Wireless device configured to operate on a cellular communication network, method of operating a wir

专利摘要:
quasi-co-located antenna ports for channel estimation systems and methods are disclosed to estimate one or more downlink channel properties from a cellular communication network based on quasi-co-located antenna ports with respect to one or more channel properties. in one embodiment, a wireless device receives a downlink subframe including a downlink control channel from the cellular communication network. the wireless device estimates one or more large-scale channel properties for an antenna port of interest in the downlink control channel based on a subset of reference signals that correspond to the antenna ports of the cellular communication network that are almost co-located with the antenna port of interest with respect to one or more large scale channel properties. as a result of using the nearly co-located antenna ports, the estimation of one or more large-scale channel properties is substantially improved.
公开号:BR112015006729B1
申请号:R112015006729-8
申请日:2013-08-02
公开日:2020-03-10
发明作者:Mattias Frenne；Erik Eriksson；Stefano Sorrentino
申请人:Telefonaktiebolaget Lm Ericsson (Publ)；
IPC主号:

专利说明:

WIRELESS DEVICE CONFIGURED TO OPERATE IN A CELLULAR COMMUNICATION NETWORK, METHOD OF OPERATING A WIRELESS DEVICE AND BASE STATION
Related orders [0001] This application claims the benefit of provisional patent application serial number 61 / 679,335, filed on August 3, 2012, the disclosure of which is hereby incorporated by reference in its entirety for reference.
Field of disclosure [0002] The current disclosure refers to antenna ports almost co-located on a cellular communication network that can be used to estimate large-scale or long-term channel properties.
Background [0003] The long-term Evolution (LTE) of a third generation Society Project (3GPP) uses orthogonal frequency division multiplexing (OFDM) in the downlink and Discrete Fourier Transform (DFT) spreading OFDM in the uplink. The basic physical LTE resource that can be viewed as a frequency-time grid as illustrated in Figure 1, where each Resource Element (RE) corresponds to a subcarrier during an OFDM symbol interval on a specific antenna port. An antenna port is defined in such a way that a channel over which a symbol on the antenna port is carried can be inferred from a channel over which another symbol on the same antenna port is carried. There is a feature grid per antenna port. Notably, as discussed in Erik Dahlman and others, 4G LTE / LTE-Advanced for Mobile Broadband, § 10.1.1.7 (2011), an antenna port does not necessarily correspond to a specific physical antenna, but is instead a more general concept introduced, for example, to allow beam formation using multiple physical antennas. At least for the downlink, an antenna port corresponds to the transmission of a reference signal. Any data transmitted from the antenna port can then be based on that reference signal for channel estimation for coherent demodulation. Thus, if the same reference signal is transmitted from multiple physical antennas, those physical antennas correspond to a single antenna port. Similarly, if two different reference signals are transmitted from the same set of physical antennas, this corresponds to two separate antenna ports.
[0004] In the time domain, LTE downlink transmissions are organized in 10 millisecond (ms) radio frames, where each radio frame consists of ten equally sized 1 ms subframes as illustrated in figure 2. A subframe is divided into two partitions, each 0.5 ms long. Resource allocation in LTE is described in terms of resource blocks (RBs) or physical RBs (PRBs) where a resource block corresponds to a partition in the time domain and 12 contiguous 15 kilohertz (kHz) subcarriers in the frequency domain . Two consecutive resource blocks in the time domain represent a pair of resource blocks and correspond to the time interval in which the schedule operates.
[0005] LTE transmissions are dynamically programmed in each subframe where a base station transmits downlink assignments / uplink leases for certain User Elements, or User Equipment (UEs) through a physical downlink control channel (PDCCH) and starting in Release LTE 11 (Rel-11), an improved PDCCH (ePDCCH). PDCCHs are transmitted in the first OFDM symbol (s) in each subframe and cover more or less the entire bandwidth of the system. A UE that has decoded a downlink assignment, loaded by a PDCCH, knows which resource elements in the subframe that contain data directed to the UE. Similarly, after receiving an uplink lease, the UE knows about which time / frequency resources to transmit. In the LTE downlink, data is loaded by a physical downlink shared channel (PDSCH). In the uplink, the corresponding link is referred to as a physical shared uplink Channel (PUSCH).
[0006] The definition of ePDCCH is continuous in 3GPP. Such control signaling is likely to have similar functionality as PDCCH. However, a fundamental difference for ePDCCH is that ePDCCH will require UE-specific reference signals (ie, Demodulation Reference Signals (DMRS)) rather than cell-specific reference signals (ie, Common reference signals (CRS) ) for demodulation. An advantage is that UE-specific spatial processing can be exploited for ePDCCH.
[0007] Demodulation of data sent via PDSCH requires estimation of large scale channel properties of the radio channel. This channel estimation is performed using transmitted reference symbols, where reference symbols are symbols of a Reference Signal (RS) and are known to the receiver. In LTE, CRS reference symbols are transmitted in all downlink subframes. In addition to assisting in downlink channel estimation, CRS reference symbols are also used for mobility measurements performed by UEs. LTE also supports EU-specific RS reference symbols intended only to assist channel estimation for demodulation purposes. Figure 3 illustrates an example of mapping data channels / physical control and signals over resource elements in an RB pair forming a downlink subframe. In this example, PDCCHs occupy the first of three possible OFDM symbols. Thus, in this specific case, the data mapping can start at the second OFDM symbol. Since CRS is common to all UEs in the cell, CRS transmission cannot be easily adapted to suit the needs of a specific UE. This is in contrast to EU-specific RSs where each EU has its own EU-specific RS placed in the data region of Figure 3 as part of the PDSCH.
[0008] The length of the control region, which can vary on a subframe basis, is transported on the Physical Control Format Indicator Channel (PCFICH). PCFICH is transmitted in the control region at locations known to the UEs. After an UE has decoded the PCFICH, the UE knows the size of the control region and at which OFDM symbol the data transmission starts. An Auto-Replay Request - Physical Hybrid (HARQ) indicator, which loads ACK / NACK responses to a UE to inform the UE if a corresponding uplink data transmission in a previous subframe has been successfully decoded by the base station, is also transmitted in the control region.
[0009] In Release LTE 10 (Rel-10) all control messages for UEs are demodulated using CRSs. Therefore, control messages have wide cell coverage to reach all UEs in the cell. An exception is the Primary Sync Signal (PSS) and the Secondary Sync Signal (SSS), which are independent and do not require reception of a CRS before demodulation. The first to four OFDM symbols in a subframe, depending on the configuration, are reserved for such control information. Control messages can be categorized into control messages that need to be sent only to one UE in the cell (that is, specific UE control messages) and control messages that need to be sent to all UEs in the cell or some subset of the UEs in the cell numbering more than one (ie, common control messages).
[0010] As illustrated in figure 4, PDCCH control messages are demodulated using CRSs and transmitted in multiples of units called Control Channel Elements (CCEs), where each CCE contains 36 Res. A PDCCH can have an aggregation level (AL) of 1,2, 4 or 8 CCEs to allow link adaptation of the control message. In addition, each CCE is mapped to 9 Resource Element Groups (REGs) consisting of 4 Res each. These REGs are distributed over the bandwidth of the entire system to provide frequency diversity for a CCE. Consequently, a PDCCH, consisting of up to 8 CCEs, covers the entire system bandwidth in the first one to four OFDM symbols, depending on the configuration.
[0011] In LTE Rel-11, it was agreed to introduce specific EU transmission of control information in the form of improved control channels. More specifically, it was agreed to allow transmission of generic control messages to a UE using transmissions based on specific EU RSs placed in the data region. This is commonly known as an ePDCCH, an improved physical HARQ indicator Channel (ePHICH), etc. Figure 5 illustrates a donwlink subframe showing 10 RB pairs and configuration of three regions of ePDCCH of size 1 RB pair each. The remaining RB pairs can be used for PDSCH transmissions. For ePDCCH in LTE Rel-11, it was agreed to use antenna port p □ {107, 108, 109, 110} for demodulation as shown in figure 6 for normal subframes and normal cyclic prefix. More specifically, figure 6 illustrates an example of RE locations for EU-specific reference symbols (i.e., DMRS reference symbols) used for ePDCCH in LTE for a PRB pair. Note that, starting in LTE Rel. 11, more than one UE may, in some cases, without knowing each other use the same DMRS reference symbols to demodulate their respective ePDCCH messages. As such, “UE-specific” should be interpreted as seen from the perspective of UEs. RS ports R7 and R9 represent the DMRS reference symbols corresponding to the antenna port 107 and 109, respectively. In addition, antenna ports 108 and 110 can be obtained by applying an orthogonal cover (1, -1) over adjacent pairs of RS R7 and R9 ports, respectively. EPDCCH allows pre-coding gains to be obtained for the control channels. Another benefit of ePDCCH is that different PRB pairs (or regions of improved control) can be allocated to different cells or different transmission points in a cell and, as such, inter-point or inter-cell interference coordination between control channels can be obtained. This is especially useful for heterogeneous network scenarios, as discussed below.
