided. The MAC control element comprises a power margin field consisting of a predetermined number of bits to comprise a power margin per user equipment with respect to all user equipment uplink transmissions on a plurality of component carriers within a sub-frame containing the MAC control element, relative to the total maximum UE transmit power of the user equipment. In a further advantageous embodiment of the invention, * the MAC control element comprises a component carrier indicator field for indicating - the number of the component carrier for which the user equipment has received resource assignments, or - a bitmap indicating the component carriers for which the user equipment has been assigned resource assignments.
In another embodiment of the invention, the power margin field comprises said power margin per user equipment or one protocol data unit per component carrier. The MAC control element comprises a component carrier indicator field which is indicating whether the power margin field comprises said user equipment power margin or said 5th component carrier power margin. * A further embodiment of the invention provides a MAC protocol data unit for transmission from a user equipment to an eNodeB in a mobile communication system using component carrier aggregation. The MAC protocol data unit comprises a sub-header and a MAC control element according to one of the embodiments thereof described herein. The MAC sub-header comprises a logical channel identifier (LCID) which is indicating the content and format of said MAC control element.
According to another embodiment of the invention, a user equipment is provided to inform an eNodeB the power state of a user equipment in a mobile communication system using component carrier aggregation. A user equipment determining section determines whether an estimated transmission power required to transmit protocol data units on the respective 25 component carriers within a sub-frame will v exceed a threshold value relative to the transmission power of
Total maximum EU of user equipment. A protocol data unit generation section of the user equipment multiplexes a MAC control element to the protocol data units 30 if the threshold value is exceeded. A transmit section of the user equipment transmits the protocol data units including the MAC control element to the eNodeB within the sub-frame. The MAC control element indicates to the eNodeB that the transmit power expended by the user equipment to transmit the uplink generated protocol data units has exceeded the threshold value.
In an advantageous embodiment of the invention, the MAC control element provides the eNodeB with a power margin per user equipment relative to all uplink protocol data * units transmitted in the sub-frame.
For another embodiment of the invention, a receiving section of the user equipment receives at least one uplink resource assignment. Each uplink resource assignment is assigning resources for the transmission of one of the protocol data units on one of the multiple component carriers to the user equipment. A protocol data unit generation section 15 of the user equipment generates for each uplink resource assignment a protocol data unit for transmission on the respective assigned component carrier. The transmission section transmits each protocol data unit over one of the corresponding component carriers according to one of the received resource assignments.
According to a further embodiment of the invention, each of the component carriers has a priority, and a protocol data unit generation section of the user equipment multiplexes the T MAC control element to the protocol data unit to be transmitted on the highest priority component carrier for which a resource assignment was received.
In relation to another embodiment of the invention, each of the component carriers has a priority, and a protocol data unit generation section of the user equipment multiplexes the MAC control element to the protocol data unit to be transmitted in the component carrier achieving the lowest block error rate, having the largest power margin or experiencing the best channel quality, and for which a resource assignment has been received.
In a further embodiment of the invention, a user equipment power control section 5 performs power control, and the determining section determines the estimated transmission power based on the resource allocation for the protocol data units to be transmitted. in the sub-frame and the state of a transmit power control section.
According to an advantageous embodiment of the invention, a receiving section of the user equipment receives radio resource control signaling from the eNodeB, indicating said threshold value as a percentage of the maximum that the user equipment is authorized to use.
A user equipment configuration section sets the threshold value according to the indicated percentage.
A further embodiment of the invention provides a computer-readable medium for storing instructions which, when executed by a user equipment processor, cause the user equipment to report to an eNodeB the power state of a user equipment in a system. communication using component carrier aggregation. This is done as follows. It is determined whether an estimated transmit power required to transmit protocol data units on respective component carriers within a sub-frame will exceed a threshold value relative to a total maximum UE transmit power of the user equipment. If the threshold value is exceeded, the MAC control element is multiplexed to protocol data units. The protocol data units including the MAC control element are transmitted to the eNodeB within the sub-frame. The MAC control element indicates to the eNodeB that the transmit power expended by the user equipment to transmit the protocol data units generated on the uplink has exceeded the threshold value. BRIEF DESCRIPTION OF THE FIGURES
In the following, the invention will be described in more detail with reference to the attached figures and drawings. Similar or corresponding details in the figures are marked with the same reference numerals. Figure 1 shows an exemplary architecture of a 3GPP LTE system. Figure 2 shows an exemplary overview of the overall E-UTRAN architecture of LTE. Figures 3 and 4 show an exemplary localized allocation and distributed allocation of uplink bandwidth in a single-carrier FDMA scheme, Figure 5 shows an SAE Carrier Architecture, Figure 6 shows the format of an exemplary MAC PDU , Figure 7 shows the format of a MAC control element for reporting a power margin (PH - "Power Headroom") per component carrier, Figure 8 shows a flowchart of an exemplary operation of a user equipment according to an embodiment of the invention and in accordance with the first aspect of the invention, Figure 9 shows a flowchart of an exemplary operation of a user equipment according to an embodiment of the invention in accordance with the first aspect of the invention, Figure 10 shows the power margin notification in an LTE-A system, where LTE 8/9 known power margin notification is employed for each component carrier individually. Figure 11 shows the power margin notification in an LTE-A system according to an embodiment of the invention, where the exemplary operation of a user equipment according to Figure 8 is employed. Figure 12 shows a notification power margin reporting in an LTE-A system according to an embodiment of the invention, where the exemplary operation of a user equipment according to Figure 9 is employed. Figure 13 shows another exemplary power margin reporting in a LTE-A system according to an embodiment of the invention, where the exemplary operation of a user equipment according to Figure 9 is employed. Figures 14 to 16 show different formats of a MAC CE according to different embodiments of the invention in accordance with the first aspect of the invention, Figure 17 shows an exemplary structure of a MAC PDU according to an embodiment of the invention, wherein the MAC PDU contains three PHR MAC CEs and corresponding subheaders reporting the power margin of three assigned component carriers within a single subframe, Figure 18 shows a MAC CE ("Multiple PHR MAC CE") format according to an embodiment of the invention in accordance with the first aspect of the invention, allowing to report multiple power margin reports on a single MAC CE, Figures 19 and 20 show the Layer 2 structure with carrier aggregation enabled for downlink and uplink respectively. Figure 21 shows a flowchart of an exemplary operation of a user equipment according to an embodiment of the invention in accordance with the first aspect of the invention, where a power scaling signal is used to indicate by signaling a limited power situation from the user equipment to the eNodeB, A Figure 22 shows a flowchart of an exemplary operation of a user equipment in accordance with an embodiment of the invention in accordance with the first aspect. of the invention, where a signaling(s) and power margin report(s) per component carrier are signaled to the eNodeB to indicate a power-limited situation of the user equipment, Figure 23 shows a flowchart of an exemplary operation of a user equipment according to an embodiment of the invention in accordance with the first aspect 15 of the invention, wherein a quantity per component carrier of power reduction and power margin reports per component carrier are signaled to the eNodeB to indicate a power limited situation of the user equipment, Figure 24 shows a flowchart of an exemplary operation 20 of a user equipment in accordance with an embodiment of the invention in accordance with the first aspect of the invention, where a quantity per carrier component of power reduction and reports of power margin per component carrier are signaled to the eNodeB to indicate a power-limit situation. of the user equipment, Figure 25 shows exemplary situations for a UE transmit power state and corresponding power margin, resulting in positive and negative power margins. Figure 26 shows an exemplary situation where the user equipment is with limited power, that is, applying power scaling on component carriers CC#1 and CC#2 configured in the uplink, Figures 27 and 28 show the definition of a power margin per component carrier according to different embodiments of the invention, Figure 29 shows an exemplary structure of a MAC PDU according to an embodiment of the invention, in which Power Scaling (PS) signals are included in the MAC subheads of the MAC PDU. Figure 30 shows a Exemplary structure of a MAC subheader for a PHR MAC CE per component carrier according to an embodiment of the invention, wherein the MAC subheader comprises a series signaling (PS signaling) to indicate that the power margin report was triggered by a user equipment power limiting situation, Figure 31 shows an exemplary structure of a MAC PDU according to an embodiment of the invention, wherein a MAC PDU contains three PHR MAC CEs and corresponding sub-headers reporting the power margin of three component carriers configured within a single sub-frame, wherein the MAC sub-headers include a flag to indicate that the power margin was triggered by a user equipment power limited situation, Figure 32 shows a MAC CE according to an embodiment of the invention, where the MAC CE is indicating the amount of power reduction applied to the component carrier of corresponding uplink, and Figure 33 shows a MAC CE according to an embodiment of the invention, where the MAC CE is indicating the power scaling factor applied to transmission on the corresponding uplink component carrier. DETAILED DESCRIPTION OF THE INVENTION
The following paragraphs will describe the various embodiments of the invention. For purposes of example only, most realizations are outlined in relation to a single-carrier uplink radio access scheme in accordance with the LTE-Advanced (LTE-A) mobile communication system discussed in the Technical Background section above. It should be noted that the invention can be advantageously used, for example, in connection with a mobile communication system such as the previously described LTE-Advanced communication system, but the invention is not limited to its use in this particular exemplary communication network. .
The explanations given in the Technical Background section above are intended to improve the understanding of the exemplary achievements, mostly specific to LTE-Advanced, described in this document and should not be understood as limiting the invention to the specific implementations of processes and functions in the network described of mobile communication. However, the improvements proposed in this document can be readily applied in some embodiments of the invention in the Technical Background section and can, in some embodiments of the invention, also make use of standardized and improved procedures of these architectures/systems.
In the following exemplary description of aspects and embodiments of the invention, it is assumed that the power margin available for uplink transmissions in a user equipment (total maximum UE transmit power) is not defined by component carrier, but by user equipment . As a consequence, the power setting on one component carrier has an influence on the power setting on another component carrier. If the user equipment only includes power margin reports for some of the assigned component carriers, the eNodeB cannot determine how much power was actually expended by the user equipment to transmit the sub-frame and whether the user equipment additionally has power available to a transmission with increased power (ie there is a power margin) in one of the following sub-frames or if there have already been problems and the user equipment has reached its power limit, thus already transmitting on some component carriers with less power than was demanded by the eNodeB. The UE reaching its power limit means that the UE is using or exceeding the total maximum UE transmit power it has available for uplink transmission.
As mentioned earlier in this document, a first aspect of the invention is to allow the UE to indicate to the eNodeB when it is potentially becoming power limited or is power limited, i.e. when it is close to using its full maximum UE transmit power. (also referred to as "user equipment total maximum transmit power", "user equipment total maximum UE transmit power", or "user equipment total maximum UE transmit power" below) or the allocations of eNodeB power control features and commands would require utilizing a transmit power that exceeds the total maximum UE transmit power of the user equipment.
Please note that in this document, the transmission of protocol data units (from MAC) or transport blocks in a sub-frame means that there has been an allocation of resources to a respective one of the protocol data units in a respective one. of the component carriers usable by the user equipment. Usable means that resources can be assigned to the user equipment on each of these component carriers - however, the component carriers on which the user equipment is authorized to transmit data (in the form of protocol data units or transport blocks) within a given subframe are decided by the scheduler (eg implemented in eNodeB) and are controlled by resource assignments to user equipment.
Component (uplink) carriers usable of a user equipment are also called component (uplink) carriers configured in this document. In most examples in this document, configured component carriers are supposed to be active, that is, configured component carrier and active component carrier are synonymous. In this case, it can be assumed that user equipment can be scheduled on configured component carriers. Therefore, the power state of the user equipment will be reported for component carriers for which the user equipment can receive a resource allocation from the scheduler, i.e. configured component carriers (or available component carriers).
Please note that in addition to a configured/unconfigured state of a component carrier, there can optionally be an active/inactive state defined for a configured component carrier. In this case, the user equipment may receive a resource allocation for a component carrier that is configured and active, that is, the user equipment is monitoring resource assignments (eg PDCCH) allocating uplink resources on these configured component carriers and respectively activated. The invention can also be applied in systems where these two types of states are distinguishable, for example, where a component carrier can have the states: not configured, configured, but inactive ("inactive"), and configured and active ("active" ). In these systems, power state notification to a user equipment according to one of the different aspects discussed here can be performed only for active component carriers of the user equipment on the uplink. Furthermore, for these types of systems, the configured component carriers mentioned in the different exemplary embodiments of the invention in this document would correspond to configured and active component carriers (or, for short, active component carriers).
Also, in this document, a transmission on an "assigned component carrier" refers to a transmission of a protocol data unit (MAC PDU) on a component carrier for which the user equipment has received an assignment of resources (also called scheduling grant, grant (abbreviated) or PDCCH).
In an exemplary implementation of the first aspect of the invention, the user equipment signals its uplink power state by means of an indicator to the eNodeB that is indicating whether the user equipment has applied power scaling to the transmit power within the respective sub-frame . The indicator can be provided for each individually configured or assigned component carrier, i.e. the user equipment can include multiple indicators for the protocol data units to indicate, for each assigned component carrier, whether the user equipment has reduced the power of transmission to transmission on the respective component carrier. For example, 0 indicator(s) may be transmitted by the user equipment in the protocol data units (MAC PDUs) of each subframe. Indicators can be, for example, included in one or more MAC subheads of MAC PDUs.
In case the power indicator is provided by assigned component carrier, the respective indicators can, for example, be multiplexed to protocol data units (MAC PDUs) transmitted by the user equipment on the respective assigned component carriers in the uplink, such that each of the indicators can be associated with a respective configured component carrier. For example, this can be accomplished by ensuring that the power state indicator for a given component carrier is multiplexed to a protocol data unit (MAC PDU) that is transmitted on the given component carrier.
Whether the user equipment power state indication is to be done before the user equipment actually reaches its maximum total UE transmit power 15 (proactive uplink power state indication), one or more threshold values (for example , certain percentages) could be set in relation to the total maximum UE transmit power, which when exceeded, triggers the user equipment to set the power state indicator. When set, the indicator would indicate to the eNodeB that the user equipment is close to using the full maximum UE transmit power (ie, has exceeded the threshold value).
Optionally, the power status indicator and threshold value(s) could be set per configured component carrier or individually assigned with respect to the maximum transport power of the respective configured component carrier. Thus, the indicator can be signaled for each assigned uplink component carrier 30 configured individually and can be, for example, included in one or more sub-headers of the MAC PDUs.
In another, second exemplary implementation of the first aspect of the invention, the user equipment is transmitting a power margin report for each configured uplink component carrier (also called power margin per component carrier), if the user equipment is to apply scaling of power to a transmission of MAC PDUs in a given subframe against resource allocations and power control commands. Component carrier (per dc) power margin reports are transmitted along with an indicator that the dc power margin reports have been triggered by the estimated transmit power required to transmit the protocol data units within a given sub. -frame exceeding the total maximum transmit power of the user equipment. Alternatively, the indicator could also be interpreted as an indication of power scaling being applied to transmissions within the given sub-frame by the user equipment due to this event.
Thus, when the transmission power required for a transmission of protocol data units on component uplink carriers within the respective subframe will exceed a total maximum transmit power of the user equipment, an aperiodic DC power margin report for all configured uplink component carriers is triggered and sent to the user equipment. The trigger indication by the DC power margin reports can be, for example, included in a MAC subheader of a MAC PDU carrying a DC power margin report in a MAC control element.
This second exemplary implementation can also be adapted to proactively report the power status of user equipment. Similar to the example described above, one or more threshold values can be set relative to the total maximum UE transmit power, which, when exceeded, triggers the user equipment to send a power margin report for each configured uplink component carrier . If there is no grant available for a component carrier, the user equipment can, for example, calculate the power margin from this component carrier based on some predefined uplink grant or predefined PUSCH power.
In addition, a power margin report for each configured uplink component carrier can optionally be sent along with an indication that the respective power margin report has been triggered by exceeding the total maximum transmit power of the user equipment or a threshold concerning the same. For example, such an indication could be comprised in a MAC subheader of a MAC control element transmitting a power margin report to a configured uplink component carrier of the user equipment.
In accordance with a further third exemplary implementation of the first aspect of the invention, the user equipment reports to the eNodeB the amount of power reduction applied to the maximum transmit power of a component carrier. Alternatively, instead of power reduction for a component carrier, the maximum effective transmit power of the uplink component carrier configured after applying the specific power reduction to the component carrier could be signaled to the eNodeB. The amount of power reduction can be, for example, signaled by configured uplink carrier component of the user equipment. If the power reduction for a given component carrier is considering transmissions on other configured component carriers, the power reduction
applied to component carriers can be made the same (but not necessarily). In a further example, the amount of power reduction can be signaled along with a power margin report for each uplink component carrier configured for the eNodeB.
Information on the power state of the user equipment may be signaled in the form of one or more MAC control elements that are comprised within the MAC PDUs of a given sub-frame.
In another fourth exemplary implementation of the invention, a new MAC control element is defined to allow the UE to indicate to the eNodeB when it is potentially becoming power-limited or is power-limited. This new MAC CE is inserted by the user equipment into one or more protocol data units transmitted on respective component (assigned) carriers within a single sub-frame which is providing the eNodeB with a corresponding indication.
The MAC control element can be inserted into the 20 protocol data units of a sub-frame. For example, the MAC control element can be inserted into one of the protocol data units transmitted by the user equipment within the sub-frame or all protocol data units transmitted by the user equipment within the sub-frame.
Furthermore, in addition to indicating the user equipment is approaching its maximum total UE transmit power, the control element inserted in the protocol data units can additionally indicate a power margin per user equipment (per UE ) .
For example, the power margin per user equipment indicates the power margin not used by the user equipment when transmitting the protocol data units (including the MAC control element) within the sub-frame relative to the maximum transmit power total user equipment. Unlike the power margin indicated in LTE Ver. 8/9, the power margin indicated in the 5 MAC control element is considering transmissions (protocol data units) on all assigned or configured component carriers (ie, more of a component carrier) within the sub-frame and is therefore not a power margin per component carrier, but rather a power margin per user equipment.
In an exemplary embodiment of the invention, this power margin per user equipment is not only taking into account the transmission power required for the transmission of protocol data units over uplink data channels, but also the transmission power. required for the transmission of control signaling over physical control channels. In a more detailed implementation it is thus taking into account the transmission power required to transmit user data and control data (protocol data units) on the assigned or configured component carriers over the shared physical uplink channel (PUSCH) and the physical uplink control channel (PUCCH).
In a fifth implementation of the first aspect of the invention, the user equipment sends power margin reports per DC for all component carriers within a single sub-frame when the user equipment is potentially becoming power limited or has limited power, that is, when it is close to 30 using its total maximum UE transmit power, or the resource allocations and power control commands of the eNodeB would require using a transmit power that exceeds the total maximum UE transmit power of the user equipment. Thus, the estimated transmit power exceeding a given threshold value or the total maximum UE transmit power, as applicable, triggers the generation and transmission of power margin reports per DC within the sub-frame for which one or both the events took place.
Please note that, in accordance with an exemplary embodiment of the invention, the power margin reports per DC for all assigned or configured component carriers are transmitted on the respective assigned or configured component carriers to which they refer. In case of reporting on all configured component carriers, and in case resources are not granted on all configured component carriers for the given sub-frame, the user equipment can assume a predefined resource allocation or alternatively a PUSCH power predefined on those configured component carriers for which no uplink resource assignment is applicable in the given sub-frame.
In the fifth exemplary implementation, a potentially employed prohibit timer controlling power margin notification on a respective one of the assigned component carriers can be overwritten/ignored, so that the power margin reports per DC can be sent in the sub-frame snapshot.
In an alternative exemplary embodiment of the invention, the DC power margin reports may also be transmitted within a single protocol data unit on one of the assigned component carriers. In this example, the respective component carrier to which a respective DC power margin report refers can be, for example, identified by including a component carrier identifier in the power margin reports. Alternatively, there may be a new MAC control element defined ("power margin report for all component carriers") that is indicating the power margins of the assigned or configured component carriers ordered according to the priority of the component carriers to which they refer.
Also, please note that in the first and second aspects of the invention, the decision of the user equipment to be approaching (or in) a power-limited situation can be determined in different ways. In an exemplary implementation, the user equipment determines (or, more correctly, estimates) the transmission power it must expend to transmit the protocol data units on the component uplink carriers within a sub-frame and compares the power of determined (or estimated) transmission with a threshold. This threshold can be, for example, a certain percentage (eg in the range 80% to 100%) of the total maximum UE transmit power. The transmit power required to transmit the protocol data units on the component uplink carriers can be, for example, determined using a transmit power control formula. In other exemplary implementations, the user equipment determines (or, more correctly, estimates) the transmission power it must expend to transmit the protocol data units on assigned component carriers within a sub-frame for a given number of successive sub-frames (ie, a monitoring time period) and decides, based on criteria better outlined below, whether or not to include a MAC control element to indicate a power-limited situation to the protocol data units of the last sub. -frame of said time tracking period.
Regardless of which of the different implementations of the first aspect of the invention is used, the signaled power state information allows the eNodeB to derive the power state for each user equipment that is signaling its power state information. The eNodeB scheduler can, for example, take into account the power state of the respective user equipment in its dynamic and/or semi-persistent 10 resource allocation for the respective user equipment.
A second aspect of the invention is to suggest a definition for a power margin per DC when reporting the power margin in a mobile communication system using carrier aggregation on the uplink. According to an exemplary definition, the power margin per DC of a configured uplink component carrier is defined as the difference between the maximum transmit power of the configured uplink component carrier and the used uplink transmit power. In a 3GPP system, the uplink transmit power used may also be called transmitted PUSCH power. Alternatively, the uplink transmit power used may additionally include the transmitted PUCCH power.
As the used uplink transmit power 25 is considering power sizing (if applied), it may be different from the estimated transmit power, which is the transmit power required for a transmission of MAC PDUs on component uplink carriers within the respective sub-frame as a result of the 30 power control formula. Unused transmit power can therefore be considered to be equal to the product of the power sizing factor and the estimated transmit power. In case no power scaling is applied (scaling factor = 1), the two transmission power values are equal.
Alternatively, a power margin of a configured uplink component carrier can be defined as the difference between the maximum transmit power of the configured uplink component carrier and the estimated transmit power. In a 3GPP system, the estimated uplink transmit power may also be called the estimated PUSCH power. The estimated uplink transmit power, respectively the estimated PUSCH power, is, for example, calculated by the power control formula for the respective uplink component carrier.
In addition, the maximum transmit power of the component uplink carrier (configured) can account for a power reduction due to two simultaneous transmissions on other component uplink carrier(s) in the sub-frame. The maximum transmit power of a configured uplink component carrier may thus not be the same as the total maximum UE transmit power.
The DC power margin according to the second aspect of the invention may be provided in the form of a DC power margin report. The power margin report per DC is, for example, signaled in the form of a MAC control element within a MAC PDU. As mentioned above, the MAC control element carrying the power margin per DC report may be associated with a MAC subheader in a header section of the MAC PDU which can be further employed to indicate that the power margin per DC is triggered by a user equipment power-limited situation requiring power scaling.
In the following, different embodiments of the invention will be outlined. It is assumed in these embodiments that the user equipment is operated in a mobile communication system that is using carrier aggregation and that the user equipment is configured with multiple component carriers, i.e., is capable of transmitting uplink data on multiple carriers components simultaneously within individual sub-frames. Uplink broadcasts are considered to be scheduled by a scheduler through resource assignments. Resources can be assigned in a semi-persistent 10 mode or per sub-frame/per TTI. The scheduler is, for example, implemented in eNodeB.
Furthermore, it should be noted that the scheduler can assign one or more (even all) of the plurality of component carriers configured for a given sub-frame and the user equipment is transmitting a respective transport block/protocol data unit in each assigned component carrier, that is, each component carrier for which a resource assignment has been received. Please note that when using MIMO on the uplink, two or more protocol data units can be transmitted in one subframe on a component carrier, the actual number of protocol data units per component carrier depending on the MIMO scheme . Using 3GPP terminology, resource allocations may also be called grants or PDCCH. Furthermore, there may be a respective transmission power mesh implemented per component carrier configured for the user equipment, i.e. the power margin control function implemented in the user equipment and the eNodeB performs the transmission power control for each component carrier individually.
Furthermore, in a further embodiment of the invention, a joint logical channel prioritization procedure can be used for generating the protocol data units for transmission within a sub-frame. Different exemplary implementations of such a joint logical channel prioritization procedure are described in co-pending European patent application EP 09005727.4 (attorney number EP64934DKFH) and co-pending European patent application EP 09013642.5 (attorney number EP64934IDKFH). The two European patent applications will be referred to as Application 1 and Application 2 below, where appropriate.
POWER MARGIN MAC CE PER EU Figure 8 shows a flowchart of an exemplary operation of a user equipment in accordance with an embodiment of the invention in accordance with the first aspect of the invention. The user equipment receives 801 multiple resource assignments for a given sub-frame and estimates 802 the transmit power (ETP) required for uplink transmissions on assigned component carriers in accordance with the received resource assignments. In an exemplary embodiment of the invention, the transmission power is estimated by the user equipment based on the resource assignments received for the protocol data units to be transmitted in the sub-frame and the state of a transmission power control function. of the user equipment. For example, user equipment can estimate the transmit power required for each transport block depending on which component carrier they are located and based on the state of the transmit power function of the component carrier. The estimated transmit power is then the sum of the individual transmit power for all assigned transport blocks.
The user equipment then determines 803 whether the estimated transmit power (ETP) is exceeding a certain threshold value. In the example in Figure 8, this threshold is defined as a certain percentage P of the maximum total UE transmit power (MATP) of the user equipment. Please note that this would be equivalent to determining whether the ratio of the estimated transmit power (ETP) to the maximum total UE transmit power (MATP) is exceeding the threshold value, which would be equivalent to the percentage P, that is,

