methods and apparatus for subframe interlacing in heterogeneous networks

专利摘要:
METHODS AND APPARATUS FOR SUBQUADING INTERLACING IN HETEROGENEOUS NETWORKS Methods and apparatus for providing wireless communications using subframe division are described. Two or more base stations can be subframes allocated on a radio board. All or part of the subframe allocation can be provided to the associated UEs, which can use it to determine signal metrics during the subframes designated for an associated base station.
公开号:BR112012005892B1
申请号:R112012005892-4
申请日:2010-09-15
公开日:2021-03-02
发明作者:Aleksandar Damnjanovic；Yongbin Wei；Peter A. Barany
申请人:Qualcomm Incorporated；
IPC主号:

专利说明:

Cross Reference to Related Orders
[0001] This application claims priority under 35 USC § 119 (e) to US provisional patent application No. 61 / 242,678, entitled MULTIPLEXING SUBFRAME INTERLACES BETWEEN NODES ON HETEROGENEOUS NETWORKS, filed on September 15, 2009, the content of which is incorporated herein by reference in its entirety for all purposes. Field
[0002] This order is generally intended for wireless communications systems. More particularly, but not exclusively, the order relates to methods and apparatus for supplying time division multiplexed subframes in a wireless communication network, such as a long-term evolution network (LTE), in addition to adjusting network nodes based on the associated performance metrics. Foundations
[0003] Wireless communication systems are widely developed to provide various types of communication content such as voice, data, video and the like, and developments are expected to increase with the introduction of new data-oriented systems such as LTE systems. Wireless communications systems can be multiple access systems capable of supporting communication with multiple users by sharing available system resources (for example, bandwidth and transmission power). Examples of such multiple access systems include code division multiple access systems (CDMA), time division multiple access systems (TDMA), frequency division multiple access systems (FDMA), LTE 3GPP systems and other systems of multiple access by orthogonal frequency division (OFDMA).
[0004] Generally, a wireless multiple access communication system can simultaneously support communication to multiple wireless terminals (also known as user equipment (UE), or access terminals (AT)). Each terminal communicates with one or more base stations (also known as access points (AP), eNóB or eNB) through transmissions on forward and reverse links. The direct link (also referred to as downlink or DL) refers to the communication link from the base stations to the terminals, and the reverse link (also referred to as uplink or UL) refers to the communication link from the terminals to the base stations . These communication links can be established through a single input and single output system, single input and multiple outputs, multiple inputs and single output or a multiple input and multiple outputs (MIMO) system.
[0005] A MIMO system employs multiple (NT) transmitting antennas and multiple (NR) receiving antennas for data transmission. A MIMO channel formed by NT transmitting antennas and NR receiving antennas can be decomposed into NS independent channels, which are also referred to as space channels. Generally, each of the NS independent channels corresponds to a dimension. The MIMO system can provide improved performance (for example, higher throughput and / or greater reliability) if the additional dimensions created by the multiple transmit and receive antennas are used. A MIMO system also supports duplex time division (TDD) and duplex frequency division (RDD) systems. In a TDD system, the transmissions in direct or reverse link are in the same frequency region so that the principle of reciprocity allows the estimation of the direct link channel to be made from the reverse link channel. This allows an access point to extract the transmission beam formation gain on the direct link when multiple antennas are available at the access point.
[0006] The base station nodes sometimes referred to as eNBs have different capabilities for development in a network. This includes transmitting power classes, restricting access, and so on. In one respect, heterogeneous network characteristics create wireless coverage dead spots (eg, Donut cover hole). This can cause severe intercellular interference requiring an unwanted user equipment cell association. In general, the characteristics of a heterogeneous network require a deep penetration of the physical channels that can cause unwanted interference between the nodes and the equipment in the respective network.
[0007] As the number of mobile stations developed increases, the need to use adequate bandwidth becomes more important. Furthermore, with the introduction of semi-autonomous base stations for the management of small cells, such as femto cells and peak cells, in systems such as LTE, interference with existing base stations can become an increasing problem.
[0008] This description is generally intended for wireless communications systems using the subframe division. The description refers, for example, to methods and apparatus for providing multiplexed subframes by time division in a wireless communication network, such as an LTE network, in addition to adjusting network nodes based on performance metrics associated companies.
[0009] In one aspect, the description can refer to a method for wireless signal transmission. The method may include storing, in a wireless network base station, a subframe split configuration including an allocation of a first DL resource to be one among a semi-static resource or a dynamic resource. The method may additionally include sending a first signal consistent with the allocation of DL resource from the base station.
[0010] The method may additionally include, for example, transmitting from the base station a second signal consistent with a second DL resource allocation. The second DL resource allocation can be allocated by setting the subframe split to be one among a semi-static resource or a dynamic resource. The first DL resource can be, for example, orthogonal to a second DL resource allocated to a second base station. The second DL resource can be allocated by the subframe split configuration to be, for example, one among a semi-static resource or a dynamic resource. The first DL resource and the second DL resource can be multiplexed by time division and / or multiplexed by frequency division.
[0011] The subframe split configuration may additionally include, for example, an allocation of at least one unassigned resource. The first base station can be, for example, one of a macro cell base station, a femto cell or a peak cell.
[0012] The method may additionally include, for example, the negotiation, with a second base station, of a subframe resource allocation configuration and the determination, based on the negotiation, of the subframe resource allocation. The subframe resource allocation can be stored, for example, in a memory.
[0013] In another aspect, the description refers to a computer program product, The computer program product may include a computer-readable medium containing codes to have a computer store, in a wireless network base station , a subframe split configuration including an allocation of a first DL resource to be one among a semi-static resource or a dynamic resource. The codes may additionally include codes to cause the computer to transmit, from the base station, a first signal consistent with the first DL resource allocation.
[0014] In another aspect, the description refers to a communication device. The communication device may include a memory configured to store, on a wireless network base station, a subframe split configuration including an allocation of a first DL resource to be one among a semi-static resource or a dynamic resource. The communications device may additionally include a transmission module configured to transmit, from the base station, a first signal consistent with the first DL resource allocation.
[0015] The communications device may additionally include, for example, a processor module configured to negotiate, with a second base station, a subframe resource allocation configuration and determine, based on the negotiation, the subframe resource allocation . The device may additionally include a memory configured to store the subframe resource allocation.
[0016] In another aspect, the description refers to a communication device. The communications device may include mechanisms for storing, on a wireless base station, a subframe split configuration including an allocation of a first DL resource to be one among a semi-static resource or a dynamic resource and means for transmitting, the from the base station, a first signal consistent with the first DL resource allocation.
[0017] In another aspect, the description refers to a method for wireless signal transmission. The method may include determining, on a first wireless base station through a communication connection with a second wireless base station, a subframe split configuration. The method may additionally include sending, from the first wireless network base station, a first signal consistent with the subframe split configuration.
[0018] The subframe split configuration may include, for example, a first DL resource allocated to the first wireless base station and may additionally include a second DL resource allocated to the second wireless base station. The first DL resource and the second DL resource can be, for example, semi-static resources. Alternatively or in addition, the first DL resource and the second DL resource can be, for example, dynamic resources. Combinations of semi-static and dynamic resources can be used. In addition, the subframe split configuration may include, for example, a DL resource allocated to the first wireless network base station. The subframe split configuration can additionally include a second DL resource allocated to the first wireless base station. The first DL resource can be, for example, a semi-static resource and the second DL resource can be, for example, a dynamic resource. The subframe split configuration can additionally include, for example, an unallocated resource. The subframe division can include partial subframe allocations, such as partial semi-static or partial dynamic subframe allocations.
[0019] The communication connection can be a wireless connection, such as, for example, an X2 connection. Alternatively or additionally, the communication connection can be a return access channel connection. If a return access channel connection is used, it can include, for example, an S1 connection. The first base station and / or the second base station can be in communication with a core network. The determination can be carried out, for example, in conjunction with the core network. Alternatively, the determination can be carried out independently of a core network, where the core network can be associated with the first base station and / or the second base station.
[0020] The method may additionally include, for example, receiving, from a UE, a second signal, where the second signal may include a signal metric generated in response to the first signal.
[0021] In another aspect, the description refers to a computer program product. The computer program product may include a computer-readable medium containing codes to have a computer determine, on a first wireless base station through a communication connection with a second wireless base station, a configuration subframe division. The codes may additionally include codes to cause the computer to transmit, from the first wireless base station, a first signal consistent with the subframe split configuration.
[0022] In another aspect, the description refers to a communications device. The communications device may include a subframe determination module configured to determine, on a first wireless base station through a communication connection with a second wireless base station, a subframe split configuration. The communications device may additionally include a transmission module configured to transmit, from the first wireless network base station, a first signal consistent with the subframe split configuration.
[0023] In another aspect, the description refers to a communications device. The communications device may include means for determining, on a first wireless base station via a communication connection with a second wireless base station, a subframe split configuration. The communication device may additionally include means for transmitting, from the first wireless network base station, a first signal consistent with the subframe split configuration.
[0024] In another aspect, the description refers to a method for measuring wireless signal. The method may include storing, in a wireless base station, a subframe split configuration including allocation to a first semi-static DL resource and / sending, from the first wireless network base station, a first signal consistent with the first semi-static DL feature. The method may additionally include receiving in response to the first signal, from a UE associated with the base station, a signal metric usable for allocating a communications resource.
[0025] The first semi-static DL resource can be, for example, orthogonal to a second semi-static DL resource allocated to a second base station. The signal metric can be, for example, an RLM metric, and the RLM metric can be determined during a semi-static subframe. The semi-static subframe can be signaled to the UE before transmission. The method may additionally include, for example, the allocation of the communications resource based at least in part on the signal metric.
[0026] In another aspect, the description refers to a computer program product. The computer program product may include a computer-readable medium containing codes to have a computer store a subframe split configuration on a wireless base station including an allocation of a first semi-static DL resource and transmit, from the first wireless base station, a first signal consistent with the first semi-static DL feature. The codes may additionally include codes to cause the computer to receive, in response to the first signal, from a UE associated with the base station, a signal metric usable to allocate a communications resource.
[0027] In another aspect, the description refers to a communication device. The communications device may include a memory configured to store a subframe split configuration including an allocation of a first semi-static DL resource and a transmitter module configured to send a first signal consistent with the first semi-static DL resource. The communications device may additionally include a receiver configured to receive, in response to the first signal, from a UE associated with the communication device, a signal metric usable to allocate a communications resource.
[0028] In another aspect, the description refers to a communication device. The communications device may include means for storing a subframe split configuration including an allocation of a first semi-static DL resource and means for transmitting a first signal consistent with the first semi-static DL resource. The communications device may additionally include mechanisms for receiving, in response to the first signal, from a UE associated with the communication device, a signal metric usable for allocating a communications resource.
[0029] In another aspect, the description refers to a method for programming transmission over a communications network. The method may include receiving, from a first wireless network node, a request for allocation of subframe resources and allocation of subframe resources between the first wireless network node and a second wireless network node. according to a subframe resource configuration. The method may additionally include providing the subframe resource configuration for the first wireless node and the second wireless node.
[0030] The subframe resource configuration may include, for example, a semi-static subframe resource allocation and / or a dynamic subframe resource allocation. Alternatively or in addition, the subframe resource configuration can include an unassigned resource allocation. The subframe resource configuration can include, for example, a first semi-static resource allocation assigned to the first wireless network node and a second semi-static resource allocation assigned to the second wireless network node. The first semi-static resource allocation and the second semi-static resource allocation can be configured to be orthogonal.
[0031] In another aspect, the description refers to a computer program product. The computer program product may include a computer-readable medium containing codes to cause a computer to receive, from a first wireless network node, a request to allocate the subframe resources and to allocate the subframe resources between the first wireless network node and a second wireless network node according to a subframe resource configuration. The codes may additionally include codes to provide the subframe resource configuration for the first wireless node and the second wireless node.
