methods and arrangements for transmitting and decoding reference signals

专利摘要:
METHODS AND ARRANGEMENTS FOR TRANSMITTING AND DECODING REFERENCE SIGNALS In some modalities, a method is provided on a radio network node to transmit a reference signal through an antenna port, in which the reference signal is transmitted in a group code division multiplexing, CDM. The CDM group comprises at least two CDM subgroups, with each CDM subgroup being transmitted on a different subcarrier. Each CDM subgroup comprises elements of appeal. In a first step, the radio network node transmits the reference signal through a first CDM subgroup using an orthogonal coverage code. The first CDM subgroup comprises resource elements in a first time slice and in a subsequent time slice. In an additional step, the radio network node transmits the reference signal through a second CDM subgroup using an orthogonal coverage code permutation. The second CDM subgroup comprises resource elements in the first time partition and the second time partition. The permutation of the orthogonal coverage code is selected in such a way as to allow the decoding of the reference signal in the (...) domain.
公开号:BR112012029204B1
申请号:R112012029204-8
申请日:2010-06-24
公开日:2021-01-19
发明作者:Yang Hu；Xinghua Song；Jianfeng Wang
申请人:Telefonaktiebolaget Lm Ericsson (Publ)；
IPC主号:

专利说明:

TECHNICAL FIELD
[001] The present invention relates to methods and arrangements for transmitting a reference signal, and methods and arrangements for decoding a reference signal. BACKGROUND
[002] The 3rd Generation Partnership project (3GPP) is responsible for the standardization of the Universal Mobile Telecommunication System (UMTS) and Long Term Evolution (LTE). The 3GPP work on LTE is also referred to as the Developed Land Access Network (E-UTRAN). LTE is a technology for performing high-speed packet-based communication that can achieve high data rates on the downlink and uplink, and resembles a next-generation UMTS-related communication system. To support high data rates, LTE allows a system bandwidth of up to 20 MHz. LTE is also capable of operating in different frequency bands and can operate in at least Frequency Division Duplexing (FDD) and Duplexing modes. Time Division (TDD). The modulation technique or transmission method used in LTE is known as Orthogonal Frequency Division Multiplexing (OFDM). The first version of LTE is expected to provide peak rates of 300 Mbps, a radio network delay of, for example, 5 ms or less, a significant increase in spectrum efficiency and a network architecture designed to simplify operation network, reduce costs, etc.
[003] For next generation mobile communication systems, for example, Advanced International Mobile Telecommunication (IMT) and / or Advanced LTE, which is an evolution of LTE, which supports bandwidths up to 100 MHz is discussed. In LTE and Advanced LTE, radio base stations are known as eNBs or eNodeBs, where "e" means evolved. In addition, multiple antennas with pre-coding and / or beam-forming technology can be used to provide high data rates to user equipment (UEs). Thus, LTE and Advanced LTE are examples of Multiple Input, Multiple Output (MIMO) radio systems. Another example of a system based on MIMO and OFDM is the Worldwide Interoperability for Microwave Access (WiMAX). Since Advanced LTE is an evolution of LTE, backward compatibility is important so that Advanced LTE can be distributed over a spectrum already occupied by LTE.
[004] In Advanced LTE, also known as Version 10 3GPP, a transmission of up to 8 layers must be sustained to meet the spectral efficiency of Advanced LTE downlink, 30bps / Hz. This can be achieved using some type of advanced antenna configuration, for example, high-order 8x8 MIMO, where 8 transmitting antennas and 8 receiving antennas are used. Throughout this document, the term "antenna port" will be used instead of an antenna, to emphasize that what is referred to does not necessarily correspond to a single physical antenna. To provide the context for the subsequent description, a brief review of the LTE downlink physical resource structure will now be provided. In OFDM systems such as LTE, the available physical resources are divided into a grid of time and frequency. The time dimension is divided into subframes, each comprising a number of OFDM symbols. In LTE and Advanced LTE, a subframe is 1 ms long, divided into two time partitions of 0.5 ms each. A guard interval, called a cyclic prefix (CP), is added to each OFDM symbol to reduce interference between symbols. For a normal cyclic prefix length (CP), the number of OFDM symbols per subframe is 14, this indicates that the time is quantized in 14 symbols during a subframe. For an extended cyclic prefix length, there are 12 OFDM symbols per subframe. The frequency corresponds to subcarriers in the OFDM symbols, and the number of subcarriers varies depending on the system's bandwidth used. Each box within the time-frequency grid represents a single subcarrier during a symbol period, and is referred to as a feature element. The smallest programmable unit of resource elements is called a physical resource block (PRB), or simply a resource block (RB). In LTE and Advanced LTE, a resource block traverses 12 subcarriers and 0.5 ms, that is, 7 or 6 OFDM symbols depending on the length of the cyclic prefix. The resource blocks are, however, allocated in pairs in the time domain. Thus, a 1 ms LTE subframe has two resource blocks wide.
[005] There is also a special type of LTE subframe, consisting of three fields: Downlink Pilot Time Partition (DwPTS), Guard Period (GP), and Uplink Pilot Time Partition (UpPTS). This special subframe is used for switching from downlink to uplink in TDD mode. The duration of the GP field varies depending on how long it takes the UE to switch from receiving to sending, and also on how long the signal propagates from the base station to the UE. The DwPTS field conducts synchronization and user data, as well as the downlink control channel for transmitting programming and control information. Since the total duration of the subframe is fixed at 1 ms, the duration of the DwPTS and UpPTS fields is adjusted based on the duration of the GP field.
[006] A reference signal is a known signal that is inserted at predetermined positions in the OFDM time-frequency grid. The presence of this known signal allows the UE to estimate the downlink channel so that it can perform channel demodulation. It has been determined for LTE that up to 8 EU specific reference signals (RS) will be introduced for the purpose of channel demodulation. UE-specific reference signals are also called RS or DM-RS demodulation. Thus, each antenna port transmits a DM-RS, which is specific to that antenna port as well as to the UE to which the transmission is directed.
[007] Reference signals are generally transmitted according to a predefined pattern in time and frequency, so that the UE knows where to find the signals. A DM-RS standard of the prior art with normal cyclic prefix (CP), which supports up to classification 8, is shown in Figure 1. The expression "classification", or transmission classification, refers to the number of independent data streams, or spatial layers, which can be reliably transmitted over a wireless channel. In the present context, classification can be interpreted as the maximum number of transmit antenna ports that are supported.
[008] Figure 1 shows a time-frequency grid for a normal subframe, that is, not a special subframe. Each row in the grid represents a subcarrier, and each column represents an OFDM symbol. The first three OFDM symbols are drawn in light gray, to indicate that these symbols can be reserved for control signaling. The grid comprises two LTE time partitions, as explained above. The DM-RS standard in Figure 1 supports a total of 8 DM-RS antenna ports. The standard exhibits a DM-RS overhead of 12 REs per layer; that is, each antenna port will use 12 REs per subframe to transmit the reference signals. For example, an antenna port will transmit reference signals in the REs represented by the 12 squares filled with sloping lines in Figure 1. The 8 antenna ports DM-RS are separated by a combination of CDM and FDM, as will be further explained below. It must be understood that other types of reference signals can also be transmitted; however, these have been omitted from Figure 1 for the sake of simplicity. Up to two code division multiplexing groups (CDM) are reserved for DM-RS, where each CDM group consists of 12 resource elements (RE) per pair of physical resource blocks (PRB). In the context of this description, a CDM group is a group of resource elements that is used to multiplex reference signals from numerous antenna ports using code division multiplexing. Thus, the 12 squares with sloping lines in Figure 1 form a CDM group, and the 12 squares with horizontal lines from another CDM group. Each CDM group supports a maximum of four layers, that is, a maximum of four antenna ports. The two CDM groups are multiplexed by FDM; in other words, the REs belonging to the first and second CDM groups are transmitted on different frequencies, that is, subcarriers. There is a CDM group in each time partition, as indicated by the thick black outlines 110, 120 in Figure 1.
[009] In addition, each CDM group comprises three CDM subgroups, that is, groups of resource elements that share the same subcarrier. For example, the four squares with sloping lines in the top row of the time-frequency grid in Figure 1 form a CDM subgroup, as indicated by the thick gray outline 130. Two additional subgroups are indicated by thick gray outlines 140 and 150. Each CDM subgroup comprises 4 REs in the time domain, and in each CDM subgroup, up to four DM-RS antenna ports can be multiplexed.
[0010] Multiplexing of reference signals within a CDM subgroup is performed by applying orthogonal coverage codes (OCC) across the time domain. An OCC is a set of codes that will have zero cross-correlation. Thus, two signals encoded with two different codes in the set will not interfere with each other. An example of an OCC is a Walsh code. Walsh codes are defined using a Walsh matrix of length N, that is, with N columns. Each row in the Walsh matrix is a Walsh code of length N. For example, the Walsh matrix of length 4 is:

[0011] Each row in this matrix forms a code of length 4, that is, the codes are [1, 1, 1, 1], [1, -1, 1, -1], [1, 1, -1, -1] and [1, -1, -1, 1]. These four codes are all orthogonal to each other. The individual "1": s and "-1": s of each code will be referred to as "code elements" below.