If the threshold value has not been exceeded, the user equipment is not in a power-limited situation, so no reports need to be signaled to the eNodeB. Therefore, the user equipment will then generate 804 protocol data units for transmission on the respective assigned component carriers and transmit 805 protocol data units (which are called Physical layer transport blocks) to the eNodeB via of the assigned component carriers. Please note that the generation of protocol data units can be, for example, implemented as described in Order 1 or Order 2.
If the threshold value is exceeded, the user equipment determines 806 the power margin per user equipment for all transmissions according to the resource assignments. As outlined above, this power margin is determined to endow the protocol data units to be transmitted within the given subframe on the assigned component carriers. The power margin per user equipment essentially indicates how much transmission power other than that used to transmit the protocol data units in the sub-frame (estimated transmission power) is missing relative to the total maximum UE transmit power of the user equipment. user. Simply put, the power margin (PH) indicates the difference between the user equipment's total maximum UE transmit power and the estimated transmit power, i.e., PH = MATP-ETP .
The user equipment additionally generates 807 a MAC control element which is comprising the determined user equipment power margin ("Per UE power margin MAC CE") and provides the per UE power margin MAC CE to a protocol data generation section that generates 808 the protocol data units for transmission according to the resource assignments, similar to step 804. However, in step 808, the power margin MAC CE per UE is included in this generation process, so that, depending on the implementation, the power margin MAC CE per UE is included in one of the protocol data units or all of the protocol data units. Subsequently, the generated protocol data units including the UE power margin MAC CE are transmitted 809 to the eNodeB in the allocated resources. Figure 11 shows the power margin notification in an LTE-A system according to an embodiment of the invention, where the exemplary operation of a user equipment according to Figure 8 is employed. In most situations, the operation is corresponding to the operation of the user equipment as outlined in relation to Figure 10 earlier in this document. In contrast to Figure 10, it is assumed that at T6 the user equipment has received three resource assignments for all three component carriers for the sub-frame at T6, however, the transmit power control function is providing a gain factor for transmission so high that, given the resource allocation, the estimated transmit power exceeds the total maximum UE transmit power (see step 803 of Figure 8). Therefore, in this case, the user equipment determines the power margin per UE and multiplexes the power margin MAC CE per UE (also called power-limiting MAC CE below) for the protocol data unit transmitted in the CoCal component carrier. The scheduler on the eNodeB receiving the uplink transmission can now detect, based on the power margin MAC CE per UE, that the user equipment is in a power limited situation and can adapt the additional schedules and/or control the power of the user equipment accordingly.
As evident from the above, the power margin MAC CE per UE can basically have two functions. The first and most important function is that the mere reception of the power margin MAC CE per UE by the eNodeB already informs the eNodeB that a problem with the transmit power for the uplink transmissions existed in the sub-frame. Second, the power margin MAC CE per UE may also be reporting the power margin per user equipment of the user equipment, thus producing more detailed information about the exact power situation in the user equipment to the eNodeB.
In an alternative exemplary implementation according to another embodiment of the invention, the user equipment is not immediately adding a power-limit MAC CE to the protocol data units transmitted on the uplink if the estimated transmission power exceeds the threshold. For example, when the threshold is exceeded, instead of transmitting the power limit MAC CE immediately, the user equipment starts to monitor the estimated transmit power by a certain number of sub-frames, i.e., by a given sub-frame monitoring period. Having monitored the given number of sub-frames, the user equipment decides whether or not a power-limit MAC CE should be included in the protocol data units to be transmitted in the next sub-frame by following certain criteria. Please note that the power limit MAC CE can, for example, be transmitted in the last transmitted sub-frame in the monitoring period, if user equipment 10 decides to enter the same.
These criteria can be, for example: The estimated transmit power of the uplink transmissions in each of the sub-frames within the monitoring period was above a threshold value. The estimated transmit power of the uplink transmission in some of the sub-frames within the monitoring period was above the threshold. The sub-frame number required to send the power cap MAC CE at the end of the monitoring period is configured by eNodeB
The per UE, via RRC signaling or alternatively can be set to a fixed value defined in the specifications. The average estimated transmit power of the uplink transmissions on sub-frames within the monitoring period was above the threshold.
Monitoring the estimated transmit power for a given period of time, ie a certain number of sub-frames, has the advantage that the power-limit MAC CE is not reported immediately when the threshold is crossed, which can avoid unnecessary notifications of a power-limited situation to the eNodeB if the threshold is only exceeded sporadically. However, since the Power Limit MAC CE is indicating an emergency situation to the eNodeB and countermeasures must be taken by the eNodeB after receiving the Power Limit MAC CE, the disadvantage of introducing a monitoring period is the delay in the transmission of power limit MAC CE, once the transmit power of the user equipment has crossed the threshold.
In a further alternative embodiment of the invention, the user equipment is configured with two thresholds. Furthermore, the second "additional" threshold can be, for example, defined by the eNodeB by RRC signaling. This second threshold may, for example, also be a fraction of the total maximum UE transmit power of the user equipment, but is preferably higher than the first threshold. Analogous to the exemplary embodiments discussed above, the user equipment again determines for each sub-frame whether the estimated transmit power of the sub-frame exceeds the first threshold. If this is the case, that is, if the first threshold is exceeded by a sub-frame, the user equipment starts to monitor the estimated transmit power as described in the paragraphs above, for example for a given monitoring period. If the second threshold is exceeded by the estimated transmit power of a sub-frame within the monitoring period, the user equipment transmits a power limit MAC CE within that sub-frame for which the estimated transmit power exceeds the second threshold has been crossed.
In another alternative embodiment of the invention, the user equipment is multiplexing the power-limit MAC CE for each of the protocol data units sent in the sub-frame over the component carriers. This can be advantageous where the reliability of reception of the control element by the eNodeB is increased. POWER MARGIN MAC CE NOTIFICATION FORMAT BY EU
The format for the power margin MAC CE per UE indicating a potential user equipment power limitation ("Power Limit MAC CE") could be based on the LTE Ver. 8/9 MAC CE format used for power margin notification as exemplified in Figure 7. The power margin MAC CE consists of 8 bits, that is, one octet. The first two bits are reserved bits, and the remaining 6 bits indicate the power margin. In one embodiment of the invention, the format is maintained, but the 6-bit field PH of the MAC CE format shown in Figure 7 includes a power margin per UE determined by the user equipment (see, for example, step 806 of Figure 8). Optionally, in an embodiment of the invention, the power margin per UE not only transmits on the PUSCH, but also transmissions on the PUCCH are taken into account when calculating the power margin per UE.
To distinguish the power-limit MAC CE from a LTE Ver. 8/9 power-margin MAC CE, one of the two reserved bits (R) of the octet shown in Figure 8, for example, the highest bit of the octet, is used to differentiate power margin MAC CEs and power limit MAC CEs (i.e., the power margin CEs per UE). For example, if the highest bit in the octet is set to 0, the MAC CE represents a power margin report for that component carrier, that is, a MAC CE per CC reporting a power margin for a given component carrier - MAC CE per DC reporting on the power margin is therefore a component carrier-specific MAC control element. If the bit is set to 1, the reported power margin is the power margin per UE of the power limit MAC CE. Please note that the Power Limit MAC CE (ie Power Margin CE per UE) can be considered to be UE specific, so the Power Limit MAC CE can be considered a UE-specific MAC control element. Please note that the differentiation between UE-specific and component-carrier-specific MAC control elements may lead to different handling and multiplexing from MAC control element to transport block (MAC protocol data units) as explained in Order 2.
When user equipment is sending a power cap MAC CE, it can be of additional value to the eNodeB to gain knowledge about which component carriers the user equipment actually received resource assignments (or uplink grants) for , if the user equipment obeyed all uplink grants correctly, or if one or more of the uplink grants failed. This information allows the eNodeB to determine if the power-limited situation already exists for a situation where the user equipment has not yet transmitted on all of the granted resources due to having failed one or more of the uplink grants.
Therefore, in another embodiment of the invention, another exemplary format for the power-limit MAC CE is proposed, which is including information about the 25 component carriers for which uplink grants have been received, respectively in the number of uplink grants received.
An exemplary format of the power limit MAC CE according to another embodiment of the invention is 30 shown in Figure 14. This power limit MAC CE consists of two fields, a first CCI field (component carrier indicator field - "Component Carries Indicator") and a second PH field (Power Headroom) to indicate the power margin per UE. The power limit MAC CE is again one octet in size.
Assuming there are five component carriers 5 configured for the user equipment, a total of 25 = 32 resource combinations is possible. As the user equipment already indicates when sending data (including the power limit MAC CE) over one of the five component carriers, it is apparent that the user equipment has been granted an uplink grant for this component carrier. Thus, 24 = 16 combinations of resource assignments are left for the other configured component carriers, that is, the CCI field would consist of 4 bits to signal all combinations (eg, indicating via a bitmap, 15 for which of the other four component carriers additional uplink grants were received). Thus, the remaining four bits of the MAC CE format are left for the PH field, allowing to differentiate 16 power margin values per UE. Component carriers other than the one to which the MAC CE is signaled, for which an uplink grant has been received, can be, for example, indicated by means of a bitmap. The actual mapping of which bit in the bitmap represents which component carrier could be, for example, configured by the eNodeB through RRC signaling, 25 or can be determined by a priority order of the component carriers, as, for example, outlined in Order 1 and in Order 2.
In another embodiment, another MAC CE format shown in Figure 15 is suggested. The CCI field is only 3 0 3 bits in size, while the PH field is 5 bits long. This format can be considered a modification of the power margin reporting MAC CE format of LTE Ver. 8/9 in Figure 7 in which the two reserved bits (R) and one additional bit from the PH field are reused as the field CCI. This obviously implies reducing the granularity of the power margin values per UE that can be reported from 6 to 5 bits.
As highlighted in Figure 16, and will be shown in Table 1 below, the MAC CE format for reporting a power margin per UE as shown in Figure 15 allows to indicate the number of component carriers for which the user equipment has been assigned an assignment of 10 uplink, while also indicating whether the MAC control element is a LTE Ver. 8/9 power margin MAC CE or a power margin MAC CE per UE, requiring the assignment of a new identifier. logical channel (LCID) to the new power margin MAC CE per UE, but being able to also use the same LCID for a LTE Ver. 8/9 power margin MAC CE and a margin MAC CE of power per EU. The eNodeB would have to evaluate the first two bits of the control element to determine whether a LTE Ver. 8/9 power margin MAC CE or a 20 power margin MAC CE per UE.