[0032] In another aspect, the description refers to a system for managing subframe allocation. The system can include a receiver module configured to receive from a first wireless network node, a request for allocation of subframe resources and a processor module configured to determine an allocation of subframe resources between the first wireless network node and a second wireless network node according to a subframe resource configuration. The system may additionally include a transmission module configured to provide the subframe resource configuration for the first wireless network node and the second wireless network node.
[0033] In another aspect, the description refers to a system for managing subframe allocation. The system may include mechanisms for receiving, from a first wireless network node, a request for subframe resource allocation and mechanisms for determining an allocation of subframe resources between the first wireless network node and a second wireless network node. according to a subframe feature configuration. The system may additionally include means for providing the subframe resource configuration for the first wireless network node and the second wireless network node.
[0034] In another aspect, the description refers to a method for wireless communication. The method may include receiving, at a UE, from a base station, information regarding a predetermined subframe resource allocation and receiving, during a time interval associated with the resource allocation, a first signal. The method may additionally include determining a signal metric associated with the first signal and sending the signal metric to the base station.
[0035] The signal metric can be, for example, a Radio Link Monitoring (RLM) metric. The information may include, for example, Radio Resource Management (RRM) control information. The information may also include channel return information and / or channel quality indication (CQI) information. The base station can be associated with a first cell and the first signal can be transmitted from a node associated with a second cell. The first cell can be, for example, a macro cell and the second cell can be a peak cell or femto cell. Alternatively, the first cell can be a peak cell or femto cell and the second cell can be a macro cell. Alternatively, the first and second cells can be macro cells or the first and second cells can be pico cells or femto cells.
[0036] The first signal can be, for example, a reference signal. The reference signal can be a common reference signal (CRS) and / or a channel status information reference signal (CSI-RS).
[0037] In another aspect, the description refers to a computer program product. The computer program product may include a computer-readable medium containing codes to cause a computer to receive, in a UE, from a base station, information related to a predetermined subframe resource allocation and receive, during an interval of time associated with resource allocation, a first signal. The codes may additionally include codes to determine a signal metric associated with the first signal and / or send the signal metric to the base station.
[0038] In another aspect, the description refers to a device for wireless communications. The device may include a receiver module configured to receive, in a UE, from a base station, information related to a predetermined subframe resource allocation and receive, during a time interval associated with the resource allocation, a first signal . The device may additionally include a processor module configured to determine a signal metric associated with the first signal and / or a transmission module configured to send the signal metric to the base station.
[0039] In another aspect, the description refers to a device for wireless communications. The device may include mechanisms for receiving, in a UE, from a base station, information related to a predetermined subframe resource allocation and mechanisms for receiving, during a time interval associated with the resource allocation, a first signal. The device may additionally include mechanisms for determining a signal metric associated with the first signal and / or mechanisms for sending the signal metric to the base station.
[0040] Additional aspects are additionally described below in conjunction with the attached drawings. Brief Description of Drawings
[0041] The present application can be more fully appreciated in relation to the following detailed description taken into consideration in conjunction with the drawings, where:
[0042] Figure 1 illustrates details of a wireless communications system;
[0043] Figure 2 illustrates details of a wireless communications system having multiple cells;
[0044] Figure 3 illustrates details of a wireless communication system of multiple cells having nodes of different types;
[0045] Figure 4a illustrates details of communication connections from base station to base station in a wireless communications system;
[0046] Figure 4b illustrates details of communication connections from base station to base station in a wireless communications system;
[0047] Figure 5 illustrates a radio frame and illustrative subframes in an LTE communications system;
[0048] Figure 6 illustrates an illustrative component configuration on a wireless network configured for subframe interlacing;
[0049] Figure 7 illustrates an illustrative component configuration in a wireless network configured for subframe interlacing;
[0050] Figure 8 illustrates an illustrative component configuration in a wireless network configured for subframe interlacing;
[0051] Figure 9 illustrates an illustrative subframe allocation configuration on a wireless network configured for subframe interlacing;
[0052] Figure 10 illustrates another illustrative subframe allocation configuration in a wireless network configured for subframe interlacing;
[0053] Figure 11 illustrates another illustrative subframe allocation configuration on a wireless network configured for subframe interlacing;
[0054] Figure 12 illustrates another illustrative subframe allocation configuration on a wireless network configured for subframe interlacing;
[0055] Figure 13 illustrates another illustrative subframe allocation configuration on a wireless network configured for subframe interlacing;
[0056] Figure 14 illustrates another illustrative subframe allocation configuration on a wireless network configured for subframe interlacing;
[0057] Figure 15 illustrates another illustrative subframe allocation configuration on a wireless network configured for subframe interlacing;
[0058] Figure 16 illustrates an example of subframe designation between a macro cell and a peak cell;
[0059] Figure 17 illustrates an example of the subframe designation between a macro cell and a peak cell;
[0060] Figure 18 illustrates an example of X2C signaling (control) for successful resource request between multiple cells in a wireless network;
[0061] Figure 19 illustrates an example of X2C signaling (control) for a partially successful resource request between multiple cells on a wireless network;
[0062] Figure 20 illustrates an example of X2C signaling (control) for an unsuccessful resource request between multiple cells on a wireless network;
[0063] Figure 21 illustrates a modality of a process for the operation of subframe interlacing in a wireless network base station;
[0064] Figure 22 illustrates a modality of a process for operating subframe interlacing on a wireless network base station;
[0065] Figure 23 illustrates a modality of a process for allocation of interlaced subframe in a wireless network;
[0066] Figure 24 illustrates a modality of a process for monitoring the signal in a UE based on an interlaced subframe configuration;
[0067] Figure 25 illustrates a modality of a base station and UE in a wireless communications system. Detailed Description
[0068] This description generally refers to the coordination and management of interference in wireless communications systems. In various modalities, the techniques and apparatus described here can be used for wireless communication networks such as CDMA networks, TDMA networks, FDMA networks, OFDMA networks, SC-FDMA networks, LTE networks, in addition to other communications networks. As described here, the terms "networks" and "systems" can be used interchangeably.
[0069] A CDMA network can implement radio technology such as Universal Terrestrial Radio Access (UTRA), cdma2000, and the like. UTRA includes broadband CDMA (W-CDMA) and Low Chip Rate (LCR). Cdma2000 covers the IS-2000, IS-95 and IS-856 standards. A TDMA network can implement radio technology such as the Global System for Mobile Communications (GSM).
[0070] An OFDMA network can implement radio technology such as UTRA Evolved (E-UTRA), IEEE 802.11, IEEE 802.16, IEEE 802.20, Flash-OFDM and the like. UTRA, E-UTRA, and GSM are part of the Universal Mobile Telecommunications System (UMTS). In particular, LTE is a version of UMTS that uses E-UTRA. UTRA, E-UTRA, GSM, UMTS and LTE are described in documents provided from an organization called "3rd Generation Partner Project" (3GPP), and cdma2000 is described in documents from an organization called " 3rd Generation 2 "Partner Project (3GPP2). These various radio technologies and standards are known or are being developed in the art. For example, 3GPP is a collaboration between groups of telecommunications associations that aim to define a globally applicable 3G mobile phone specification. LTE 3GPP is a 3GPP project that aims to improve the standard of UMTS mobile telephony. 3GPP can define specifications for the next generation of mobile networks, mobile systems and mobile devices. For the sake of clarity, certain aspects of the device and techniques are described below for LTE implementations, and the LTE terminology is used in much of the description below; however, the description should not be limited to LTE applications. Accordingly, it will be apparent to those skilled in the art that the device and the methods described here can be applied to various other communications systems and applications.
[0071] Logical channels in wireless communication systems can be classified into Control Channels and Traffic Channels. The Logical Control Channels can include a Diffusion Control Channel (BCCH), which is a DL channel for disseminating system control information, a Paging Control Channel (PCCH) which is a DL channel that transfers paging information and a Multicast Control Channel (MCCH) which is a multi-point point DL channel used to transmit Multimedia Broadcast and Multicast Service (MBMS) programming and control information to one or more MTCHs. Generally, after the establishment of a Radio Resource Control (RRC) connection, this channel is only used by UEs that receive MBMS. A Dedicated Control Channel (DCCH) is a bidirectional point-to-point channel that transmits dedicated channel information and is used by UEs having an RRC connection.
[0072] Logical Traffic Channels may include a Dedicated Traffic Channel (DTCH) which is a two-way point-to-point channel, dedicated to a UE, for the transfer of user information, and a Multicast Traffic Channel (MTCH) ) for point DL channel to multiple points to transmit traffic data.
[0073] Transport Channels can be classified into DL and UL Transport Channels. DL Transport Channels can include a Broadcast Channel (BCH), a Shared Downlink Data Channel (DL-SDCH), and a Paging Channel (PCH). The SHP can be used to support the EU energy savings (when a DRX cycle is indicated by the network to the UE), diffusion through an entire cell and mapped to the Physical Layer (PHY) resources that can be used for other channels control / traffic. UL Transport Channels can include a Random Access Channel (RACH), a Request Channel (REQCH), a Uplink Shared Data Channel (UL-SDCH), and a plurality of PHY channels. PHY channels can include a set of DL channels and UL channels.
[0074] Additionally, PHY DL channels can include the following: Common Pilot Channel (CPICH) Synchronization Channel (SCH) Common Control Channel (CCCH) Shared DL Control Channel (SDCCH) Multicast Control Channel (MCCH) Channel Shared Designation Channel (SUACH) Receipt Notice Channel (ACKCH) Shared Physical Data Channel DL (DL- PSDCH) UL Power Control Channel (UPCCH) Paging Indicator Channel (PICH) Charge Indicator Channel (LICH) Os PHY UL channels can include the following: Physical Random Access Channel (PRACH) Channel Quality Indicator Channel (CQICH) Receipt Warning Channel (ACKCH) Antenna Subset Indicator Channel (ASICH) Shared Request Channel (SREQCH) Channel Physical Shared Data System (UL-PSDCH) Broadband Pilot Channel (BPICH)
[0075] The term "illustrative" is used here to mean "serving as an example, case or illustration". Any aspect and / or modality described here as "illustrative" should not necessarily be considered preferred or advantageous over other aspects and / or modalities.
[0076] For the purpose of explaining the various aspects and / or modalities, the following terminology and abbreviations can be used here: AM Accused Receiving Mode AMD Accused Receiving Mode data ARQ Automatic Repeat Request BCCH Diffusion Control Channel BCH Diffusion Channel C- Control- CCCH Control channel Common CCH Control Channel CCTrich Composite Transport Channel CP Cyclic Prefix Cyclic Redundancy Check CTCH Common Traffic Channel DCCH Dedicated Control Channel DCH Dedicated Channel DL Downlink DSCH Shared Downlink Channel DTCH FACH Dedicated Traffic Channel Direct Link Access Channel FDD Duplexing by Frequency Division L1 Layer 1 (physical layer) L2 Layer 2 (data link layer) L3 Layer 3 (network layer) LI Length Indicator LSB Bit less significant MAC Media Access Control MBMS Multimedia Broadcast and Multicast Service MCCH Point control channel for multiple MBMS points MRW Motion Receive Window MSB Most Significant Bit MSCH Point Programming Channel for Multiple Points MBMS MTCH Point Traffic Channel for Multiple Points MBMS PCCH Paging Control Channel PCH Paging Channel PDU PHY Protocol Data Unit PhyCH Physical Layer RACH Physical Channels RLC Random Access Channel RRC Radio Link Control SAP Radio Resource Control SDU Service Access Point SHCCH Service Data Unit Shared Channel Control Channel SN Sequence Number SUFI Super Field TCH Traffic Channel TDD TFI Time Division Duplexing TM Transport Format Indicator TM Transparent Mode TMD Transparent Mode Data TTI Transmission Time Range U- User- EU UL User Equipment Uplink UM No Receipt Warning Mode UMD No Warning Data Data UMTS Receiving UTRA Universal Mobile Telecommunications System Access to Terrestrial Radio UMTS UTRAN Terrestrial Radio Access Network U MTS MBSFN MCE multicast broadcast single frequency network MBMS MCH coordinating entity DL-SCH multicast channel Shared downlink channel MSCH Control channel MBMS PDCCH physical downlink control channel PDSCH physical downlink channel
[0077] A MIMO system employs multiple (NT) transmitting antennas and multiple (NR) receiving antennas for data transmission. A MIMO channel formed by NT transmitting antennas and NR receiving antennas can be decomposed into Ns independent channels, which are also referred to as space channels. The maximum spatial multiplexing Ns if a linear receiver is used is min (NT, NR), with each of the NS independent channels corresponding to a dimension. This provides an NS increase in spectral efficiency. A MIMO system can provide improved performance (for example, higher throughput and / or greater reliability) if additional dimensions created by multiple transmitting and receiving antennas are used. The special dimension can be described in terms of a classification.
[0078] MIMO systems support TDD and FDD implementations. In a TDD system, forward and reverse link transmissions use the same frequency regions so that the principle of reciprocity allows the estimation of the direct link channel from the reverse link channel. This allows the access point to extract the transmission beam formation gain on the direct link when multiple antennas are available at the access point.
[0079] System designs can support various time and frequency reference signals for downlink and uplink to facilitate beam formation and other functions. A reference signal is a signal generated based on known data and can also be referred to as a pilot, preamble, sequencing signal, audible signal and the like. A reference signal can be used by a receiver for various purposes such as channel estimation, coherent demodulation, channel quality measurement, signal strength measurement and the like. MIMO systems using multiple antennas generally provide the coordination of sending and reference signals between the antennas, however, LTE systems in general do not provide the coordination of sending reference signals from multiple base stations or eNBs.
[0080] The 3GPP specification 36211-900 defines in Section 5.5 reference signals in particular for demodulation, associated with the transmission of PUSCH or PUCCH, in addition to sound, which is not associated with the transmission of PUSCH or PUCCH. For example, Table 1 lists some reference signals for LTE implementations that can be transmitted in downlink and uplink and provides a short description for each reference signal. A cell-specific reference signal can also be referred to as a common pilot, a broadband pilot and the like. An EU-specific reference signal can also be referred to as a dedicated reference signal. Table 1