[0012] Although Walsh codes are used throughout this description to exemplify the invention, it should be understood that any OCC can be used. When this description refers to "applying an orthogonal coverage code" or "transmitting a signal using an orthogonal coverage code" this should be understood as referring to a code among a set of mutually orthogonal codes, for example, a row of the matrix of Walsh.
[0013] Each antenna port transmits a reference signal within the CDM subgroup, by applying an orthogonal coverage code to the signal. If four antenna ports are multiplexed within a CDM subgroup, an OCC of length 4 will be used, and each of the four antenna ports will use a different code from the array. This allows the reference signals to be separated and decoded on the receiving side.
[0014] The concept of OCC mapping was introduced for the double layer beam conformation, with the objective of performing the randomization of total peak power, which is expected to improve the use of eNodeB side power. OCC mapping means that the code elements in each OCC are mapped to the reference elements in a specific pattern, or in a specific order. An example of an OCC mapping design, which uses Walsh codes of length 2, is shown in Figure 2. In the lower right corner of Figure 2, the Walsh matrix of length 2 is shown. Since a length 2 code is used, two antenna ports are multiplexed in each CDM subgroup in this example. Each antenna port will transmit two reference signals; one in the first time partition, and one in the second time partition. Layer 1, that is, the first antenna port, uses the code of the first row in the Walsh matrix, that is, [+1, +1]. Layer 2, that is, the second antenna port, uses the code for the second row, [+1, -1]. Index a corresponds to the first code element, and index b corresponds to the second code element of each code. Thus, in the second code [+1, - 1], the index a corresponds to +1 and b corresponds to -1. Each antenna port will encode its reference signal when applying the code elements in the order indicated by the a: s and b: s pattern in the time-frequency grid in Figure 2.
[0015] An example can help to illustrate the encoding process. Concentrating on the first CDM 210 subgroup, the first antenna port will transmit two reference signals, denoted X1 and X2, in that CDM subgroup. The second antenna port will also transmit two reference signals, denoted Y1 and Y2, in the same subgroup CDM 210. The first antenna port will encode its first reference signal, X1, in OFDM symbols 6 and 7 when applying the elements of code [a, b], corresponding to [+1, +1], since the first antenna port uses the first Walsh code. Thus, the first antenna port will transmit [X1, X1]. The second antenna port will also encode its first reference signal, denoted Y1, in OFDM symbols 6 and 7. This will apply the code elements [a, b] of the second Walsh code, that is, [+1, - 1]. Therefore, the second antenna port will transmit [Y1, -Y1]. These signals will be superimposed, so that the resulting signal transmitted in OFDM symbols 6 and 7 is [X1 + Y1, X1 - Y1].
[0016] However, in the second subgroup CDM 220, that is, the sixth row of the time-frequency grid, the two antenna ports will encode their reference signals when applying the code elements in reverse order. By focusing again on the OFDM 6 and 7 symbols, the first antenna port will use the code [+1, +1], that is, [X1, X1] - effectively the same code again, as inverting the non-code elements it makes a difference in this case - however the second antenna port will use the code [-1, +1], that is, [-Y1, Y1]. Thus, the resulting signal transmitted in OFDM symbols 6 and 7 in the second subgroup CDM 220 will be [X1- Y1, X1 + Y1]. As a whole, it is pointed out that each antenna port will also transmit a second reference signal, denoted X2 and Y2, respectively, in OFDM 13 and 14 symbols. The code pattern is the same as in the previous example and the resulting signal transmitted in OFDM symbols 13 and 14 it can be derived in the same way.
[0017] It is pointed out that in this example, only the CDM 1 group is allocated. Also, the mapping pattern is different for even PRBs and odd PRBs. Total peak power randomization can be performed between two adjacent PRBs. To better understand, we consider the special case where the reference signals X1 and Y1 are the same, that is, X1 = X2. Using the same example above, the signal transmitted in symbols 6 and 7 of the first subgroup CDM 210 will be [X1 + X1, X1 - X1], that is, [2X1, 0]. In the second subgroup CDM 220, the resulting signal will be [X1 - X1, X1 + X1], that is, [0, 2X1]. Thus, in the OFDM 6 symbol, the 2X1 signal will be transmitted in the first CDM 210 subgroup, and O will be transmitted in the second CDM 220 subgroup. In the OFDM 7 symbol, the situation is the opposite, that is, O in the first CDM 210 subgroup, and 2X1 in the second subgroup CDM 220. This means that the total transmission power level will be approximately the same in the OFDM 6 symbol as in the symbol 7. In other words, the transmission power level is balanced between the OFDM symbols, this indicates that high spikes in transmission power levels between symbols can be avoided.
[0018] As mentioned above, the use of orthogonal coverage codes allows the receiver to decode the reference signals to estimate the channel. Thus, on the EU side, channel-by-port estimation is performed using the appropriate OCC. In other words, each reference signal is decoded, or concatenated, using the corresponding OCC that was used to encode the signal. An OCC of different length is applied for the channel estimate depending on how many layers are multiplexed in a CDM group. Two exemplary cases with two and four layers, respectively, will now be described with reference to Figures 3 (a) and 3 (b).
[0019] When up to two layers are multiplexed in a CDM group, an OCC of length 2 can be used for each CDM group 340, 350 in both partitions, as shown in Figure 3 (a). This means that the Doppler impact introduced by mobility can be well captured by considering two CDM groups.
[0020] When more than two layers are multiplexed in a CDM group, an OCC of length 4 must be used in both groups in a subframe, as illustrated in Figure 3 (b). OCC of length 4 is typically used for high-rated cases, that is, four or more antenna ports. On the EU side, a common strategy for performing DM-RS-based channel estimation is to apply a D 2x1 D filter method per PRB, that is, first a frequency domain filter and then a time domain filter. The basic principle is shown in Figure 4. Frequency domain filtering and time domain filtering are performed based on the respective delay spread, Doppler, and SNR inputs. Due to uncertain resource allocation and bandwidth, the frequency domain filter has been identified as requiring a much longer processing time than the time domain filter. In a way, the time required by the frequency domain filter becomes an obstacle that prevents the acceleration of processing through channel estimation and additional detection, and this can have an impact on the total detection latency.
[0021] When performing the channel estimation with an OCC of length 2, as shown in Figure 3 (a), it is observed that the partition-by-partition channel estimation can be explored. That is, the channel estimate in the 12partition can be performed first before receiving the total subframe. The reason for this is that a reference signal is transmitted in two consecutive REs, which are comprised in the same time partition. In other words, all the information required to decode the reference signal is available within a single time partition. This allows the processing time spent by the frequency domain filter on the first partition to be reduced, as the information received on the first partition can be processed during the time that the second partition is received. This can result in a low latency channel estimator.
[0022] However, in 3GPP Version 10, an OCC of length 4 is used to support the multiplexing of up to four layers in each CDM group, as explained above. when performing channel estimation with OCC of length 4, as shown in Figure 3 (b), an OCC of length 4 is used instead of an OCC of length 2. However, the concatenation of OCC of length 4 cannot be performed until the entire subframe is received. This is due to the fact that each reference signal is broadcast over four REs, which are distributed across two time partitions (see Figure 1). Thus, in the conventional scheme, the channel estimate cannot be performed until both time partitions are received. This means that the processing of the first partition cannot be performed in parallel with the reception of the second partition, and additional time will be required, particularly by the frequency domain filter. Consequently, there is a risk of greater latency when performing channel estimation in the case of a length 4 OCC, since partition-by-partition channel estimation is not possible, as in the case of a length 2 OCC. in the case of an OCC of length 4, the Doppler impact cannot be satisfactorily overcome as the code concatenation needs to be considered in both partitions.
[0023] Furthermore, the OCC mapping pattern shown in Figure 2 performs the randomization of total peak power in two RBs, as described above, but only for normal cyclic prefix length (CP). Thus, there is a need for a mechanism to allow randomization of total peak power also in the case of extended CP, and / or for special subframes that comprise the DwPTS (Downlink Pilot Time Partition) field.
[0024] SUMMARY
[0025] An objective of some embodiments of the invention is to provide a mechanism to reduce latency when performing channel estimation. An additional objective of some modalities is to provide a mechanism to allow randomization of total peak power in the case of extended CP, and / or for special subframes that comprise the DwPTS (Downlink Pilot Time Partition) field.
[0026] In some embodiments of this invention, the goal is achieved by providing a low complexity length 4 OCC mapping standard to normal cyclic prefix (CP) with a simple length 2 OCC mapping extension, which essentially maintains the backward compatibility with prior art mapping standards, such as the defined 3GPP Version 9 standard, and provides 2D orthogonality by PRB to allow for partition processing.