Table 1 If the first two bits are both set to 0, that is, the reserved bits as shown in Figure 7 are set to zero, the MAC control element 5 is a LTE Ver. 8/9 power margin report , as shown in Figure 7.
In any other case, the MAC control element is a power margin MAC CE per UE. If the first two bits are not set to 0, the eNodeB must also evaluate the third bit within the octet, as the first three bits produce the number of uplink grants received by the user equipment. The remaining five bits (see Figure 15) - the PH field - indicate the power margin value per UE.
When user equipment has a power-limited situation, one way the eNodeB can react to notification of the same by a power-limit MAC CE is by reducing the number of component carriers on which the user equipment is simultaneously scheduled. It would be advantageous if the user equipment assisted the eNodeB in choosing which of the resource component carriers should be scheduled for the UE. Therefore, in another embodiment of the invention, the power-limit MAC CE can be used not only to signal the power margin per UE in a PH field, but also to suggest to the eNodeB which component carriers the eNodeB should additionally send assignments to resources. In one example, this is implemented in a manner similar to that described earlier in this document in relation to Figure 14. Instead of indicating the component carriers for which an uplink grant has been received, the four bits of the CCI field can be used to signal a bitmap that indicates on which component carriers (other than the one on which the power-limit MAC CE is received), the eNodeB should continue to provide grants. Alternatively, the bitmap could represent the component carriers to which the eNodeB should stop granting grants.
In a further embodiment of the invention, the MAC CE as shown in Figure 7 is first used for power margin notification per UE. One of the two reserved bits, for example, the first reserved bit shown in Figure 7, is used to identify whether the MAC CE is a LTE Ver. 8/9 power margin MAC CE or a margin MAC CE of power per EU. In both cases, the PH field can be 6 bits long and indicates a margin per CC, as in LTE Ver. 8/9 or power margin per UE. In addition, the MAC control element is a power margin MAC CE per UE, the component carrier on which the control element was transmitted is the component carrier to which the user equipment is suggesting the eNodeB to continue assigning resources .
As indicated above, the MAC control element formats discussed above in relation to Figure 7, and Figures 14 through 16, have the advantage that - compared to LTE Ver. 8/9 - no logical channel identifier needs to be assigned for the power margin reports by EU. As shown in Figure 6, a MAC PDU outputs the format of the MAC control elements included in the MAC PDU payload by respective logical channel identifiers in the subheader of the respective MAC control elements. In another embodiment of the invention, a new logical channel identifier (LCID) is defined to indicate one power margin MAC CE per UE. Thus, this embodiment of the invention provides a MAC PDU comprising a subheader ("per UE power margin MAC CE subheader") and the related MAC CE. The power margin MAC CE subheader per UE comprises an LCID that is identifying the MAC CE as being a power margin MAC CE per UE.
The format of the power margin MAC CE per UE can again be that described in one of the embodiments related to Figures 7, 14 or 15 above, however, no indication of a LTE 8/9 power margin MAC CE is need to be included in the format definition, as the differentiation between the LTE Ver. 8/9 power margin MAC CE and the power margin MAC CE per UE is now achieved through the LCID in the subheader of the MAC PDU. COMPONENT CARRIER SELECTION TO TRANSMIT THE EU POWER MARGIN MAC CE
When the user equipment includes the power limit MAC CE in the protocol data units transmitted in the given sub-frame, the transmit power that is available for UL transmissions is already critical. Therefore, the most reliable component carrier transport block needs to be chosen for inclusion of the power limit MAC control element.
The criteria for selecting the most reliable component carrier can be based on the following conditions. One option would be to choose the component carrier which is the "special cell", i.e. the component carrier where the UE camps out and reads system information. Another option would be to choose, from the set of component carriers with UL transmissions, the one with the best physical parameters. Parameters could be, for example, the target BLER or the actual power margin of a component carrier. Furthermore, if a ranking by priority of the component carriers is already known by the UE, the UE could send the power limit MAC CE on the component carrier with the highest priority. SETTING THE THRESHOLD VALUE
In each sub-frame where the user equipment has resources assigned for uplink transmission on at least one of its aggregate component carriers, the user equipment can calculate the 94/125 transmit power required to fulfill all uplink concessions ( resource allocations) in that subframe, that is, it determines the estimated transmit power required in the subframe. As explained above, a threshold can be configured with respect to the total maximum UE transmit power, which essentially indicates the maximum transmit power that the user equipment is authorized (or able) to spend on all uplink transmissions in the component carriers in a given sub-frame.
The threshold can be, for example, set by the eNodeB in relation to the total maximum UE transmit power. The threshold can be, for example, set by the eNodeB for each user equipment individually and the threshold value could be, for example, transmitted to respective user equipment through RRC signaling. The threshold can be, for example, a fractional value of (or percentage P) of the total maximum UE transmit power. As outlined above, in case the user equipment requires more power for all 20 uplink transmissions on the component carriers than defined by the threshold value or the total maximum UE transmit power, an indication of the equipment power state For example, a power-limit MAC CE is included in subframe uplink transmissions.
It should be noted that the estimated transmit power of the user equipment may not only cross the configured threshold, but may even be above the maximum available power of the user equipment. In the latter case, the user equipment is already in a severe power-limited situation, and cannot fulfill all uplink resource assignments as demanded by the eNodeB.
In addition, it should also be noted that, according to all aspects and realizations of the invention, the user equipment power state notification does not necessarily need to be proactive, ie, ETP > P • MATP , but that the value of threshold cannot be used (P = 1 ) . Basically, this means that the user equipment is triggered to report the power state when the estimated transmit power exceeds the total maximum US transmit power (ie, ETP > MATP}. In this case, the power state information (indicator, power limit MAC CE, etc.) indicate whether, respectively, the user equipment has applied power scaling on the given sub-frame, while, in case of using a threshold value, the power state information they may have already been signaled before the user equipment had to use power scaling on the component carriers. POWER SIZING SIGNALING
According to another exemplary embodiment of the invention in accordance with the first aspect of the invention, the user equipment is not sending any detailed information to the eNodeB regarding its power state, but indicates to the eNodeB in each transmission whether the user equipment has applied power scaling to uplink transmissions or not. For this purpose, one or more indicators can be comprised in the protocol data units transmitted by the user equipment. This indicator is also called power scaling signal. Power scaling signaling may be provided on one of the assigned component carriers or on all assigned component carriers. For example, power scaling signaling to be transmitted on a given component carrier can be included in a protocol data unit transmitted on a given assigned component carrier.
According to an embodiment of the invention, power scaling signaling is defined in one of the two reserved/unused bits of a MAC PDU subheader known by the LTE Ver.8/9 subheader format. If power scaling (PS) signaling is enabled (e.g. = 1), the estimated transmit power for transmissions within a sub-frame has been reduced, i.e. the estimated transmit power has exceeded the UE power total maximum. If PS signaling is not enabled (eg = 0), the user equipment has not applied power scaling within the sub-frame.
Alternatively, if PS signaling is provided for individual configured component carriers, the signaling indicates whether the transmit power, e.g., PUSCH power, for the respective configured component carrier has been reduced. For example, if uplink control information (UCI) is multiplexed with a transport block (MAC PDU) for an assigned uplink component carrier at the physical layer, transmission on this assigned uplink component carrier it may not be reduced, although other PUSCH transmissions on the other component uplink carriers - comprising uplink control information - are power sized.
In 3GPP based system using uplink carrier aggregation, like LTE-A, activation of PS signaling may indicate that the PUSCH power for the corresponding transport block (MAC PDU) has been reduced due to power limitations. Consequently, the bit set to zero indicates that no power scaling has been applied. Figure 29 shows an exemplary MAC PDU in accordance with an embodiment of the invention. Since there is a MAC PDU subheader in the MAC PDU for each MAC SDU (Service Data Unit) that contains RLC PDUs of a logical channel (identified by the LCID) which has data in MAC PDU, PS signaling can be enabled on any, all or a subset of MAC PDU subheaders within a given MAC PDU. In principle, this is sufficient if only one of the MAC PDU subheads, for example the first MAC PDU subhead of a MAC PDU, contains a power scaling signal (PS signaling). This can simplify the processing of MAC PDUs in the user equipment and in the eNodeB, since only one bit would need to be set in one of the MAC PDU subheads, respectively analyzed by the eNodeB.
Furthermore, as already mentioned above, it could alternatively be defined that instead of enabling power scaling signaling when power-limited, signaling could be enabled when the required uplink transmit power exceeds a certain pre-defined threshold or signaled from the maximum allowable transmission power.
According to another exemplary embodiment of the invention, power margin reports per DC for the configured or assigned component carriers may be triggered if the estimated transmit power for a given sub-frame exceeds the total maximum UE transmit power or one threshold related to it. This will be outlined in more detail below. In this embodiment, power state signaling (or also called power scaling signaling) is signaled along with the DC power margin reports. Thus, a power state signaling is provided in each MAC PDU subheader for the MAC CE comprising the power margin per DC for the respective assigned or configured component carrier. In this embodiment, the power state signaling can thus be considered as an indication that the signaled per DC power margin report within the MAC CE of the MAC PDU for given assigned or configured component carriers has been triggered by the estimated transmit power for a given sub-frame exceeding the total maximum UE transmit power or a threshold value related thereto. Alternatively, the power state signaling could be signaled using one of the two reserved/unused bits in the MAC control element itself containing the DC power margin report.
Figure 30 shows an exemplary embodiment of a MAC PDU subheader for a power margin reporting MAC CE including power state signaling. In case the MAC PDU with the DC power margin MAC CE for a configured component carrier is signaled on the respective assigned component carrier, no identification of the component carrier to which the DC power margin MEC CE belongs.
In case the DC power margin MAC CE is to be signaled to a configured component carrier for which no resource allocations are available in the given sub-frame, the user equipment can, for example, calculate the power margin from this component carrier based on some predefined uplink grant or respectively predefined PUSCH power. Power margin MAC CEs per DC for the configured component carrier can be signaled in a MAC PDU on an assigned component carrier. Figure 31 shows an exemplary MAC PDU comprising power margin MAC CEs per DC for three configured component carriers of a user equipment. In this exemplary embodiment, special logical channel identifications (LCIDs) are defined for the respective component carriers so as to be able to associate the per-DC power margin MAC CEs with the respective component carrier to which they refer. Figure 21 shows a flowchart of an exemplary operation 10 of a user equipment in accordance with an embodiment of the invention in accordance with the first aspect of the invention. The user equipment receives 2101 (similar to step 801 of Figure 8) multiple resource assignments for a given sub-frame and estimates 2102 (similar to step 802 of Figure 8) the transmission power (ETP) required for uplink transmissions in component carriers assigned according to resource assignments received. In an exemplary embodiment of the invention, the transmission power is estimated by the user equipment based on the resource assignments received for the protocol data units to be transmitted in the sub-frame and the state of a transmission power control function. of user equipment as explained in relation to Figure 8 above.
Then, the user equipment determines 2103, if the estimated transmit power (ETP) is exceeding the total UE transmit power (MATP or Pr.,AV ) • IF the maximum total UE transmit power is not exceeded, the user equipment is not in a power-limited situation, so no power status reports from it need to be signaled to the eNodeB. Therefore, the user equipment will generate 2104 (similar to step 804 of Figure 8) thereafter the protocol data units for transmission on the respective assigned component carriers. Please note that the generation of the protocol data units can be, for example, implemented as described in Order 1 or 5 Order 2. For example, as part of this step 2104 generation process, the user equipment additionally defines 2105 one or more indicator(s) - that is, power scaling signal(s) - in the MAC PDUs to indicate that no power scaling has been applied by the user equipment to the transmission of PROTOCOL DATA UNIT PDUs OF MAC PDUs generated in step 2104. For example, each MAC PDU may comprise a power scaling signaling in one or more of the MAC PDU subheaders for each component carrier on which the 15 MAC PDUs are transmitted in step 2106.
In case the transmission power exceeds the total maximum UE transmission power in step 2103, the user equipment will then generate 2107 (similar to step 2104 of Figure 21) the protocol data units 20 for transmission on the respective component carriers additionally assigned 2108 sets one or more indicator(s) - i.e., power scaling flag(s) - in the MAC PDUs to indicate that the power scaling has been applied by user equipment to transmit power, i.e. PUSCH power, of the MAC PDUs. For example, each MAC PDU may comprise a respective power scaling signaling in one or more MAC PDU sub-headers for a given assigned component carrier that indicates whether the respective transmit power for transmitting on the component carrier has been scaled.
In addition, the user equipment 2109 performs a power sizing to reduce the transmit power for at least one of the assigned component carriers to reduce the overall transmit power for transmissions on the assigned component carriers below (or equal to) the power of maximum UE transmission. As explained above, no power scaling can be applied to transmission on a component carrier if, for example, uplink control information is transmitted on this component carrier along with the MAC PDU in a given sub-frame, i.e. also called PUSCH with UCI as explained above. The MAC PDUs are then transmitted 2110 on their assigned component uplink carriers using the reduced transmission power.
Please note that the order of steps 2107 to 2110 in Figure 21 may not represent the chronologically correct order of steps over time as some of the steps may require interaction - as evident from the explanations above. SYNCHRONOUS DC POWER MARGIN REPORTS IN A SUB-FRAME
In accordance with the first aspect of the invention, another implementation and alternative embodiment of the invention to inform the eNodeB of a user equipment power limited situation, the user equipment sends a DC power margin report for each configured or assigned component carrier of the sub-frame to inform the eNodeB of a situation where the user equipment is close to using its full maximum UE transmit power or the eNodeB power control command resource allocations would require using a transmit power that exceeds the power maximum total UE transmission rate of the user equipment. The power margin per DC can be, for example, defined according to one of the definitions provided in the section "Definition of Power Margin Per DC" below.
CC reports are sent within a single sub-frame on the uplink. Basically, this can be thought of as setting a new trigger to send power margin reports.
Optionally, to identify that the power margin report for a component carrier is not aperiodic, respectively, triggered by a power limited situation, a bit in the MAC PDU subheader of the MAC CE for the DC power margin report (CE of MAC of PHR per CC) could be used, similar to the power state signaling described above. Therefore, also in this embodiment, one of the two reserved bits in the MAC PDU subhead corresponding to the PHR MAC CE per CC is used for power limitation indication and/or this being the cause for transmission of the power margin report . The logical channel identification (LCID) of the power margin report triggered by power capping via the PHR MAC CE by DC can be the same as for the power margin report triggered by periodic notification or by loss change by path, for example 11010 as shown in Figure 30 (PS signaling would indicate that the corresponding MAC CE contains a power margin report triggered by power capping). Alternatively, the signaling could be signaled using one of the two reserved/unused bits in the MAC control element itself containing the DC power margin report.
In another implementation, instead of using a flag, a new LCID can be defined to indicate that the power margin reporting for an assigned or configured uplink component carrier has been triggered by power capping.
In a further exemplary implementation, individual LCIDs could be defined for the configured uplink component carriers so that the LCID can be used to indicate which uplink component carrier configured the MAC CE (and the power margin report of the same) belongs. Figure 31 shows a MAC PDU comprising PHR MAC CEs per CC for three configured component carriers (CoCal, CoCa2 and CoCa3) of a user equipment according to an exemplary embodiment of the invention. In the subheader section of the MAC PDU, three MAC subheaders are provided which include special LCIDs defined for the respective component carriers configured for the user equipment on the uplink (LDIC CoCal, LCID CoCa2, and LCID CoCa3). Based on the LCIDs in the MAC PDU subheads, the eNodeB can associate the power margin reports per DC in the MAC CEs within the MAC PDU load section to the respective configured component carriers of the user equipment.
Please note that in this example the same LCID is used regardless of trigger. Therefore, the subheader for the respective PHR MAC CEs per CC comprises a signaling in the first (or second) bit of the subheader 25 (similar to power scaling signaling) which, when enabled, respectively not enabled, indicates that the reporting of power margin in PHR MAC CE per DC is an event-triggered power margin report triggered by a power-limited situation. If the component carrier-specific LCIDs 30 are only for power margin reporting due to a power-limited situation, no sub-header signaling is required.
In this exemplary embodiment, the user equipment may optionally reuse the power margin notification mechanism (including the user of periodicPHR-Timer and prohibitPHR-Timer} timers and its format as shown in Figure 7 known to by LTE Ver. 8/9 for each respective report sent in the sub-frame. When the user equipment is in a situation where it is close to using its maximum total UE transmit power or the resource allocations and power control commands of the eNodeB would require using a power of transmission that exceeds the total maximum UE transmit power of the user equipment, the user equipment will send on each assigned component carrier a DC power margin report as known by LTE Ver. 8/9 for the respective component carrier. to do this, the user equipment ignores the prohibitPHR-Timer timer, if it is running. multiple power margin reports per DC, periodicPHR-Timer and prohibitPHR-Timer timers can be reset.
Upon receipt of all power margin reports in the sub-frame, the eNodeB has the complete picture of the total power status of the user equipment.
In a further exemplary implementation according to another embodiment of the invention, power margin reports per DC on all configured or assigned component carriers could be sent on only one MAC PDU on one of the assigned component carriers. The selection of this component carrier on which power margin reports are to be sent can be implemented as described earlier in this document (see, inter alia, the section on Component Carrier for transmitting power margin MAC CE per UE).
In an exemplary implementation of this realization, multiple power margin reports per DC could be included in a MAC PDU. An exemplary format of a MAC PDU containing multiple PHR MAC CEs is shown in Figure 17, where a report of three power margin reports referring to the assigned component carriers CoCal, CoCa2 and CoCa4 is exemplified.
The MAC PDU primarily comprises the component carrier-specific Logical Channel IDs (LCIDs) within the respective sub-header field which allows the identification of reported component carriers and indicates that the MAC PDU load section comprises three PHR MAC CEs . Each subheader (indicating the LCID) has 8 bits (one octet), where the first two bits of the octet are reserved bits (R), and the third bit (E) indicates whether the next octet in the MAC PDU is another subheader of the MAC PDU header or if the MAC PDU payload section is following the octet (that is, if the next octet is the PHR MAC CE in this example), and the last 5 bits are the LCID.
For example, if the E bit is on (eg 1), another subhead is presented in the next octet of the MAC PDU; if the E bit is not set (eg 0) , the next octet is part of the MAC PDU load section that is considered to start with the first PHR MAC CE.
In another alternative implementation, power margin reports relating to multiple component carriers may also be included in a single MAC control element ("Multi-PHR MAC CE").
The multiple PHR MAC CE comprises in its first octet a 5-bit bitmap indicating for which component carrier a PHR field is included in the multiple PHR MAC CE. A priority order of component carriers, as described in Order 1 and Order 2, may define the meaning of individual bit positions within the bitmap. In general, an enabled bit (eg 1) at a certain position in the bitmap means that there is a PHR field for the associated component carrier including in the MAC CE. Following the octet comprising the component carrier bitmap, the respective PHR field(s) with the power margin value for the component carrier is/are included. The PHR field may, for example, have the same format as shown in Figure 7, and report the power margin (PH) for a component carrier. An example of a PHR MAC CE, where a report of three power margin reports on assigned component carriers CoCal, Coca3 and CoCa4 is exemplified in Figure 18.
Please note that for this alternative implementation, LTE Ver. 8/9 power margin reports and multiple PHR MAC CEs could use the same logical channel identifier, and the two formats can be distinguished by enabling or not enabling activating the first or second bit reserved in the first octet of the control element. Obviously, the multiple PHR MAC CE can also have its own logical channel identification (LCID) assigned in the MAC PDU header.
The multiple PHR MAC CE can additionally have its own logical channel identification assigned, so that it can be identified by corresponding sub-headers in the MAC PDU header (see Figure 6). Figure 9 shows a flowchart of an exemplary operation of a user equipment in accordance with an embodiment of the invention in accordance with the second aspect of the invention. Similar to Figure 8, the user equipment receives 801 multiple resource assignments for a given sub-frame and estimates 802 the transmission power (ETP) required for uplink transmissions on assigned component carriers according to received resource assignments. The user equipment then determines 803 whether the estimated transmit power (ETP) is exceeding a certain threshold value. If the threshold value has not been exceeded, the user equipment is not in a power limited situation, then that report of the same needs to be signaled to the eNodeB. Therefore, the user equipment will then generate 804 protocol data units for transmission on the respective assigned component carriers, and transmit 805 protocol data units (which are called Physical layer transport blocks) to the eNodeB via of the assigned component carriers. Please note that the generation of protocol data units can be, for example, implemented as described in Order 1 or Order 2.
If the user equipment is in a power-limited situation as determined in step 803, the user equipment determines 906, for each component carrier for which a resource assignment has been received, a power margin per DC.
Then, the user equipment may generate 907 for each component carrier assigned an individual DC power margin MAC CE (for example, using the format shown in Figure 7) and additionally generate 908 the MAC PDUs including each CE of Corresponding DC power margin MAC according to resource assignments. Subsequently, the user equipment transmits the PDUs including the power margin MAC CEs per DC on the component carriers assigned to the eNodeB.