[0081] In some implementations a system can use TDD. For TDD, downlink and uplink share the same frequency or channel spectrum, and downlink and uplink transmissions are sent on the same frequency spectrum. The downlink channel response can therefore be correlated with the uplink channel response. A principle of reciprocity can allow a downlink channel to be estimated based on transmissions sent via uplink. These uplink transmissions can be reference signals or uplink control channels (which can be used as reference symbols after demodulation). Uplink transmissions can allow the estimation of a selective space channel through multiple antennas.
[0082] In LTE implementations, orthogonal frequency division multiplexing is used for downlink, that is, from the base station, the access point or eNodeB to the terminal or UE. The use of OFDM meets LTE requirements for spectrum flexibility and allows cost-effective solutions for very large carriers with high peak rates, and is a well-established technology, for example, OFDM is used in standards such as IEEE 802.11a / g, 802.16 , HIPERLAN-2, DVB and DAB.
[0083] Physical resource blocks of frequency and time (also denoted here as resource blocks or "RBs") can be defined in OFDM systems as groups of transport carriers (for example, subcarriers) or intervals that are designated for the data carriage. RBs are defined over a period of time and frequency. Resource blocks are made up of time and frequency resource elements (also referred to here as resource elements or "REs"), which can be defined by time and frequency indices in a partition. Additional details of the LTE RBs and REs are described in 3GPP TS 36.211.
[0084] LTE UMTS supports scalable carrier bandwidth from 20 MHz to 1.4 MHz. In LTE, an RB is defined as 12 subcarriers when the subcarrier's bandwidth is equal to 15 kHz, or 24 subcarriers when the width bandwidth of the subcarrier is equal to 7.5 kHz. In an illustrative implementation, in the time domain there is a defined radio frame that is 10 ms long and consists of 10 subframes of 1 ms each. Each subframe consists of 2 partitions, where each partition is 0.5 ms. The subcarrier spacing in the frequency domain in this case is 14 kHz. Twelve of these subcarriers together (per partition) constitute an RB, so that in this implementation a resource block is 180 kHz. 6 resource blocks fit on a 1.4 MHz carrier and 100 resource blocks fit on a 20 MHz carrier.
[0085] In downlink there is typically a number of physical channels as described above. In particular, the PDCCH is used to send the control, the PHICH to send ACK / NACK, PCFICH to specify the number of control symbols, the Physical Downlink Shared Channel (PDSCH) for data transmission, the Physical Multicast Channel ( PMCH) to broadcast the transmission using a Single Frequency Network, and the Physical Broadcast Channel (PBCH) to send important system information within a cell. Modulation formats supported in PDSCH over LTE are QPSK, 16QASM and 64QAM.
[0086] In uplink there are typically three physical channels. While the Random Physical Access Channel (PRACH) is used only for initial access and when the UE is not synchronized in uplink, the data is sent in the PUSCH. If there is no data to be uplinked to a UE, the control information will be transmitted on the PUCCH. Modulation formats supported on the uplink data channel are QPSK, 16QAM and 64QAM.
[0087] If spatial division / virtual MIMO (SDMA) multiple access is introduced the data rate in the uplink direction can be increased depending on the number of antennas on the base station. With this technology more than one piece of furniture can reuse the same resources. For MIMO operation, a distinction is made between single-user MIMO, for better user data throughput, and multi-user MIMO for improved cell throughput.
[0088] In LTE 3GPP, a mobile station or device can be referred to as a "user device" or UE. A base station can be referred to as an evolved Node B or eNB. A semi-autonomous base station can be referred to as a home eNB or HeNB. A HeNB can therefore be an example of an eNB. The HeNB and / or the coverage area of a HeNB can be referred to as a femto cell, a HeNB cell or a closed subscriber group (CSG) cell (where access is restricted).
[0089] Several other aspects and characteristics of the description are further described below. It should be apparent that the teachings presented here can be embodied in a wide variety of forms and that any specific structure, function, or both described here are merely representative. Based on the teachings presented here, those skilled in the art should appreciate that one aspect described here can be implemented independently of any other aspects and that two or more of these aspects can be combined in various ways. For example, an apparatus can be implemented or a method can be practiced using any number of aspects presented here. In addition, such an apparatus can be implemented or such a method can be practiced using another structure, functionality or structure and functionality in addition to or in addition to one or more of the aspects presented here. In addition, an aspect may comprise at least one element of a claim.
[0090] Figure 1 illustrates details of an implementation of a multiple access wireless communication system, which can be an LTE system. An evolved Node B (eNB) 100 (also known as an access point or AP) can include multiple groups of antennas, one including 104 and 106, another including 108 and 110 and an additional including 112 and 114. In Figure 1 only two antennas are illustrated for each group of antennas, however, more or less antennas can be used for each group of antennas. An UE 116 (also known as an access terminal or AT) is in communication with antennas 112 and 114, where antennas 112 and 114 transmit information to UE 116 through the direct link (also known as downlink) 120 and receive information from the UE 116 through the reverse link (also known as uplink) 118. A second UE 122 is in communication with antennas 106 and 108, where antennas 106 and 108 transmit information to UE 122 through direct link 126 and receive information from the terminal of access 122 through the reverse link 124. In an FDD system, the communication links 118, 120, 124 and 126 can use different frequencies for communication. For example, direct link 120 can use a different frequency than that used by reverse link 118. In a TDD system, downlinks and uplinks can be shared.
[0091] Each group of antennas and / or the area in which they must communicate is often referred to as an eNB sector. The antenna groups are each designed to communicate with the UEs in a sector of the areas covered by the eNB 100. In communication through the forward links 120 and 126, the eNB 400 transmission antennas use beam formation in order to to optimize the signal to noise ratio of forward links for different access terminals 116 and 124. In addition, an eNB using beam formation to transmit to the UEs scattered at random through its coverage causes less interference for the UEs in neighboring cells than an eNB transmitting through a single antenna to all its UEs. An eNB can be a fixed station used to communicate with UEs and can also be referred to as an access point, a Node B, or some equivalent terminology. A UE can also be called an access terminal, AT, user equipment, wireless communication device, terminal, or some other equivalent terminology.
[0092] Figure 2 illustrates details of an implementation of a multiple access wireless communication system 200, such as an LTE system. The multiple access wireless communication system 200 includes multiple cells, including cells 202, 204 and 206. In one aspect the system 200, cells 202, 204 and 206 can include an eNB that includes multiple sectors. The multiple sectors can be formed by groups of antennas with each antenna responsible for communicating with UEs in a part of the cell. For example, in cell 202, antenna groups 212, 214 and 216 can each correspond to a different sector. In cell 204, antenna groups 224, 226 and 228 each correspond to a different sector. Cells 202, 204 and 206 can include several wireless communication devices, for example, user equipment or UEs, which can be in communication with one or more sectors of each cell 202, 204 or 206. For example, UEs 230 and 232 can be in communication with eNB 242, UEs 234 and 236 can be in communication with eNB 244, and UEs 238 and 240 can be in communication with eNB 246. The cells and associated base stations can be coupled to a controller of system 250, which can be part of a core or return access channel network, as can be used to perform the functions as further described here with respect to the allocation and configuration of subframe division.
[0093] Figure 3 illustrates details of an implementation of a multiple access wireless communication system 300, such as an LTE system, in which subframe splitting can be implemented. Various elements of system 300 can be implemented using components and configurations as illustrated in figures 1 and 2. System 300 can be configured as a heterogeneous network where several access points or eNBs having different characteristics can be employed. For example, eNBs of different types such as macro cell eNBs, peak cell eNBs, and femto cell eNBs can be developed in close proximity in a particular area or region. In addition, eNBs of different energy classes can also be developed in several implementations. The eNBs illustrated in figure 3, together with their associated cells, can be configured to use the subframe division as further described here. In general, subframe splitting is provided in connected mode to facilitate mitigation of network interference and / or provide range extension.
[0094] The 300 network includes six eNBs 310, 320, 330, 340, 350 and 360. These eNBs can be of different types and / or different power classes in various implementations. For example, in system 300, the eNB 310 can be a higher power eNB associated with a macro cell, the eNB 320 can be another macro cell eNB that can operate in a different power class, the eNB 330 can be another eNB operating in the same power class or in a different class, and the 340 and 350 eNBs can be peak cell eNBs. Other eNBs of other types and / or classes, such as femto cell nodes, etc. (not shown) can also be included. ENB 330 can be in communication with UEs served 331 and 332, and can additionally create interference with UE 351, which can be served by eNB 350. Accordingly, intercellular interference coordination between eNB 330 and eNB 350 can be used to mitigate such interference, as further described here. Likewise, UEs 341 and 342, which can be served by eNB 340, can be subjected to interference from macro cell eNB 320, which may be serving UE 321. In these two examples, macro cell nodes can create interference with peak cell nodes, however, in other cases, peak cell nodes may create interference with macro cell nodes (and / or femto cell nodes) and, in addition, macro cell nodes may create interference with each other. the other. For example, the macro cell eNB 360, which is serving the UE 361, may create interference with the UE 312, which is being served by the eNB 310, which may be a higher-powered eNB, which may also be serving the UE 311.
[0095] As illustrated in the simplified timing diagrams 315-365 of figure 3, in one aspect, each eNB and its associated UEs can receive certain subframes (as illustrated by the dashed part in figure 3) where to operate. The subframes illustrated in white can be restricted so that transmissions are limited or prohibited. Some eNBs can receive all or most of the subframes. For example, eNB 310 is illustrated as being able to use all of the subframes in the 315 timing diagram. Other eNBs can only receive specific subframes in which to operate. For example, eNB 330 receives certain subframes as illustrated in timing diagram 335, while eNB 360 receives orthogonal subframes as illustrated in diagram 365 (where subframes are designated to be orthogonal by time division). Various other combinations of subframes can be used in various modalities, including those described further below here.
[0096] The allocation of subframes can be done by direct negotiations between the eNBs such as those illustrated in figure 3, and / or can be carried out in conjunction with a return access channel network. Figure 4a illustrates details of an illustrative network modality 400b of the interconnection of eNB with other eNBs. Network 400a may include a macro eNB 402 and / or multiple additional eNBs, which may be peak cell eNBs 410. Network 400 may include a HeNB 434 access circuit for scalability reasons. The macro eNB 402 and the access circuit 434 can each communicate with a set 440 of mobility management entities (MME) 442 and / or a set 444 of server access circuits (SGW) 446. The access circuit eNB 434 access can appear as a plan C relay and a U plan for dedicated S1 connections 436. An S1 connection 436 can be a logical interface specified as the boundary between an evolved packet core (EPC) and an Evolved Universal Terrestrial Access Network (EUTRAN). As such, it provides an interface to a core network (not shown) that can be additionally coupled to other networks. The eNB 434 access circuit can act as a macro eNB 402 from an EPC point of view. The interface of plane C can be MME S1 and the interface of plane U can be S1-U. The allocation of subframes can be carried out by direct negotiations between eNBs as shown in figure 3, and / or can be carried out in conjunction with a return access channel network. Network 400 may include a macro eNB 402 and multiple additional eNBs, which may be cell 410 peak eNBs.
[0097] The return access channel eNB 434 can act in the direction of an eNB 410 as a single EPC node. The eNB 434 access circuit can measure S1-flex connectivity for an eNB 410. The eNB 434 access circuit can provide 1: n relay functionality so that a single eNB 410 can communicate with n MMEs 442. The circuit access code eNB 434 records in the direction of the set 440 of MMEs 442 when put into operation through the configuration procedure S1. The eNB 434 access circuit can support the configuration of S1 interfaces 436 with eNBs 410.
[0098] The 400b network can also include a self-organizing network server (SON) 438. The SON 438 server can provide automated optimization of an LTE 3GPP network. The SON 438 server can be a key driver to enhance the operation and maintenance management (OAM) functions in the wireless communication system 400. An X2 420 link can exist between the eNB macro 402 and the eNB 434 access circuit. Links X2 420 can also exist between each of the 410 eNBs connected to a common eNB 434 acceptance circuit. The X2 420 links can be configured based on the SON 438 server register. An X2 420 link can carry ICIC information. If an X2 420 link cannot be established, link S1 436 can be used to carry ICIC information. The return access channel signaling can be used in the communication system 400 to manage various functionalities as further described here between eNB macro 402 and eNBs 410. For example, these connections can be used as described further in succession here to facilitate coordination and scheduling of subframe allocation.
[0099] Figure 4b illustrates another illustrative modality of a 400b network modality of the eNB interconnection with other eNBs. In network 400b, no SON servers are included, and macro eNBs, such as eNB 402, can communicate with other eNBs, such as eNB pico 410 (and / or with other base stations that are not illustrated).
[00100] Figure 5 illustrates an illustrative frame structure 500 as can be used, for example, in a TDD LTE system. In frame structure 500, a radio frame consists of 10 subframes, denoted subframes No. 0 to No. 9. The radio frame can be divided into two frame halves consisting of 5 subframes as illustrated. In illustrative implementations, each subframe has a duration of 1 ms, resulting in a radio frame duration of 10 ms.
[00101] In one aspect, the subframes of a radio frame, as illustrated, for example, in figure 5, can be allocated interlaced with particular cells and associated eNBs, as illustrated, for example, in figure 3.
[00102] Figure 6 illustrates an illustrative wireless network 600 for use of the divided subframes. System 600 may employ subframe interleaving over a 610 wireless network, as in a network configuration as previously illustrated in figures 1 through 4. System 600 includes one or more eNBs 620 (also referred to as a node , base station, eNB server, target eNB, femto node, peak node, etc.) that can be an entity capable of communicating over the 610 wireless network to various 630 devices.
[00103] For example, each device 630 can be a UE (also referred to as a terminal or AT, UE, MME or mobile device). ENBs or base stations 120 may include an interleaving split component 640, which can be a module where subframe interleaving can be configured semi-statically or dynamically as further described here to mitigate interference on the 610 network. Devices 630 can include a 644 interlacing processing component which can be a module configured to receive and respond to the configured subframe interlocks as further described here. As illustrated, the eNB 620 can communicate with the device or devices 630 via DL 660, and receive data via UL 670. Such designation as UL and DL is arbitrary since the device 630 can also transmit data via downlink and receive data through uplink channels. It is noted that although two wireless network components 620 and 630 are illustrated, more than two components can be employed in network 610, where such additional components can also be adapted for processing the subframe interleaving described here.
