JP2012175491A - Receiving device, feedback method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a receiving device capable of reducing the data amount of channel estimation results which are feedback objects.SOLUTION: A receiving device comprises: a receiving portion 11 for receiving a reference signal transmitted from a transmission device 2; a channel estimating portion 12 for obtaining a channel estimation value of a frequency area for each radio communication channel during transmission/reception, by using the reference signal; a producing portion 13 for producing a delay profile including amplitude, a phase, and a delay interval, by performing reverse Fourier transform of the channel estimation value; a measuring portion 14 for measuring the number of paths of the delay profile; a determining portion 15 for determining whether the number of the paths exceeds a threshold value; a feedback portion 17 for transmitting channel estimation results; and a control portion 18 for making the feedback portion 17 transmit the channel estimation value of the frequency area when the number of the paths exceeds the threshold value, and making the feedback portion 17 transmit the delay profile when the number of the paths does not exceed the threshold value.

Description

  The present invention relates to a receiving apparatus that feeds back a channel estimation result using a reference signal.

  Conventionally, wireless communication of a multiple input multiple output (MIMO) system that performs transmission / reception by spatial multiplexing via a plurality of antennas has been performed (for example, Patent Documents 1 and 2). Various methods related to channel estimation in the frequency domain in such MIMO wireless communication are also known (see, for example, Non-Patent Document 1). In such MIMO wireless communication, channel estimation results are fed back to the transmission side.

JP 2003-338777 A JP 2005-328312 A

M.M. K. Ozdemir, H.M. Arslan, “Channel estimation for wireless OFDM systems”, IEEE Communications Surveys & Tutorals, vol. 9, no. 2, p. 18-48, 2007

  In recent years, in mobile radio communication systems, demand for high-speed data transmission such as content download has increased. In order to cope with this, for example, by installing femtocells and picocells with a small distance between the base station and the mobile station, the transmission rate per line is increased by reducing the number of mobile stations accommodated per base station. Has also been done. Furthermore, multi-user MIMO techniques have also been proposed to provide high-speed data transmission to multiple users.

  In the downlink of multi-user MIMO in FDD (Frequency Division Duplex) -OFDM (Orthogonal Frequency Division Multiplexing) scheme, in most cases, it is necessary to perform channel estimation on the receiving station side and feed back the channel estimation result to the transmitting station side . In particular, in order to improve the transmission rate, more accurate channel estimation result feedback is required. On the other hand, the feedback of the channel estimation result consumes radio resources, which is particularly remarkable when a more accurate channel estimation result is fed back. Therefore, in such multi-user MIMO communication and the like, there is a demand for reducing the data capacity to be transmitted when the channel estimation result is fed back to the transmission side. This is because if the amount of data to be fed back can be reduced, more accurate feedback can be performed.

  Generally speaking, in a wireless communication system in which the receiving side feeds back the channel estimation result to the transmitting side, there has been a desire to reduce the amount of data to be fed back.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a receiving apparatus or the like that can reduce the amount of data when a channel estimation result is fed back.

In order to achieve the above object, a receiving device according to the present invention includes a receiving unit that receives a reference signal transmitted from one or more transmitting antennas via the one or more receiving antennas, and a reference signal received by the receiving unit. , A channel estimation unit for acquiring a frequency domain channel estimation value for a channel corresponding to a combination of one or more transmission antennas and one or more reception antennas, and a frequency domain channel estimation value acquired by the channel estimation unit A generation unit that generates a delay profile including the amplitude, phase, and delay interval of each path constituting the channel, a measurement unit that measures the number of paths of the delay profile generated by the generation unit, and a measurement A determination unit that determines whether the number of paths measured by the unit exceeds a threshold, and a channel estimation value or delay profile in the frequency domain. If the number of paths exceeds the threshold value using the feedback unit that transmits the file to the transmission device and the determination result of the determination unit, the channel estimation value in the frequency domain is transmitted to the feedback unit. And a control unit that causes the feedback unit to transmit a delay profile when the threshold value is not exceeded.
With such a configuration, depending on the number of paths in the delay profile, in order to determine whether the feedback target is a frequency domain channel estimation value or a time domain delay profile, the smaller data amount is appropriately selected. You can select and give feedback. Therefore, for example, it may be possible to transmit a delay profile with higher accuracy.