Please note that, alternatively to steps 907 and 908, there could also be a single PHR multiple MAC CE formed and transmitted in one of the MAC PDUs as outlined above. Figure 12 shows the power margin notification in an LTE-A system according to an embodiment 5 of the invention, where the exemplary operation of a user equipment according to Figure 9 is employed. In most situations, the operation corresponds to the operation of the user equipment as outlined in relation to Figure 10 earlier in this document. In contrast to Figure 10, it is assumed that, at T6, the user equipment has received three resource assignments for all three component carriers for the sub-frame at T6, however, the transmit power control function is producing a factor. of gain for transmission so high that, given the allocation of 15 resources, the estimated transmit power exceeds the maximum UE transmit power of UE (see step 803 of Figure 9). Therefore, in this case, the user equipment determines the DC power margin values for all three component carriers and sends PDUs each comprising a DC power margin report for the respective component carrier in the uplink. As can be recognized from Fig. 12, the prohibitPHR-Timer timer is running in T6 for the CoCa3 component carrier, but is ignored by the user equipment.
After sending the DC power margin reports, the respective timers are reset for each component carrier. Figure 13 shows another exemplary power margin reporting in an LTE-A system in accordance with an embodiment of the invention, where the exemplary operation of a user equipment in accordance with Figure 9 is employed. The example shown here is the same as in Figure 12, except that the user equipment has only resources assigned on the component carriers CoCal and CoCa3 to the sub-frame in T6. Similar to Figure 12, the user equipment is additionally in a power-limiting situation for this sub-frame, but sends a single multiple PHR MAC 5 CE in the PDU transmitted on the CoCal component carrier that reports the power margins for the CoCal and CoCa3 component carriers. Then, the periodicPHR-Timer and prohibitPHR-Timer timers are reset for the component carriers for which a power margin report per DC has been sent, i.e., the component carriers CoCal and CoCa3 in this example. Figure 22 shows a flowchart of an exemplary operation of a user equipment in accordance with an embodiment of the invention in accordance with the first aspect 15 of the invention. User equipment receives 2101 (similar to step 801 of Figure 8) multiple resource assignments for a given sub-frame and estimates 2102 (similar to step 802 of Figure 8) the transmission power (ETP) required for uplink transmissions in component carriers assigned 20 according to resource assignments received. In another exemplary embodiment of the invention, the transmission power is estimated by the user equipment based on the resource assignments received for the protocol data units to be transmitted in the sub-frame and the state of a power control function 25 transmission from the user equipment as explained in relation to Figure 8 above. In addition, the user equipment determines 2103, whether the estimated transmit power (ETP) is exceeding the maximum total UE transmit power (MATP or PCMAx ) ■
If the total maximum UE transmit power is not exceeded, the user equipment is not in a power-limited situation, so no power status reports of the same need to be signaled to the eNodeB. Therefore, the user equipment will then generate 804 protocol data units for transmission on the respective assigned component carriers. The generation 5 of protocol data units can be, for example, implemented as described in Order 1 or Order 2. Then, the user equipment transmits 805 the MAC PDUs to the eNodeB.
If the estimated transmit power exceeds 10 total maximum UE transmit power in step 2103, the user equipment generates 2201 for each configured (alternatively assigned) uplink component carrier a respective power margin report (power margin report per CC) and additionally generates 2202 for each configured component carrier an individual power margin MAC CE per CC (e.g., using the format shown in Figure 7). If no uplink grant is available for a given component carrier, the user equipment can, for example, assume a predefined resource allocation or, alternatively, a predefined PUSCH power on those configured component carriers for which the assignment of uplink resources is not applicable on the given sub-frame.
The user equipment then forms 2203 the 25 MAC PDUs including the power margin MAC CEs per DC. MAC PDUs are formed according to resource assignments. Subsequently, the user equipment transmits the PDUs including power margin MAC CEs per DC on the component carriers assigned to the eNodeB.
If the transmission identification of the power margin reports in the PHR MAC CEs per CC triggered by the estimated transmit power of the sub-frame exceeding the total maximum UE transmit power is not otherwise provided, the user equipment may optionally enable 2204 flags - that is, flags - on the MAC PDUs to indicate the cause of sending the DC power margin reports. For example, each MAC subheader for a PHR MAC CE or each PHR MAC CE may comprise a respective signaling that indicates whether the estimated transmit power has exceeded the total maximum UE transmit power.
In addition, the user equipment performs power scaling 2109 to reduce the transmit power for at least one of the assigned component carriers to reduce the overall transmit power for transmissions on the assigned component carriers below (or equal to) the transmit power of maximum EU. As explained above, no power scaling can be applied to transmission on a component carrier if, for example, the uplink control information is transmitted on this component carrier along with the PDU in a given sub-frame, i.e. also called PUSCH with UCI. The MAC PDUs including the PHR CEs per CC are then transmitted 2206 on the respective assigned uplink component carriers using the reduced transmit power.
Please note that the order of steps in Figure 22 may not represent the correct chronological order of steps over time as some of the steps may require interaction - as evident from the explanations above. DEFINITION OF POWER MARGIN BY CC
Currently, there is no clear definition for the component carrier-specific power margin report. For example, it is still unclear whether the (nominal) power reduction applied to the maximum transmission power specific to the component carrier (PCMAX c) takes into account only the uplink transmission (resource allocation) in the corresponding DC or also transmissions in other assigned component uplink carriers. For example, if there are 5 uplink transmissions scheduled on multiple component carriers simultaneously, the amount of power reduction, sometimes called power back-off, can be increased to avoid unwanted emissions. Simultaneous transmission of PUSCH and/or PUCCH between aggregated components or PUSCH grouped within a component carrier can generate products between additional modulations in the UE transmission chain which may consequently need a transmitter back-off to meet the ALCR requirements. Definition of PH 1
In an exemplary embodiment of the invention, as shown in Figure 28, the power margin per DC is not taking into account the power scaling on a given component carrier. The power margin is defined as the difference between the maximum transmit power of the PCMAX component carrier c (after power reduction) minus the estimated transmit power of the UE for the component carrier c prior to scaling. The estimated transmit power of the UE for the component carrier c can be given by a transmit power control of the user equipment for the component carrier c.
In an exemplary implementation and in accordance with this realization, the power margin per DC can be, for example, determined as described in 3GPP TS 36.213, version 8.8.0, section 5.1.1 already mentioned earlier in this document. Thus, Equation 2 above is reused and applied to the respective component carriers configured or assigned as follows.
The power margin per DC PHc(f) of the component carrier c can be, for example, defined as PHc(i) ~ PCMAX,c {10 • logu)(AfpuscH c(0) + PQ PUSCH,c Ü) + ac (j)-PLc + ^i) + fc(i)} Equation 3 where PCMAX c is the maximum transmission power of a component carrier c (after power reduction), obeying: PPP _ ICMAX_L,c< *CMAX,c < 1CMAX _H,c _ PCMAX_L ~ m^n(P/:MAX,c ~ ^Pc'Ppowers ~ MPRC ~ AMPRC — &TC) _ PCMAX _H,C ~ mln(P/-:MAX ,c'PpowerClass')
The index c of the different parameters indicates that this is for the component carrier c. Also, some of the parameters in the equation may be EU specific. The meaning of the parameters in Equation 3 are defined differently than in the Technical Background section (for the respective component carrier c, where applicable, or by user equipment).
The estimated transmit power -PPUSCH,CO) of the UE for the component carrier c as given by a user equipment transmit power control for the component carrier c can be defined as follows: ^PUSCH.C(z) — min{/'CMAXc,101og]0(ÀfpUSCHc(z)) + ^0_PUSCH,c (j) + «c 0) ■ PLc + ΔTF,C (0 + fc (0) Equation 4 Definition of PH 2
In an exemplary embodiment of the invention, as shown in Figure 27, the power margin per DC is taking into account the power sizing on a given component carrier (if applied). The power margin is defined as the difference between the maximum transmit power of the component carrier PCMAX,C (after power reduction) minus the used transmit power of the UE for the component carrier c after potential power scaling.
In one example, the used transmit power of the UE for the component carrier c after power scaling is the transmitted PUSCH power P/,SPUSCH,C(/) of subframe i as defined by: P PUSCH.C(0 = PSFC • min{PCMAX c, 10 log|0(A/PLJSCH^c (/)) + ^%_PUSCH,c (/) + G) ■ PLC + ΔTF c (i) + fc (i Equation 5 where PSFC is the factor of power scaling applied to the respective configured uplink component carrier c.k PpsPUSCH,c(í) can also be expressed as: P PUSCH.c (0 = PSFC • PpusCH,c (f) Equation 6 where PpTTcrM.O' ) is the estimated transmit power for component carrier c according to the applicable resource allocation within sub-frame i: ^PUSCH.c ( ) = min{PCMAKc,101og10(MPUSCHc(/)) + ^0_PUSCH, c (y) + «c (y) • PLc + ΔTF,C (0 + fc (0) Equation 7
According to Definition 2, the power margin can be expressed as: PHC(Í) = PCMAX,C - PpsPUSCH,c(i) Equation 8 Optionally, the power reduction applied to the maximum (nominal) transmit power of a Component carrier can be determined by taking into account simultaneous uplink transmissions on other aggregated component carriers. For example, the maximum rated transmit power for a PCMAX H,C component carrier is reduced by a PR power reduction that takes into account uplink transmissions on other aggregated component carriers within a given sub-frame. The result of applying power reduction defines the maximum transmit power of the component carrier PCMAx,c • PcMAX _L,c — PcMAX,c = ^CMAX_H,c ~ P^c — PcMAX _H,c Equation 9 where PRC < MPRC . Thus, PCMAX c in Equation 3 and Equation 8 can optionally include applied power reduction PR which can optionally take into account uplink transmissions on aggregated component carriers within a given sub-frame.
Optional Enhancements In Equations 3 through 9 above, the parameters comprising index c can be specific to the component carrier. However, some or all parameters can be additionally configured or defined per UE. For example, the parameters /’o PUSCHCÜ) AND aÁf) can be defined per UE.
Furthermore, a power margin according to Definition 2 should, in principle, never be negative, since the total used transmit power, i.e. the sum of all uplink transmit powers on all component carriers of uplink allocated, should never exceed (after power scaling) the maximum transmit power of the total UE. On the other hand, a power margin according to Definition 1 could be negative. In order to have the same range of power margin values for both power margin definitions, a negative power margin value for a power margin according to Definition 2 could therefore be defined to have special meaning. For example, it could be defined that a negative value indicates that the transmit power used is a result of power scaling, i.e. the total maximum UE transmit power has been exceeded. Thus, the power margin report would already transmit some information regarding the power state of the user equipment. REPORTING THE AMOUNT OF POWER REDUCTION
As previously mentioned, the eNodeB can be considered as not knowing the maximum power reduction (MPR). As a consequence of this, the power reduction applied by the user equipment to the maximum transmit power of a given component carrier is also unknown by the eNodeB. Thus, the eNodeB essentially does not know the maximum transmit power of the component carrier against which the power margin is calculated. Therefore, according to a further embodiment of the invention, the user equipment informs the eNodeB the amount of power reduction (also called power back-off) applied to an uplink component carrier.
In an exemplary implementation, user equipment signals the amount of power reduction when reporting a power margin. Based on the power margin on the amount of power reduction applied, the eNodeB can calculate the power margin actually used on a given component carrier and thus know the power state of the UE.
Unlike previous exemplary realizations, the amount of power reduction for the assigned or configured uplink component carriers may not necessarily be reported when the user equipment is in or approaching a power-limited situation, but the amount of power reduction power applied to a component carrier may be sent/updated to user equipment periodically or in response to a change beyond a given threshold value, similar to power margin notification. To reduce signaling overhead, the user equipment can only report the amount of power derating if the user equipment is in a power-limited situation or is approaching 10 of it, as exemplified above. Figure 23 shows a flowchart of an exemplary operation of a user equipment in accordance with an embodiment of the invention in accordance with the first aspect of the invention. User equipment receives 2101 (similar to step 15 801 of Figure 8) the transmit power (ETP) required for uplink transmissions on component carriers assigned in accordance with the received resource assignments. In an exemplary embodiment of the invention, the transmission power is estimated by the user equipment based on the received resource assignments for the protocol data units to be transmitted in the sub-frame as explained in relation to Figure 8 above. In addition, the user equipment determines 2103, whether the estimated transmit power (ETP) is exceeding the maximum total UE transmission power 25 {MATP or PCMAX ) •
If the total maximum UE transmit power has not been exceeded, the user equipment is not in a power-limited situation, so no power status reports of the same need to be signaled to the 30 eNodeB. Therefore, the user equipment will generate 804 protocol data units for transmission on the respective assigned component carriers. The generation of the protocol data units can be, for example, implemented as described in Order 1 or Order 2. Then, the user equipment transmits 805 the MAC PDUs to the eNodeB.
If the estimated transmit power exceeds the total maximum UE transmit power in step 2103, the user equipment generates 2201 for each configured (alternatively assigned) uplink component carrier a respective power margin report 10 (margin report of power per DC) and additionally generates 2202, for each configured component carrier, an individual DC power margin MAC CE (e.g., using the format shown in Figure 7). If no uplink grant is available for a given component carrier, the user equipment can, for example, assume a predetermined resource allocation, or alternatively, a predefined PUSCH power, on the configured component carriers for which none assignment of uplink resources is applicable in the given sub- frame. The power margin can be calculated using, for example, Setting 1 or Setting 2 outlined above.
In addition, the user equipment generates 2301, for each component carrier assigned or configured in the uplink, a DC Power Reduction MAC CE that indicates the amount of power reduction (e.g., in dB) that is applied to the respective component carrier. The user equipment then forms 2302 MAC PDUs, DC Power Margin MAC CEs, and 30 Power Reduction CEs per DC. MAC PDUs are formed according to resource assignments.
The DC Power Reduction MAC CE comprises the amount of power reduction applied to the component carrier and can be defined similarly to the PHR MAC CE in LTE Ver. 8, as shown in Figure 32. A new identification of logical channel (LCID) could be reserved for identification of DC power reduction MAC CE.
User equipment performs power scaling 2109 to reduce transmit power for at least one of the assigned component carriers, to reduce overall transmit power for transmissions on assigned component carriers below (or equal to) UE transmit power maximum. The MAC PDUs including the PHR CEs per CC and the DC power-reduction MAC CEs are then transmitted 2303 on the respective assigned uplink component carriers using the reduced transmit power.
Please note that the order of steps in Figure 23 may not represent the correct chronological order of steps over time as some of the steps may require interaction - as evident from the explanations above.
Instead of signaling individual DC PHR CEs and DC power reduction CEs, the DC power margin and DC power reduction applied to the component carrier can also be signaled in a MAC CE. To identify this new MAC CE (Power Reduction and Power Margin), a one-bit signal could be used to indicate the MAC CE format. For example, the signaling could be one of the two reserved (R) bits provided in the MAC subheader. The notification being activated (eg 1) may, for example, indicate that that amount of power reduction and a power margin report according to Definition 1 or Definition 2 are comprised in the MAC CE. Notification not being enabled (eg 0) indicates that only a Power Margin report according to Definition 1 or Definition 2 has been flagged.
Alternatively, instead of signaling the amount of derating, user equipment can signal a power margin report for all configured or assigned component carriers when the derating applied to the maximum transmit power of a component carrier changes beyond a predetermined threshold. Basically, a new trigger for CC PHR notification would be introduced. SIGNALING THE AMOUNT OF POWER SIZING
In another alternative implementation and realization of the invention to inform the eNodeB of a power-limited situation of the user equipment, the user equipment signals the amount of power scaling applied to the different configured or assigned uplink component carriers. The amount of power scaling (in dB) can be, for example, signaled for each uplink component carrier when the user equipment is power limited, i.e. the estimated overall transmit power for the sub-frame exceeds the power of total maximum UE transmission. Figure 24 shows a flowchart of an exemplary operation of a user equipment in accordance with an embodiment of the invention in accordance with the first aspect of the invention. User equipment receives 2101 (similar to step 801 of Figure 8) multiple resource assignments for a given sub-frame and estimates 2102 (similar to step 802 of Figure 8) the transmission power (ETP) required for uplink transmissions in component carriers assigned according to resource assignments received. In an exemplary embodiment of the invention, the transmission power is estimated by the user equipment based on the resource assignments received for the protocol data units to be transmitted in the sub-frame and the state of a transmission power control function. of the user equipment as explained in relation to Figure 8 above. In addition, the user equipment determines 203, whether the estimated transmit power (ETP) is exceeding the total maximum UE transmit power {MATP or MATP}.
If the total maximum UE transmit power is not exceeded, the user equipment is not in a power-limited situation, so no power status reports of the same need to be signaled to the eNodeB. Therefore, the user equipment will then generate 804 protocol data units for transmission on the respective assigned component carriers. The generation of protocol data units can be, for example, implemented as described in Order 1 or Order 2. Then, the user equipment transmits 805 the MAC PDUs to the eNodeB.
If the estimated transmit power exceeds the total maximum UE transmit power in step 2103, the user equipment generates 2201 for each configured (or alternatively assigned) uplink component carrier a respective power margin report (margin report of power per DC) and additionally generates 2202, for each assigned component carrier, an individual DC power margin MAC CE (e.g., using the format shown in Figure 7). If there are no uplink concessions available for a given component carrier, the user equipment can, for example, assume a predefined resource allocation or, alternatively, a predefined PUSCH power, on the configured component carriers for which there are no assignments of uplink resources applicable on the given sub-frame. The power margin can be calculated using, for example, Setting 1 or Setting 2 outlined above.
In addition, the user equipment generates 24 01, for each component carrier assigned on the uplink, a power scaling MAC CE per DC that indicates the power scaling factor (eg, in dB) of the power scaling applied to the transmission of the respective component carrier. The user equipment then forms 2402 MAC PDUs, DC Power Margin MAC CEs, and DC Power Scaling CEs. PDUs are formed according to resource assignments.
For signaling, a new MAC CE can be defined which comprises the power scaling factor (PSF - "Power Scaling Factor"). This power scaling MAC CE could be defined similarly to the PHR MAC CE in LTE Ver. 8 as shown in Figure 33. A new logical channel identification (LCID) could be reserved for MAC CE identification of power scaling per DC.
User equipment performs power scaling 2109 to reduce transmit power for at least one of the assigned component carriers, to reduce overall transmit power for transmissions on assigned component carriers below (or equal to) UE transmit power maximum. The MAC PDUs including the PHR CEs per CC and the power scaling MAC CEs are then transmitted 2403 on the respective assigned uplink component carriers using the reduced transmit power.
Please note that the order of steps in Figure 24 may not represent the chronologically correct order of steps over time as some of the steps may require interaction - as evident from the explanations above.
In an alternative embodiment, the amount of power scaling could be signaled via the power margin report. Instead of reporting the absolute amount of power scaling, the user equipment reports a power margin per DC in accordance with Definition 1, and a power margin per DC in accordance with Definition 2 simultaneously for a component carrier. The eNodeB can then calculate the power scaling amount by taking the difference of the two power margins.
Since reporting a power margin per DC according to Definition 1 and a power margin according to Definition 2 will report the same values when no power scaling is applied, it is only useful to report both power margins if user equipment is power-limited. To distinguish the different notification formats, a reserved bit (R) of the MAC PDU subhead corresponding to the PHR MAC CE per CC can be used. For example, the reserved bit being set (eg 1) indicates that power scaling has been applied, that a power margin per DC in accordance with Definition 1 (or Definition 2) along with the absolute amount of power scaling , or alternatively, a DC power margin in accordance with Definition 1 and a DC power margin in accordance with Definition 2 are reported. The reserved bit not being set (eg 0) may indicate that no power scaling has been applied and the normal DC PHR is reported. IMPLEMENTATION OF INVENTION HARDWARE AND SOFTWARE
Another embodiment of the invention is related to the implementation of the various embodiments described above using hardware and software. In this connection, the invention provides a user equipment (mobile terminal) and an eNodeB (base station). User equipment is adapted to carry out the methods described in this document. In addition, the eNodeB comprises means that allow the eNodeB to determine the power state of the respective user equipment from the power state information received by the user equipment and consider the power state of the different user equipment in scheduling different user equipment by its scheduler.
It is further recognized that the various embodiments of the invention can be implemented or realized using computing devices (processors). A computer device or processor can be, for example, general purpose processors, digital signal processors (DSP), application specific integrated circuits (ASIC), programmable port arrays in field (FPGA - "field programmable gate arrays") or other programmable logic devices, etc. The various embodiments of the invention can also be realized or incorporated by a combination of these devices.
Furthermore, the various embodiments of the invention can also be implemented by means of software modules, which are executed by a processor or directly in hardware. Furthermore, a combination of software modules and a hardware implementation may be possible. Software modules can be stored on any type of computer readable storage media, eg RAM memory, EPROM, EEPROM, flash memory, registers, hard disks, CD-ROM, DVD, etc.
It should further be noted that individual features of the different embodiments of the invention may, individually or in arbitrary combination, be the subject of another invention.
It would be appreciated by one skilled in the art that various variations and/or modifications can be made to the present invention as shown in the specific embodiments, without departing from the spirit or scope of the invention as broadly described. The present embodiments, therefore, are intended to be considered illustrative and not restrictive in all respects.

