The present disclosure relates to methods of controlling sending of reference signals from a wireless communication device to a radio base station, as well as a wireless communication device and a radio base station performing the methods.
Current and future wireless communications systems such as for instance 5th generation (5G) New Radio (NR) and 4th generation advanced Long Term Evolution (LTE) are expected to provide ubiquitous high data-rate coverage. Achieving this requires an efficient use of available system resources. For example, a higher number of antenna elements on both transmitter and receiver side are considered in future standards of LTE and NR.
With multiple antennas at the transmitter and/or the receiver, it is possible to exploit the spatial degrees of freedom offered by multipath fading inside a communication channel in order to provide a substantial increase in the data rates and reliability of wireless transmission. In the downlink, there are three basic approaches for utilizing the antenna: diversity, multiplexing and beamforming.
In order to control transmission of data using for instance beamforming or multiplexing of the data to each specific user, the transmitter needs information about the channel over which the data is transmitted, so-called channel state information (CSI). Typically, the transmitter being e.g. a radio base station relies on extensive reporting from the receiver being e.g. a smartphone.
One objective is to solve, or at least mitigate, this problem in the art, and to provide an improved method of a radio base station of controlling sending of reference signals from a wireless communication device.
This objective is attained in a first aspect by a method of a radio base station of controlling sending of reference signals from a wireless communication device. The method comprises determining, from an estimated characteristic of a communication channel established via each of a plurality of antennas of the wireless communication device, a measure of similarity in the estimated characteristics for at least two of the communication channels; and if the similarity exceeds a similarity threshold value instructing the wireless communication device to send further reference signals only on one of said at least two communication channels during a time period.
This objective is attained in a second aspect by a radio base station configured to control sending of reference signals from a wireless communication device, the radio base station comprising a processing unit and a memory, said memory containing instructions executable by said processing unit, whereby the radio base station is operative to determine, from an estimated characteristic of a communication channel established via each of a plurality of antennas of the wireless communication device, a measure of similarity in the estimated characteristics for at least two of the communication channels; and if the similarity exceeds a similarity threshold value instruct the wireless communication device to send further reference signals only on one of said at least two communication channels during a time period.
This objective is attained in a third aspect by a method of a radio base station of controlling sending of reference signals from a wireless communication device. The method comprises determining, from an estimated characteristic of a communication channel established via each of a plurality of antennas of the wireless communication device, a measure of channel quality from the estimated characteristics for at least two of the communication channels; and if the channel quality exceeds a channel quality threshold value for only a subset of the at least two of the communication channels instructing the wireless communication device to send further reference signals only on said subset of said at least two communication channels during a time period.
This objective is attained in a fourth aspect a radio base station configured to control sending of reference signals from a wireless communication device, the radio base station comprising a processing unit and a memory, said memory containing instructions executable by said processing unit, whereby the radio base station is operative to determine, from an estimated characteristic of a communication channel established via each of a plurality of antennas of the wireless communication device, a measure of channel quality from the estimated characteristics for at least two of the communication channels; and if the channel quality exceeds a channel quality threshold value for only a subset of the at least two of the communication channels instruct the wireless communication device to send further reference signals only on said subset of said at least two communication channels during a time period.
This objective is attained in a fifth aspect by a method of a wireless communication device of controlling sending of reference signals to a radio base station. The method comprises sending, to the radio base station, data enabling the radio base station to determine a characteristic of a communication channel established via each of a plurality of antennas with which the wireless communication device is equipped and receiving an instruction from the radio base station to send further reference signals more often on at least one of the communication channels as compared to another of the channels during a time period.
This objective is attained in a sixth aspect by a wireless communication device configured to control sending of reference signals to a radio base station, the wireless communication device comprising a processing unit and a memory, said memory containing instructions executable by said processing unit, whereby the wireless communication device is operative to send, to the radio base station, data enabling the radio base station to determine a characteristic of a communication channel established via each of a plurality of antennas with which the wireless communication device is equipped and receive an instruction from the radio base station to send further reference signals more often on at least one of the communication channels as compared to another of the channels during a time period.
Advantageously, by determining characteristics of communication channels established via antennas of a wireless communication device, it is possible for a radio base station to determine a sequence in which reference signals, e.g. so-called Sounding Reference Signals (SRSs), are to be sent by the wireless communication device.