[0012] The concept of a point is intensively used in combination with techniques for coordinated Multipoints (CoMP). In this context, a point corresponds to a set of antennas covering essentially the same geographic area in a similar way. In this way, a point can correspond to one of multiple sectors in a location (that is, one of two or more sectors of a cell served by an improved Node B (eNB)), but it can also correspond to a location having one or more antennas all intended to cover a similar geographic area. Different points often represent different locations. Antennas correspond to different points when they are sufficiently geographically separated and / or have antenna diagrams pointing in sufficiently different directions. CoMP techniques include introducing dependencies on programming or transmitting / receiving between different points, in contrast to conventional cellular systems where a point from a programming point of view is operated more or less independently from other points. CoMP downlink operations can include, for example, serving a certain UE from multiple points, at different time instances or for a given subframe, in overlapping or non-overlapping parts of the spectrum. Dynamic switching between transmission points serving a certain UE is often called Dynamic Point Selection (DPS). Simultaneously serving an UE from multiple points on overlapping resources is often referred to as Joint Transmission (JT). Point selection can be based on, for example, instantaneous channel conditions, interference or traffic. CoMP operations are intended to be performed for data channels (eg, PDSCH) and / or control channels (eg, ePDCCH).
[0013] The same ePDCCH region can be used by different transmission points in a cell or that belong to different cells that are not highly interfering with each other. A typical case is the shared cell scenario illustrated in figure 7. As shown, a heterogeneous network includes a macro node, or macro base station, and multiple lower power peak nodes, or peak base stations, in a coverage area of the macro node. The same ePDCCH region can be used by the macro node and peak node. Note that throughout this order, nodes or points in a network are often referred to as being of a certain type, for example, "macro" or "peak". Unless explicitly mentioned otherwise, this should not be interpreted as an absolute quantification of the role of the node / point in the network, but rather as a convenient way of discussing the roles of different nodes / points in relation to each other. In this way, a discussion about macro and peak knots / points can, for example, also be applicable to the interaction between micro and femto knots / points.
[0014] For peak nodes that are geographically separated, such as peak nodes B and C, the same ePDCCH region can be reused. In this way, the total control channel capacity in the shared cell will increase once a given PRB resource is reused, potentially multiple times, in different parts of the cell. This ensures that area-sharing gains are made. An example is given in figure 8 where peak nodes B and C share the same ePDCCH regions. Conversely, due to proximity, peak nodes A and B and peak nodes A and C are at risk of interfering with each other and therefore peak node A is assigned an ePDCCH region that is not overlapped with the shared peak ePDCCH regions. nodes B and C. The interference coordination between peak nodes A and B, or equivalent transmission points A and B, in the shared macro cell is thus obtained. In some cases, a UE may need to receive part of the ePDCCH signaling from the macro cell and the other part of the ePDCCH signaling from the nearby peak cell. Such frequency division control channel frequency coordination is not possible with the PDCCH since the PDCCH covers the entire bandwidth. Also, the PDCCH does not provide the possibility to use UE-specific pre-coding since it is based on the use of CRS for demodulation.
[0015] Figure 9 illustrates an ePDCCH that, similar to the CCE in the PDCCH, is divided into multiple groups and mapped to one of the regions of improved control of a subframe. Note that in figure 9, the ePDCCH regions do not start at the OFDM zero symbol to accommodate simultaneous transmission of a PDCCH in the subframe. However, there may be types of portals in future LTE releases that do not have a PDCCH, in which case ePDCCH regions can start from the OFDM zero symbol in the subframe.
[0016] Even if ePDCCH enables specific UE pre-encoding and localized transmission as discussed above, it may, in some cases, be useful to be able to transmit ePDCCH in a wide area coverage mode, with broadcast. This is useful if the base station (ie, eNB) does not have secure information to perform pre-coding in the sense of a certain UE. In this situation, a wide area coverage transmission is more robust. Another case is when the specific control message is intended for more than one UE. In that case, EU-specific pre-coding cannot be used. An example is the transmission of common control information using PDCCH (that is, in the Common Search Space (CSS)). In either case, a transmission distributed over multiple regions of ePDCCH in a subframe can be used. An example of such a distribution is illustrated in figure 10 where the four parts belonging to the same ePDCCH are distributed over multiple regions of improved control in a subframe. It was agreed in the development of 3GPP ePDCCH that both distributed and localized transmission of an ePDCCH must be supported. When distributed ePDCCH transmission is used, it is also beneficial if antenna diversity can be obtained to maximize the diversity order of an ePDCCH message. On the other hand, sometimes only broadband pre-coding information and broadband channel quality is available at the base station, in which case it may be useful to perform a distributed transmission, but with broadband pre-coding, specific to HUH.
[0017] As discussed above, improved control signaling, such as ePDCCH in LTE, offers many advantages. However, advanced network architectures (for example, heterogeneous network architectures) and downlink CoMP lead to problems that must be resolved. In particular, as discussed below, the inventors have found that there is a need for systems and methods for improved channel estimation techniques.
SUMMARY
[0018] Systems and methods are revealed to estimate one or more channel properties of a downlink from a cellular communication network based on antenna ports almost co-located with respect to one or more channel properties. In one embodiment, a wireless device receives a downlink subframe including a downlink control channel from the cellular communication network. The wireless device estimates one or more large-scale channel properties for an antenna port of interest in the downlink control channel based on a subset of RSs that correspond to antenna ports on the cellular communication network that are almost co- located with the antenna port of interest with respect to one or more channel properties. By estimating one or more channel properties based on a subset of the RSs that correspond to the almost co-located antenna ports instead of a single RS that corresponds to the antenna port of interest for which one or more large scale channel properties are estimated, the estimation of one or more large scale channel properties is substantially improved.
[0019] In one embodiment, the cellular communication network is a Long Term Evolution (LTE) cellular communication network, and the donwlink control channel is an improved Public downlink Control Channel (ePDCCH). In one embodiment, the wireless device does not assume that antenna ports that correspond to RSs in the ePDCCH are almost co-located with respect to large scale channel properties between antenna ports and between physical resource blocks in the donwlink subframe. In a specific embodiment, the wireless device determines whether a Downlink Control Information (DCI) message in ePDCCH is associated with two or more demodulation RS ports (DMRS) and / or two or more physical resource blocks. If so, the antenna ports that are almost co-located with respect to one or more channel properties of the RS port in the ePDCCH include antenna ports, and preferably all antenna ports, associated with the DCI message.
[0020] In another specific modality, ePDCCH resources forming an antenna device search space are divided into two or more sets of ePDCCH resources where antenna ports in the same set of ePDCCH resources must be almost co-located at least with respect to one or more large scale channel properties according to one or more predefined rules of the cellular communication network. In this modality, the wireless device estimates one or more large-scale channel properties for the RS port on the ePDCCH based on a subset of the RSs that correspond to antenna ports that are comprised in the same set of ePDCCH features and, therefore, they are almost co-located with respect to one or more large scale channel properties.
[0021] In another specific modality, ePDCCH resources forming a wireless device search space are divided into two or more sets of ePDCCH resources. The wireless device receives signaling from the cellular communication network that indicates whether antenna ports in the same set of ePDCCH resources in the donwlink subframe are almost co-located with respect to one or more large-scale channel properties. If so, the wireless device estimates one or more large-scale channel properties for the RS port on the ePDCCH based on a subset of the RSs that correspond to antenna ports that are within the same set of ePDCCH features and therefore , are almost co-located with respect to one or more large scale channel properties. In an additional embodiment, the wireless device can receive signaling from the cellular communication network that indicates whether antenna ports in two or more different sets of ePDCCH resources in the downlink subframe are almost co-located with respect to one or more large-scale channel properties. If the antenna ports on two or more different sets of ePDCCH resources are almost co-located, then the wireless device estimates one or more large-scale channel properties for the ES port on the ePDCCH based on the subset of the RSs that correspond to antenna ports that are in two or more different sets of ePDCCH resources and therefore are almost co-located with respect to one or more large scale channel properties.
[0022] In one embodiment, a base station on a cellular communication network includes a radio subsystem and a processing subsystem associated with the radio subsystem. The processing subsystem provides, via the radio subsystem, a downlink subframe that includes multiple RSs corresponding to multiple antenna ports according to one or more predefined rules that define one or more subsets of the antenna ports that should be almost co-located located in a downlink control channel of a downlink subframe. In this way, the base station enables a wireless device to, for example, estimate one or more large-scale channel properties based on a subset of the RSs in the downlink subframe corresponding to antenna ports that are almost co-located with respect to to one or more large scale channel properties.
[0023] In another embodiment, a base station in a cellular communication network includes a radio subsystem and a processing subsystem associated with the radio subsystem. The processing subsystem sends information, via the radio subsystem, to a wireless device that is indicative of antenna ports that are almost co-located on a donwlink control channel of a downlink subframe from the communication network cell phone. Using this information, the wireless device is enabled, for example, to estimate one or more large-scale channel properties based on RSs that correspond to antenna ports that are almost co-located with respect to one or more channel properties large-scale.
[0024] Those skilled in the art will recognize the scope of the present disclosure and perform additional aspects of it after reading the following detailed description of the preferred modalities in association with the attached drawing figures.
BRIEF DESCRIPTION OF THE DRAWING FIGURES
[0025] The attached drawing figures incorporated in and forming part of this specification illustrate various aspects of the disclosure, and together with the description serve to explain the principles of the disclosure.