[00104] In general, interlacing techniques can be provided to mitigate interference between nodes on a heterogeneous 610 wireless network (which can also be denoted hetnet). In one aspect, TDM division of subframe interlaces can be provided between classes and / or types of eNB to solve near-far interference problems for UE in connected mode, and / or to solve other problems and concerns. Subframe interlaces can be allocated to an eNB class and can be assigned semi-static to base station 620, where UE 630 is reliably signaled in advance of allocation (that is, in a semi-static allocation, a device, such as a UE 630, is signaled before the transmission of a particular subframe allocation or allocations). Semi-static allocation can then be used, for example, for the 630 device and / or eNB physical layer control procedures. Semi-static allocations can be used for UE and eNB physical layer control procedures.
[00105] In another aspect, the subframe interlaces can be dynamically designated, where the designation is performed dynamically and is unknown to the 630 device in advance. Dynamic designations can typically be used for eNB 620 physical layer control procedures (but typically not UE). The subframe interleaving division can be denoted by triple identifiers (L, N, K), for example, as will be described in greater detail subsequently. Dynamic allocations will generally be used for eNB physical layer control procedures, but not for UE.
[00106] The system design for heterogeneous network design (for example, LTE-A) can employ existing signals and channels that use system acquisition, random access, data communication, control and data. Advanced receptor algorithms can be provided to allow deep channel penetration, and provide more accurate measurements on the UE 630 and eNB 620. This approach can allow for a more flexible EU cell association and can facilitate better coordination across cells. In addition, the TDM-based interleaving division between different eNB power classes can be semi-static or dynamic as previously described. Additional dynamic resource coordination components between eNBs 620 can also be provided (such as, for example, return access channel communications channels between nodes as illustrated in figure 4).
[00107] It is noted that implementations of system 600 can be employed with a UE or other fixed or mobile device, and can, for example, be implemented as a module such as an SD card, a network card, a network card wireless, a computer (including laptops, desktops, PDAs), mobile phones, smart phones, or any other suitable device that can be used to access a network. The UE can access the network through an access component (not shown).
[00108] In one example, a connection between the UE and the access components can be wireless in nature, where the access components can be the eNB (or other base station) and the mobile device is a wireless terminal. For example, the terminal and the mobile station can communicate via any suitable wireless protocol, including, but not limited to TDMA, CDMA, FDMA, FDMA, Flash OFDM, OFDMA, or any other suitable protocol.
[00109] The access components can be an access node associated with a wired network or a wireless network. For this purpose, the access components can be, for example, a router, a switch and the like. The access component can include one or more interfaces, for example, communication modules, to communicate with other network nodes. In addition, the access component can be a base station such as an eNB (or other wireless access point) on a cellular type network, where base stations (or wireless access points) are used to provide wireless coverage areas. wire for a plurality of subscribers. Such base stations (or wireless access points) can be arranged to provide contiguous coverage areas for one or more cell phones and / or other wireless terminals, as illustrated, for example, in figures 2 and 3.
[00110] Figure 7 illustrates details of a modality of wireless network components 700 that can be used to implement the subframe interleaving division. In particular, two or more base stations, illustrated as eNBs 710 and 720, can communicate with request interlocks (that is, particular subframe allocations), negotiate or determine subframe allocations and / or transmit to associated network components, such as associated UEs (not shown) using interlacing subframes. Each of the eNBs u710 and 720 can include a subframe allocation and coordination module 715, 725 to perform the subframe allocation and use functions described here. Base stations 710 and 720 can communicate via an X2 750 connection, and / or via an S1 762, 764 connection. A core or return access channel 708 network can provide interconnectivity and / or can manage, across or in part, the division and allocation of subframes.
[00111] Figure 8 illustrates details of a modality of the wireless network components 800 that can be used to implement the subframe interleaving division. Base station (eNB) 810 may be in communication with associated UE 810 via downlink 852 and uplink 854. Another base station (eNB) 820 may be in an adjacent cell and may have subframe interleaving coordinated with eNB 810, such as illustrated in figure 7. A semi-static subframe can be assigned to eNB 810, which then communicates the subframe to UE 830. Alternatively and / or in addition, a dynamic subframe or subframe can also be allocated between eNBs 810 and 820.
[00112] During the semi-static subframe, eNB 820 may refrain from transmitting during the semi-static subframe, with the UE 830 performing monitoring or other functions during the semi-static subframe. Monitoring can be based on the transmission on a DL 860 from eNB 820. The transmission of eNB during the semistatic subframe assigned to eNB 810 can be controlled on a transmission control module of subframe 825. Likewise, the allocation subframe can be implemented in eNB 810 in module 815 and / or in communication between eNB 810 and eNB 920 and / or in a core network module (not shown). After performing the monitoring functionality, which can be performed on the UE 830 on a subframe monitoring module 835, the parameters determined on the UE 830 can then be transmitted to the eNB 810. For example, RSRP, RSRQ and / or other common reference signal (CRS) metrics can be performed on the UE 830 during the semistatic interval. These measurements can be associated with radio link monitoring (RLM) measurements and processing and radio link failure declaration (RLF). For example, the RLF statement can be based on measurements made during the semi-static subframe rather than on other subframes that may be subjected to additional interference. In general, the network should have a freedom in configuring resources (such as subframes or anything else that is allowed by the standard) to which the UE will restrict its measurements. A basis for the configuration of semi-static subframes can be the minimization of signaling to the UE.
[00113] Measurements of radio resource management (RMM), such as RSRP and RSRQ, in addition to other metrics such as channel return and / or other metrics, can be performed by the UE 830, and can be performed in the module of monitoring 835. In one aspect, the network can configure the UE to use semi-static designated subframes only, in whole or in part, thereby restricting measurements in the UE to a signaled or configured set of resources.
[00114] Alternatively or additionally, the network can also configure measurements on resources that are not designated in a semi-static manner. In general, the network can restrict EU measurements to a set of resources where the interference characteristics must be similar within the set, but potentially and significantly different outside the set. Measurement restrictions in this case may allow the UE to report the separate measurement quantities to the network, and therefore provide more information about radio conditions in the UE. In the case of common non-collision reference signals (CRS), the measurements (for example, measurements made on the received CRS) will only compensate for the interference of the data resource elements and can therefore be significantly dependent on whether the neighboring cell is programming data traffic on a given resource (for example, subframe) or not. In the case of collision CRS, measurements will only compensate for interference from neighboring CRS. It is noted that, similar to RRM measurements, channel quality measurements (for example, CQI / PMI / RI) can also be restricted to a set of features. During the initial connection, as in LTE systems, the initial communication between the UEs and the base stations can be denoted as Msg 1, Msg 2, Msg 3, etc., based on the order of the communication. Msg1 can be started from the base station to the UEs within the coverage range. In the event of interference from a neighboring cell, an access procedure may include having the eNB transmit Msg2 in DL allocated subframes and programming Msg3 in UL allocated subframes. In particular, Msg 3 can be designed to benefit from HARQ. In order to extend the HARQ benefits when subframe splitting is used, the delay bit in Msg 2 may need to be extended to cover all subframe splitting situations (for example, delays of more than one subframe may need to be considered) in the EU). This can be done by adding one or two extra bits to allow a delay of four to eight milliseconds to be signaled to the UE. Alternatively or additionally, a UE can reinterpret the meaning of a bit (assuming that a bit is used). For example, instead of a bit representing five or six milliseconds, the additional delay bit represents a different delay value. In one example, the delay bit can be set so that it does not refer to six milliseconds, but instead to the next known and available protected subframe. In this situation, the subframe when Msg 2 is transmitted is known to be protected and repeated every eight ms, and the next available subframe is 12 ms afterwards (for example, eight milliseconds for periodicity and four milliseconds for the nominal deviation between UL and DL).
[00115] Figure 9 illustrates an illustrative embodiment of the allocation of subframe 900 between a macro cell (denoted as Mj) and a peak cell (denoted as PK) in a wireless communication system as illustrated in 3. It is noted that this allocation of subframe interlacing in particular is provided for purposes of illustration, not limitation, and many other subframe allocations, including those illustrated subsequently here, can also be used in various implementations. The subframe allocation can be described by a crack (L, N, K) where L is the number of semi-static allocations for an eNB of a particular class, such as, for example, Class M defining a macro cell, N is the number of semi-static allocations from a second class, such as, for example, Class P defining a peak cell, and K which is the number of dynamic subframe divisions available. Where a subframe allocation is equal to 8, such as, for example, to facilitate HARQ, K is equal to 8-L-N.
[00116] Timing diagram 910 illustrates the subframe allocations designated for cell downlink Mj and diagram 920 illustrates the corresponding uplink. Likewise, diagrams 930 and 940 correspond to DL and UL for the peak cell Pk. In this example (L, N, K) = (1,1,6). HARQ can be used in the wireless communication system. Using HARQ as defined in an LTE implementation, responses are defined as occurring at intervals of 4 subframes. For example, as illustrated in cell Mj, a DL transmission in subframe 0 (illustrated as subframe 922) would expect a response in an ACK / NACK transmission in subframe 4 (illustrated as 924). This cycle is repeated periodically as shown in figure 9.
[00117] Subframe allocation can be done so that the semistatic subframe designation from a first cell, such as the macro cell Mj, has a corresponding unassigned partition in the adjacent peak cell Pk. For example, in subframe 0, subframe 922 can be semi-statically assigned to cell Mj, and correspondingly not designated in cell Pk. During that subframe, between moments T0 and T1, a UE in cell Mj can perform the monitoring functions as described here. Likewise, if subframe 4 (illustrated as subframe 924) is assigned to cell Pk, the subframe may not be assigned to cell Mj, as illustrated between time T23 and T4.
[00118] Additionally, as illustrated in figure 9, the subframes can be dynamically allocated to any cell. In this case, 6 subframes were dynamically allocated to cell Mj, while none were allocated to cell Pk. Dynamic allocation can be based on particular traffic requirements associated with the particular cells, cell types and / or power level, or other related parameters. In general, dynamic allocation can be done in conjunction with a core network, such as a 708 core network in figure 7. Dynamic allocation may vary during operation based on load, interference level, power level or other operational parameters .
[00119] Semi-static allocation can typically be performed on a limited number of subframes. For example, in an implementation, only a few subframes in each cell can be allocated semi-statically. Furthermore, in implementations having relatively low traffic, such as the cell Pk illustrated in figure 9, allocations can include only a single semi-static subframe for DL and / or UL.
[00120] Figure 10 illustrates another illustrative subframe division allocation 1000, in this case having a crack (L, N, K) equal to (3: 3: 2). In this example, multiple subframes can be allocated to cell Mj and cell Pj as illustrated. In this case, at least one semi-static allocation will have a corresponding unassigned subframe allocated to another cell. For example, subframe 0 (illustrated as 1022) can be allocated semi-statically to cell Mj, with a corresponding unallocated subframe in cell Pk. Likewise, subframe 3 (illustrated as 1024) can be allocated semi-statically to cell Pk, with the corresponding unallocated subframes in cell Mj. During these time intervals (for example, between T0 and T1 and T2 and T3) UEs in the corresponding cells can perform the measurements as described here.
[00121] Figures 11 to 15 illustrate additional examples of the interlacing allocations of subframes 1100, 1200, 1300, 1400 and 1500 and associated subframes in a semi-static or dynamic manner.
[00122] Figure 11 illustrates an illustrative allocation 1100 where the subframes are dynamically allocated to both cells Mj and Pk with the value (L, N, K) of (2: 2: 4). Timing diagram 1110 illustrates a downlink subframe configuration for cell Mj, which can be a macro cell, and timing diagram 1120 illustrates the corresponding uplink configuration. Likewise, timing diagram 1130 illustrates a downlink subframe configuration for cell Pk, which can be a peak cell, while timing diagram 1140 illustrates the corresponding uplink configuration.
[00123] Figure 12 illustrates an illustrative allocation 1200 where the subframes are dynamically allocated to both cells Mj and Pk with values (L, N, K) of (2: 2: 4). Timing diagram 1210 illustrates a downlink subframe configuration for cell Mj, which can be a macro cell, and timing diagram 1220 illustrates the corresponding uplink configuration. Likewise, timing diagram 1230 illustrates a downlink subframe configuration for cell Pk, which can be a peak cell, while timing diagram 1240 illustrates the corresponding uplink configuration. The allocations illustrated in the example in figure 14 can be determined, for example, by the coordination between the two cells and associated base stations, which may additionally include coordination with a return access channel core or network, as described elsewhere. .
[00124] Figure 13 illustrates an illustrative allocation 1300 where subframes are dynamically allocated to both Mj and Pk cells with values (L, N, K) equal to (2: 2: 4). Timing diagram 1310 illustrates a downlink subframe configuration for cell Mj, which can be a macro cell, timing diagram 1320 illustrates the corresponding uplink configuration. Likewise, timing diagram 1330 illustrates the downlink subframe configuration for cell Pk, while timing diagram 1340 illustrates the corresponding uplink configuration. The allocations illustrated in the example of figure 14 can be determined, for example, by the coordination between two cells and associated base stations, which may additionally include coordination with a return access channel core or network, as described elsewhere.
[00125] Figure 14 illustrates an illustrative allocation 1400 where subframes are dynamically allocated between three cells, Mj, Pk and Fr. Timing diagram 1410 illustrates a downlink subframe configuration for cell Mj, which can be a macro cell and timing diagram 1420 illustrates the corresponding uplink configuration. Likewise, timing diagram 1430 illustrates a downlink subframe configuration for cell Pk, which can be a peak cell, while timing diagram 1440 illustrates the corresponding uplink configuration. In addition, timing diagram 1450 illustrates a downlink subframe configuration for cell Fr, which can be a femto cell, and timing diagram 1460 illustrates a corresponding uplink configuration. The allocations illustrated in the example in figure 14 can be determined, for example, by coordination between the three cells and associated base stations, which may additionally include coordination with a return access channel core or network, as described elsewhere .
[00126] Figure 14 illustrates another illustrative allocation 1500 where subframes are dynamically allocated between three cells, Mj, Pk and Fr. Timing diagram 1510 illustrates a downlink subframe configuration for cell Mj, which can be a macro cell and timing diagram 1520 illustrates the corresponding uplink configuration. Likewise, timing diagram 1530 illustrates a downlink subframe configuration for cell Pk, which can be a peak cell, while timing diagram 1540 illustrates the corresponding uplink configuration. In addition, timing diagram 1550 illustrates a downlink subframe configuration for cell Fr, which can be a femto cell, and timing diagram 1560 illustrates a corresponding uplink configuration. The allocations illustrated in the example in figure 15 can be determined, for example, by coordination between the three cells and associated base stations, which may additionally include coordination with a core or return access channel network, as described elsewhere .