In the receiving apparatus according to the present invention, the generation unit may generate a delay profile excluding a path having an amplitude smaller than a threshold value.
With such a configuration, a delay profile from which noise components are removed can be generated. As a result, the data amount of the delay profile can be reduced. Also, channel estimation performance can be improved.

In addition, the receiving device according to the present invention further includes a Fourier transform unit that Fourier-transforms the delay profile generated by the generation unit, and the feedback unit uses the frequency domain channel estimation value as a frequency estimated by the Fourier transform unit Fourier-transforming the delay profile. The channel estimation value of the area may be transmitted to the transmission device.
With such a configuration, it is possible to remove a noise component from a channel estimation value in the frequency domain.

In the receiving apparatus according to the present invention, the receiving unit may perform equalization processing using a frequency domain channel estimation value obtained by Fourier transforming the delay profile by the Fourier transform unit.
With such a configuration, equalization processing is performed using a channel estimation value in the frequency domain from which noise components are removed, so that equalization processing with higher performance can be realized.

In the receiving apparatus according to the present invention, the transmitting apparatus and the receiving apparatus communicate with each other by MIMO (Multiple Input Multiple Output), and the transmitting apparatus may perform transmission using two or more antennas.
With such a configuration, the amount of feedback data can be reduced even in MIMO communication.

  Further, the feedback method according to the present invention uses a reception step in which a transmission device receives reference signals transmitted from one or more transmission antennas via one or more reception antennas, and a reference signal received in the reception step. A channel estimation step for obtaining a frequency domain channel estimation value for a channel corresponding to a combination of the above transmission antenna and one or more reception antennas, and an inverse Fourier transform on the frequency domain channel estimation value obtained in the channel estimation step. Generating a delay profile including the amplitude, phase and delay interval of each path constituting the channel, a measuring step for measuring the number of paths of the delay profile generated in the generating step, and a path measured in the measuring step. A decision step that determines whether the number exceeds the threshold. If the number of paths exceeds the threshold using the determination result in the determination step, the frequency domain channel estimation value is transmitted to the transmitter, and the number of paths does not exceed the threshold. Includes a feedback step of transmitting the delay profile to the transmission device.

  According to the receiving device or the like according to the present invention, the amount of data to be fed back can be reduced.

The block diagram which shows the structure of the receiver by Embodiment 1 of this invention The block diagram which shows the structure of the receiving part in the embodiment The block diagram which shows the structure of the production | generation part in the embodiment The flowchart which shows operation | movement of the receiver by the same embodiment The figure for demonstrating the delay profile in the embodiment Schematic diagram showing an example of the appearance of the computer system in the embodiment The figure which shows an example of a structure of the computer system in the embodiment

  Hereinafter, a receiving apparatus according to the present invention will be described using embodiments. In the following embodiments, components and steps denoted by the same reference numerals are the same or equivalent, and repetitive description may be omitted.

(Embodiment 1)
A receiving apparatus according to Embodiment 1 of the present invention will be described with reference to the drawings. The receiving apparatus according to the present embodiment feeds back the channel estimation result to the transmitting side.