[0026] Figure 1 illustrates a resource block of a downlink in a long-term Evolution (LTE) cellular communication network of the 3rd generation Society Project (3GPP);
[0027] Figure 2 illustrates a domain-time structure of a downlink in an LTE 3GPP cellular communication network;
[0028] Figure 3 illustrates mapping of LTE physical control signaling, data link and Common reference signals (CRS) in a downlink subframe in a 3G LTE cellular communication network;
[0029] Figure 4 illustrates the mapping of a Control Channel Element (CCE) that belongs to a Public Donwlink Control Channel (PDCCH) for the control region in a downlink subframe in an LTE 3GPP cellular communication network;
[0030] Figure 5 illustrates regions of improved control, or regions of improved PDCCH (ePDCCH), in a downlink subframe in an LTE 3GPP cellular communication network;
[0031] Figure 6 illustrates an example of Demodulation Reference Signal (DMRS) ports used for ePDCCH, where DMRS ports correspond to antenna ports;
[0032] Figure 7 illustrates a heterogeneous network architecture for a cellular communication network;
[0033] Figure 8 illustrates different ePDCCH resource regions where some ePDCCH resource regions are reused by peak nodes in heterogeneous network architecture without interference;
[0034] Figure 9 illustrates a downlink subframe including a CCE belonging to an ePDCCH mapped to one of the ePDCCH regions in the donwlink subframe;
[0035] Figure 10 illustrates a downlink subframe including a CCE that belongs to an ePDCCH mapped to multiple regions of ePDCCH to obtain frequency diversity and distributed transmission or subband precoding;
[0036] Figure 11 illustrates a cellular communication network in which a wireless device performs channel estimation for a downlink control channel using reference signals that correspond to antenna ports almost co-located according to one modality of the present revelation;
[0037] Figure 12A illustrates an example of a cellular communication network in which reference signals corresponding to antenna ports almost co-located in a downlink subframe are used for channel estimation of a downlink control channel according to one embodiment of the present disclosure;
[0038] Figure 12B illustrates another example of a cellular communication network in which reference signals corresponding to antenna ports almost co-located in a downlink subframe are used for channel estimation for a downlink control channel according to one embodiment of the present disclosure;
[0039] Figure 13 illustrates the operation of the cellular communication network of figure 11 to provide channel estimation for a downlink control channel using reference signals in a donwlink subframe corresponding to antenna ports almost co-located according to one embodiment of the present disclosure; [0040] Figure 14 illustrates the operation of the cellular communication network of figure 11 to provide channel estimation for a downlink control channel using reference signals corresponding to almost co-located antenna ports in which the antenna ports almost co. -located are signaled by the cellular communication network according to one modality of the present disclosure;
[0041] Figure 15 illustrates the operation of the cellular communication network of figure 11 to provide channel estimation for a downlink control channel using reference signals corresponding to almost co-located antenna ports in which the antenna ports almost co. -located are predefined for the cellular communication network according to one embodiment of the present disclosure;
[0042] Figure 16 illustrates multiple ePDCCH resource regions in a subframe;
[0043] Figures 17A through 17C illustrate different CRS ports that correspond to different antenna ports that are found in the ePDCCH resource regions of figure 16;
[0044] Figures 18A and 18B illustrate different Demodulation Reference Signal (DMRS) ports that correspond to different antenna ports that are found in the ePDCCH resource regions of Figure 16;
[0045] Figure 19 illustrates different Channel State Information Reference Signal (CSI-RS) ports that correspond to different antenna ports that are found in the ePDCCH resource regions of Figure 16;
[0046] Figure 20 illustrates the operation of the wireless device in Figure 11 to perform channel estimation for a Reference Signal (RS) port in an RS-based ePDCCH region that corresponds to nearly co-located antenna ports of according to one embodiment of the present disclosure;
[0047] Figure 21 illustrates the operation of the wireless device in Figure 11 to perform channel estimation for an RS port in an ePDCCH region based on RSs that correspond to antenna ports almost co-located according to another modality of present disclosure in which antenna ports in the same set of ePDCCH resources are predefined as being almost co-located;
[0048] Figure 22 illustrates the operation of the base station of the cellular communication network of figure 11 to transmit ePDCCH according to one or more predefined rules indicating that all antenna ports in a set of ePDCCH resources must be almost co-located. located in accordance with an embodiment of the present disclosure;
[0049] Figure 23 illustrates the operation of the wireless device in Figure 11 to perform channel estimation for an RS port in an ePDCCH region based on RSs that correspond to antenna ports almost co-located according to another modality of present disclosure in which antenna ports in the same set of ePDCCH resources and potentially different sets of ePDCCH resources that are almost co-located are signaled to the wireless device;
[0050] Figure 24 illustrates an example of the process of figure 23 according to an embodiment of the present disclosure;
[0051] Figure 25 is a block diagram of a wireless device according to one embodiment of the present disclosure: and [0052] Figure 26 is a block diagram of a base station according to one embodiment of the present disclosure.
DETAILED DESCRIPTION
[0053] The modalities set out below represent the information needed to enable those skilled in the art to put the modalities into practice and illustrate the best way to implement the modalities. After reading the following description in the light of the attached drawing figures, those skilled in the art will understand the concepts of disclosure and recognize applications of those concepts not particularly addressed here. It should be understood that these concepts and applications are included in the scope of the disclosure and claims attached.
[0054] Note that although the terminology from the 3rd generation Society Project (3GPP) Long Term Evolution (LTE) specifications is used in much of the description below to exemplify preferred modalities of the present disclosure, this should not be viewed as limiting the scope of the present disclosure to only LTE 3GPP. Other wireless systems such as, but not limited to, Broadband Code Division Multiple Access (WCDMA), Worldwide interoperability for Microwave Access (WiMax), Ultra Mobile Broadband (UMB), and Global System for mobile communications (GSM) can also benefit from exploring the concepts revealed here.
[0055] Before discussing various modalities of the present disclosure, a discussion of a fundamental problem discovered by the inventors is beneficial. One of the principles that guide the design of the LTE 3GPP cellular communication network is network transparency for the User Equipment (UE). In other words, in LTE, the UE is able to demodulate and decode its intended channels without specific knowledge of programming assignments for other UEs or network deployments. However, in advanced scenarios such as MultiPonto Coordinated downlink (CoMP) and uplink and distributed downlink, this concept of network transparency results in the fact that the UE cannot assume that reference signals in a subframe originate from the same transmission points on the cellular communication network.
[0056] For example, in LTE, different Downlink Control Information (DCI) messages on an improved physical downlink Control Channel (ePDCCH) can be transmitted from ports that belong to different transmission points. Although there are several reasons for serving a UE with control signaling from different points, an application is to distribute parts of the programming algorithm at different points in such a way that, for example, downlink (DL) transmissions are associated with a point different than uplink (UL) transmissions. This scenario is referred to here as a distributed uplink and downlink scenario. In such a case, it makes sense to schedule donwlink and uplink transmissions with control signaling provided directly from the respective points. As another example, a UE can be served with parallel data transmissions from different points (For example, to increase data speed or during handover between points). As another example, system control information can be transmitted from a “master” point and data transmissions can be transmitted from other points, typically associated with peak nodes. In all the examples above, it makes sense to be able to serve the UE with control signaling in ePDCCH from different points in the same subframe. However, due to network transparency, UEs are not aware of the geographical location from which each Reference Signal (RS) port is transmitted.
[0057] Demodulation RSs (DMRSs), or EU-specific RSs, are used for demodulation of data channels and possibly certain control channels (ie, ePDCCH). A DMRS relieves the UE of having to know many of the transmission properties and thereby allows flexible transmission schemes to be used from the network side. This is referred to as transmission transparency (with respect to the UE). However, the inventors found that the estimation accuracy of a DMRS may not be sufficient in some situations.
[0058] The geographical separation of RS ports implies that instantaneous channel coefficients of each port towards the UE are in general different. In addition, even statistical properties of channels for different RS ports and RS types can be significantly different. Examples of such statistical properties include power received for each port, delay spread, Doppler spread, received timing (i.e., timing of a significant first channel tap), a number of significant channel taps, frequency shift, average gain and average delay. In LTE, nothing can be assumed about the channel properties corresponding to an antenna port based on the channel properties of another antenna port. This is actually an important part of maintaining transmission transparency.
[0059] Based on the above observations, the inventors found that the UE needs to perform independent estimation for each RS port of interest for each RS. In general, this results in channel estimation quality occasionally inadequate for certain RS ports, leading to undesirable degradation of system and link performance. However, the inventors have also found that, although in general the channel of each antenna port for each UE receiving port is substantially unique, some statistical properties and propagation parameters may be common or similar between different antenna ports, depending on whether whether or not the different antenna ports originate from the same transmission point. Such properties include, for example, a received power level for each antenna port, a delay spread, a Doppler spread, received timing (ie, timing of a significant first channel drift), frequency shift, average gain and average delay. In this way, the channel estimation for one RS port can be performed based on other RS ports having sufficiently similar channel properties.
[0060] Typically, channel estimation algorithms perform a three-step operation. A first step is to estimate some statistical properties of the channel. A second step is to generate an estimation filter based on the estimated statistical properties. A third step is to apply the estimation filter to the received signal to obtain channel estimates. The estimation filter can be applied equivalently in the time or frequency domain. Some implementations of channel estimator may not be based on the three-step method described above, but still explore the same principles.