[00127] Potential Impacts on Subframe Structure - In some implementations, the use of subframe interlacing can be performed so that no change in the transmission format is necessary for signals including PSS / SSS, PBCH, RS and SIB1. PSS and SSS are transmitted in subframe 0 and 5. PBCH is transmitted in subframe 5 of the even radio frames. SIB-1 is transmitted in subframe 5 of the even radio frames. A reference signal (for example, CRS) can be transmitted in each subframe. For subframe interleavings designated for an eNB (either semi-static or dynamic), the same considerations apply. For subframe interleavings not assigned to an eNB, PDCCH, PHICH and PCFICH may not be transmitted and PDSCH may not be programmed (unless SIB-1 is programmed). PUSCH may not be programmed, PUCCH may not be configured (unless legacy UE Version 8 is designated to transmit CQI / PMI and RI). PRACH and SRS may not be configured.
[00128] In some implementations, certain allocations can be adjusted in order to protect, for example, channels of particular importance. An example of this is illustrated in figure 16, where a macro cell, which may be a high-power cell, is operating in close proximity to a peak cell, which may be a low-power cell. It can be important to protect certain resources, such as those illustrated in figure 16. For example, resources 1612 (in subframe 5) can be assigned to the macro cell. PCFICH, PDCCH and / or other resources can be programmed in a semi-persistent manner, which can be performed using SIB-1. This may include the use of dedicated signaling for UEs in RRC_Connected mode only. Additionally, some 1612 resources, such as the physical downlink shared channel (PDSCH) can be protected, such as by orthogonalization of the resource, and / or interference cancellation. This can allow the pico cell to use these 1622 resources, as illustrated in the 1620 resource diagram, without interference from the macro cell.
[00129] Figure 17 illustrates another example of resource protection. In this example, certain resources can be protected for a macro cell. For example, the interference can be from SIB-1 and / or page transmissions. The subframe and page occasions can be assigned to a peak cell (or another cell of lower power). SIB-1 and / or page interference cancellation can be used, in addition to PCFICH / PDCCH interference cancellation. If, for example, the dominant interference in the subframes designated from SIB-1 and page transmissions cannot be canceled (for example, if they are in the control channel region only), the retransmissions on that interface (for example, the subframe 8 mS previous) can request the programming of the retransmission in that subframe. In order to facilitate this, 1722 resources can be excluded from the peak cell, as illustrated in the 1720 resource diagram. These can be within the PDSCH. Similarly, 1712 resources can be allocated to the macro cell as illustrated in the 1710 resource diagram.
[00130] Potential Impacts on RRM - The division of semi-static subframe will typically be carried out on a core network or return access channel as an operation based on OA&M. This approach can compensate for the target performance of physical layer control procedures. The dynamic subframe division can be based on a quality of service (QoS) metric of the EU supports associated with a cell. This can compensate for the use of the physical resource block (PRB) and the amount of data that a UE is transmitting and receiving.
[00131] The downlink radio link failure (RLM) monitoring procedure can be based on a semi-static configured subframe. Since the UE will be notified in advance about the semi-static subframes, it can make considerations about the channel characteristics during these subframes. The UE will generally not be able to carry out considerations on dynamically allocated subframes.
[00132] The supervision of the uplink RLM procedure can be based on subframes configured in a semi-static and / or dynamic way.
[00133] The control signaling X2 (X2-C) is generally not required for the division of semi-static subframe, however, it can be used in some implementations. Signaling for dynamic subframe division can be performed using a transfer procedure between eNBs. These can be eNBs that interfere with each other, which can belong to different classes. Examples of transfer procedures are further illustrated in figures 18 to 20.
[00134] Figure 18 illustrates details of the illustrative signal flow 1800 using X2-C signaling, for a successful total resource expansion request between three cells and associated nodes, such as eNBs. Signaling can be provided, for example, between wireless network nodes in cells 1872, 1874, 1876, 1878 and 1880, as shown in figure 18. Cells designated as P can be pico cells, and cells designated like M can be macro cells. Alternatively, other cell types and / or power levels can communicate in a similar way. An 1810 resource expansion request can be sent from cell 1872 to cell 1874. Alternatively or in addition, another 1820 resource expansion request can be sent from cell 1872 to cell 1876. Cells 1874 and 1876 can be macro cells operating adjacent to cell 1872, which may be a peak cell or another cell of lower potency. Response timing can be governed by a resource expansion timer, which can be initialized at times 1815 and 1825, corresponding to requests 1810 and 1820. In this case, cells 1874 and 1876 can still accept the resource expansion request by complete, as illustrated with acceptances 1830 and 1840, before a time expiration. In addition, cells 1874 and 1876 can signal other cells, such as cells 1878, with respect to the resource request and associated resource adjustments. For example, cells 1878 and 1880 can be provided with resource usage indications 1850 and 1860, which can indicate which resources have been adjusted with respect to cells 1872 and 1874, so that these resources can be used by cells 1878 and 1880, and / or for other signaling or control purposes. For example, cell 1874 can signal adjacent or neighboring cells 1878, while cell 1876 can signal adjacent or neighboring cell 1880. Resource utilization timers 1835 and 1845 can be started with resource expansion acceptances 1830 and 1840.
[00135] Figure 19 illustrates details of another illustrative signal flow 1900 using X2-C signaling, in this case for a partially successful resource request, for example, where the resources can be partially, rather than fully, expanded. This can be done between, for example, three cells and associated nodes, such as eNBs. Signaling can be provided, for example, between wireless network nodes in cells 1972, 1974, 1976, 1978 and 1980, as shown in figure 19. The cells designated as P can be pico cells, and the cells designated as M can be macro cells. Alternatively, other cell types and / or power levels can communicate in a similar way. A 1910 resource expansion request can be sent from cell 1972 to cell 1974. Alternatively or in addition, another 1920 resource expansion request can be sent from cell 1972 to cell 1976. Cells 1974 and 1976 can be macro cells operating adjacent to the 1972 cell, which may be a peak cell or another cell of lower potency. Response timing can be governed by a resource expansion timer, which can be started at times 1915 and 1925, corresponding to requests 1910 and 1920. In this case, cell 1974 can accept the request completely (with 1930 acceptance), but the 1976 cell can accept the resource expansion request only partially, as illustrated with the partial acceptance and 1940. This can trigger a 1945 prohibition timer, which can be used to limit resource usage, as in the 1972 cell. 1950 response indication can be provided with respect to partial release, which may indicate, for example, full acceptance, partial or no acceptance. Based on the response to expansion requests, cell 1976 can signal acceptance of partial release, such as through the 1960 indication. This information can be additionally provided to other adjacent or neighboring cells, such as through the 1970 indication. full expansion can be signaled from cell 1974 to cell 1980 (not shown in figure 19). Resource utilization timers 1935 and 1945 can be started with resource expansion acceptance and partial acceptance 1930 and 1940.
[00136] Figure 20 illustrates details of the illustrative signal flow 2000 using X2-C signaling, for a partially unsuccessful resource request between three cells and associated nodes, such as eNBs. Signaling can be provided, for example, between wireless network nodes in cells 2072, 2074, 2076, 2078 and 2080, as shown in figure 20. Alternatively, other cell types and / or power levels can communicate in a similar way. A 2010 resource expansion request can be sent from cell 2072 to cell 2074. Alternatively or additionally, another resource expansion request 2020 can be sent from cell 2073 to cell 2076. Cells 2074 and 2076 can be macro cells operating adjacent to cell 2072, which may be a peak cell or another cell of lower potency. Response timing can be governed by a resource expansion timer, which can be started at times 2015 and 2025, corresponding to requests 2010 and 2020. In this case, cell 2074 can accept the request, such as through acceptance 2030, while cell 2076 can reject the request. The rejection can be signaled to cell 2072 via a 2040 rejection response, which can then start a 2045 ban timer. An indication of resource usage 2050 can be provided from cell 2072 to cell 2074. Acceptance can be additionally signaled to other cells, such as cells 2078 and 2080 (not shown in figure 20). The 2035 resource utilization timer can be started with the 2030 resource expansion acceptances.
[00137] Figure 21 illustrates details of an embodiment of an illustrative process 2100 for providing wireless communications using subframe allocation. At stage 2110, a subframe split configuration can be received, such as, for example, at a base station, which can be an eNB or HeNB, from, for example, a core network. Alternatively or additionally, the subframe split can be generated, in whole or in part, in communication with another base station, such as a base station in a neighboring or adjacent cell, and / or in conjunction with the core network. In stage 2120, the split information can be stored, for example, in a base station memory. At a 2130 stadium, a first signal can be sent and can, for example, be consistent with a first DL resource allocation included in the split configuration. At stage 2140, a second signal can be sent and can, for example, be consistent with a second DL resource allocation included in the split configuration. The first and second DL resources can be of different types. For example, the first DL resource can be a semi-static resource and the second DL resource can be a dynamic resource. In another example, both resources can be of the same type.
[00138] The first DL resource can be, for example, orthogonal to a second DL resource allocated to a second base station. The first DL resource and the second DL resource can be multiplexed by time division and / or multiplexed by frequency division. The subframe split configuration may additionally include, for example, an allocation of at least one unassigned resource. The first base station can be, for example, one of a macro cell base station, a femto cell base station or a peak cell base station.
[00139] The method may additionally include, for example, the negotiation, with a second base station, of a configuration and determination of subframe resource allocation based on the negotiation, the subframe resource allocation. The subframe resource allocation can be stored, for example, in a memory. Various modalities can be in the form of a computer program product, communication device, device module or other configuration.
[00140] Figure 22 illustrates details of an embodiment of an illustrative process 2200 for providing wireless communications using subframe allocation. At stage 2210, a subframe split configuration can be received and stored, such as, for example, on a network node, which can be a base station. The allocation can be provided from, for example, a core network. Alternatively, or in addition, the subframe split configuration may be determined, in whole or in part, at the base station, which may be in communication with another base station and / or the core network to facilitate determination of the split configuration. Base stations can be, for example, eNBs or HeNBs. The subframe split configuration can include one or more features configured in a semi-static and / or dynamic way. In an illustrative embodiment, the configuration may include at least one first semi-static feature. At stage 2220, a signal can be transmitted, such as to a UE, consistent with the resource allocation. The signal can be transmitted, for example, consistently with a semi-static resource allocation. At stage 2230, a signal metric can be received from a network node, such as, for example, a UE. At stage 2240, communication system resources can be allocated, which can be done, for example, in a manner consistent with the received signal metric.
[00141] The first semi-static DL resource can be, for example, orthogonal to a second semi-static DL resource allocated to a second base station. The signal metric can be, for example, an RLM metric, and the RLM metric can be determined during a semi-static subframe. The semi-static subframe can be signaled to the UE before transmission. The method may additionally include, for example, the allocation of the communications resource based at least in part on the signal metric. The communication connection between the base stations can be a wireless connection, such as, for example, an X2 connection. Alternatively or additionally, the communication connection may be a return access channel connection to one or more core networks and / or functional modules OA&M. If a return access channel connection is used, it can include, for example, an S1 connection. The first base station and / or the second base station can be in communication with the core network. The determination can be carried out, for example, in conjunction with the core network. Alternatively, the determination of a configuration can be carried out independently of a core network, where the core network can be associated with the first base station and / or the second base station. Various modalities can be in the form of a computer program product, communication device, device, module or other configuration.
[00142] Figure 23 illustrates details of an embodiment of an illustrative process 2300 for providing wireless communications using subframe allocation. At stage 2310, a subframe resource allocation request can be received from a first network node, such as a base station, which can be, for example, an eNB or HeNB. The request can be generated based on communications between the base station and the UEs served, UEs of adjacent cells, and / or between the base stations, such as in adjacent cells. At stage 2320, subframe resources can be allocated based on the request. The allocation can be, for example, an allocation between the base station and another adjacent base station, which can be associated with an adjacent or neighboring cell. At stage 2330, an allocation configuration can be generated and delivered to the first base station. The allocation can also be provided for one or more additional base stations, such as base stations in neighboring or adjacent cells. At stage 2340, signaling can be sent from one or more of the base stations consistent with the resource allocation configuration. The signals can be used, for example, to determine a signal metric for the configuration of the communication system, and / or for other purposes, such as those described elsewhere.
[00143] The subframe resource configuration may include, for example, a semi-static subframe resource allocation and / or a dynamic subframe resource allocation. Alternatively or in addition, the subframe resource configuration can include an unassigned resource allocation. The subframe resource configuration can include, for example, a first semi-static resource allocation designated for the first wireless node and a second semi-static resource allocation designated for the second wireless network node. The first semi-static resource allocation and the second semi-static resource allocation can be configured to be orthogonal. Various modalities can be in the form of a computer program product, communication device, device, module or other configuration.
[00144] Figure 24 illustrates details of an embodiment of an illustrative process 2400 for providing wireless communications using subframe allocation. At stage 2410, a communication device, such as a terminal or UE, can receive a subframe resource allocation, such as, for example, from a first base station, which can be an eNB, HeNB, or another station base. At stage 2420, a first signal can be received from another base station, during a subframe or part of a subframe consistent with the resource allocation, which can be, for example, a semi-static resource allocation. At stage 2430, a signal metric can be determined based on the first signal. In stage 2440, the signal metric can be sent to the first base station, where it can be additionally used for configuration of the communication system or other processing.