[0027] In addition, some modalities provide a low complexity length 2 OCC mapping standard for extended CP by reusing the same mechanism applied in 3GPP Version 9, which, on the one hand, can achieve total peak power randomization within of a PRB and on the other hand maintains the 2D-per-PRB orthogonality property.
[0028] In some embodiments of this invention, an OCC mapping is provided for normal CP and extended CP, where an OCC mapping of length 4 is proposed for normal CP and an OCC mapping of length 2 is proposed for extended CP. In some embodiments, a method is provided on a radio network node to transmit a reference signal through an antenna port, where the reference signal is transmitted in a code division multiplexing group, CDM. The CDM group comprises at least two CDM subgroups, with each CDM subgroup being transmitted on a different subcarrier. Each CDM subgroup comprises elements of appeal. In a first step, the radio network node transmits the reference signal through a first CDM subgroup using an orthogonal coverage code. The first CDM subgroup comprises resource elements in a first time partition and a subsequent time partition. In an additional step, the radio network node transmits the reference signal through a second CDM subgroup using an orthogonal coverage code permutation. The second CDM subgroup comprises resource elements in the first time partition and the second time partition. The permutation of the orthogonal coverage code is selected in such a way as to allow the decoding of the reference signal in the frequency domain, by applying the orthogonal coverage code only to the resource elements in the CDM group that are comprised in the first time partition.
[0029] In some embodiments, a method is provided on user equipment to decode a reference signal that is received in a code division multiplexing group, CDM. The CDM group comprises at least two CDM subgroups, each CDM subgroup being received in a different subcarrier. Each CDM subgroup comprises resource elements in a first time slice and a subsequent time slice. In a first step, the UE receives, in a first time partition, a first set of resource elements comprised in a first CDM subgroup, and a second set of resource elements comprised in a second CDM subgroup. The UE decodes the reference signal by applying an orthogonal coverage code to the first and second sets of resource elements. In some embodiments, a method is provided on a radio network node for transmitting reference signals, where a first reference signal is transmitted in a first code division multiplexing group, CDM, and a second reference signal is transmitted in a second CDM group. Each CDM group comprises at least two CDM subgroups, and each CDM subgroup comprises resource elements. The radio network node transmits the first reference signal through a first CDM subgroup using an orthogonal coverage code, and through a second CDM subgroup using an orthogonal coverage code permutation. In addition, the radio network node transmits the second reference signal through a third CDM subgroup using the orthogonal coverage code, and through a fourth CDM subgroup using the permutation of the orthogonal coverage code. The permutation of the orthogonal coverage code is selected in such a way as to allow peak power randomization within a single resource block.
[0030] In particular embodiments of this invention, an orthogonal coverage code is exchanged between different CDM subgroups. When exchanging the code, that is, changing the order of the code elements, it is guaranteed that each code element will be applied at least once to a given reference signal within a single subframe. This indicates that a UE will receive enough information in the first subframe to be able to decode the reference signal; this can be done by applying the OCC in the frequency domain instead of, or beyond the time domain. Thus, the 2D orthogonality by-PRB can be exploited to allow processing by partition.
[0031] An additional advantage of at least some modalities is the implementation of low complexity. This is due to the use of a reference signal pattern that is an existing length 2 OCC mapping extension or reuse.
[0032] Yet an additional advantage of some modalities is that backward compatibility with the 3GPP Version 9 mapping standard is maintained in the case of normal CP.
[0033] Another advantage is that peak power randomization can be achieved, either completely or partially, by displacing and / or exchanging the orthogonal coverage code. In some particular modalities, the randomization of total peak power is achieved through two PRBs. Other modalities obtain peak power randomization within a single PRB.
[0034] BRIEF DESCRIPTION OF THE DRAWINGS
[0035] Figure 1 is a schematic diagram that illustrates a reference signal pattern.
[0036] Figure 2 is a schematic diagram illustrating a reference signal pattern.
[0037] Figure 3 is a schematic diagram that illustrates a reference signal pattern.
[0038] Figure 4 is a diagram that illustrates a part of the channel estimation procedure.
[0039] Figure 5 is a schematic diagram that illustrates a reference signal pattern.
[0040] Figure 6 is a flow chart that illustrates an exemplary method.
[0041] Figure 7 is a schematic diagram that illustrates a reference signal pattern.
[0042] Figure 8 is a flowchart that illustrates an example method.
[0043] Figure 8a is a diagram showing a performance comparison between different methods.
[0044] Figure 9 is a schematic diagram that illustrates a reference signal pattern.
[0045] Figure 10 is a flow chart that illustrates an exemplary method.
[0046] Figure 11 is a schematic diagram that illustrates a reference signal pattern.
[0047] Figure 12 is a schematic diagram that illustrates a reference signal pattern.
[0048] Figure 13 is a flowchart that illustrates an exemplary method.
[0049] Figure 14 is a schematic diagram that illustrates a reference signal pattern.
[0050] Figure 15 is a flowchart that illustrates an exemplary method.
[0051] Figure 16 is a schematic block diagram that illustrates an example radio network node.
[0052] Figure 17 is a schematic block diagram that illustrates exemplary user equipment.
[0053] ABBREVIATIONS
[0054] 3GPP 38Generation Partnership Project
[0055] CDM multiplexing by code division
[0056] DwPTS Downlink Pilot Time Partition
[0057] DM-RS Demodulation reference signals
[0058] FDD duplexing by frequency division
[0059] Frequency division multiplexing FDM
[0060] LTE Long-term evolution
[0061] MIMO Multiple Inputs, Multiple Outputs
[0062] OCC orthogonal coverage code
[0063] OFDM orthogonal frequency division multiplexing
[0064] PRB physical resource block
[0065] TDD duplexing by time division
[0066] DETAILED DESCRIPTION
[0067] It should be noted that although the terminology of 3GPP LTE has been described to exemplify the invention, it should not be seen as limiting the scope of the invention to just the previously mentioned system. Other wireless systems, such as WiMax, can also benefit from exploring the ideas covered within this description.
[0068] In the OCC design, three criteria are commonly applied: Retroactive compatibility, 2D orthogonality property, and peak power randomization. One or more of these criteria will be satisfied by at least some of the following modalities.
[0069] As explained above, an OCC of length 4 can be used to support multiplexing of up to four layers, that is, antenna ports, in each CDM group. If two CDM groups are used, a total of up to eight antenna ports can be supported, that is, four antenna ports in each CDM group. However, using a length 4 OCC will cause each reference signal to spread across four resource elements across two time partitions. This results in increased detection latency, due to the need for the UE to wait for the second time slice before it can start decoding the reference signals.
[0070] In some modalities, the latency can be reduced using a modified OCC mapping pattern, which makes it possible to decode the reference signals based on the information in the first time partition, when applying the orthogonal coverage code in the frequency domain through two or more CDM subgroups, instead of, or in addition to, applying the OCC in the time domain within a single CDM subgroup.
[0071] A method for transmitting a reference signal on a radio network node according to some modalities will now be described with reference to Figure 5 and Figure 6. Figure 5 is a time-frequency grid that illustrates a pattern of OCC mapping, where an OCC of length 4 is constructed through two adjacent CDM subgroups in the frequency domain through OCC mapping. The letters a, b, c and d in the grid correspond to different code elements in a Walsh code, similar to the example described in conjunction with Figure 2 above. The Walsh matrix of length 4 is displayed to the right of the time-frequency grid. Since a code of length 4 is used in this example, four letters are required to denote the different code elements. For example, the second antenna port could use the Walsh code of the second row of the array, [1, -1, 1, -1] to encode its reference signal, and the letters a, b, c, and d correspond to the different code elements in that row, that is, a = 1, b = -1, c = 1, and d = -1. The third antenna port could use the code in the third row, [1, 1, - 1, -1], that is, a = 1, b = 1, c = -1, and d = -1.
[0072] Figure 6 is a flowchart showing the steps of the example method for transmitting a reference signal according to the pattern in Figure 5. The steps of the method will be described from the point of view of a single antenna port. However, it is pointed out that signals from up to four antenna ports can be multiplexed within each CDM subgroup, by applying different orthogonal coverage codes to each reference signal as described above. Thus, it should be understood that up to three additional antenna ports can perform the following steps of the method at the same time; however, each antenna port will be using its own specific reference signal and OCC.
[0073] Thus, according to this modality, a radio network node transmits a reference signal in a CDM group, which comprises three CDM subgroups. Each CDM subgroup is transmitted on a different subcarrier. In Figure 5, the four squares marked a, b, c, and d in the highest row in the grid, that is, the first subcarrier, form a subgroup CDM 510. The corresponding four squares in the sixth row form a second subgroup CDM 520, and the four squares in the twelfth group form a third CDM subgroup. However, it should be understood that any number of CDM subgroups from two, up to the available number of subcarriers, can be used to transmit the reference signal. Each CDM subgroup comprises four elements of appeal. Now with reference to Figure 6, in a first step 610, the radio network node transmits the reference signal through a first subgroup CDM 510 using an orthogonal coverage code. The first CDM 510 subgroup, which is transmitted on the first subcarrier, that is, the top row of the grid in Figure 5, comprises resource elements in a first time partition and a subsequent time partition. As can be seen in Figure 5, the REs marked a and b are comprised in the first time partition, and the REs marked c and d are comprised in the second time partition.