For instance, in an embodiment, the radio base station determines that the characteristics of two channels are similar, in which case it is sufficient for the wireless communication device to send the SRS on only one of the two channels, at least for a time period, and the radio base station will instruct the wireless communication device accordingly.
In another embodiment, the radio base station determines that the quality of one channel is low while the quality of another channel is high, in which case an SRS should be sent over the high-quality channel, but not over the low-quality channel (at least for a time period), and the radio base station will instruct the wireless communication device accordingly.
Further embodiments will be described in the following.
Generally, all terms used in the claims are to be interpreted according to their ordinary meaning in the technical field, unless explicitly defined otherwise herein. All references to “a/an/the element, apparatus, component, means, step, etc.” are to be interpreted openly as referring to at least one instance of the element, apparatus, component, means, step, etc., unless explicitly stated otherwise. The steps of any method disclosed herein do not have to be performed in the exact order disclosed, unless explicitly stated.
Aspects and embodiments are now described, by way of example, with reference to the accompanying drawings, in which:
The aspects of the present disclosure will now be described more fully hereinafter with reference to the accompanying drawings, in which certain embodiments of the invention are shown.
These aspects may, however, be embodied in many different forms and should not be construed as limiting; rather, these embodiments are provided by way of example so that this disclosure will be thorough and complete, and to fully convey the scope of all aspects of invention to those skilled in the art. Like numbers refer to like elements throughout the description.
For a wireless communication device comprising a plurality of antennas, such as e.g. a smart phone or a tablet, the radio base station must be able to estimate a characteristic of a downlink (DL) channel established which each antenna in order to correctly select a DL channel configuration in terms of assign resources to the DL channel, for instance selecting DL signal transmission power, assigned bandwidth, selected antenna beamforming, etc. In the following, the wireless communication device will be referred to as User Equipment (UE).
In order for the RBS to be able to estimate the communication channel characteristics, the UE may be instructed to (periodically or aperiodically) send an uplink (UL) reference signal via each antenna or a subset of the antennas based on which the RBS can estimate the respective channel characteristic upon receiving the reference signal. For instance, from the reference signals, the RBS may estimate signal-to-interference-plus-noise ratio (SINR), attenuation, phase-shift, noise, etc., of the channel.
This reference signal is commonly referred to as a Sounding Reference Signal (SRS), which in the following will be used to embody the reference signal from which the RBS estimates channel characteristics, even though other signals may be envisaged.
Now, some of the downsides of continuously transmitting SRSs to the RBS in the UL is, i.a., that battery power is consumed at the UE, bandwidth is used for the SRSs, and the SRSs may cause interference.
In a straightforward SRS signalling scheme, a round-robin approach may be utilized where first antenna 11 transmits an SRS via channel A, thereafter second antenna 12 transmits an SRS via channel B, followed by third antenna 13 transmitting an SRS via channel C and finally fourth antenna 14 transmits an SRS via channel D. After some time, the process is repeated. The UE 10 may be preconfigured with data determining periodicity for transmitting the SRSs.
Alternatively, an SRS may be transmitted on each antenna 11-14 simultaneously, if the UE 10 is capable of performing such multi-antenna transmission.
Oftentimes UEs are capable of receiving data on multiple antennas simultaneously, but only capable of transmitting data over one or a couple of antennas at a time.
From the SRS received from each UE antenna 11-14, the RBS 15 estimates the channel characteristics for the corresponding channel A, B, C, D.
In another scenario, the UE 10 will not transmit the SRS via all four antennas 11-14 in a round-robin sequence, but occasionally send an SRS via one or more selected antennas. This may occur upon receiving an instruction from the RBS 15 to transmit an SRS over a particular antenna. However, the RBS 15 will only be able to estimate the characteristics of the channel for which an SRS is transmitted.
In a first step S101, the RBS 15 receives an SRS from each antenna 11-14, based on which received SRS the RBS 15 in step S102 estimates characteristics of the communication channel A, B, C, D established via the respective antenna 11-14.
In step S103, the RBS 15 determines a measure of similarity MSIM in the estimated communication channel characteristic of at least two of the plurality of antennas. For instance, the RBS 15 may determine that the characteristics of channel A established via the first antenna 11 is similar to the characteristics of channel B established via the second antenna 12.