[00145] The information received can be related to a predetermined subframe resource allocation, which can be, for example, a semi-static or dynamic allocation. The signal metric can be, for example, an RLM metric. The information received can include, for example, RRM control information. The information can also include channel return information and / or CQI information. The first base station can be associated with a first cell and the first signal can be transmitted from a node, such as a base station, which can be an eNB, HeNB, or another base station associated with a second cell. The first cell can be, for example, a macro cell and the second cell can be a peak cell or femto cell. Alternatively, the first cell can be a peak cell or femto cell and the second cell can be a macro cell. Alternatively, the first cell can be a peak cell or femto cell and the second cell can be a macro cell. Alternatively, the first and second cells can be macro cells or the first and second cells can be pico cells or femto cells. The first signal can be, for example, a reference signal. The reference signal can be a CRS and / or a CSI-RS. Various modalities can be in the form of a computer program product, communication device, device, module, or other configuration.
[00146] Figure 25 illustrates a block diagram of a modality of the base station 2510 (that is, an eNB or HeNB) and a terminal 2550 (that is, a terminal, AT or UE) in an illustrative LTE communication system 2500 These systems can correspond to those illustrated in figures 1 to 4, and can be configured to implement the processes previously illustrated here in figures 18 to 24.
[00147] Various functions can be performed on the processors and memories as illustrated in the base station 2510 (and / or other components not shown), such as determining subframe division allocations and configuration, output transmission control to provide transmission during semi-static and / or dynamically allocated subframes, in addition to other functions as previously described here. UE 2550 may include one or more modules to receive signals from the base station 2510 to determine channel characteristics, such as during the semistatic subframes perceived in the UE, such as channel performance estimates, demodulated received data and generation of spatial information, determination power level information and / or other information associated with the base station 2510 or other base stations (not shown).
[00148] In one embodiment, the base station 2510 can adjust the output transmissions in response to information received from the UE 2550 or from the return access channel signaling from another base station or a core network (not shown in figure 25 ) as previously described here. This can be done on one or more components (or other components not shown) of the base station 2510, such as processors 2514, 2530 and memory 2532. The base station 2510 may also include a transmission module including one or more components (or others) components (not shown) of the eNB 2510, such as 2524 transmission modules. The base station 2510 may include an interference cancellation module including one or more components (or other components not shown), such as 2530, 2542 processors, 2540 demodulator module , and 2532 memory to provide interference cancellation functionality. The base station 2510 may include a subframe division coordination module including one or more components (or other components not shown) such as processors 2530, 2514 and memory 2532 to perform subframe division functions as previously described here and / or manage the transmitter module based on subframe division information. The base station 2510 may also include a control module to control the functionality of the receiver. The base station 2510 may include a network connection module 2590 to provide networking with other systems, such as return access channel systems in the core network or other components as illustrated in figures 2 and 3.
[00149] Likewise, UE 2550 may include a receiving module including one or more components of UE 2550 (or other components not shown), such as 2554 receivers. UE 2550 may also include a signal information module including one or more more components (or other components not shown) of the UE 2550, such as processors 2560 and 2570, and memory 2572. In one embodiment, one or more signals received on the UE 2550 are processed to estimate channel characteristics, power information, information space and / or other information related to eNBs, such as base station 2510 and / or other base stations (not shown). Measurements can be performed during the semi-static subframes that are perceived by the UE 2550 by the base station 2510. Memories 2532 and 2572 can be used to store a computer code to run on one or more processors, such as processors 2560, 2570 and 2538, to implement the processes associated with the measurement and information of channel, power level and / or determination of spatial information, selection of cell ID, intercellular coordination, interference cancellation control, in addition to other functions related to the allocation of subframe, interlacing, and associated transmission and reception as described here.
[00150] In operation, at base station 2510, traffic data for various data streams can be provided from a data source 2512 to a transmission data processor (TX) 2514, where it can be processed and transmitted to one or more 2550 UEs. The transmitted data can be controlled as previously described here in order to provide interlaced subframe transmissions and / or to carry out associated signal measurements on one or more 2550 UEs.
[00151] In one aspect, each data stream is processed and transmitted via a respective transmitting subsystem (illustrated as transmitters 252412525Nt) from base station 2510. The TX 2514 data processor receives, formats, encodes, and merges traffic data for each data stream based on a particular coding scheme selected for that data stream in order to provide encoded data. In particular, the base station 2510 can be configured to determine a particular reference signal and the reference signal pattern and provide a transmission signal including the reference signal and / or beamforming information in the selected pattern.
[00152] The encoded data for each data sequence can be multiplexed with pilot data using OFDM techniques. Pilot data is typically a known data pattern that is processed in a known way and can be used in the receiving system to estimate the channel response. For example, pilot data can include a reference signal. Pilot data can be supplied to the TX 2514 data processor as shown in figure 25 and multiplexed with the encoded data. The multiplexed pilot data and the encoded data for each data sequence can then be modulated (that is, mapped by symbol) based on a particular modulation scheme (for example BPSK, QSPK, M-PSK, M-QAM, etc.). ) selected for that data sequence to provide modulation symbols, and the data and pilot can be modulated using different modulation schemes. The data rate, encoding and modulation for each data stream can be determined by instructions performed by the 2530 processor based on instructions stored in memory 2532, or in other memory or instruction storage medium of the UE 2550 (not shown).
[00153] The modulation symbols for all data streams can then be provided for a MIMO TX 2520 processor, which can further process the modulation symbols (for example, for OFDM implementation). The MIMO TX 2520 processor can then supply Nt modulation symbol strings for Nt transmitters (TMTR) 25521 to 2522Nt. The various symbols can be mapped to associated RBs for transmission.
[00154] The MIMO TX 2530 processor can apply beamforming weights to the symbols in the data streams and corresponding to one or more antennas from which the symbol is being transmitted. This can be done by using information such as channel estimation information provided by or in conjunction with the reference signals and / or spatial information provided from a network node such as UE. For example, a beam B = transposition ([b1 b2..bNt]) is composed of a set of weights corresponding to each transmission antenna. The transmission over a beam corresponds to the transmission of an x modulation symbol across all antennas staggered by beam weighting for that antenna; that is, on antenna t the transmitted signal is bt * x. When multiple beams are transmitted, the signal transmitted on an antenna is the sum of the signals corresponding to different beams. This can be expressed mathematically as B1x1 + B2x2 + BNsxNs, where Ns beams are transmitted and xi is the modulation symbol sent using the Bi beam. In various implementations the bundles can be selected in several ways. For example, beams can be selected based on channel feedback from a UE, channel knowledge available in the eNB, or based on information provided from a UE to facilitate mitigation of interference, such as with a macro adjacent cell.
[00155] Each transmitting subsystem 25221 to 2522Nt receives and processes a respective symbol sequence to provide one or more analog signals, and further conditions (for example, amplifies, filters and upwards converts) the analog signals to provide a modulated signal suitable for transmission through the MIMO channel. Nt modulated signals from transmitters 25221 to 2522Nt are then transmitted from Nt antennas 25241 to 2524Nt, respectively.
[00156] In UE 2550, the transmitted modulated signals are received by Nt antennas 25521 to 2552Nr and the signal received from each antenna 2552 is supplied to a respective receiver (RCVR) 25541 to 2554Nr. Each 2554 receiver conditions (e.g., filters, amplifies and downwardly converts) a respective received signal, digitizes the conditioned signal to provide samples, and further processes the samples to provide a corresponding "received" symbol sequence.
[00157] An RX 2560 data processor then receives and processes the received Nr symbol strings from Nr receivers 25541 to 2552Nr based on a particular receiver processing technique in order to provide Ns "detected" symbol strings so to provide estimates of the transmitted symbol strings. The RX 2560 data processor then demodulates, deinterleaves and decodes each detected symbol sequence to retrieve traffic data for the data sequence. Processing by the RX 2560 data processor is typically complementary to that performed by the MIMO TX 2520 processor and the TX 2514 data processor at the base station 2510.
[00158] A 2570 processor may periodically determine a pre-coding matrix for use as further described below. The 2570 processor can then formulate a reverse link message that can include a matrix index part and a classification value part. In many respects, the reverse link message can include various types of information regarding the communication link and / or data stream received. The reverse link message can then be processed by a TX 2538 data processor, which can also receive traffic data for various data streams from a 2536 data source which can then be modulated by a 2580 modulator, conditioned by the transmitters. 25541 to 2554Nr, and transmitted back to base station 2510. Information transmitted back to base station 2510 may include information on power level and / or spatial information to provide beam formation to mitigate interference from base station 2510 .
[00159] At base station 2510, modulated signals from UE 2550 are received by antennas 2524, conditioned by receivers 2522, demodulated by a demodulator 2540, and processed by a data processor RX 2542 to extract the message transmitted by UE 2550. O processor 2530 then determines which pre-coding matrix to use for determining beamforming weights, and then processes the extracted message.
[00160] In some configurations, the device for wireless communication includes means for carrying out various functions as described here. In one aspect, the means mentioned above can be a processor or processors and associated memory in which the modalities reside, as illustrated in figure 25, and which are configured to perform the functions recited by the means mentioned above. They can, for example, be modules or devices resident in UEs, eNBs or other network nodes as illustrated in figures 1 to 4, and 6 to 8, to perform the functions related to the subframe division described here. In another aspect, the means mentioned above can be a module or any device configured to perform the functions recited by the means mentioned above.
[00161] In one or more illustrative modalities, the functions, methods and processes described can be implemented in hardware, software, firmware or any combination thereof. If implemented in software, functions can be stored in or encoded as one or more instructions or codes in a computer-readable medium. The computer-readable medium includes a computer storage medium. The storage medium can be any available medium that can be accessed by a computer. By way of example, and not limitation, such a computer-readable medium may include RAM, ROM, EEPROM, CD-ROM or other optical disk storage, magnetic disk storage or other magnetic storage devices, or any other medium that may be used to carry or store the desired program code in the form of instructions or data structures and which can be accessed by a computer. Floppy disk and disk, as used here, include compact disk (CD), laser disk, optical disk, digital versatile disk (DVD), floppy disk and blu-ray disk where diskettes normally reproduce data magnetically, while disks reproduce data optically with lasers. The combinations of the above should also be included in the scope of computer-readable media.
[00162] It should be understood that the specific order or hierarchy of the steps or stages in the processes and methods described are examples of illustrative approaches. Based on the design preferences, it is understood that the specific order or hierarchy of steps in the processes may have a new disposition while remaining within the scope of the present description. The attached method claims present elements of various stages in an illustrative order, and should not be limited to the specific order or hierarchy presented.
[00163] Those skilled in the art will understand that information and signals can be represented using any one of a variety of different technologies and techniques. For example, data, instructions, commands, information, signals, bits, symbols and chips that can be referenced throughout the above description can be represented by voltages, currents, electromagnetic waves, particles or magnetic fields, particles or optical fields or any combination thereof.
[00164] Those skilled in the art will additionally appreciate that the various illustrative logic blocks, modules, circuits, and algorithm steps described in relation to the modalities described here can be implemented as electronic hardware, computer software, or combinations of both. In order to clearly illustrate this ability to exchange hardware and software, several illustrative components, blocks, modules, circuits, and steps have been described above generally in terms of their functionality. Whether such functionality will be implemented as hardware or software depends on the particular application and the design restrictions imposed on the system as a whole. Those skilled in the art can implement the described functionality in a number of ways for each particular application, but such implementation decisions should not be interpreted as being responsible for distancing the scope of the description.
[00165] The various illustrative logic blocks, modules and circuits described in relation to the modalities described here can be implemented or carried out with a general purpose processor, a digital signal processor (DSP), an application specific integrated circuit (ASIC), a field programmable gate (FPGA) set, or other programmable logic device, discrete gate or transistor logic, discrete hardware components, or any combination thereof designed to perform the functions described here. A general purpose processor can be a microprocessor, but in the alternative, the processor can be any conventional processor, controller, micro controller, or state machine. A processor can also be implemented as a combination of computing devices, for example, a combination of a DSP and a microprocessor, a plurality of microprocessors, one or more microprocessors in conjunction with a DSP core, or any other similar configuration.
[00166] The steps or stages of a method, process or algorithm described in relation to the modalities described here can be embodied directly in hardware, in a software module executed by a processor, or in a combination of the two. A software module can reside in RAM memory, flash memory, ROM memory, EPROM memory, EEPROM memory, registers, hard disk, removable disk, CD-ROM, or any other form of storage medium known in the art. An illustrative storage medium is coupled to the processor so that the processor can read information from, and write information to, the storage medium. Alternatively, the storage medium can be integral to the processor. The processor and storage medium can reside in an ASIC. The ASIC can reside on a user terminal. Alternatively, the processor and the storage medium can reside as discrete components in a user terminal.
[00167] The claims should not be limited to the aspects illustrated here, but the full scope consistent with the language of the claims should be agreed, where the reference to an element in the singular should not mean "one and only one" unless specifically mentioned , but instead "one or more". Unless specifically stated otherwise, the term "some" refers to one or more. A phrase referring to "at least one of" a list of items refers to any combination of those items, including unique elements. As an example, "at least one of: a, b or c" should cover: a; B; ç; a and b; a and c; b and c; and a, b and c.
[00168] The previous description of the described aspects is provided to allow anyone skilled in the art to create or make use of this description. Various modifications to these aspects will be readily apparent to those skilled in the art, and the generic principles defined here can be applied to other aspects without departing from the spirit or scope of the description. Accordingly, the description should not be limited to the aspects illustrated here, but the broader scope consistent with the principles and novelty features described here must be agreed. The following claims and equivalences are intended to define the scope of the description.