权利要求:
Claims (14)
[0001]
1. METHOD FOR INFORMING AN ENODEB THE TRANSMISSION POWER STATE OF A USER EQUIPMENT IN A MOBILE COMMUNICATION SYSTEM USING COMPONENT CARRIER AGGREGATION, in which the method is characterized by comprising the following steps performed by the user equipment: generating a power state report that includes a power margin report and a component carrier-specific maximum transmit power for each enabled and configured uplink component carrier, where the component carrier-specific maximum transmit power takes into account an amount of power reduction on the respective configured and activated component uplink carrier and is generated when the user equipment has a resource assignment for the configured and activated component uplink carrier, and transmits the power status report to the eNodeB.
[0002]
2. METHOD, according to claim 1, characterized in that the transmission of the power status report is triggered upon activation of a configured uplink component carrier.
[0003]
3. METHOD, according to claim 1 or 2, characterized in that the power state report takes into account a Physical Uplink Control Channel power, PUCCH, transmitted in the same sub-frame.
[0004]
4. METHOD according to any one of claims 1 to 3, characterized in that, if the power margin report is to be transmitted to a configured and activated uplink component carrier for which there are no resource allocations available in the data subframe, the user equipment generates the component carrier power state report based on a predefined uplink grant or, respectively, a Physical Uplink Shared Channel, PUSCH power.
[0005]
5. METHOD, according to any one of claims 1 to 4, characterized in that the power margin report and the maximum transmission power specific to the component carrier of each configured component carrier are included in a single Control Control element. Media Access, MAC, which is used for multiple power margin notifications with a bitmap, where a bit turned on at a certain position in the bitmap indicates that there is a power margin reporting field for the associated component carrier included in the element MAC control.
[0006]
6. The method according to claim 5, characterized in that the MAC control element for multiple power margin notifications additionally includes indicators indicating the presence of the maximum transmission power specific to the associated component carrier for the power margin report. corresponding power, respectively.
[0007]
7. METHOD, according to any one of claims 1 to 6, characterized in that the maximum transmission power specific to the component carrier is Pcmax,c.
[0008]
8. USER EQUIPMENT TO REPORT TO AN ENODEB THE TRANSMISSION POWER STATE OF A USER EQUIPMENT IN A MOBILE COMMUNICATION SYSTEM USING COMPONENT CARRIER AGGREGATION, where the user equipment is characterized by comprising: a processor to generate a report state indicator that includes a power margin report and a component carrier-specific maximum transmit power for each configured and enabled uplink component carrier, where the component carrier-specific maximum transmit power takes into account a reduction amount of power on the respective configured and enabled component uplink carrier and is generated when the user equipment has a resource assignment for the configured and enabled component uplink carrier, and a transmitter to transmit the power status report to the eNodeB.
[0009]
9. USER EQUIPMENT, according to claim 8, characterized in that the transmission of the power status report is triggered upon activation of a configured uplink component carrier.
[0010]
10. USER EQUIPMENT according to claim 8 or 9, characterized in that the power status report takes into account a Physical Uplink Control Channel power, PUCCH, transmitted in the same sub-frame.
[0011]
11. USER EQUIPMENT according to any one of claims 8 to 10, characterized in that, if the power margin is to be transmitted to a configured and activated uplink component carrier for which there are no resource allocations available in the data subframe, the processor generates the power state report from the component carrier, based on a predefined uplink grant or, respectively, a Physical Uplink Shared Channel, PUSCH power.
[0012]
12. USER EQUIPMENT according to any one of claims 8 to 11, characterized in that the power margin report and the maximum transmission power specific to the component carrier of each configured component carrier are included in a single control element. Media Access Control, MAC, which is used for multiple margin notifications with a bitmap, 5 where a bit turned on at a certain position in the bitmap indicates that there is a power margin reporting field for the associated component carrier included in the MAC control element.
[0013]
13. USER EQUIPMENT according to claim 12, characterized in that the MAC control element for multiple power margin notifications additionally includes an indicator indicating the presence of the maximum transmission power specific to the associated component carrier for the 15 corresponding power margin report, respectively.
[0014]
14. USER EQUIPMENT according to any one of claims 8 to 13, characterized in that the maximum transmission power specific to the component carrier is Pcmax,c.