[0061] Obviously, the accurate estimation of the filter parameters in the first step leads to improved channel estimation. While it is often in principle possible for the UE to obtain such filter parameters from observing the channel over a single subframe and for an RS port, it is usually possible for the UE to improve the estimation accuracy of the filter parameters by combining measurements associated with different antenna ports (ie different RS transmissions) sharing similar statistical properties. In addition, channel estimation accuracy can be improved by combining RSs associated with multiple PRBs.
[0062] Systems and methods are disclosed here to estimate one or more channel properties of a downlink from a cellular communication network based on antenna ports almost co-located with respect to one or more channel properties. In the preferred embodiments described below, systems and methods are revealed to estimate one or more channel properties for an ePDCCH contained in a downlink subframe from an LTE 3GPP cellular communication network. Again, although the preferred modalities disclosed here focus on LTE, the concepts disclosed here can be used to estimate one or more channel properties for a downlink, and in particular a downlink control channel in a downlink subframe, from others types of cellular communication networks.
[0063] In one embodiment, a wireless device estimates one or more large-scale channel properties for an antenna port of interest in an ePDCCH of a downlink subframe received from a cellular communication network based on a subset of RSs in the downlink downlink subframe. The subset of the RSs used to estimate one or more large-scale channel properties correspond to antenna ports on the cellular communication network that are almost co-located with the antenna port of interest with respect to one or more ePDCCH channel properties . Preferably, in addition to the subset of the RSs that correspond to the nearly co-located antenna ports, estimation is also based on an RS that corresponds to the antenna port of interest in the ePDCCH. Because it estimates one or more channel properties instead of just the single RS that corresponds to the antenna port for which one or more large scale channel properties are estimated, the estimation of one or more large scale channel properties is substantially enhanced.
[0064] In this regard, figure 11 illustrates a cellular communication network 10 that enables channel estimation based on RSs from antenna ports almost co-located in a subframe according to a modality of the present disclosure. In this modality, the cellular communication network 10 is an LTE 3GPP cellular communication network. As illustrated, the cellular communication network 10 includes a Radio Access Network (RAN) 12 which itself includes base stations (BSs) 14. Base stations 14 provide service for wireless devices, such as wireless device (WD) 16 , located in the corresponding service areas, or cells. The base stations 14 included in RAN 12 can be high power or macro base stations (i.e., Bs improved nodes (eNBs)), peak base stations or other base power stations, or a combination thereof.
[0065] As illustrated in figure 11, and more specifically illustrated in figure 12A, in a specific embodiment, RAN 12 and WD 16 operate to provide a UL and DL distributed to WD 16. In particular, uplink data transmissions from WD 16 (ie, Physical uplink shared channel (PUSCH)) are directed to and programmed by a first point (for example, a first base station 14) on RAN 12 whereas DL data transmissions to WD 16 (ie, Shared physical downlink channel (PDSCH)) are transmitted from and programmed by a second point (for example, a second base station 14) in RAM 12. This can be beneficial, for example, in a scenario of heterogeneous network where WD 16 uplink data transmissions are directed to and programmed by a peak or low power base station 14 and WD 16 downlink data transmissions are transmitted and programmed by a macro or high power base station 1 4. In that case, an ePDCCH in a downlink subframe for WD 16 can include either ePDCCH transmission (s) from the peak or low power base station 14 (for example, an ePDCCH transmission for uplink programming) as well as ePDCCH transmission (s) from macro base station 14 (for example, an ePDCCH transmission for downlink programming).
[0066] As discussed above, to demodulate ePDCCH in the subframe, WD 16 needs to estimate one or more large-scale or long-term channel properties for each RS port of interest in the subframe. However, using conventional channel estimation techniques, channel estimation would need to be performed independently for each RS port of interest for each RS. This is because different RS ports for RSs of the same or different RS types in the same subframe can be transmitted from different points on RAN 12 and therefore can have significantly different large-scale channel properties. In addition, the same RS port on different Physical Resource Blocks (PRBs) in the same subframe can be transmitted from different points, which again means that the channel properties for those antenna ports can have significantly wide scale channel properties many different. As mentioned above, using conventional channel estimation techniques to independently perform channel estimation for each RS port of interest for each RS would lead to inadequate channel estimation quality for certain RS ports, which would lead to undesirable link and system performance degradation. .
[0067] In one embodiment, a wireless device estimates one or more large-scale channel properties for an antenna port of interest in an ePDCCH of a downlink subframe received from a cellular communication network based on a subset of RSs in the downlink downlink subframe. The subset of the RSs used to estimate one or more large-scale channel properties correspond to antenna ports on the cellular communication network that are almost co-located with the antenna port of interest with respect to one or more ePDCCH channel properties . Preferably, in addition to the subset of the RSs that correspond to the nearly co-located antenna ports, estimation is also based on an RS that corresponds to the antenna port of interest in the ePDCCH. Because it estimates one or more channel properties instead of just the single RS that corresponds to the antenna port for which one or more large scale channel properties are estimated, the estimation of one or more large scale channel properties is substantially enhanced.
[0068] In this regard, figure 11 illustrates a cellular communication network 10 that enables channel estimation based on RSs from antenna ports almost co-located in a subframe according to a modality of the present disclosure. In this modality, the cellular communication network 10 is an LTE 3GPP cellular communication network. As illustrated, the cellular communication network 10 includes a Radio Access Network (RAN) 12 which itself includes base stations (BSs) 14. Base stations 14 provide service for wireless devices, such as wireless device (WD) 16 , located in the corresponding service areas, or cells. The base stations 14 included in RAN 12 can be high power or macro base stations (i.e., Bs improved nodes (eNBs)), peak base stations or other base power stations, or a combination thereof.
[0069] As illustrated in figure 11, and more specifically illustrated in figure 12A, in a specific embodiment, RAN 12 and WD 16 operate to provide a UL and DL distributed to WD 16. In particular, uplink data transmissions from WD 16 (ie, Physical uplink shared channel (PUSCH)) are directed to and programmed by a first point (for example, a first base station 14) on RAN 12 whereas DL data transmissions to WD 16 (ie, Shared physical downlink channel (PDSCH)) are transmitted from and programmed by a second point (for example, a second base station 14) in RAM 12. This can be beneficial, for example, in a scenario of heterogeneous network where WD 16 uplink data transmissions are directed to and programmed by a peak or low power base station 14 and WD 16 downlink data transmissions are transmitted and programmed by a macro or high power base station 1 4. In that case, an ePDCCH in a downlink subframe for WD 16 can include either ePDCCH transmission (s) from the peak or low power base station 14 (for example, an ePDCCH transmission for uplink programming) as well as ePDCCH transmission (s) from macro base station 14 (for example, an ePDCCH transmission for downlink programming).
[0070] As discussed above, to demodulate ePDCCH in the subframe, WD 16 needs to estimate one or more large-scale or long-term channel properties for each RS port of interest in the subframe. However, using conventional channel estimation techniques, channel estimation would need to be performed independently for each RS port of interest for each RS. This is because different RS ports for RSs of the same or different RS types in the same subframe can be transmitted from different points on RAN 12 and therefore can have significantly different large-scale channel properties. In addition, the same RS port on different Physical Resource Blocks (PRBs) in the same subframe can be transmitted from different points, which again means that the channel properties for those antenna ports can have significantly wide scale channel properties many different. As mentioned above, using conventional channel estimation techniques to independently perform channel estimation for each RS port of interest for each RS would lead to inadequate channel estimation quality for certain RS ports, which would lead to undesirable link and system performance degradation. .
[0071] To improve the channel estimation for ePDCCH, the WD 16 performs joint estimation of one or more large scale channel properties for each RS port of interest in the ePDCCH of a downlink subframe based on RSs in the downlink subframe that corresponds to antenna ports that are almost co-located. As used here, two antenna ports are “almost co-located” if the large scale channel properties of the channel over which a symbol in an antenna port is carried can be inferred from the channel over which a symbol in the another antenna port is carried. The large scale channel properties preferably include one or more delay spread, Doppler spread, Doppler shift, average gain and average delay. In addition, or alternatively, large-scale channel properties may include one or more of the received power for each port, received timing (i.e., timing of a significant first channel tap), a number of significant channel taps, and frequency shift. For example, channel estimation based on RSs corresponding to the nearly co-located antenna ports, a quality of channel estimation is substantially improved.
[0072] As illustrated in figure 11 and more specifically in figure 12B, in another specific modality, RAN 12 provides CoMP donwlink in which the downlink to WD 16 is provided from multiple base stations 14 in a coordinated mode. In this case, the ePDCCH in a downlink subframe for the WD 16 can include ePDCCH transmissions from two or more transmission points (for example, two or more base stations 14). Again, as discussed below, to demodulate ePDCCH transmissions in the subframe, the WD 16 needs to estimate one or more large-scale or long-term channel properties for each RS port of interest in the subframe. However, using conventional channel estimation techniques, channel estimation would need to be performed independently for each RS port of interest for each RS. This would lead to inadequate channel estimation quality for certain RS ports, which would lead to undesirable degradation of system and link performance. To improve the channel estimation for ePDCCH, the WD 16 performs joint estimation of the large scale channel properties of each RS port of interest based on RSs in the subframe that correspond to the antenna ports that are almost co-located.