[0074] In particular modalities, the OCC is a Walsh code of length 4. As a specific example, the transmission of the third antenna port is considered. The third antenna port is transmitting a reference signal, which will be denoted Z1, in the first subgroup CDM 510. The code [1, 1, -1, -1] will be used, and the code elements will be applied in order to, b, c, d - that is, 1, 1, -1, -1. Thus, the signal transmitted by the third antenna port in the first CDM 510 subgroup will be [Z1, Z1, -Z1, -Z1].
[0075] Then, the radio network node transmits the reference signal through a second CDM 520 subgroup in step 620. The second CDM 520 subgroup also comprises resource elements in the first time partition and the second time partition. In Figure 5, the second subgroup CDM 520 corresponds to the REs in the sixth subcarrier, that is, the sixth row, which are marked d, c, b, a. The same reference signal is transmitted in the second CDM 520 subgroup as in the first CDM 510 subgroup, that is, using the same specific example above, the third antenna port will transmit the reference signal Z1. However, in the second subgroup CDM 520, the reference signal is transmitted using an orthogonal coverage code permutation. That is, the code elements in the OCC are applied in a different order in the second subgroup CDM 520, compared to the first subgroup CDM 510. The permutation of the orthogonal coverage code is selected in such a way as to allow the decoding of the reference signal in the frequency domain, when applying the orthogonal coverage code only to the resource elements in the CDM group that are included in the first time partition.
[0076] To understand how this is possible, it is considered that in the first subgroup CDM 510, the code elements a and b are applied in the first time partition. In the second subgroup CDM 520, however, code elements d and c are applied in the first time partition, due to OCC permutation. This means that the signal encoded with all four OCC elements - a, b, c, and d - will be received within the first time slice. Thus, the UE receives all the information necessary to decode the RS by combining a and b of the first CDM 510 subgroup with c and c of the second CDM 520 subgroup. Going back to the specific example of the third antenna port, in the second CDM 520 subgroup, the third antenna will transmit a reference signal Z1 using the permutation d, c, b, a, that is, -1, -1, 1, 1. Thus, the signal transmitted in the second subgroup CDM 520 is [-Z1, -Z1, Z1, Z1]. Now, remembering that in the first subgroup CDM 510, the transmitted signal is [Z1, Z1, -Z1, -Z1]. Thus, the last two elements in the first subgroup CDM 510 are equal to the first two elements in the second subgroup CDM 520. Thus, in the first time partition, the UE will receive [Z1, Z1] in the first subgroup CDM 510 and [-Z1 , - Z1] in the second CDM 520 subgroup. When combining the signals from the first and second CDM subgroups in the first time partition, the receiving UE obtains [Z1, Z1, -Z1, -Z1]. This is the same signal that was transmitted in the first CDM 510 subgroup through both time partitions, and therefore the UE is now able to decode the reference signal Z1, even if it has not yet received the second time partition.
[0077] Consequently, the permutation of the OCC in the present example allows decoding by partitioning of reference signals. Otherwise, the code concatenation of an OCC of length 4 can be processed within each partition. This provides the possibility of estimating the partition-by-partition channel. As can be explained above, in this modality, the concatenation of OCC code of length 4 is no longer processed in the time domain, but in the frequency domain through two CDM subgroups, for example, two adjacent CDM subgroups. However, it is still possible to perform code concatenation in the time domain, in addition to the frequency domain, when necessary. In an alternative of this modality, the permutation comprises applying the code elements that were applied to the REs in the second time partition in the first CDM subgroup 510 to the REs in the first time partition in the second CDM 520 subgroup, and vice versa. That is, if elements a and b are applied to the first time partition, eced are applied to the second time partition to the first subgroup CDM 510, then elements a and b will be applied to the second time partition, eced to the first time partition, to the second subgroup CDM 520.
[0078] In another alternative, the permutation comprises applying the code elements in reverse order in the second subgroup CDM 520. That is, if the order a, b, c, d is used in the first subgroup CDM 510, the reverse order d, c, b, a will be used in the second subgroup CDM 520.
[0079] An additional method for transmitting a reference signal on a radio network node according to some modalities will now be described with reference to the pattern shown in Figure 7, and the flow chart of Figure 8. In the OCC mapping illustrated in Figure 7, the same pattern is used for two CDM groups. As in the previous example, Walsh codes of length 4 are used for the allocation of OCC. The pattern of the first CDM group, that is, subcarriers 1, 6, and 11 of the first RB, is the same as in the previous example. However, in this example, a second CDM group is used, comprising subcarriers 2, 7, and 12 of the first RB. Thus, up to eight antenna ports can be supported in this example; four in the first CDM group, and four in the second CDM group. Each antenna port will transmit a reference signal in each CDM subgroup, and the reference signal is broadcast over four REs in the time domain using a Walsh code of length 4. Now with reference to Figure 8, in a first step 810, the radio network node transmits the reference signal through a first CDM 710 subgroup using an orthogonal coverage code. The first CDM 710 subgroup, which is transmitted on the first subcarrier, that is, the top row of the grid in Figure 7, comprises resource elements in a first time partition and a subsequent time partition. As can be seen in Figure 7, the REs marked a and b are transmitted in the first time slot, and the REs marked c and d are transmitted in the second time slot.
[0080] In step 820, the radio network node transmits the reference signal through a second CDM 720 subgroup, which also comprises resource elements in the first time partition and the second time partition. In Figure 7, the second CDM 720 subgroup corresponds to the REs in the sixth subcarrier, that is, the sixth row, which are marked d, c, b, a. The same reference signal is transmitted in the second CDM 720 subgroup as in the first CDM 710 subgroup. However, in the second CDM 720 subgroup, the reference signal is transmitted using an orthogonal coverage code permutation. That is, the code elements in the OCC are applied in a different order in the second CDM 720 subgroup, compared to the first CDM 710 subgroup. The permutation of the orthogonal coverage code is selected in such a way to allow the decoding of the reference signal in the frequency domain, when applying the orthogonal coverage code only to the resource elements in the CDM group that are included in the first time partition.
[0081] The method further comprises transmitting a second reference signal through a second antenna port on a second CDM group. The second CDM group comprises at least two CDM subgroups, with each CDM subgroup being transmitted on a different subcarrier. Each CDM subgroup comprises four elements of appeal. The transmission of the second reference signal comprises an additional step 830, in which the network node transmits the second reference signal through a third subgroup CDM 730, for example, the second subcarrier, using the same orthogonal coverage code that was applied to the first RS in the first CDM 710 subgroup. The third CDM 730 subgroup comprises resource elements in a first time partition and a subsequent time partition.
[0082] The transmission of the second reference signal further comprises a step 840, in which the network node transmits the second reference signal through a fourth subgroup CDM 740, for example, to the 72 carrier, using the same permutation of the coverage code orthogonal that was applied to the first RS in the second CDM 720 subgroup. The fourth CDM 740 subgroup comprises resource elements in the first time partition and the subsequent time partition. In an alternative of this modality, the permutation comprises applying the code elements that were applied to the REs in the second time partition in the first CDM 710 subgroup to the REs in the first time partition in the second CDM 720 subgroup, and vice versa. That is, if the elements a and b are applied in the first time partition, eced are applied in the second time partition in the first CDM subgroup, then the elements a and b will be applied in the second time partition, eced in the first time partition in the second CDM subgroup. 720.
[0083] In another alternative, the permutation comprises applying the code elements in reverse order in the second subgroup CDM 720. That is, if the order a, b, c, d is used in the first subgroup CDM 710, the reverse order d, c, b, a will be used in the second CDM 720 subgroup.
[0084] Alternatively, the first CDM subgroup (710) is repeated the same number of times as the second CDM subgroup (720) in two resource blocks. For example, in the pattern shown in Figure 7, the first CDM subgroup (710) is transmitted three times over two resource blocks, and the second CDM subgroup (720) is also transmitted three times. Thus, peak power randomization is performed on two consecutive PRBs. It is pointed out that this alternative can also be applied to the pattern described in conjunction with Figures 5 and 6 above, where only one CDM group is used.
[0085] In some additional alternatives, the third CDM subgroup (730) is repeated the same number of times as the fourth CDM subgroup (740) in two resource blocks. This further improves peak power randomization, in a manner similar to the alternative described above. As explained above, the same pattern is used in both CDM groups in this example, this provides a low complexity implementation. Other important characteristics of this modality are:
[0086] - Low complexity implementation with simple extension to the existing length 2 OCC mapping. That is, in the case of classification 1-2, when c and d are equal to a and b, respectively, the pattern is the same as in the OCC mapping of length 2 of the prior art. It also indicates that the OCC mapping pattern of length 2 is backwards compatible when only two layers in the CDM 1 group are allocated.
[0087] - Each CDM group can provide 2D orthogonality by PRB to allow processing by partition, as described above.