权利要求:
Claims (13)
[0001]
1. Method for wireless signal transmission, the method comprising: storing a subframe split configuration on a first base station, where the subframe split configuration includes an interlacing allocation from a first downlink resource, DL , which is configured to be one of a semi-static feature or a dynamic feature; transmit, from the base station, a first signal according to the first DL resource allocation; the method CHARACTERIZED by: the first DL resource being orthogonal to the time division to a second DL resource allocated to a second base station, the second DL resource being allocated by the subframe division configuration to be one among a semi-static resource or a dynamic resource ; wherein the base station type of the first base station is one of a first power class macro cell base station, a femto cell base station, or a peak cell base station; and the type of base station of the first base station is different from the type of base station of the second base station.
[0002]
2. Method according to claim 1, CHARACTERIZED by further comprising transmitting, from the base station, a second signal consistent with a second DL resource allocation, the second DL resource being allocated by the subframe split configuration to be a between a semi-static resource and a dynamic resource in which the first DL resource is a semi-static resource and the second DL resource is a dynamic resource.
[0003]
3. Method, according to claim 1, CHARACTERIZED in that it further comprises sending a request to a core network for the subframe division; and receive the subframe split configuration.
[0004]
4. Method according to claim 3, CHARACTERIZED that the subframe split configuration is determined in the core network at least in part based on the information associated with a second base station.
[0005]
5. Method according to claim 1, CHARACTERIZED that the signal metric is an RLM metric, in which the RLM metric is determined during a semi-static subframe, in which the semi-static subframe is signaled to the UE before transmission.
[0006]
6. A communications device, comprising: mechanisms for storing a subframe split configuration on the first base station, wherein the subframe split configuration includes an interlacing allocation of a first downlink resource, DL, which is configured as one among a semi-static resource or a dynamic resource; and mechanisms for transmitting, from the first base station, a first signal according to the first DL resource allocation; the communications device CHARACTERIZED by: the first DL resource being orthogonal to time division to a second DL resource allocated to a second base station, the second DL resource being allocated by the subframe division configuration to be one among a semi-static resource or a dynamic resource; wherein the base station type of the first base station is one of a first power class macro cell base station, a femto cell base station, or a peak cell base station; and the type of base station of the first base station is different from the type of base station of the second base station.
[0007]
7. Method for wireless communications, comprising: receiving, in a UE, information regarding a predetermined subframe resource interlacing allocation from a first downlink resource, DL, to a first base station; receiving, by the UE for a period of time associated with the allocation of resource interlacing, a first signal; and determine, in the UE, a signal metric associated with the first signal, the method CHARACTERIZED by: the first DL resource is orthogonal to the time division to a second DL resource allocated to a second base station, the second DL resource being allocated by configuration of subframe division to be one among a semi-static resource or a dynamic resource; wherein the base station type of the first base station is one of a first power class macro cell base station, a femto cell base station, or a peak cell base station; and the type of base station of the first base station is different from the type of base station of the second base station.
[0008]
8. Method according to claim 7, characterized by the signal metric being a radio link monitoring metric, RLM, and further comprising determining whether to declare radio link failure, RLF, based on the signal metric.
[0009]
9. Method according to claim 7, CHARACTERIZED by the information additionally including radio resource management control information, RRM, and further comprising transmitting the signal metric to a base station and / or in which the information additionally includes information return channel and / or in which the information additionally includes CQI channel quality indication information.
[0010]
10. The method of claim 7, wherein the base station is associated with a first cell and the first signal is transmitted from a node associated with a second cell.
[0011]
11. Method according to claim 10, CHARACTERIZED that the resource allocation is a semi-static resource allocation, in which the time interval is preferably a part of the semi-static resource allocation.
[0012]
12. Memory CHARACTERIZED for understanding instructions for making a computer perform the method as defined in any one of claims 1 to 5 or 7 to 11.
[0013]
13. Device for wireless communications, comprising: mechanisms for receiving, in a UE, information regarding a predetermined subframe resource interlacing allocation from a first downlink resource, DL, to a first base station; mechanisms for receiving, by the UE during a time interval associated with the allocation of resource interlacing, a first signal; and mechanisms for determining, in the UE, a signal metric associated with the first signal, the device for wireless communications FEATURED by: the first DL resource being orthogonal to time division to a second DL resource allocated to a second base station, the second DL resource being allocated by the subframe split configuration to be one among a semi-static resource or a dynamic resource; wherein the base station type of the first base station is one of a first power class macro cell base station, a femto cell base station, or a peak cell base station; and the type of base station of the first base station is different from the type of base station of the second base station.