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同族专利:

---

公开号 | 公开日

---

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---

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---

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---

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---

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---

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---

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---

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---

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---

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---

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---

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---

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---

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---

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---

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---

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---

US20170064649A1|2017-03-02|

---

US20160021624A1|2016-01-21|

---

JP6145902B2|2017-06-14|

---

HRP20181486T1|2018-11-16|

---

EP3383114B1|2019-12-18|

---

EP2497318A1|2012-09-12|

---

LT2497318T|2018-09-10|

---

JP6628067B2|2020-01-08|

---

US20200359340A1|2020-11-12|

---

US20140307681A1|2014-10-16|

---

US20180007642A1|2018-01-04|

---

JP2013509759A|2013-03-14|

---

RS57812B1|2018-12-31|

---

US9179424B2|2015-11-03|

---

US10764843B2|2020-09-01|

---

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---

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---

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---

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---

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---

PT2497318T|2018-10-22|

---

ES2688231T3|2018-10-31|

---

AU2010311871A1|2012-05-24|

---

CN102687577A|2012-09-19|

---

EP2317815A1|2011-05-04|

---

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---

US8811322B2|2014-08-19|

---

US9794894B2|2017-10-17|

---

HUE039501T2|2019-01-28|

---

JP2016158252A|2016-09-01|

---

EP2497318B1|2018-06-20|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

US4456046A|1981-05-11|1984-06-26|Miller Timothy I|High-speed tires|

---

KR100832117B1|2002-02-17|2008-05-27|삼성전자주식회사|Apparatus for transmitting/receiving uplink power offset in communication system using high speed downlink packet access scheme|

---

RU2386213C2|2005-09-22|2010-04-10|Мицубиси Денки Кабусики Кайся|Communication method|

---

US9215731B2|2007-12-19|2015-12-15|Qualcomm Incorporated|Method and apparatus for transfer of a message on a common control channel for random access in a wireless communication network|

---

US20090175187A1|2008-01-07|2009-07-09|Kristina Jersenius|Method and Arrangement for Triggering Power Headroom Report Transmissions in a Telecommunications System|

---

KR20090077647A|2008-01-11|2009-07-15|삼성전자주식회사|Method and apparatus for reporting ue power headroom information in mobile communication system|

---

US8570957B2|2008-03-26|2013-10-29|Nokia Siemens Networks Oy|Extension of power headroom reporting and trigger conditions|

---

US8223708B2|2008-06-10|2012-07-17|Innovative Sonic Limited|Method and apparatus for handling scheduling information report|

---

US9125164B2|2008-06-18|2015-09-01|Lg Electronics Inc.|Method of transmitting power headroom reporting in wireless communication system|

---

KR20150023886A|2008-12-03|2015-03-05|인터디지탈 패튼 홀딩스, 인크|Uplink power headroom reporting for carrier aggregation|

---

WO2010073290A1|2008-12-22|2010-07-01|Nec Corporation|Communication system, user equipment, base station, transmit power deciding method, and program|

---

CN112584476A|2009-02-09|2021-03-30|交互数字专利控股公司|Method for uplink power control in WTRU and WTRU|

---

CN102428731B|2009-03-17|2016-08-24|三星电子株式会社|Uplink transmission power in multi-carrier communications systems controls|

---

EP2244515A1|2009-04-23|2010-10-27|Panasonic Corporation|Logical channel prioritization procedure for generating multiple uplink transport blocks|