[0088] - Partial peak power randomization can be performed. In the present example, peak power randomization is performed through two consecutive PRBs.
[0089] - The standard is also applicable to the DM-RS standard of DwPTS.
[0090] The diagram in Figure 8a provides a comparison of performance between the present exemplary method where concatenation is performed in the frequency domain, and the prior art method of concatenation in the time domain. Note that two methods are foreseen to obtain a similar performance at 3km / h, however the speed increases, the frequency domain method is better performed and a significant gain can be obtained. So, two advantages of the frequency domain method can be expected: 1) processing time can be efficiently reduced by allowing for partition-by-partition processing, especially for high-grade transmission, that is, two partitions can be independently processed; 2) performance can be improved by taking into account the Doppler impact between two partitions, that is, by weighting the 2nd partition using the appropriate Doppler factor. In principle, in high-grade transmission, a less selective frequency channel is expected to support this feature. An additional exemplary method for transmitting a reference signal on a radio network node will now be described with reference to the pattern shown in Figure 9, and the flowchart in Figure 10.
[0091] In the OCC mapping shown in Figure 9, a different OCC mapping is used for two CDM groups, with a specific CDM group exchange between the two groups. Here, as in the previous example, Walsh Codes of length 4 are used for the allocation of OCC.
[0092] The steps in the method in Figure 10 correspond essentially to those in Figure 8. However, a difference is that when the third subgroup CDM 930 is transmitted in step 1030, it is done using an offset version of the OCC that was used in the first subgroup 910. For example, the code elements applied in the first CDM subgroup, that is, the first subcarrier, in Figure 9 are a, b, c, d. However, in the third subgroup CDM 930, that is, the second subcarrier, the code elements are applied in an exchanged order, such as c, d, a, b. In addition to the advantages already described together with the modality of Figures 7 and 8, the randomization of additional peak power can be explored by displacing the orthogonal coverage code. Peak power randomization is improved due to alternating code elements in the frequency domain. However, the pattern in Figure 9 is slightly more complex, due to the exchange of code between the CDM groups. A method on a network node, for example, an eNodeB, for transmitting a reference signal according to an additional mode will now be described with reference to Figures 11-13. The OCC mapping pattern in Figures 11 and 12, respectively, has two different mechanisms, both for a normal subframe and a special subframe with DwPTS, when the extended cyclic prefix (CP) is used. Figure 11 shows the same pattern applied for two CDM groups, while Figure 12 shows a different pattern applied for the respective CDM group. Here, Walsh codes of length 2 are used.
[0093] In this example, a first reference signal is transmitted in a first code division multiplexing group, CDM, and a second reference signal is transmitted in a second CDM group. Each CDM group comprises at least two CDM subgroups, and each CDM subgroup comprises two resource elements.
[0094] The steps of the method are shown in the flowchart of Figure 13. In a first step 1310, the network node transmits the first reference signal through a first CDM subgroup using an orthogonal coverage code, and through a second subgroup CDM using an orthogonal coverage code permutation. In an additional step 1320, the network node transmits the second reference signal through a third CDM subgroup using the orthogonal coverage code, and through a fourth CDM 940 subgroup using the permutation of the orthogonal coverage code. The permutation of the orthogonal coverage code is selected in such a way as to allow peak power randomization within a single resource block. In a variant, the permutation comprises reversing the order of the code elements. This is shown in Figure 11, where the code elements a, b in the first CDM 1110 subgroup and the third CDM 1130 subgroup are inverted to become b, a in the second CDM 1120 subgroup and the fourth CDM 1140 subgroup.
[0095] In some modalities, the first CDM subgroup is repeated the same number of times as the second CDM subgroup within a resource block. In some additional embodiments, the third CDM subgroup is repeated the same number of times as the fourth CDM subgroup within a resource block.
[0096] In some variants, like the one shown in Figure 12, the orthogonal coverage code used in the third CDM subgroup is shifted compared to the orthogonal coverage code used in the first CDM subgroup. In other words, the OCC is displaced between the first and second CDM groups. In other variants, the orthogonal coverage code used in the third CDM subgroup is applied in the same order as the orthogonal coverage code used in the first CDM subgroup. That is, the same pattern is used in the two CDM groups.
[0097] In the present example, the orthogonal coverage code is a Walsh code of length 2.
[0098] It should be understood that although the present example is described from the point of view of a single antenna port, reference signals from up to two antenna ports can be multiplexed through the first CDM subgroup and the second CDM subgroup, a different orthogonal coverage code is used for each of the two antenna ports. Also, the reference signals from two additional antenna ports can be multiplexed via the third CDM subgroup and the fourth CDM subgroup, with a different orthogonal coverage code being used for each of the two additional antenna ports.
[0099] An advantage of the present example is that total peak power randomization can be achieved within a PRB. This is due to the fact that the OCC is switched so that the code elements are alternated in the frequency domain. For example, in the pattern shown in Figure 12 (a), in the fifth OFDM symbol there are four occurrences of code element "a", and four occurrences of code element "b". The same applies to the sixth, thirteenth and fourteenth OFDM symbols. This indicates that the transmission power of the antenna port is balanced between different OFDM symbols within a single PRB, thus reducing peak power.
[00100] Some additional features of the present example are: 002. An OCC mapping of length 2 is designed based on an exemplary DM-RS standard, where an OCC of length 2 is used for channel estimation. It is assumed here that only classification 1-4 will be supported in the case of extended CP. Thus, each CDM group supports up to two layers. 003. The present example reuses the same mechanism applied in normal CP to extended CP, this reduces the complexity of implementation. 004. The OCC mapping pattern is the same for even and odd PRBs. 005. 2D time-frequency orthogonality can be explored by PRB per partition.
[001] Figure 14 shows an exemplary DM-RS standard for DwPTS using normal CP. It is pointed out that several modalities described here are also applicable to this standard. In particular, in the grid to the far right of Figure 14, all four REs that carry reference signals in a CDM subgroup are comprised in the first time partition. However, the same principles of permutation of code elements between the first and second CDM subgroups can be used here. For example, if code elements a, b, c, and d are applied to the first CDM subgroup, the swapped code can be, for example, d, a, b, c. Other possibilities are, for example, a, d, b, c or a, b, d, c. Also, the OCC applied to the second CDM group may or may not be exchanged compared to the OCC in the first CDM group. OCC permutations can be selected in such a way as to allow peak power randomization, in a manner similar to the modalities described in conjunction with Figure 11-13 above.
[002] A method on user equipment to decode a reference signal according to some modalities will now be described with reference to the pattern in Figure 7, and the flowchart in Figure 15. The reference signal is received in a CDM group, the CDM group comprising at least two CDM subgroups. Each CDM subgroup is being received on a different subcarrier, and each CDM subgroup comprises resource elements in a first time partition and a subsequent time partition.
[003] In a first time partition, the UE receives a first signal in a first set of resource elements comprised in a first subgroup CDM 710, and a second signal in a second set of resource elements comprised in a second subgroup CDM 720. As a specific example, the first signal is received at
[004] 5 REs marked "a" and "b" in the subgroup CDM 710, and the second signal is received in the REs marked "d" and "c" in the subgroup CDM 720.
[005] The UE decodes the reference signal by applying an orthogonal coverage code to the signals in the first and second sets of resource elements. As can be seen in Figure 7, the first signal corresponds to a reference signal that was encoded using code elements a and b, while the second signal corresponds to the same reference signal, but encoded using code elements c and d. The first and second signals contain enough information to restore the original reference signal. Thus, the UE is also able to decode the RS based on the information received in the first time partition, and does not have to wait for the second time partition to arrive.
[006] In a variant of this modality, the UE decodes a second reference signal that is received in a second CDM group. The second CDM group comprises at least two CDM subgroups, each CDM subgroup being received in a different subcarrier. Each CDM subgroup comprises resource elements in a first time slice and a subsequent time slice. The UE receives, in a first time partition, a third signal in a set of resource elements comprised in a third subgroup CDM 730, and a fourth signal in a set of resource elements comprised in a fourth subgroup CDM 740. Similar to description above, the third and fourth signals contain enough information to restore the original reference signal. The UE decodes the second reference signal by applying an orthogonal coverage code to the third and fourth sets of feature elements.
[007] In some variants, each CDM subgroup comprises four REs, two of which are included in the first time partition.
[008] It is pointed out that signals from up to four antenna ports can be multiplexed within each CDM subgroup, by applying different orthogonal coverage codes to each reference signal as described above. Thus, in an additional modality, the UE decodes three additional reference signals, corresponding to three additional multiplexed antenna ports within the first CDM group, by applying a different orthogonal coverage code for each reference signal to the first and second signals. It should be understood that when multiple reference signals are multiplexed within the same CDM subgroup, the different orthogonal coverage codes must originate from the same set of OCCs, so that all codes are mutually orthogonal. For example, the different codes can be different rows of the Walsh matrix of length 4.