[0073] Figure 13 illustrates the operation of the cellular communication network 10 of figure 11 according to one embodiment of the present disclosure. As illustrated, the WD 16 receives a downlink subframe from RAN 12, where the downlink subframe includes an ePDCCH and multiple RSs in the ePDCCH (step 100). The subframe can contain RS of different types, such as common reference signals (CRS) or channel status information reference signals (CSI-RS). EPDCCH uses PRBs located in one or more ePDCCH resource regions in the subframe. Note that the RSs in the ePDCCH resource regions are more specifically referred to here as ePDCCH RSs on corresponding ePDCCH RS ports. The RSs in the donwlink subframe, and more specifically the ePDCCH URs in the ePDCCH, can include:. multiple RSs of the same RS type in the same and / or different PRB (s) (for example, two or more DMRSs in two or more corresponding DMRS ports in the same PRB (s) ( and / or different (s); and / or multiple RSs of different RS types than the same and / or different PRB (s) (for example, a DMRS on a DMRS port and a channel status information RS (CSI-RS) on a CSI-RS port on the same and / or different PRB (s) Note that CSI-RS and CRS are reference signals In other words, CSI-RS and CRS found across the entire bandwidth of the downlink and not just on the EPDCCH. As such, when performing channel analysis for example, on CSI-RS, the entire bandwidth of the CSI-RS can be used, not just the part that resides in the EPDCCH RBs. Due to the network transparency, the WD 16 does not assume that any specific RS on any specific RS port is transmitted from the same transmission point through blocks of resource in the ePDCCH of donwlink subframe. For example, a DMRS on port DMRS 7 cannot be assumed to be from the same transmission point through different ePDCCH resource regions or even through different PRBs in the same ePDCCH region.
[0074] WD 16 then estimates one or more large scale channel properties for an antenna port of interest in the downlink subframe based on a subset of the RSs in the previous subframe and / or subframe (s) that correspond to antenna ports that are almost co-located on the antenna port of interest with respect to one or more large-scale channel properties (step 102). The antenna port of interest corresponds to an ePDCCH RS port of interest in a PRB in an ePDCCH resource region. In one embodiment, one or more large scale channel properties are one or more large scale channel properties of a channel between a transmission point from which the antenna port of interest in the PRB originated and WD 16. One or more Large scale channel properties preferably include one or more delay spread, Doppler spread, Doppler shift, average gain and average delay. In addition or alternatively, one or more large-scale channel properties may include one or more of the received power for each port, received timing (i.e., timing of a significant first channel tap), a number of significant channel taps, and frequency shift.
[0075] The estimation of one or more large scale channel properties can be performed using any suitable joint estimation technique that uses almost co-located antenna ports to estimate the large scale channel properties for the desired antenna port . The estimation is preferably based on the RS that corresponds to the antenna port of interest in the downlink subframe as well as the RSs that correspond to the antenna ports that are almost co-located with the antenna port of interest with respect to the wide channel properties scale. RSs that correspond to antenna ports that are almost co-located with the antenna port of interest with respect to large-scale channel properties can include RSs in the same downlink subframe as the antenna port of interest and / or RSs in one or more previous donwlink subframes. The use of RSs in a previous subframe or subframes can be beneficial where, for example, CSI-RS are not transmitted in the downlink subframe of the antenna port of interest. Notably, the estimates generated in step 102 can be initial estimates for one or more large scale channel properties or updated estimates for one or more large scale channel properties. For example, estimation / updating across multiple subframes can be used to improve estimates of one or more large scale channel properties.
[0076] Finally, WD 16 uses one or more large scale channel properties, or more specifically uses estimates of one or more large scale channel properties (step 104). More specifically, in one embodiment, WD 16 uses the estimates of one or more large-scale channel properties to configure one or more parameters of an estimation filter that is applied by WD 16 in the time or frequency domain to perform the estimation of channel used to receive the downlink signal to enable ePDCCH demodulation and reception.
[0077] In LTE 3GPP, a main feature of the cellular communication network 10 is network transparency. As a result of network transparency, the WD 16 is not aware of the points on RAN 12 from which the different antenna ports originate. As such, for the WD 16 to estimate one or more large scale channel properties in step 102 of figure 13, the WD 16 must be aware of which antenna ports are almost co-located with the antenna port of interest with respect to to one or more large scale channel properties. Figures 14 and 15 illustrate two modalities in which the WD 16 obtains knowledge of the antenna ports that are almost co-located through signaling from RAN 12 and through predefined rule (s) for the cellular communication network. 10.
[0078] More specifically, with reference to figure 14, the WD 16 receives information from RAN 12 that are indicative of antenna ports that are almost co-located (step 200). In the preferred mode, the information from RAN 12 is indicative of antenna ports that are almost co-located with respect to ePDCCH. This information can be explicitly signaled to the WD 16 from RAN 12 through Radio Resource Control (RRC) or similar signaling. Alternatively, this information can be implicitly signaled to WD 16 from RAN 12 through, for example, DCI messages transmitted in ePDCCH. Information from RAN 12 indicates which antenna ports are almost co-located with respect to one or more large scale channel properties and physical resources on which antenna ports are almost co-located with respect to one or more properties large-scale channel In a specific modality, information from RAN 12 indicates which antenna ports are almost co-located with respect to one or more large-scale channel properties in a sublink of a downlink to WD 16 and physical resources such as sub-frame on which those antenna ports are almost co-located with respect to one or more large scale channel properties.
[0079] From that point on, the process continues as described above with respect to steps 100-104 of figure 13. More specifically, WD 16 receives a donwlink subframe from RAN 12 where the donwlink subframe includes an ePDCCH and multiple RSs in the ePDCCH (step 202). WD 16 then estimates one or more large-scale channel properties for an antenna port of interest in a subframe based on a subset of the RSs in the subframe and / or a previous subframe (s) that corresponds to antenna ports that are almost co-located with the antenna port of interest with respect to one or more large scale channel properties (step 204). The antenna port of interest corresponds to an ePDCCH RS port of interest in a PRB in an ePDCCH resource region. Here, the antenna ports that are almost co-located with respect to one or more large scale channel properties are indicated by the information received from RAN 12 in step 200. In one embodiment, one or more wide channel properties scale are one or more large-scale channel properties of a channel between a transmission point from which the antenna port of interest originated and the WD 16. One or more large-scale channel properties preferably includes one or more delay, Doppler scattering, Doppler shift, average gain and average delay. In addition or alternatively, one or more large-scale channel properties may include one or more received power for each port, received timing (i.e., timing of a significant first channel tap), a number of significant channel taps and frequency shift.
[0080] The estimation of one or more large scale channel properties can be performed using any suitable joint estimation technique that uses almost co-located antenna ports to estimate the large scale channel properties for the desired antenna port . The estimation is preferably based on the RS that corresponds to the antenna port of interest in the downlink subframe as well as the RSs that correspond to the antenna ports that are almost co-located with the antenna port of interest with respect to the wide channel properties scale. RSs that correspond to antenna ports that are almost co-located with the antenna port of interest with respect to large-scale channel properties can include RSs in the same downlink subframe as the antenna port of interest and / or RSs in one or more previous downlink subframes. The use of RSs in a previous subframe or subframes can be beneficial where, for example, CSI-RS are not transmitted in the donwlink subframe of the antenna port of interest. Notably, the estimates generated in step 204 can be initial estimates for one or more large scale channel properties or updated estimates for one or more large scale channel properties. For example, estimation / updating across multiple subframes can be used to improve estimates of one or more large scale channel properties.
[0081] Finally, WD 16 uses one or more large scale channel properties and more specifically uses estimates of one or more large scale channel properties (step 206). More specifically, in one embodiment, WD 16 uses the estimates of one or more large-scale channel properties to configure one or more parameters of an estimation filter that is applied by WD 16 in the time or frequency domain to perform estimation of channel required for receiving and demodulating ePDCCH.
[0082] Figure 15 illustrates the operation of the cellular communication network 10 of figure 11 in which almost co-located antenna ports are predefined for the cellular communication network 10 according to one embodiment of the present disclosure. In a specific modality, the antenna co-located ports are defined by one or more specifications (ie 3GPP specifications) that define the operation of the cellular communication network 10. Thus, in this modality, RAN 12 transmits a downlink including RSs for the WD 16 according to one or more predefined rules that define antenna ports that should be almost co-located (step 300). More specifically, the downlink includes a donwlink subframe that includes an ePDCCH. The RS ports of the RSs transmitted in the ePDCCH correspond to antenna ports. One or more predefined rules define which of the antenna ports should be almost co-located for ePDCCH. In this way, in other words, one or more predefined rules define which of the RSs in the ePDCCH should originate from antenna ports almost co-located. For example, as discussed in detail below, in one embodiment, ePDCCH resources in a subframe are divided into two or more ePDCCH resource sets where WD 16 is configured to fetch at least two of the ePDCCH resource sets. In this example, one or more predefined rules may determine, for example, that antenna ports corresponding to all RS ports in the same set of ePDCCH resources must be almost co-located. Note, however, that this example is not limiting. The rules can define antenna ports that should be almost co-located in any desired mode.