---

EP2244514A1|2009-04-23|2010-10-27|Panasonic Corporation|Logical channel prioritization procedure for generating multiple uplink transport blocks|

---

TW201039665A|2009-04-24|2010-11-01|Asustek Comp Inc|Apparatus and method for handling priority of MAC control element|

---

US8437798B2|2009-04-27|2013-05-07|Motorola Mobility Llc|Uplink scheduling support in multi-carrier wireless communication systems|

---

CN101932087A|2009-06-19|2010-12-29|大唐移动通信设备有限公司|Method, device and system for reporting power headroom|

---

US20110080838A1|2009-10-02|2011-04-07|Telefonaktiebolaget Lm Ericsson |Methods and Arrangements in a Mobile Telecommunication Network|

---

EP2317815A1|2009-11-02|2011-05-04|Panasonic Corporation|Power-limit reporting in a communication system using carrier aggregation|

---

CN101778416B|2010-02-10|2015-05-20|中兴通讯股份有限公司|Measuring and reporting method of power climbing space and terminal|

---

US8537767B2|2010-04-06|2013-09-17|Sunplus Technology Co., Ltd|Method for performing power headroom reporting procedure and PHR MAC control element|

---

US8594718B2|2010-06-18|2013-11-26|Intel Corporation|Uplink power headroom calculation and reporting for OFDMA carrier aggregation communication system|

---

CN103155659B|2010-08-13|2016-03-23|黑莓有限公司|Total surplus power in carrier aggregation is estimated|

---

US8798663B2|2010-10-01|2014-08-05|Acer Incorporated|Method of performing power headroom reporting and communication device thereof|

---

EP2774426B1|2011-11-04|2019-01-02|Interdigital Patent Holdings, Inc.|Method and apparatus for power control for wireless transmissions on multiple component carriers associated with multiple timing advances|WO2010135699A2|2009-05-22|2010-11-25|Research In Motion Limited|System and method for transmitting power headroom information for aggregated carriers|

---

EP2317815A1|2009-11-02|2011-05-04|Panasonic Corporation|Power-limit reporting in a communication system using carrier aggregation|

---

EP2360866A1|2010-02-12|2011-08-24|Panasonic Corporation|Component carrier activation and deactivation using resource assignments|

---

JP5216058B2|2010-02-15|2013-06-19|株式会社エヌ・ティ・ティ・ドコモ|Mobile terminal apparatus and uplink control information signal transmission method|

---

US9237526B2|2010-03-12|2016-01-12|Sunrise Micro Devices, Inc.|Power efficient communications|

---

ES2541906T3|2010-05-04|2015-07-28|Telefonaktiebolaget L M Ericsson |Presentation of power margin reports for carrier aggregation|

---

KR101852814B1|2010-06-18|2018-04-27|엘지전자 주식회사|Method of transmitting power headroom information at user equipment in wireless communication system and apparatus thereof|

---

DK3232717T3|2010-06-18|2020-02-10|Ericsson Telefon Ab L M|Methods for providing headroom reports arranged in sequence by component carrier indices and related wireless terminals and base stations|

---

MX2012015138A|2010-06-21|2013-05-28|Nokia Siemens Networks Oy|Carrier aggregation with power headroom report.|

---

US9113422B2|2010-06-28|2015-08-18|Samsung Electronics Co., Ltd.|Method and apparatus for reporting maximum transmission power in wireless communication|

---

CN102378325B|2010-08-13|2016-03-30|索尼公司|The up link of the secondary community of terminal is activated and the method for deexcitation and device|

---

KR101276853B1|2010-08-17|2013-06-18|엘지전자 주식회사|A method and an apparatus of transmitting a power headroom report in a wireless communication system supporting multi-carriers|

---

US9258092B2|2010-09-17|2016-02-09|Blackberry Limited|Sounding reference signal transmission in carrier aggregation|

---

CN102457351B|2010-10-29|2017-02-15|广州飞曙电子科技有限公司|Method and system for obtaining actual power headroomof carrier of UE |

---

WO2012060612A2|2010-11-03|2012-05-10|Pantech Co., Ltd.|Apparatus and method of transmitting power information regarding component carrier in multi-component carrier system|

---

US20130215866A1|2010-11-05|2013-08-22|Jae Hyun Ahn|Apparatus and method for transmitting power information about component carrier in multiple component carrier system|

---

WO2012060641A2|2010-11-05|2012-05-10|팬택|Method and device for transmitting and receiving aperiodic reference signal|

---

HUE048606T2|2010-11-05|2020-08-28|Ericsson Telefon Ab L M|Method of communicating power information from a user equipment, method for processing received power information as well as a corresponding user equipment and base station|

---

KR101762610B1|2010-11-05|2017-08-04|삼성전자주식회사|Device and method for uplink scheduling and reporting information for uplink scheduling in wireless communication system|

---

US9084207B2|2010-11-08|2015-07-14|Qualcomm Incorporated|System and method for uplink multiple input multiple output transmission|

---

US9516609B2|2010-11-08|2016-12-06|Qualcomm Incorporated|System and method for uplink multiple input multiple output transmission|

---

US9380490B2|2010-11-08|2016-06-28|Qualcomm Incorporated|System and method for uplink multiple input multiple output transmission|

---

US20120281642A1|2010-11-08|2012-11-08|Qualcomm Incorporated|System and method for uplink multiple input multiple output transmission|

---

US8953713B2|2010-11-08|2015-02-10|Qualcomm Incorporated|System and method for uplink multiple input multiple output transmission|

---

US9007888B2|2010-11-08|2015-04-14|Qualcomm Incorporated|System and method for uplink multiple input multiple output transmission|

---

MY165865A|2010-12-30|2018-05-18|Ericsson Telefon Ab L M|Methods and apparatuses for enabling power back-off indication in phr in a telecommunications system|

---

EP2664205B1|2011-01-11|2020-07-29|Nokia Solutions and Networks Oy|Methods and apparatuses for non-adjacent carrier signalling in a multicarrier broadband wireless system|

---

CN108990143A|2011-02-21|2018-12-11|三星电子株式会社|The method and device thereof of effective reporting user facility transimission power|

---

KR101995293B1|2011-02-21|2019-07-02|삼성전자 주식회사|Method and appratus of activating or deactivating secondary carriers in time division duplex mobile communication system using carrier aggregation|

---

CN102123437B|2011-03-03|2016-02-17|电信科学技术研究院|Power headroom reporting and the scheduling method of subframe, system and equipment|

---

WO2012134193A2|2011-04-01|2012-10-04|Samsung Electronics Co., Ltd.|Method and system of handling in-device coexistence in various wireless network technologies|

---

KR102073027B1|2011-04-05|2020-02-04|삼성전자 주식회사|Method and appratus of operating multiple time alignment timer in mobile communication system using carrier aggregation|

---

US9185666B2|2011-05-06|2015-11-10|Qualcomm Incorporated|Power headroom reporting related to power management maximum power reduction|

---

US9439061B2|2011-05-27|2016-09-06|At&T Mobility Ii Llc|Selective prioritization of voice over data|

---

US9232482B2|2011-07-01|2016-01-05|QUALOCOMM Incorporated|Systems, methods and apparatus for managing multiple radio access bearer communications|

---

US9167472B2|2011-07-01|2015-10-20|Qualcomm Incorporated|Methods and apparatus for enhanced UL RLC flow control for MRAB calls|

---

JP6032650B2|2011-07-13|2016-11-30|サン パテント トラスト|Terminal apparatus and transmission method|

---

US9591593B2|2011-07-22|2017-03-07|Qualcomm Incorporated|Systems, methods and apparatus for radio uplink power control|

---

US8395985B2|2011-07-25|2013-03-12|Ofinno Technologies, Llc|Time alignment in multicarrier OFDM network|

---

US9930569B2|2011-08-04|2018-03-27|Qualcomm Incorporated|Systems, methods and apparatus for wireless condition based multiple radio access bearer communications|

---

KR102247818B1|2011-08-10|2021-05-04|삼성전자 주식회사|Method and apparatus for transmitting data in mobile communication system with multiple carrier|

---

US11223455B2|2011-08-10|2022-01-11|Samsung Electronics Co., Ltd.|Method and apparatus for transmitting data using a multi-carrier in a mobile communication system|

---

CA2845036C|2011-08-12|2020-09-22|Interdigital Patent Holdings, Inc.|Methods, apparatus and systems for power control and timing advance|

---

WO2013025236A1|2011-08-12|2013-02-21|Intel Corporation|System and method of uplink power control in a wireless communication system|

---

US9521632B2|2011-08-15|2016-12-13|Google Technology Holdings LLC|Power allocation for overlapping transmission when multiple timing advances are used|

---

WO2013036029A1|2011-09-05|2013-03-14|엘지전자 주식회사|Terminal apparatus for controlling uplink signal transmission power and method for same|

---

CN102291812B|2011-09-13|2014-12-03|电信科学技术研究院|Uplink power control parameter configuration and uplink power control method, system and equipment|

---

US9686046B2|2011-09-13|2017-06-20|Qualcomm Incorporated|Systems, methods and apparatus for wireless condition based multiple radio access bearer communications|

---

US8873535B2|2011-09-26|2014-10-28|Qualcomm Incorporated|Systems, methods and apparatus for retransmitting protocol data units in wireless communications|

---

WO2013046964A1|2011-09-28|2013-04-04|シャープ株式会社|Mobile station device, communication system, communication method, and integrated circuit|

---

CN103875285B|2011-10-05|2018-05-08|三星电子株式会社|Method and apparatus for reselecting cell in heterogeneous network in a wireless communication system|

---

WO2013055108A2|2011-10-10|2013-04-18|삼성전자 주식회사|Operating method for wireless communication system using improved carrier aggregation technology and device therefor|

---

US9451651B2|2011-10-12|2016-09-20|At&T Mobility Ii Llc|Management of multiple radio access bearer sessions in communication system|

---

US20130114571A1|2011-11-07|2013-05-09|Qualcomm Incorporated|Coordinated forward link blanking and power boosting for flexible bandwidth systems|

---

US9516531B2|2011-11-07|2016-12-06|Qualcomm Incorporated|Assistance information for flexible bandwidth carrier mobility methods, systems, and devices|

---

US9001679B2|2011-11-07|2015-04-07|Qualcomm Incorporated|Supporting voice for flexible bandwidth systems|

---

US9848339B2|2011-11-07|2017-12-19|Qualcomm Incorporated|Voice service solutions for flexible bandwidth systems|

---

US9277511B2|2011-12-02|2016-03-01|St-Ericsson Sa|Method of setting UE mode switching for RPD reduction|

---

US20130150045A1|2011-12-09|2013-06-13|Qualcomm Incorporated|Providing for mobility for flexible bandwidth carrier systems|

---

US8995405B2|2012-01-25|2015-03-31|Ofinno Technologies, Llc|Pathloss reference configuration in a wireless device and base station|

---

US8526389B2|2012-01-25|2013-09-03|Ofinno Technologies, Llc|Power scaling in multicarrier wireless device|

---

US9237537B2|2012-01-25|2016-01-12|Ofinno Technologies, Llc|Random access process in a multicarrier base station and wireless device|

---

WO2013112021A1|2012-01-27|2013-08-01|삼성전자 주식회사|Method and apparatus for transmitting and receiving data by using plurality of carriers in mobile communication systems|

---

US9525526B2|2012-02-02|2016-12-20|Nokia Solutions And Networks Oy|Signaling of uplink scheduling information in case of carrier aggregation|

---

US9414409B2|2012-02-06|2016-08-09|Samsung Electronics Co., Ltd.|Method and apparatus for transmitting/receiving data on multiple carriers in mobile communication system|

---

US9497773B2|2012-02-08|2016-11-15|QUALOCOMM Incorporated|Method and apparatus for enhancing resource allocation for uplink MIMO communication|

---

US9629028B2|2012-03-16|2017-04-18|Qualcomm Incorporated|System and method for heterogeneous carrier aggregation|

---

EP2829093B1|2012-03-19|2021-04-21|Nokia Technologies Oy|Method and apparatus for establishing condition under which network assistance information is provided|

---

CN103327595B|2012-03-23|2016-11-23|华为技术有限公司|Ascending power control method, network node and system|

---

EP2835023B1|2012-04-01|2021-09-01|Comcast Cable Communications, LLC|Cell group configuration in a wireless device and base stationwith timing advance groups|

---

US20130259008A1|2012-04-01|2013-10-03|Esmael Hejazi Dinan|Random Access Response Process in a Wireless Communications|

---

US11252679B2|2012-04-16|2022-02-15|Comcast Cable Communications, Llc|Signal transmission power adjustment in a wireless device|

---

US8995381B2|2012-04-16|2015-03-31|Ofinno Technologies, Llc|Power control in a wireless device|

---

US8964593B2|2012-04-16|2015-02-24|Ofinno Technologies, Llc|Wireless device transmission power|

---

US9179425B2|2012-04-17|2015-11-03|Ofinno Technologies, Llc|Transmit power control in multicarrier communications|

---

US9210664B2|2012-04-17|2015-12-08|Ofinno Technologies. LLC|Preamble transmission in a wireless device|

---

US8964683B2|2012-04-20|2015-02-24|Ofinno Technologies, Llc|Sounding signal in a multicarrier wireless device|

---

RU2539650C2|2012-05-11|2015-01-20|ЭлДжи ЭЛЕКТРОНИКС ИНК.|Method and apparatus for performing power headroom reporting procedure in wireless communication system|

---

WO2013191353A1|2012-06-17|2013-12-27|엘지전자 주식회사|Method for reporting buffer status for device-to-device communication and apparatus therefor|

---

US9107206B2|2012-06-18|2015-08-11|Ofinne Technologies, LLC|Carrier grouping in multicarrier wireless networks|

---

US8971298B2|2012-06-18|2015-03-03|Ofinno Technologies, Llc|Wireless device connection to an application server|

---

US9084228B2|2012-06-20|2015-07-14|Ofinno Technologies, Llc|Automobile communication device|

---

US9210619B2|2012-06-20|2015-12-08|Ofinno Technologies, Llc|Signalling mechanisms for wireless device handover|

---

US9179457B2|2012-06-20|2015-11-03|Ofinno Technologies, Llc|Carrier configuration in wireless networks|

---

US9113387B2|2012-06-20|2015-08-18|Ofinno Technologies, Llc|Handover signalling in wireless networks|

---

US8767662B1|2012-06-27|2014-07-01|Sprint Spectrum L.P.|Managing allocation of control channel resources|