[009] Still in an additional modality, the UE decodes three signals, corresponding to three additional antenna ports multiplexed in the second CDM group, by applying a different orthogonal coverage code for each reference signal to the third and fourth signals.
[0010] Consequently, in this modality, a total of eight reference signals are decoded, four in each CDM group.
[0011] A radio network node, configured to transmit reference signals according to some of the modalities described above, is illustrated in Figure 16. The radio network node 1600 could, for example, be implemented as an eNodeB LTE. Those skilled in the art will recognize that the radio network node 1600 in one or more embodiments includes one or more processing circuits 1610, 1620, such as microprocessors, 1620 transceiver circuits, or other computer / digital processing circuits, which are configured to perform the functions described here to transmit reference signals. Although Figure 16 shows the network node equipped with eight antenna ports, it should be understood that in some embodiments, network node 1600 may have another number of antenna ports, for example, two or four.
[0012] In one example, one or more processing circuits 1610, 1620 are configured to transmit a reference signal through a first CDM subgroup using an orthogonal coverage code, the first CDM subgroup comprising feature elements in a first time partition and a subsequent time partition. In addition, one or more processing circuits 1610, 1620 are configured to transmit the reference signal through a second CDM subgroup using an permutation of the orthogonal coverage code, wherein the second CDM subgroup comprises resource elements in the first time partition and in the second time partition. One or more processing circuits 1610, 1620 are further configured to select the permutation of the orthogonal coverage code in such a way as to allow the decoding of the reference signal in the frequency domain. That is, a receiving UE can decode the signal by applying the orthogonal coverage code only to the resource elements in the CDM group that are included in the first time partition.
[0013] In some variants of this modality, one or more processing circuits 1610, 1620 are configured to transmit a second reference signal through a second antenna port in a second CDM group, the second CDM group comprising at least two CDM subgroups, each CDM subgroup is transmitted on a different subcarrier, each CDM subgroup comprises one or more resource elements. To carry out this transmission of the second reference signal, one or more processing circuits 1610, 1620 are configured to transmit 830 the second reference signal through a third subgroup CDM 730 using the orthogonal coverage code, the third subgroup CDM 730 comprises elements resource in a first time partition and a subsequent time partition. In addition, one or more processing circuits 1610, 1620 are configured to transmit 840 the second reference signal through a fourth subgroup CDM 740 using a second permutation of the orthogonal coverage code, the fourth subgroup CDM 740 comprises resource elements in the first partition and in the subsequent time partition. One or more processing circuits 1610, 1620 are configured to select the second permutation of the orthogonal coverage code in such a way as to allow the decoding of the second reference signal in the frequency domain, when applying the orthogonal code only to the resource elements in the second CDM group that are included in the first time partition.
[0014] In some variants, one or more processing circuits 1610, 1620 are configured for the second reference signal in the third subgroup CDM 730 using an orthogonal coverage code that is exchanged, for example, using a cyclic offset, compared to orthogonal coverage code used in the first CDM 710 subgroup. That is, the OCC is shifted between the first and second CDM groups.
[0015] In other variants, one or more processing circuits 1610, 1620 are configured to apply the orthogonal coverage code used in the third CDM 730 subgroup in the same order as the orthogonal coverage code used in the first CDM 710 subgroup.
[0016] In some variants, the orthogonal coverage code is a Walsh code. In particular variants, the OCC is of length 4, and each CDM subgroup comprises four resource elements.
[0017] In some variants, one or more processing circuits 1610, 1620 are configured to perform the permutation of the orthogonal coverage code when displacing the orthogonal coverage code.
[0018] In some variants, one or more processing circuits 1610, 1620 are configured to perform the permutation of the orthogonal coverage code by applying the code elements that were applied to the resource elements in the first time partition in the first CDM 910 subgroup. resource elements in the second time partition in the second CDM 920 subgroup, and vice versa.
[0019] In other variants, one or more processing circuits 1610, 1620 are configured to perform the permutation of the orthogonal coverage code by reversing the order of the code elements.
[0020] In some variants, one or more processing circuits 1610, 1620 are configured to multiplex the reference signals from four antenna ports via the first CDM 510 subgroup and the second CDM 520 subgroup, and to use an orthogonal coverage code different for each of the four antenna ports.
[0021] In some additional variants, one or more processing circuits 1610, 1620 are configured to multiplex the reference signals from four additional antenna ports through the third and fourth subgroups CDM 730, 740, and to use an orthogonal coverage code different for each of the four additional antenna ports.
[0022] In some variants, one or more processing circuits 1610, 1620 are configured to repeat the first CDM 910 subgroup the same number of times as the second CDM 920 subgroup through two resource blocks.
[0023] In some additional variants, one or more processing circuits 1610, 1620 are configured to repeat the third CDM 730 subgroup the same number of times as the fourth CDM 740 subgroup through two resource blocks.
[0024] In another example, one or more processing circuits 1610, 1620 are configured to transmit a first reference signal through a first CDM subgroup using an orthogonal coverage code, and through a second CDM subgroup using a code permutation orthogonal coverage. One or more processing circuits 1610, 1620 are configured to transmit the second reference signal through a third CDM subgroup using the orthogonal coverage code, and through a fourth CDM subgroup using the permutation of the orthogonal coverage code. One or more processing circuits 1610, 1620 are further configured to select the permutation of the orthogonal coverage code in such a way as to allow peak power randomization within a single resource block.
[0025] In some variants of this example, one or more processing circuits 1610, 1620 are configured to perform the permutation of the orthogonal coverage code by reversing the order of the code elements.
[0026] In some variants, one or more processing circuits 1610, 1620 are configured to repeat the first CDM subgroup the same number of times as the second CDM subgroup within a resource block. In some additional variants, one or more processing circuits 1610, 1620 are configured to repeat the third CDM subgroup the same number of times as the fourth CDM subgroup within a resource block.
[0027] In some variants, one or more processing circuits 1610, 1620 are configured to use an orthogonal coverage code in the third CDM subgroup, which is shifted, for example, using a cyclic offset, compared to the orthogonal coverage code used in the first CDM subgroup. Thus, the OCC is moved between the first and second CDM groups. Figure 17 illustrates a 1700 user device, configured to decode the reference signals according to some of the modalities described above. Those skilled in the art will recognize that the UE 1700 in one or more embodiments includes one or more 1710, 1720 processing circuits, such as microprocessors, 1720 transceiver circuits, or other computer / digital processing circuits, which are configured to perform the tasks. functions described here to decode the reference signals. In one example, the UE 1700 is configured to receive, in a first time partition, a first set of resource elements comprised in a first CDM subgroup. The UE 1700 is additionally configured to receive, in the first time partition, a second set of resource elements comprised in a second CDM subgroup. The UE 1700 is also configured to decode the reference signal by applying an orthogonal coverage code to the first and second sets of feature elements.
[0028] In some variants of this example, one or more processing circuits 1710, 1720 are configured to decode a second reference signal that is received in a second code division multiplexing group, CDM, the CDM group comprising at least minus two CDM subgroups, each CDM subgroup is received on a different subcarrier, each CDM subgroup comprises resource elements in a first time partition and a subsequent time partition. In order to decode the second reference signal, one or more processing circuits 1710, 1720 are configured to receive, in the first time partition, a third set of resource elements comprised in a third CDM subgroup, and a fourth set of elements resource comprised in a fourth CDM subgroup. In addition, one or more processing circuits 1710, 1720 are configured to decode the reference signal by applying an orthogonal coverage code to the third and fourth sets of resource elements.
[0029] In some variants, each CDM subgroup comprises four REs, two of which are included in the first time partition.
[0030] In some variants, one or more processing circuits 1710, 1720 are configured to decode three additional reference signals, sent by three additional antenna ports, by applying a different orthogonal coverage code for each reference signal to the first and second sets of resource elements. It should be understood here that when multiple reference signals are multiplexed within the same CDM subgroup, different orthogonal coverage codes must originate from the same set of OCCs, so that all codes are mutually orthogonal. For example, the different codes may be different rows of the Walsh matrix of length 4. In some additional variants, one or more processing circuits 1710, 1720 are configured to decode three additional reference signals when applying a different orthogonal coverage code to each reference signal to the third and fourth sets of resource elements.
[0031] In the present description, when the word "comprises" or "comprising" is used, it must be interpreted as non-limiting, that is, it means "at least consists of".
[0032] Furthermore, it is pointed out that when this description refers to the application of an OCC to certain resource elements, for example, "the resource elements in the CDM group comprised in the first time partition", it means that the OCC is applied to the signal that is transmitted or received in those resource elements.
[0033] The present invention is not limited to the modalities described above. Various alternatives, modifications and equivalents can be used. Therefore, the above modalities should not be interpreted as limiting the scope of the invention, this is defined by the appended claims. A point that should be highlighted is that although the invention is illustrated using certain specific reference signal standards, the general concepts are also potentially applicable to other DM-RS standards.