[0083] WD 16 then estimates one or more large scale channel properties for an antenna port of interest in the subframe based on a subset of the RSs in the subframe and / or a corresponding previous subframe (s) ( m) antenna ports that are almost co-located with the antenna port of interest with respect to one or more large scale channel properties (step 302). The antenna port of interest corresponds to an RS ePDCCH port of interest on a PRB in an ePDCCH resource region. Here, the antenna ports that are almost co-located with respect to one or more large-scale channel properties are predefined for the cellular communication network 10. In one embodiment, one or more large-scale channel properties are one or more more large-scale channel properties of a channel between a transmission point from which the antenna port of interest originated and the WD 16. One or more large-scale channel properties preferably includes one or more delay spread, Doppler spread , Doppler shift, average gain and average delay. In addition or alternatively, one or more large-scale channel properties may include one or more of the received power for each port, received timing (i.e., timing of a significant first channel tap), a number of significant channel taps and frequency shift. [0084] The estimation of one or more large scale channel properties can be performed using any suitable joint estimation technique that uses the almost co-located antenna ports to estimate the large scale channel properties for the desired antenna port . The estimation is preferably based on the RS that corresponds to the antenna port of interest in the donwlink subframe as well as the RSs that correspond to the antenna ports that are almost co-located with the antenna port of interest with respect to wide channel properties. scale. RSs that correspond to antenna ports that are almost co-located with the antenna port of interest with respect to large-scale channel properties can include RSs in the same downlink subframe as the antenna port of interest and / or RSs in one or more previous donwlink subframes. The use of RSs in a previous subframe or subframes can be beneficial where, for example, CSI-RS are not transmitted in the downlink subframe of the antenna port of interest. Notably, the estimates generated in step 302 can be initial estimates for one or more large scale channel properties or updated estimates for one or more large scale channel properties. For example, estimation / updating across multiple subframes can be used to improve estimates of one or more large scale channel properties.
[0085] Finally, WD 16 uses one or more large scale channel properties, or more specifically uses estimates of one or more large scale channel properties (step 304). More specifically, in one embodiment, WD 16 uses one or more large-scale channel properties to configure one or more parameters of an estimation filter that is applied by WD 16 in the time or frequency domain for the downlink signal received for perform channel estimation required for the reception and demodulation of the ePDCCH.
[0086] In preferred embodiments of the present disclosure, channel estimation is performed for RS ports in ePDCCH resource regions in a downlink subframe from RAN 12. Before discussing further details of these preferred modalities, a discussion of regions of ePDCCH feature in a subframe and several corresponding RSs and antenna ports that can be found in the ePDCCH feature regions are provided. In this regard, Figure 16 illustrates a subframe of an LTE downlink that includes multiple ePDCCH resource regions. In this example, each ePDCCH resource region included a portion of a PRB in the first half of the subframe (that is, the first partition of the subframe) and a PRB in the second half of the subframe (that is, the second partition of the subframe). Note that in another embodiment, there are no orthogonal frequency division Multiplexing (OFDM) symbol ranges reserved for control information (for example, PDCCH) at the beginning of the subframe, and each ePDCCH resource region includes a total PRB pair. . Note that although four ePDCCH resource regions are illustrated in the example in Figure 16, any number of ePDCCH resource regions can be included in the subframe.
[0087] Figures 17A through 17C illustrate a Common Reference Signal (CRS) on a pair of PRBs in a subframe. A CRS is a cell-specific RS that consists of CRS reference symbols of predefined values inserted at frequency and time locations in the PRBs in each subframe. Figure 17A illustrates a CRS port that corresponds to a single antenna port. In contrast, figures 17B and 17C illustrate CRS ports corresponding to two and up to four antenna ports, respectively. As such, depending on the specific configuration, each ePDCCH region in a subframe can include from one to four CRS ports (that is, from one to four antenna ports carrying CRSs).
[0088] Figures 18A and 18B illustrate DMRS ports on a pair of PRBs in a subframe. A DMRS is a UE-specific RS transmitted in PRBs assigned to that specific UE. DMRSs are intended to be used for channel estimation for PDSCH transmissions particularly for non-codebook based pre-coding. A DMRS includes DMRS reference symbols of known values at known frequency and time locations in the PRBs in the subframe. Figure 18A illustrates two DMRS ports using 12 DMRS resource elements (Res), where the two DMRS ports correspond to two antenna ports. Conversely, figure 18B illustrates eight DMRS ports using 24 Res DMRS, where the eight DMRS ports correspond to eight antenna ports. Thus, depending on the specific configuration, each ePDCCH region in a subframe can include from one to eight DMRS ports corresponding from one to eight antenna ports.
[0089] Figure 19 illustrates CSI-RS ports in a pair of PRBs in a subframe. As illustrated, there can be one to eight CSI-RSs in the PRB pair in the subframe on one to eight CSI-RS ports, respectively. Each CSI-RS port is using two resource elements in the PRB pair. CSI-RS (s) can be used by a WD to acquire channel status information when DMRSs are used for channel estimation (for example, in transmission mode 9 of LTE Rel-10 and Rel-11). A CSI-RS includes CSI-RS reference symbols of known values at known time and frequency locations in the PRBs for the corresponding CSI-RS port. Since CSI-RS (s) are transmitted across all PRBs in the system's bandwidth, corresponding CSI-RS ports in the ePDCCH resource regions of Figure 16 can be found. Depending on the specific configuration, each ePDCCH resource region in a subframe can include one to eight CSi-RS ports corresponding to one to eight antenna ports.
[0090] Figure 20 illustrates the operation of WD 16 to estimate one or more large scale channel properties for an RS port of interest (or correspondingly an antenna port of interest) in an ePDCCH resource region of a subframe using RSs that correspond to antenna ports almost co-located according to one embodiment of the present disclosure. In this modality, WD 16 does not assume that the antenna ports corresponding to DMRS ports are almost co-located with respect to any of the large scale channel properties between DMRS ports and between PRBs in a subframe. In this modality, WD 16 receives a downlink from RAN 12 (step 400) and determines that a DCI message from an ePDCCH in a donwlink subframe is associated with two or more DMRS ports (for example, for transmission of spatial diversity) and / or two or more PRBs (step 402). In this case, the DCI message is an implicit signaling from RAN 12 that all antenna parts associated with the DCI message are almost co-located for the subframe. In other words, WD 16 can infer from the DCI message that all antenna ports associated with the DCI message are almost co-located for the substrate. As such, WD 16 estimates one or more large scale channel properties for the RS port of interest in ePDCCH based on reference symbols on RS ports associated with the DCI message, where the RS ports associated with the DCI message correspond to antenna ports almost co-located (step 404). Finally, WD 16 uses one or more large scale channel properties, as discussed above (step 406).
[0091] Notably, estimates of large scale channel properties can be used for channel estimation using DMRS. However, channel estimation algorithms use Doppler shift, delay spread, and other large-scale channel properties. These large-scale channel properties can be obtained from, for example, CSI-RS (s) since CSI-RSs are broadband and time periodic. However, in order to obtain adequate estimates of channel properties, WD 16 must be ensured that estimates of large scale channel properties obtained using CSI-RS (s) actually reflect the same channel as DMRS (s) ) of interest. This is done, for example, by estimating the desired large-scale channel properties for the DMRS port of interest using CSI-RS ports that are almost co-located with the DMRS port of interest.
[0092] By estimating one or more large scale channel properties based on CSI-RS (s) that are almost co-located with a DMRS port of interest, WD 16 can determine which (which) CSI-RS (s) ) are almost co-located with the DMRS port of interest in any suitable way. For example, the WD 16 can be configured to receive two CSI-RS (s) (ie, two CSI-RS ports). WD 16 can then determine which (which) CSI-RS port (s) are almost co-located with a DMRS port of interest based on resource allocation (that is, which ePDCCH resources are received by WD 16, which is indicated by the DCI message). In this way, the CSI-RS (s) associated with the DCI message can be used to estimate the large scale channel properties for the DMRS port of interest. In another modality, WD 16 can determine which (which) CSI-RS port (s) are almost co-located with a DMRS port of interest based on the type of transmission scheme. More specifically, ePDCCH can be transmitted in localized or distributed mode. In the following, DMRS ports for localized ePDCCH reception can be defined as being almost co-located with a first CSI-RS port (s) and any DMRS ports for distributed ePDCCH reception can be defined as being almost co-located with a second CSI-RS port (s).
[0093] Figure 21 illustrates the operation of WD 16 to estimate one or more large scale channel properties for an RS port of interest (or correspondingly an antenna port of interest) in a set of ePDCCH resources in a subframe using RSs that correspond to antenna ports almost co-located according to one embodiment of the present disclosure. In this modality, the ePDCCH resource regions in the subframe are divided into two or more sets of ePDCCH resources. For example, each ePDCCH resource region can correspond to a different set of ePDCCH resources. However, ePDCCH feature sets are not limited to them. For example, a set of ePDCCH resources can include ePDCCH resources from multiple different ePDCCH resource regions in the subframe. Conversely, an ePDCCH resource set can include only a subset of the resources in the ePDCCH resource region.
[0094] In this modality, WD 16 does not assume that the antenna ports corresponding to DMRS ports are almost co-located with respect to any of the large scale channel properties between DMRS ports and between PRBs that belong to different sets of ePDCCH. However, WD 16 does not assume that DMRS ports, and potentially all or some other types of RS ports, in the same set of ePDCCH features are almost co-located with respect to one or more of the large scale channel properties.