---

US9392556B2|2012-07-19|2016-07-12|Lg Electronics Inc.|Apparatus and method for reporting power headroom in wireless communication system|

---

US9648638B2|2012-07-20|2017-05-09|Lg Electronics Inc.|Method and apparatus for transmitting device-to-device related information in wireless communication system|

---

US20140036794A1|2012-08-03|2014-02-06|Ali T. Koc|User equipment assistance information signaling in a wireless network|

---

CA2880503C|2012-08-06|2018-03-20|Nokia Corporation|Apparatus and method for support of additional maximum power reduction by user equipment|

---

US10104612B2|2012-08-07|2018-10-16|Hfi Innovation Inc.|UE preference indication and assistance information in mobile communication networks|

---

CN104584651A|2012-08-13|2015-04-29|夏普株式会社|Wireless communication device, wireless communication method, program, and integrated circuit|

---

GB2505892B|2012-09-12|2015-09-23|Broadcom Corp|Methods, apparatus and computer programs for controlling power of wireless transmissions|

---

RU2626086C2|2012-09-19|2017-07-21|Телефонактиеболагет Л М Эрикссон |Network node and method of controlling maximum levels of transmission power for d2d communication line|

---

US9750028B2|2012-10-11|2017-08-29|Qualcomm Incorporated|Apparatus and methods for enhanced maximum power in multicarrier wireless communications|

---

US8867397B2|2012-10-17|2014-10-21|Motorola Solutions, Inc.|Method and apparatus for uplink power control in an orthogonal frequency division multiple access communication system|

---

US9264930B2|2012-11-07|2016-02-16|Qualcomm Incorporated|Buffer status reporting and logical channel prioritization in multiflow operation|

---

US20140153500A1|2012-12-03|2014-06-05|Qualcomm Incorporated|Methods, systems, and devices for configuring maximum transmit power|

---

EP3550897A1|2013-01-03|2019-10-09|LG Electronics Inc.|Method and apparatus for transmitting uplink signals in wireless communication system|

---

US20140192740A1|2013-01-10|2014-07-10|Texas Instruments Incorporated|Methods and apparatus for dual connectivity operation in a wireless communication network|

---

GB2509910B|2013-01-16|2019-02-20|Sony Corp|Telecommunications apparatus and methods|

---

CN104956748B|2013-01-25|2019-01-22|日本电气株式会社|Movement station, base station and the method for sending and receiving power headroom reporting |

---

CN103974319B|2013-01-29|2017-08-11|电信科学技术研究院|Power headroom reporting method and apparatus under carrier aggregation|

---

US9681483B2|2013-04-02|2017-06-13|Lg Electronics Inc.|Method for operating time alignment timer and communication device thereof|

---

JP6426708B2|2013-04-22|2018-11-21|エルジー エレクトロニクス インコーポレイティド|Method and apparatus for reporting power headroom in a wireless communication system supporting change of use of wireless resources|

---

WO2014178690A1|2013-05-02|2014-11-06|Samsung Electronics Co., Ltd.|Method and apparatus for controlling uplink power in wireless communication system|

---

US9844008B2|2013-05-23|2017-12-12|Lg Electronics|Method for transmitting power headroom report in network supporting interworkings between multiple communication systems, and apparatus therefor|

---

US9872259B2|2013-06-24|2018-01-16|Lg Electronics Inc.|Method for controlling transmission power of sounding reference signal in wireless communication system and apparatus for same|

---

JP6711622B2|2013-07-12|2020-06-17|シャープ株式会社|Terminal device, method and integrated circuit|

---

WO2015010023A1|2013-07-18|2015-01-22|Convida Wireless, Llc|Billing of relayed device|

---

US9578539B1|2013-07-19|2017-02-21|Sprint Spectrum L.P.|Transmitting a data packet over a wireless communication link|

---

JP6301094B2|2013-09-26|2018-03-28|株式会社Ｎｔｔドコモ|User terminal and wireless communication method|

---

JP2015080066A|2013-10-16|2015-04-23|株式会社Ｎｔｔドコモ|Mobile communication system|

---

WO2015062024A1|2013-10-31|2015-05-07|VýþU½¬W«ØWæ®WæiZr°VeÐV±½|Power control method, user equipment, and base station|

---

JP5913255B2|2013-10-31|2016-04-27|株式会社Ｎｔｔドコモ|Mobile station and mobile communication method|

---

CN108566673A|2013-12-03|2018-09-21|索尼公司|Wireless communication system and the method carried out wireless communication in a wireless communication system|

---

US9572047B2|2013-12-27|2017-02-14|Intel Corporation|Adjacent channel leakage reduction in scalable wireless communication network|

---

US9491709B2|2013-12-27|2016-11-08|Qualcomm Incorporated|Apparatus and method for triggering a maximum power reporting event in a wireless communication network|

---

CN104780561A|2014-01-15|2015-07-15|电信科学技术研究院|Power headroom reporting method and device|

---

US9554359B2|2014-02-07|2017-01-24|Apple Inc.|Dynamic antenna tuner setting for carrier aggregation scenarios|

---

JP6298329B2|2014-03-20|2018-03-20|株式会社Ｎｔｔドコモ|User terminal, radio base station, and radio communication method|

---

PL3609266T3|2014-03-21|2022-01-17|Nokia Technologies Oy|Parallel preamble transmission in power limited situations|

---

JP6379629B2|2014-04-24|2018-08-29|ソニー株式会社|Communication control device, wireless communication device, communication control method, and wireless communication method|

---

US10057861B2|2014-06-03|2018-08-21|Qualcomm Incorporated|Techniques for reporting power headroom in multiple connectivity wireless communications|

---

US20170142668A1|2014-06-30|2017-05-18|Ntt Docomo, Inc.|User terminal, radio base station, radio communication system and radio communication method|

---

CN105451262B|2014-08-07|2019-09-24|上海诺基亚贝尔股份有限公司|Method under dual link communication environment for supporting power headroom reportingto transmit|

---

CN105517004B|2014-09-26|2019-07-05|上海诺基亚贝尔股份有限公司|Power rating determines method and device|

---

US20160128045A1|2014-10-31|2016-05-05|Qualcomm Incorporated|Reliable transmission of information on control channels|

---

US9608764B2|2014-12-11|2017-03-28|Qualcomm Incorporated|Uplink data routing during multiple carrier power imbalance|

---

HUE041363T2|2015-01-13|2019-05-28|Ericsson Telefon Ab L M|Wireless terminals, nodes of wireless communication networks, and methods of operating the same|

---

WO2016112526A1|2015-01-16|2016-07-21|华为技术有限公司|Method and device for controlling transmit power of user equipment|

---

WO2016163683A1|2015-04-09|2016-10-13|Lg Electronics Inc.|Method for transmitting a power headroom reporting in a carrier aggregation with at least one scell operating in an unlicensed spectrum and a device therefor|

---

CN114095996A|2015-05-15|2022-02-25|北京三星通信技术研究有限公司|Uplink power distribution method and user equipment|

---

US10412690B2|2015-07-10|2019-09-10|Qualcomm Incorporated|Power headroom reporting for low cost machine type communication|

---

CN105246106B|2015-09-02|2019-02-12|北京星河亮点技术股份有限公司|LTE-A terminal test instrument MAC layer data dispatching method under carrier wave polymerization|

---

CA3003390C|2015-11-11|2020-04-28|Telefonaktiebolaget Lm Ericsson |Method and apparatus for wireless communication|

---

EP3843315A1|2015-11-16|2021-06-30|LG Electronics Inc.|Method for transmitting or receiving a mac pdu in a wireless communication system and a devie therefor|

---

US10413889B2|2015-11-24|2019-09-17|Indian Oil Corporation Limited|Composition and process for preparation of cracking catalyst suitable for enhancing yields of light olefins|

---

EP3400733B1|2016-01-06|2021-08-25|LG Electronics Inc.|Method for transmitting a mac pdu in wireless communication system and a device therefor|

---

KR102270541B1|2016-04-01|2021-06-30|삼성전자 주식회사|Method and apparatus for wireless communication in wireless communication system|

---

EP3432665B1|2016-04-22|2020-11-18|Kyocera Corporation|Radio terminal and base station|

---

EP3800868B1|2016-05-18|2021-11-17|Samsung Electronics Co., Ltd.|Method and apparatus for performing efficient layer 2 function in mobile communication system|

---

CN107517497A|2016-06-16|2017-12-26|中兴通讯股份有限公司|Poewr control method, apparatus and system|

---

WO2018064799A1|2016-10-07|2018-04-12|Qualcomm Incorporated|Power allocation for uplink transmissions|

---

US10855409B2|2016-10-11|2020-12-01|Qualcomm Incorporated|Media access control header and transport block formats|

---

JP6529563B2|2016-10-21|2019-06-12|華碩電腦股▲ふん▼有限公司|Method and apparatus for power headroom reporting for beam operation in a wireless communication system|

---

EP3529936A1|2016-10-24|2019-08-28|Telefonaktiebolaget LM Ericsson |Method and network node for enabling measurements on reference signals|

---

US10743266B2|2016-11-03|2020-08-11|Guangdong Oppo Mobile Telecommunications Corp., Ltd.|Terminal device determining different transmit powers for use during different transmit periods|

---

US10362571B2|2016-11-04|2019-07-23|Qualcomm Incorporated|Power control and triggering of sounding reference signal on multiple component carriers|

---

US10123278B2|2016-11-14|2018-11-06|Qualcomm Incorporated|Techniques and apparatuses for adjusting transmission power for power-limited uplink carrier aggregation scenarios|

---

WO2018090537A1|2016-11-15|2018-05-24|华为技术有限公司|Method and device for reporting power headroom|

---

CN106793028B|2016-11-29|2020-08-28|海能达通信股份有限公司|Control method of transmission power and user equipment|

---

CN108288982B|2017-01-10|2019-07-23|上海朗帛通信技术有限公司|A kind of UE for power adjustment, the method and apparatus in base station|

---

WO2018129853A1|2017-01-13|2018-07-19|华为技术有限公司|Method for adjusting terminal power, and terminal|

---

WO2018195820A1|2017-04-26|2018-11-01|Oppo广东移动通信有限公司|Resource scheduling method and device|

---

US10470140B2|2017-05-04|2019-11-05|Qualcomm Incorporated|Power headroom report for uplink split bearer communications|

---

CN109152030A|2017-06-16|2019-01-04|中兴通讯股份有限公司|The shared method and device of power|

---

EP3652998A4|2017-07-10|2020-12-16|LG Electronics Inc. -1-|Method for transmitting a power headroom reporting in wireless communication system and a device therefor|

---

JPWO2019026296A1|2017-08-04|2020-07-30|株式会社Ｎｔｔドコモ|User terminal and wireless communication method|

---

WO2019028815A1|2017-08-11|2019-02-14|Oppo广东移动通信有限公司|Wireless communication method, terminal device, network device and network node|

---

EP3627903A4|2017-08-16|2020-05-27|Guangdong Oppo Mobile Telecommunications Corp., Ltd.|Signal transmission method and terminal device|

---

US10750453B2|2017-09-07|2020-08-18|Ofinno, Llc|Sounding reference signal transmission for uplink beam management|

---

US10448233B2|2017-11-08|2019-10-15|Google Llc|Emergency communication in a wireless system|

---

CN110012532B|2018-01-04|2021-04-20|维沃移动通信有限公司|PHR triggering method, terminal equipment and network equipment|

---

EP3739789A4|2018-01-11|2021-03-10|China Academy of Telecommunications Technology|Power headroom reporting processing method, terminal and network side device|

---

RU2753573C1|2018-03-07|2021-08-17|Гуандун Оппо Мобайл Телекоммьюникейшнс Корп., Лтд.|Method for sending srs power headroom report, terminal apparatus and computer data storage medium|

---

US20210266828A1|2018-09-21|2021-08-26|Lg Electronics Inc.|Method for transmitting and receiving downlink channel and device therefor|

---

US10925007B2|2018-11-02|2021-02-16|Apple Inc.|Dynamic power reduction requests for wireless communications|

---

CN109617660B|2018-12-19|2021-08-03|惠州Tcl移动通信有限公司|Method and device for setting carrier aggregation frequency band, storage medium and mobile terminal|

---

US11166240B2|2019-01-24|2021-11-02|Parallel Wireless, Inc.|Power budget calculation using power headroom|

---

CN113228749A|2019-02-13|2021-08-06|上海诺基亚贝尔股份有限公司|Power control in uplink transmission|

---

US11129109B2|2019-05-06|2021-09-21|Qualcomm Incorporated|Uplink transmission techniques for exposure limited transmissions|

---

CN110392419A|2019-07-25|2019-10-29|维沃移动通信有限公司|A kind of information uploading method, terminal device|

---

WO2022033691A1|2020-08-13|2022-02-17|Nokia Technologies Oy|Apparatus, methods, and computer programs for uplink power reduction|

法律状态:
2017-09-26| B25A| Requested transfer of rights approved|Owner name: PANASONIC INTELLECTUAL PROPERTY CORPORATION OF AME |

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2017-10-10| B25A| Requested transfer of rights approved|Owner name: SUN PATENT TRUST (US) |

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2019-01-08| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2020-02-04| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2020-02-18| B15K| Others concerning applications: alteration of classification|Free format text: AS CLASSIFICACOES ANTERIORES ERAM: H04W 72/12 , H04W 52/14 Ipc: H04L 5/00 (2006.01), H04W 52/14 (2009.01), H04W 52 |

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2020-02-27| B15K| Others concerning applications: alteration of classification|Free format text: A CLASSIFICACAO ANTERIOR ERA: H04L 5/00 Ipc: H04L 5/00 (2006.01), H04W 52/14 (2009.01), H04W 52 |

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2021-03-30| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-05-04| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 10 (DEZ) ANOS CONTADOS A PARTIR DE 04/05/2021, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

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申请号 | 申请日 | 专利标题

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EP0913756.3|2009-11-02|

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EP09013756A|EP2317815A1|2009-11-02|2009-11-02|Power-limit reporting in a communication system using carrier aggregation|

---

EP10008477A|EP2317816A1|2009-11-02|2010-08-13|Power-limit reporting in a communication system using carrier aggregation|

---

EP10008477.1|2010-08-13|

---

PCT/EP2010/006423|WO2011050921A1|2009-11-02|2010-10-20|Power-limit reporting in a communication system using carrier aggregation|

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