[0034] The invention can also be defined by any of the solutions presented below:
[0035] A method in a radio network node to transmit a reference signal through an antenna port, in which the reference signal is transmitted in a code division multiplexing group, CDM, the CDM group being comprises at least two CDM subgroups, each CDM subgroup is transmitted on a different subcarrier, each CDM subgroup comprises resource elements, characterized by the fact that it comprises the steps of:
[0036] - transmitting the reference signal 610 through a first CDM 910 subgroup using an orthogonal coverage code, the first CDM 910 subgroup comprising resource elements in a first time partition and a subsequent time partition,
[0037] - transmitting 620, 720 the reference signal through a second CDM 920 subgroup using an orthogonal coverage code permutation, the second CDM 920 subgroup comprises resource elements in the first time partition and the second time partition;
[0038] in which the permutation of the orthogonal coverage code is selected in such a way as to allow the decoding of the reference signal in the frequency domain, when applying the orthogonal coverage code only to resource elements in the CDM group that are included in the first time partition.
[0039] The method further comprises transmitting a second reference signal through a second antenna port on a second CDM group, the second CDM group comprises at least two CDM subgroups, each CDM subgroup is transmitted on a different subcarrier, each CDM subgroup comprises one or more elements of appeal, which comprises the steps of:
[0040] - transmitting the second reference signal 830 through a third CDM 730 subgroup using the orthogonal coverage code, the third CDM 730 subgroup comprising resource elements in a first time partition and a subsequent time partition,
[0041] - transmitting the second reference signal 840 through a fourth subgroup CDM 740 using a second permutation of the orthogonal coverage code, the fourth subgroup CDM 740 comprises resource elements in the first time partition and in the subsequent time partition;
[0042] in which the second permutation of the orthogonal coverage code is selected in such a way as to allow the decoding of the second reference signal in the frequency domain, when applying the orthogonal code only to resource elements in the second CDM group that are included in the first time partition.
[0043] In the method, the orthogonal coverage code used in the third CDM 730 subgroup is offset compared to the orthogonal coverage code used in the first CDM 710 subgroup.
[0044] In the method, the orthogonal coverage code used in the third CDM 730 subgroup is applied in the same order as the orthogonal coverage code used in the first CDM 710 subgroup.
[0045] In the method, the third subgroup CDM 730 is adjacent to the first subgroup CDM 710, and the fourth subgroup CDM 740 is adjacent to the second subgroup CDM 720. In the method, the orthogonal coverage code is a Walsh code.
[0046] In the method, the permutation of the orthogonal coverage code comprises displacing the orthogonal coverage code.
[0047] In the method, the permutation of the orthogonal coverage code comprises applying the code elements that were applied to the resource elements in the first time partition in the first CDM 910 subgroup to the resource elements in the second time partition in the second CDM 920 subgroup. , and vice versa.
[0048] In the method, the permutation of the orthogonal coverage code comprises reversing the order of the code elements.
[0049] In the method, the orthogonal coverage code has a length of 4, and each CDM subgroup comprises four resource elements.
[0050] In the method, the reference signals from four antenna ports are multiplexed through the first CDM 510 subgroup and the second CDM 520 subgroup, and where a different orthogonal coverage code is used for each of the four antenna ports.
[0051] In the method, the reference signals from one of the four additional antenna ports are multiplexed through the third and fourth subgroups CDM 730, 740, and where a different orthogonal coverage code is used for each of the four additional antenna ports .
[0052] In the method, the first CDM 910 subgroup is repeated the same number of times as the second CDM 920 subgroup in two resource blocks.
[0053] In the method, the third CDM 730 subgroup is repeated the same number of times as the fourth CDM 740 subgroup in two resource blocks.
[0054] A method in a user equipment to decode a reference signal that is received in a code division multiplexing group, CDM, the CDM group comprising at least two CDM subgroups, each CDM subgroup is received in one different subcarrier, each CDM subgroup comprises resource elements in a first time partition and a subsequent time partition, characterized by the fact that the method comprises the steps of:
[0055] - receiving 1510, in a first time partition, a first set of resource elements comprised in a first CDM subgroup, and a second set of resource elements comprised in a second CDM subgroup;
[0056] - decode (1520 the reference signal when applying an orthogonal coverage code to the first and second sets of resource elements.
[0057] The method additionally comprises decoding a second reference signal that is received in a second code division multiplexing group, CDM, the CDM group comprising at least two CDM subgroups, each CDM subgroup is received in a different subcarrier , each CDM subgroup comprises resource elements in a first time partition and a subsequent time partition, where the method comprises the steps of:
[0058] - receiving 1530, in a first time partition, a third set of resource elements comprised in a third CDM subgroup, and a fourth set of resource elements comprised in a fourth CDM subgroup;
[0059] - decode 1540 the reference signal by applying an orthogonal coverage code to the third and fourth sets of resource elements.
[0060] In the method, two resource elements are received in each CDM subgroup in the first time partition.
[0061] The method additionally comprises decoding three additional reference signals by applying a different orthogonal coverage code for each reference signal to the first and second sets of resource elements.
[0062] The method further comprises decoding three additional reference signals by applying a different orthogonal coverage code for each reference signal to the third and fourth sets of resource elements.
[0063] A method on a radio network node for transmitting reference signals, characterized by the fact that a first reference signal is transmitted in a first code division multiplexing group, CDM, and a second reference signal is transmitted in a second CDM group, each CDM group comprises at least two CDM subgroups, each CDM subgroup comprises resource elements, in which the method comprises the steps of:
[0064] - transmit 1310 the first reference signal through a first CDM subgroup using an orthogonal coverage code, and through a second CDM subgroup using an orthogonal coverage code permutation;
[0065] - transmit 1320 the second reference signal through a third CDM subgroup using the orthogonal coverage code, and through a fourth CDM subgroup using the permutation of the orthogonal coverage code;
[0066] in which the permutation of the orthogonal coverage code is selected in such a way as to allow peak power randomization within a single resource block.
[0067] In the method, the permutation comprises reversing the order of the code elements.
[0068] In the method, the first CDM subgroup is repeated the same number of times as the second CDM subgroup within a resource block.
[0069] In the method, the third CDM subgroup is repeated the same number of times as the fourth CDM subgroup within a resource block.
[0070] In the method, the orthogonal coverage code used in the third CDM subgroup is offset compared to the orthogonal coverage code used in the first CDM subgroup.
[0071] In the method, the orthogonal coverage code used in the third CDM subgroup is applied in the same order as the orthogonal coverage code used in the first CDM subgroup.
[0072] In the method, each CDM subgroup comprises two elements of appeal.
[0073] In the method, the orthogonal coverage code is a Walsh code of length 2.
[0074] In the method, the reference signals from two antenna ports are multiplexed through the first CDM subgroup and the second CDM subgroup, and where a different orthogonal coverage code is used for each of the two antenna ports; and where the reference signals from two additional antenna ports are multiplexed through the third CDM subgroup and the fourth CDM subgroup, and where a different orthogonal coverage code is used for each of the two additional antenna ports.
[0075] A radio network node 1600 configured to transmit a reference signal through an antenna port, in which the reference signal is transmitted in a code division multiplexing group, CDM, the CDM group comprising at least two CDM subgroups, each CDM subgroup is transmitted on a different subcarrier, each CDM subgroup comprises resource elements, characterized by the fact that it comprises one or more 1610, 1620 processing circuits configured for:
[0076] - transmit 610 the reference signal through a first subgroup CDM 510 using an orthogonal coverage code, the first subgroup CDM 510 comprises resource elements in a first time partition and a subsequent time partition,
[0077] - transmitting 620 the reference signal through a second CDM 520 subgroup using an orthogonal coverage code permutation, the second CDM 520 subgroup comprising resource elements in the first time partition and the second time partition; wherein one or more processing circuits 1610, 1620 are additionally configured to select the permutation of the orthogonal coverage code in such a way as to allow the decoding of the reference signal in the frequency domain, when applying the orthogonal coverage code only to the elements of resource in the CDM group that are included in the first time partition.
[0078] A 1700 user device configured to decode a reference signal that is received in a code division multiplexing group, CDM, the CDM group comprising at least two CDM subgroups, each CDM subgroup is received in a subcarrier differently, each CDM subgroup comprises resource elements in a first time partition and a subsequent time partition, characterized by the fact that it comprises one or more processing circuits 1710, 1720 configured to:
[0079] - receiving, in a first time partition, a first set of resource elements comprised in a first CDM subgroup, and a second set of resource elements comprised in a second CDM subgroup;
[0080] - decode the reference signal when applying an orthogonal coverage code to the first and second sets of resource elements.