[0095] As illustrated, the WD 16 receives a donwlink signal from RAN 12 (step 500). WD 16 then estimates one or more large scale channel properties for an RS port in a set of ePDCCH resources in a subframe of the downlink signal based on the RSs that correspond to antenna ports in the set of ePDCCH resources (step 502). The RSs in the ePDCCH resource set, or more specifically the reference symbols on the RS ports in the ePDCCH resource set, correspond to antenna ports that are almost co-located with respect to one or more large scale channel properties. according to the assumption noted above. For example, WD 16 can estimate one or more large scale channel properties for a DMRS port of interest based on the CSI-RS port (s) in the same set of ePDCCH features. Finally, WD 16 uses one or more large scale channel properties of the RS port as discussed above (step 504).
[0096] Figure 22 illustrates the operation of one of the base stations 14 in RAM 12 to provide the downlink according to the embodiment of figure 21 according to an embodiment of the present disclosure. As illustrated, base station 14 configures ePDCCH resource sets (step 600). More specifically, base station 14 configures WD to monitor one or more of the ePDCCH resource sets (i.e., configures a WD 16 search space for ePDCCH). Base station 14 then broadcasts ePDCCH according to the predefined rule (s) that all antenna ports in the same set of ePDCCH resources must be nearly co-located (step 602). Notably, in WD 16, antenna ports in different sets of ePDCCH resources in a subframe are assumed not to be nearly co-located.
[0097] Figure 23 illustrates the operation of the cellular communication network 10 according to another embodiment of the present disclosure. This modality is similar to that described above with respect to figures 21 and 22. However, in this modality, RAN 12 provides information for WD 16 that indicates whether all RS ports or any defined subset of RS ports in the same set of ePDCCH resources correspond to nearly co-located antenna ports and, in some embodiments, information that is indicative of whether RS ports in two or more different sets of ePDCCH resources correspond to nearly co-located antenna ports. More specifically, as illustrated in figure 23, RAN 12 configures a WD 16 search space for ePDCCH (step 700). In particular, RAN 12 sets up a WD 16 search space for ePDCCH (step 700). In particular, RAN 12 configures the search space to include one or more sets of ePDCCH resources. The search space can be configured, for example, using RRC signaling.
[0098] In addition, RAN 12 provides information for the WD 16, which is referred to as almost co-located antenna information, which is indicative of which RS ports the WD 16 can assume correspond to almost co-located antenna ports ( step 702). In a preferred embodiment, the information indicates whether the WD 16 can assume that all RS ports or some subset of the RS ports in the same ePDCCH feature set correspond to nearly co-located antenna ports. In some embodiments, the information also indicates whether the WD 16 can assume that all RS ports or some subset of the RS ports in two or more different sets of ePDCCH resources correspond to nearly co-located antenna ports. So, for example, if there are two sets of ePDCCH resources, the information indicates: (1) whether the RS ports or some subset of the RS ports in the same PDCCH resource set correspond to almost co-located antenna ports and, optionally , (2) whether the RS ports or any subset of the RS ports in the two different sets of ePDCCH resources correspond to nearly co-located antenna ports. The information provided in step 702 can be provided, for example, by RRC signaling. Note that although steps 700 and 702 are illustrated as separate steps, steps 700 and 702 can be performed using a single message.
[0099] Some time later, RAN 12 transmits a donwlink subframe that includes ePDCCH (step 704). WD 16 estimates one or more large-scale channel properties for an RS port in a set of RS-based ePDCCH features, or more specifically reference symbols on RS ports, which correspond to antenna ports almost co-located as indicated in the information received from RAN 12 in step 702 (step 706). WD 16 then uses one or more large scale channel estimates as discussed above (step 708).
[00100] Figure 24 illustrates the operation of the cellular communication network 10 according to a modality in which the WD 16 receives ePDCCH from two different base stations 14 (i.e., two different transmission points). As illustrated, in this embodiment, one of the base stations 14 (base station 14 corresponding to transmission point 1) transmits configuration information to the WD 16 that configures ePDCCH resources, namely, a first set of ePDCCH resources for the transmission 1 and a second set of ePDCCH resources for transmission point 2 (steps 800 and 802). In addition to configuring the ePDCCH feature sets, base station 14 transmits near-co-located antenna information to the WD 16 (step 804). In this mode, the almost co-located antenna information indicates that the WD 16 can assume that the antenna ports, or the corresponding RS ports, in the same ePDCCH resource set are almost co-located. Notably, although steps 800 - 804 are illustrated as separate steps, the corresponding information can be transmitted in a single message.
[00101] Some time later, base station 14 corresponding to transmission point 1 transmits a downlink subframe including ePDCCH transmission (s) in the first set of ePDCCH resources for WD 16 (step 806). In the same downlink subframe, the base station 14 corresponding to the transmission point 32 transmits ePDCCH transmission (s) in the second set of ePDCCH resources (step 808). WD 16 estimates one or more large scale channel properties for an RS port in the first set and / or the second set of ePDCCH features based on RSs, or more specifically reference symbols on the RS ports, in the same set of features ePDCCH (step 810). Thus, WD 16 estimates one or more large-scale channel properties for an RS port in the first set of ePDCCH resources based on all other RS ports in the first set of ePDCCH resources, which for this modality can be assumed by WD 16 as corresponding to almost co-located antenna ports. Similarly, WD 16 estimates one or more large-scale channel properties for an RS port in the second set of ePDCCH resources based on all other RS ports in the second set of ePDCCH resources, which for this modality can be assumed by the WD 16 to correspond to almost co-located antenna ports. WD 16 then uses one or more large scale channel estimates as discussed above (step 812).
[00102] Figure 25 is a block diagram of one of the WDs 16 according to one embodiment of the present disclosure. As illustrated, WD 16 includes a radio subsystem 18 and a processing subsystem 20. Radio subsystem 18 generally includes analog components and in some modalities, digital to send and receive data to and from base stations 14. In modalities radio subsystem 18 may represent or include one or more radio frequency (RF) transceivers, or separate RF transmitter (s) and receiver (s), capable of transmitting appropriate information wirelessly to and receiving appropriate information from others network components or nodes. From a wireless communication protocol view, radio subsystem 18 implements at least part of Layer 1 (i.e., the physical layer or "PHY").
[00103] The processing subsystem 20 generically implements any remaining portion of layer 1 as well as functions for higher layers in the wireless communication protocol (for example, layer 2 (data link layer), layer 3 (network layer) , etc.). In specific embodiments, the processing subsystem 20 may comprise, for example, one or more general purpose or special purpose microprocessors or other microcontrollers programmed with appropriate software and / or firmware to perform part or all of the functionality of the WD 16 described here. In addition or alternatively, the processing subsystem 20 may comprise several digital hardware blocks (for example, one or more application specific Integrated Circuits (ASICs), one or more immediately available digital and analog hardware components, or a combination thereof ) configured to perform some or all of the WD 16 functionality described here. In addition, in specific modalities, the functionality described above of WD 16 can be implemented, totally or in part, by the processing subsystem 20 running software or other instructions stored in a non-transitory computer-readable medium, such as Random Access Memory (RAM) , Read-only memory (ROM), a magnetic storage device, an optical storage device, or any other suitable type of data storage components. Of course, the detailed operation for each of the functional protocol layers, and thus the radio subsystem 18 and processing subsystem 20, will vary depending on the specific implementation as well as the standard or standards supported by WD 16.
[00104] Figure 26 is a block diagram of one of the base stations 14 according to an embodiment of the present disclosure. As illustrated, base station 14 includes a radio subsystem 22 and a processing subsystem 24. Radio subsystem 22 generally includes analog components and in some embodiments, digital to send and receive data to and from wireless devices, such as o WD 16, in a corresponding cell of the cellular communication network 10. In specific embodiments, radio subsystem 22 may represent or include one or more RF transceiver (s), or separate RF transmitter (s) and receiver (s), capable of transmitting appropriate information wirelessly to and receiving appropriate information from other network components or nodes. From a wireless communications protocol view, radio subsystem 22 implements at least part of layer 1 (i.e., the physical layer or "PHY"). [00105] The processing subsystem 24 generically implements any remaining portion of layer 1 not implemented in the radio subsystem 22 as well as functions for higher layers in the wireless communication protocol (for example, layer 2 (data link layer), layer 3 (network layer), etc.). In specific embodiments, the processing subsystem 24 may comprise, for example, one or more general purpose or special purpose microprocessors or other microcontrollers programmed with appropriate software and / or firmware to perform part or all of the functionality of the base station 14 described herein. In addition or alternatively, the processing subsystem 24 may comprise several blocks of digital hardware (for example, one or more ASICs, one or more immediately available digital and analog hardware components or a combination of them) configured to perform part or all of the base station functionality 14 described here. In addition, in specific embodiments, the functionality described above of the base station 14 can be implemented, in whole or in part, by the processing subsystem 24 by executing software or other instructions stored in a non-transitory computer-readable medium, such as RAM, ROM, a device magnetic storage device, an optical storage device, or any other suitable type of data storage components.