For example, it may be envisaged that if two channels have identical channel characteristics, MSIM is 1, while if two channels have no similarities MSIM is 0.
In this exemplifying embodiment, it is assumed that the characteristics of channel A and channel B has a similarity measure of MSIMAB=0.9, and that the similarity in characteristics of channel C via the third antenna 13 and channel D via the fourth antenna 14 also is high, in this MSIMCD=0.88. The RBS 15 further determines that the similarity measure for channels A and C is low.
Further, it is assumed that in case the determined similarity measure MSIM exceeds a predetermined similarity threshold vale TSIM, the characteristics of the corresponding channels are considered sufficiently similar. For instance, TSIM=0.8, wherein two or more channel characteristics are considered sufficiently similar if TSIM>0.8, which is the case for channels A-B and C-D, respectively. In contrast, should MSIMCD=0.7, the RBS 15 would not have considered the characteristics of channels C and D to be sufficiently similar.
From these determined similarity measures, the RBS 15 concludes that the characteristics of channels A-B are similar, as are the characteristics of channels C-D, while there is little similarity between any one of channels A-B compared to any one of channels C-D.
The RBS 15 will apply this conclusion by instructing the UE 10 in step S104 to send an SRS either on channel A-B (but not both), and either on channel C-D (but not both), at least for a given time period.
Thus, if the UE 10 is instructed to send an SRS on channel A (but not on channel B), the RBS 15 will use that SRS to estimate the channel characteristics of channel A as well as channel B, since the RBS 15 estimated in S102 that these characteristics are highly similar, i.e. MSIMAB=0.9.
Similarly, if the UE 10 is instructed to send an SRS on channel C (but not on channel D), the RBS 15 will use that SRS to estimate the channel characteristics of channel C as well as channel D, since the RBS 15 estimated in S102 that these characteristics are highly similar, i.e. MSIMCD=0.88.
Now, with reference to
If the SRS is sent via channel A and channel C with the same periodicity as the prior art round-robin approach, as shown in
As is understood, as shown in
If the determined similarity measure no longer indicates that there is sufficient similarity between the channels as discussed hereinabove, the process will have to be repeated where new similarity measures are determined.
Hence, in line with the embodiment illustrated in
The UE 10 responds in step S105 by sending an SRS on channel A in S105a (SRSA) and on channel C in S105b (SRSC).
Upon receiving the two reference signals SRSA and SRSC in step S105, the RBS determines in step S106 the channel characteristics of channels A and B from SRSA and the channel characteristics of channels C and D from SRSC.
Further, in this example, since the RBS 15 is aware of the channel characteristics of channel A and that there is a great similarity in characteristics between channels A and B, the RBS 15 may select a particular DL configuration for channel A in step S107 and further apply that DL configuration also to channel B.
In other words, not only is a decreased battery consumption attained at the UE 10 since fewer SRSs are sent, but the selection of DL channel configuration is further advantageously simplified at the RBS 15. For instance, the RBS 15 may determine that the experienced SINR at the UE 10 is more or less identical for channels A and B, and the RBS 15 hence will select the same DL transmission power level for channels A and B only by estimating the channel characteristics of channel A.
Further, even in a scenario where SRSs would be sent as often as in the round-robin case of
It may further be envisaged that in certain scenarios, for instance when applying antenna switching, the UE 10 is not allowed to send SRSs via all antennas 11-14 simultaneously, but may only be allowed to transmit two SRSs simultaneously. In such scenario, the above described embodiment is particularly advantageous since only two out of four antennas (first antenna 11 and third antenna 13) are activated for SRS transmission via channels A and C during time period T.
The channel characteristics to be estimated may be embodied in the form of so-called channel state information (CSI) describing how a signal propagates from the UE 10 to the RBS 15 and represents a combined effect of e.g. scattering, fading, power attenuation with distance, etc.
The measure of similarity to be determined for the channel characteristics may be embodied in the form of covariance between one or more particular characteristics, where a high degree of covariance indicates great similarity.
The RBS 15 may send the instructions to the UE 10 to send the SRS in a particular order via e.g. Radio Resource Control (RRC) signalling, and/or Medium Access Control (MAC) Control Element (CE) and/or Downlink Control Information (DCI) element.