[0081] A radio network node 1600 configured to transmit reference signals, in which a first reference signal is transmitted in a first code division multiplexing group, CDM, and a second reference signal is transmitted in a second CDM group, each CDM group comprises at least two CDM subgroups, each CDM subgroup comprises resource elements, characterized by the fact that it comprises one or more processing circuits 1610, 1620 configured for:
[0082] - transmitting the first reference signal through a first CDM subgroup using an orthogonal coverage code, and through a second CDM subgroup using an orthogonal coverage code permutation;
[0083] - transmit the second reference signal through a third CDM subgroup using the orthogonal coverage code, and through a fourth CDM subgroup using the permutation of the orthogonal coverage code;
[0084] in which one or more processing circuits 1610, 1620 are additionally configured to select the permutation of the orthogonal coverage code in such a way as to allow peak power randomization within a single resource block

权利要求:
Claims (8)
[0001]
1. Method in a radio network node to transmit a reference signal through an antenna port, in which the reference signal is transmitted in a code division multiplexing group, CDM, with the CDM group comprising at least minus two CDM subgroups, each CDM subgroup is transmitted on a different subcarrier, each CDM subgroup comprises resource elements, characterized by the fact that the method comprises the steps of: - transmitting (610) the reference signal via a first CDM subgroup (910) using an orthogonal coverage code, the first subgroup CDM (910) comprising resource elements in a first time partition and a subsequent time partition, and - transmitting (620, 920) the reference signal via a second CDM subgroup (920) using a first permutation of the orthogonal coverage code, the second CDM subgroup (920) comprises resource elements in the first time partition and the second time partition , in which the first permutation of the orthogonal coverage code is selected in such a way as to enable the decoding of the reference signal in the frequency domain, applying the orthogonal coverage code only to resource elements in the CDM group that are included in the first partition of time, and the first CDM subgroup (510, 910) is repeated an equal number of times as the second CDM subgroup (520, 920) in two resource blocks, and the method comprises transmitting a second reference signal via a second antenna port in a second CDM group, the second CDM group consisting of two CDM subgroups, each CDM subgroup being transmitted on a different subcarrier, each CDM subgroup comprises one or more resource elements and the steps of: - transmitting (830) the second reference signal through a third subgroup CDM (930) using a second permutation of the orthogonal coverage code, the third subgroup CDM (930) comprising elements of r resources in a first time partition and a subsequent time partition, e- transmit (840) the second reference signal through a fourth CDM subgroup (940) using the orthogonal coverage code, the fourth CDM subgroup (940) comprises elements of resources in the first time partition and in the subsequent time partition, in which the second permutation of the orthogonal coverage code is selected in order to allow the decoding of the second signal reference in the frequency domain, applying the orthogonal code only to the resource elements in the second CDM group that are included in the first time partition, and where the first permutation comprises a reversal of the order of the code elements of the orthogonal coverage code and the second permutation is the orthogonal coverage code twice cyclically shifted, with a first pair of adjacent code elements of the orthogonal coverage codes exchanged in relative position with a second pair of element adjacent code ones.
[0002]
2. Method according to claim 1, further characterized by the fact that the third CDM subgroup (930) is adjacent to the first CDM subgroup (910) and the fourth CDM subgroup (940) is adjacent to the second CDM subgroup (920) ).
[0003]
Method according to either of claims 2 or 3, characterized in that the permutation of the orthogonal coverage code comprises applying the code elements that were applied to the resource elements in the first time partition in the first CDM subgroup ( 910) to the resource elements in the second time partition in the second CDM subgroup (920), and vice versa.
[0004]
4. Method according to any one of claims 1 to 3, characterized in that the orthogonal coverage code is 4 in length, and each CDM subgroup comprises four feature elements and the reference signals from four antenna ports are multiplexed through the first CDM subgroup (510) and the second CDM subgroup (520), and where a different orthogonal coverage code is used for each of the four antenna ports.
[0005]
Method according to any one of claims 1 to 6, characterized in that the orthogonal coverage code is 4 in length, and each CDM subgroup comprises four feature elements and the reference signals from one of the four additional antenna ports they are multiplexed through the third and fourth CDM subgroups (930, 940), and where a different orthogonal coverage code is used for each of the four additional antenna ports.
[0006]
6. Method in a user equipment to decode a reference signal that is received in a code division multiplexing group, CDM, the CDM group comprising at least two CDM subgroups, each CDM subgroup is received in a different subcarrier , each CDM subgroup comprises resource elements in a first time partition and a subsequent time partition, characterized by the fact that the method comprises the steps of: - receiving (1510), in a first time partition, a first set of resource elements comprised in a first CDM subgroup transmitted using an orthogonal coverage code, and a second set of resource elements comprised in a second CDM subgroup being transmitted using a first permutation of the orthogonal coverage code, where the first CDM subgroup ( 510, 910) is repeated an equal number of times that the second CDM subgroup (520, 920) in two resource blocks, - decode (1520) the re signal reference by applying an orthogonal coverage code to the first and second sets of resource elements. - decode a second reference signal that is received in a second code division multiplexing group, CDM, the CDM group comprising at least two CDM subgroups, each CDM subgroup is received in a different subcarrier, each CDM subgroup comprises elements resource in a first time partition and a subsequent time partition, receiving (1530), in a first time partition, a third set of resource elements comprised in a third CDM subgroup having been transmitted using a second permutation of the code of orthogonal coverage and a fourth set of resource elements comprised in the fourth subgroup CDM having been transmitted using the orthogonal coverage code, and - decode (1540) the reference signal by applying an orthogonal coverage code to the third and fourth sets of elements of resource, in which the first permutation comprises a reversal of the order of the code elements of the ortho coverage code nal and the second permutation is the orthogonal coverage code twice cyclically shifted, with a first pair of adjacent code elements from the orthogonal coverage codes exchanged in relative position with a second pair of adjacent code elements.
[0007]
7. Method on a radio network node (1600) configured to transmit reference signals through an antenna port, in which the reference signal is transmitted in a code division multiplexing group, CDM, the CDM group consists of in two CDM subgroups, each CDM group comprising resource elements, characterized by the fact that the radio network node (1600) comprises one or more processing circuits (1610, 1620) configured to: - transmit (610) the signal reference via a first CDM subgroup (910) using an orthogonal coverage code, the first CDM subgroup (910) comprises resource elements in the first time partition and the subsequent time partition, and - transmitting (620) the reference signal through a second CDM subgroup (920) using the first permutation of the orthogonal coverage code, the CDM subgroup (920) comprises resource elements in the first time partition and the second time and partition, where the one or more processing circuits (1610, 1620) are additionally configured to select the first permutation of the orthogonal coverage code in such a way to decode the reference signal in the frequency domain, applying the orthogonal coverage code only to the resource elements in the CDM group that are comprised in the first time partition and the first CDM subgroup (910), the same number of times the second CDM subgroup (920) is repeated in two resource blocks, and in which the radio network node (1600) is additionally configured to transmit a second reference signal through a second antenna port on a second CDM group, the second CDM group consisting of two CDM subgroups, each CDM subgroup being transmitted on a different subcarrier, each CDM subgroup comprising one or more elements feature, characterized by the fact that one or more processing circuit (1610, 1620) are additionally configured to: - transmit (840) the second reference signal through a fourth CDM subgroup (940) using the orthogonal coverage code, the fourth CDM subgroup (940) comprises resource elements in the first time partition and the subsequent time partition, where the second code permutation orthogonal coverage is selected in order to enable the decoding of the second reference signal in the frequency domain, applying the orthogonal code only to resource elements in the second CDM group that are comprised by the first time partition, and in which the first permutation comprises a reversal of the order of the code elements of the orthogonal coverage code and the second permutation is the orthogonal coverage code twice cyclically displaced, with a first pair of adjacent code elements of the orthogonal coverage codes exchanged in relative position with a second pair of adjacent code elements.
[0008]
8. User equipment (1700) configured to decode a reference signal that is received in a code division multiplexing group, CDM, the CDM group comprising at least two CDM subgroups, each CDM subgroup is received in a subcarrier differently, each CDM subgroup comprises resource elements in the first time partition and the subsequent time partition, characterized by the fact that the user equipment (1700) comprises one or more processing circuits (1710, 1720) configured to: - receive , in a first time partition, a first set of resource elements comprised in a first CDM subgroup being transmitted using an orthogonal coverage code and a second set of resource elements comprised in a second CDM subgroup being transmitted using a first permutation of orthogonal coverage code, in which the first CDM subgroup (910) is repeated an equal number of times, as well as the second subgroup CDM (920), through two resource blocks, - decode the reference signal by applying an orthogonal coverage code to the first and second sets of resource elements.- decode a second reference signal that is received in a second group of resources code division multiplexing, CDM, the second CDM group consists of two CDM subgroups, each CDM subgroup being received on a different subcarrier, each CDM subgroup comprises resource elements in the first time partition and the second time partition, - receiving, in the first time partition, a third set of resource elements comprised in a third CDM subgroup that was transmitted using a second permutation of the orthogonal coverage code and a fourth set of resource elements comprised in a fourth CDM subgroup being transmitted using the code with orthogonal cover, and - decode the reference signal by applying an orthogonal cover code to the third and fourth set of resource elements, where the first permutation comprises a reversal of the order of the code elements of the orthogonal coverage code and the second permutation is the orthogonal coverage code twice shifted cyclically, with a first pair of adjacent code elements of the orthogonal coverage codes exchanged in relative position with a second pair of adjacent code elements.

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法律状态:
2019-01-15| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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