[00106] The following acronyms are used throughout this description. .3GPP 3rd generation partnership project. AL ASIC aggregation level Application-specific integrated circuit. BS Base station. CCE Control channel element. CoMP Multi-point coordinate. CRS Common reference signal. CSI-RS Channel status information reference signal. CSS Common search space. DCI Downlink control information. DFT Discrete Fourier Transform. DL Downlink. DMRS Demodulation reference signal. DPS Selection of dynamic point eNB Improved node B. ePDCCH Improved physical donwlink control channel. ePHICH Channel Improved Physical Hybrid Automatic Replay Request Indicator. GSM Global system for mobile communication. HARQ Hybrid automatic repeat request. JT Joint transmission. KHz kHz. LTE Long-term evolution. ms millisecond. OFDM Orthogonal frequency division multiplexing. PCFICH Channel Physical control format indicator. PDCCH Physical downlink control channel. PDSCH Channel shared physical downlink. PRB Physical resource block. PSS Primary synchronization signal. PUSCH Channel shared physical uplink. RAM Random access memory. RAN radio access network. RB resource block. RE feature element. REG resource element group. Rel-10 Long-term Evolution Release 10. Rel-11 Release of long-term evolution 11. RF Radio frequency. ROM Read-only memory. RRC Radio resource control. RS Reference signal. SSS Secondary synchronization signal. UE User element. UL Uplink. UMB Ultra mobile broadband. WCDMA Broadband code split multiple access. WD Wireless device. WiMAX Worldwide interoperability for Microwave Access [00107] Those skilled in the art will recognize improvements and modifications to the preferred modalities of the present disclosure. All of these improvements and modifications are considered to be within the scope of the concepts disclosed here and in the claims that follow.

权利要求:
Claims (20)
[1]
1. Wireless device (16) configured to operate on a cellular communication network (10), characterized by the fact that it comprises: a radio subsystem (18); and a processing subsystem (20) associated with the radio subsystem (18) configured to: receive, through the radio subsystem (18), a downlink subframe comprising a downlink control channel from the cellular communication network (10), a search space of the wireless device (16) with respect to the downlink control channel comprising one or more sets of physical downlink control channel resources; and estimating one or more large-scale channel properties for an antenna port of interest in a set of physical downlink control channel resources in the search space of the wireless device (16) based on a subset of a plurality of reference signals corresponding to the antenna ports in the cellular communication network (10) that are almost co-located with the antenna port of interest with respect to one or more large scale channel properties, the antenna ports that are almost co -located with the antenna port of interest comprising at least a subset of antenna ports in the same set of downlink control channel physical resources in the search space of the wireless device (16).
[2]
2. Wireless device (16), according to claim 1, characterized by the fact that the processing subsystem (20) is further configured to receive, through the radio subsystem (18), information from the communication network cellular (10) which is indicative of the antenna ports that are almost co-located with the antenna port of interest with respect to one or more large scale channel properties.
[3]
3. Wireless device (16), according to claim 2, characterized by the fact that the information from the cellular communication network (10) is still indicative of one or more blocks of physical resource on which the communication ports antennas are almost co-located with the antenna port of interest with respect to one or more large-scale channel properties.
[4]
4. Wireless device (16) according to claim 1, characterized by the fact that the antenna ports that are almost co-located with the antenna port of interest with respect to one or more large scale channel properties are predefined for the cellular communication network (10).
[5]
5. Wireless device (16) according to claim 4, characterized by the fact that one or more physical resource blocks on which the antenna ports are almost co-located with the antenna port of interest with respect to one or more large scale channel properties are also predefined by the cellular communication network (10).
[6]
6. Wireless device (16) according to claim 1, characterized by the fact that the antenna ports that are almost co-located with the antenna port of interest with respect to one or more large scale channel properties comprise first antenna ports that are predefined for the cellular communication network (10) as being almost co-located with the antenna port of interest with respect to one or more large scale channel properties and second antenna ports indicated as being almost co-located with the antenna port of interest with respect to one or more large-scale channel properties through signaling the cellular communication network (10).
[7]
7. Wireless device (16) according to claim 6, characterized by the fact that one or more physical resource blocks on which the first antenna ports are almost co-located with the antenna port of interest with respect to the one or more large scale channel properties are also predefined by the cellular communication network (10).
[8]
8. Wireless device (16) according to claim 6, characterized by the fact that one or more blocks of physical resource on which the second antenna ports are almost co-located with the antenna port of interest with respect to the one or more large scale channel properties are also indicated for the wireless device (16) by signaling the cellular communication network (10).
[9]
9. Wireless device (16) according to claim 1, characterized by the fact that the cellular communication network (10) is a Long Term Evolution cellular communication network, and the downlink control channel is a Improved Physical Downlink Control Channel.
[10]
10. Wireless device (16) according to claim 1, characterized by the fact that: the wireless device (16) does not assume that antenna ports that correspond to the reference signals on an improved Physical Downlink Control Channel are almost co-located with respect to large-scale channel properties between antenna ports and between physical resource blocks within a subframe; and the antenna ports that are almost co-located with the antenna port of interest with respect to one or more large-scale channel properties comprise antenna ports signaled by the cellular communication network (10).
[11]
11. Wireless device (16), according to claim 1, characterized by the fact that: the cellular communication network (10) is a Long Term Evolution cellular communication network; the downlink control channel is an improved Physical Downlink Control Channel; and the plurality of reference signals comprises a plurality of reference signals transmitted within the improved Physical Downlink Control Channel.
[12]
12. Wireless device (16) according to claim 11, characterized in that a search space of the wireless device (16) in relation to the improved Physical Downlink Control Channel includes two or more sets of physical resources, and the processing subsystem (20) is further configured to: receive information from the cellular communication network (10) which is indicative that antenna ports within the two or more sets of physical resources are almost co-located with respect to one or more large scale channel properties.
[13]
13. Wireless device (16) according to claim 12, characterized by the fact that information from the cellular communication network (10) indicates that at least some of the antenna ports within the same set of physical resources are almost co-located with respect to one or more large scale channel properties.
[14]
14. Wireless device (16) according to claim 12, characterized by the fact that the information from the cellular communication network (10) indicates that at least some of the antenna ports within two or more different sets of physical resources of the two or more sets of physical resources are almost co-located with respect to one or more large scale channel properties.
[15]
15. Wireless device (16) according to claim 1, characterized in that the one or more large scale channel properties include one or more of a group consisting of: delay spread, Doppler spread, Doppler shift, gain medium, and medium delay.
[16]
16. Wireless device (16) according to claim 1, characterized by the fact that the cellular communication network (10) is a long-term evolution cellular communication network, the downlink control channel is a control channel Enhanced Physical Downlink, the one or more sets of downlink control channel physical resources are one or more sets of enhanced Physical Downlink Control Channel physical resource blocks, where each set of physical resource block pairs Enhanced physical downlink control channel includes one or more pairs of physical resource blocks in one or more regions of enhanced physical downlink control channel within the downlink subframe.
[17]
17. Wireless device (16) according to claim 1, characterized by the fact that the search space of the wireless device (16) includes two or more sets of physical downlink control channel features, and the wireless device (16) does not assume that antenna ports in different sets of physical downlink control channel resources are almost co-located with respect to one or more large scale channel properties.
[18]
18. Wireless device (16) according to claim 1, characterized by the fact that the antenna port of interest is a Demodulation Reference Signal port, DMRS, and at least a subset of antenna ports in the same set physical downlink control channel resources in the wireless device's search space (16) comprise at least one of a group consisting of: at least one other DMRS port in the same set of downlink control channel physical resources and at least one Reference Signal port, RS, of a different type than DMRS.
[19]
19. Method of operation of a wireless device (16) in a cellular communication network (10), characterized by the fact that it comprises: receiving a downlink subframe from the cellular communication network (10), the downlink subframe comprising a communication channel downlink control of the cellular communication network (10), a search space of the wireless device (16) with respect to the downlink control channel comprising one or more sets of physical downlink control channel resources; and estimating one or more large-scale channel properties for an antenna port of interest in a set of physical downlink control channel resources in the search space of the wireless device (16) based on a subset of a plurality of reference signals corresponding to the antenna ports in the cellular communication network (10) that are almost co-located with the antenna port of interest with respect to one or more large-scale channel properties, the antenna ports that are almost co -located with the antenna port of interest comprising at least a subset of antenna ports in the same set of downlink control channel physical resources in the search space of the wireless device (16).
[20]
20. Base station (14) of a cellular communication network (10), characterized by the fact that it comprises: a radio subsystem (22); and a processing subsystem (24) associated with the radio subsystem (22) configured to: provide, through the radio subsystem (22), a downlink subframe comprising a plurality of reference signals corresponding to a plurality of gateway ports antenna according to one or more predefined rules that define one or more subsets of the plurality of antenna ports that must be almost co-located within a downlink control channel of the downlink subframe, the one or more rules comprising a rule that at least some antenna ports within the same set of physical downlink control channel resources in a configured search space of a wireless device (16) should be almost co-located with respect to one or more channel properties large-scale.

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法律状态:
2018-01-23| B25D| Requested change of name of applicant approved|Owner name: TELEFONAKTIEBOLAGET LM ERICSSON (PUBL) (SE) |

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2018-12-04| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2020-01-21| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2020-01-21| B15K| Others concerning applications: alteration of classification|Free format text: AS CLASSIFICACOES ANTERIORES ERAM: H04L 5/00 , H04L 25/02 Ipc: H04L 25/02 (2006.01), H04L 5/00 (2006.01) |

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2020-03-10| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 02/08/2013, 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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US201261679335P| true| 2012-08-03|2012-08-03|

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US61/679,335|2012-08-03|

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US13/917,717|US9203576B2|2012-08-03|2013-06-14|Quasi co-located antenna ports for channel estimation|

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US13/917,717|2013-06-14|

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PCT/IB2013/056357|WO2014020580A1|2012-08-03|2013-08-02|Quasi co-located antenna ports for channel estimation|

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