In an embodiment, channel quality in terms of e.g. channel gain or attenuation is particularly taken into account. If the RBS 15 concludes in step S102 that the quality of channel A is better than that of channel C in terms of signal strength, the RBS 15 will instruct the UE 10 in step S104 to send the SRS on channel A more often than on channel C (even with the previously mentioned similarity measures MSIMAB and MSIMCD), the rationale being that any data received over channels C and D will be given less weight at the UE 10 as compared to data received over signals A and B due to inferior channel quality.
An SRS signalling sequence as illustrated in
Thus, in a first step S102a, the UE 10 estimates characteristics of the communication channel A, B, C, D established via the respective antenna 11-14 based on signals received via the antennas and sends an indication of the estimated characteristics to the RBS 15 in step S102b.
Similar to the previously described embodiment of
As is understood, the UE 10 may determine the measure of similarity MSIM in the estimated communication channel characteristic and send result to the RBS 15, in which case step S103 is performed at the UE 10 rather than at the RBS 15.
In this exemplifying embodiment, it is assumed that the characteristics of channel A and channel B has a similarity measure of MSIMAB=0.9, and that the similarity in characteristics of channel C via the third antenna 13 and channel D via the fourth antenna 14 also is high, in this MSIMCD=0.88. The RBS 15 further determines that the similarity measure for channels A and C is low.
From these determined similarity measures, the RBS 15 concludes that the characteristics of channels A-B are similar, as are the characteristics of channels C-D, while there is little similarity between any one of channels A-B compared to any one of channels C-D.
The RBS 15 will apply this conclusion by instructing the UE 10 in step S104 to send an SRS either on channel A-B (but not both), and either on channel C-D (but not both), at least for a given time period, as previously described.
In a first step S201, the RBS 15 receives an SRS from each antenna 11-14, based on which received SRS the RBS 15 in step S202 estimates characteristics of the communication channel A, B, C, D established via the respective antenna 11-14.
In step S203, the RBS 15 determines a measure of channel quality M Q from the estimated communication channel characteristic for at least two of the plurality of antennas. For instance, the RBS 15 may determine that the quality of channel A established via the first antenna 11 is high while that of the remaining channels B, C and D established via antennas 12-14 is low in terms of e.g. channel gain, SINR or similar.
For example, it may be envisaged that MQA=0.9 while MQB=0.1, MQC=0.2 and MQD=0.1, where a value of 1 indicates high quality and 0 low quality.
Further, it is assumed that in case the determined channel quality measure MQ exceeds a predetermined channel quality threshold vale TQ, the quality of the channel is considered sufficiently high. For instance, TSIM=0.8, which indicates that only the quality of channel A is currently sufficiently high for an SRS to be sent.
The RBS 15 will thus instruct the UE 10 in step S204 to send an SRS only on channel A, at least for a given time period. For instance, the following SRS sequence may be sent:
If any one of channels B, C and D (for which an SRS is occasionally sent to determine channel quality) indicates a quality exceeding the channel quality threshold vale TQ, an SRS will regularly be sent on that channel as well, for instance channel B:
Advantageously, SRS signals are only sent on channels presenting a sufficiently high quality, such that SRSs are not unnecessarily sent on channels which does not have sufficient quality for the RBS 15 to attain required channel information.
In a first step S202a, the UE 10 estimates characteristics of the communication channel A, B, C, D established via the respective antenna 11-14 based on signals received via the antennas and sends an indication of the estimated characteristics to the RBS 15 in step S202b.
Similar to the previously described embodiment of
As is understood, the UE 10 may determine the measure of similarity MSIM in the estimated communication channel characteristic and send result to the RBS 15, in which case step S203 is performed at the UE 10 rather than at the RBS 15.
The RBS 15 will as previously described thus instruct the UE 10 in step S204 to send an SRS only on channel A, at least for a given time period.
The aspects of the present disclosure have mainly been described above with reference to a few embodiments and examples thereof. However, as is readily appreciated by a person skilled in the art, other embodiments than the ones disclosed above are equally possible within the scope of the invention, as defined by the appended patent claims.
Thus, while various aspects and embodiments have been disclosed herein, other aspects and embodiments will be apparent to those skilled in the art. The various aspects and embodiments disclosed herein are for purposes of illustration and are not intended to be limiting, with the true scope and spirit being indicated by the following claims.
Filing Document | Filing Date | Country | Kind |
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PCT/SE2020/051235 | 12/18/2020 | WO |