类似技术:

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同族专利:

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公开号 | 公开日

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EP2608618A3|2017-11-15|

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BR112012005892A2|2018-03-20|

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CN102577560B|2015-07-29|

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法律状态:
2019-01-08| B06F| Objections, documents and/or translations needed after an examination request according art. 34 industrial property law|

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2020-01-14| B15K| Others concerning applications: alteration of classification|Free format text: A CLASSIFICACAO ANTERIOR ERA: H04W 72/04 Ipc: H04W 16/10 (2009.01), H04W 16/14 (2009.01), H04W 7 |

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2020-01-14| B06U| Preliminary requirement: requests with searches performed by other patent offices: suspension of the patent application procedure|

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2020-07-28| B07A| Technical examination (opinion): publication of technical examination (opinion)|

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2020-12-22| B09A| Decision: intention to grant|

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2021-03-02| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 10 (DEZ) ANOS CONTADOS A PARTIR DE 02/03/2021, 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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US24267809P| true| 2009-09-15|2009-09-15|

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US61/242,678|2009-09-15|

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US12/882,090|2010-09-14|

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US12/882,090|US8942192B2|2009-09-15|2010-09-14|Methods and apparatus for subframe interlacing in heterogeneous networks|

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PCT/US2010/048988|WO2011034966A1|2009-09-15|2010-09-15|Methods and apparatus for subframe interlacing in heterogeneous networks|

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