  FIG. 1 is a block diagram showing a configuration of receiving apparatus 1 according to the present embodiment. The receiving device 1 communicates with the transmitting device 2. In the present embodiment, a case where the receiving apparatus is a mobile station (UE: User Equipment) and the transmitting apparatus 2 is a base station (BS: Base Station) will be mainly described, but this need not be the case. In this embodiment, a case where the receiving apparatus 1 and the transmitting apparatus 2 perform MIMO communication via a plurality of antennas will be described. However, the receiving apparatus 1 and the transmitting apparatus 2 receive channel estimation results other than MIMO. Communication for feedback may be performed. Moreover, although this Embodiment demonstrates the case where the receiver 1 has the two receiving antennas 3 and 4, it may not be so. The receiving device 1 only needs to have one or more receiving antennas. Further, in the present embodiment, a case where there is one receiving apparatus 1 will be described, but two or more receiving apparatuses may exist. In that case, for example, multi-user MIMO communication may be performed. Further, in the present embodiment, the case where communication by OFDM is performed from the transmission device 2 to the reception device 1 will be mainly described, but this need not be the case. Moreover, although this Embodiment demonstrates the case where the transmitter 2 transmits via the two transmission antennas 5 and 6, it may not be so. The transmission device 2 may be any device that performs transmission via one or more transmission antennas, for example. Note that when MIMO communication is performed, the transmission device 2 normally has two or more transmission antennas. As shown in FIG. 1, the receiving apparatus 1 according to the present embodiment includes a receiving unit 11, a channel estimation unit 12, a generation unit 13, a measurement unit 14, a determination unit 15, a Fourier transform unit 16, A feedback unit 17 and a control unit 18 are provided.

  The reception unit 11 receives the reference signals transmitted from the transmission antennas 5 and 6 by the transmission device 2 via the reception antennas 3 and 4. The receiving unit 11 may receive MIMO according to the fed back delay profile. In the present embodiment, as described above, the receiving unit 11 receives an OFDM transmission signal. FIG. 2 is a block diagram showing a detailed configuration of the receiving unit 11. In FIG. 2, the reception unit 11 includes a low noise amplification unit 31, a local oscillation unit 32, a frequency conversion unit 33, an AD conversion unit 34, a Fourier transform unit 35, an equalizer 36, and a demodulation unit 37. And a P / S (parallel / serial) converter 38. In FIG. 2, only one reception processing sequence is shown, but the reception unit 11 may have a reception processing sequence corresponding to the number of antennas included in the reception device 1. In that case, there may be a processing unit that extracts a signal for each antenna with respect to MIMO (for example, in the case of single user MIMO) in the subsequent stage of the P / S conversion unit 38 or the like. It is not necessary (for example, in the case of precoding).

  The low noise amplifier 31 receives the reception signals received by the reception antennas 3 and 4 and amplifies the received reception signals. The local oscillator 32 generates a signal for frequency conversion. The frequency converter 33 uses the signal generated by the local oscillator 32 to frequency-convert the received signal and convert it to an equivalent baseband received signal that can be converted by the AD converter 34. The AD converter 34 converts an analog signal, which is an equivalent baseband reception signal, into a digital signal. This digital signal is a plurality of parallel signals corresponding to a plurality of subcarriers. The Fourier transform unit 35 receives the digital signal after AD conversion, and converts the time domain signal into a frequency domain signal by performing a fast Fourier transform on the plurality of signals in parallel. The equalizer 36 performs an equalization process using the frequency domain channel estimation value obtained by Fourier transforming the delay profile by the Fourier transform unit 16 described later. The demodulator 37 demodulates the signal after the equalization processing. The P / S conversion unit 38 converts the parallel arrangement signal for each subcarrier into a serial arrangement. As a result, the reception unit 11 can obtain the signal itself transmitted by the transmission device 2.

  In addition, the structure of the receiving part 11 is not limited to this, Other structures may be sufficient. For example, a discrete Fourier transform may be used instead of the fast Fourier transform. As described above, the configuration of the receiving unit 11 is arbitrary. Further, the reception unit 11 may perform reception by means other than OFDM. That is, the receiving unit 11 may have a configuration capable of performing reception by means other than OFDM. The receiving unit 11 may be realized by hardware, or a part that can be realized by software may be realized by software such as a driver that drives the receiving device.

  Further, in the receiving device 1, the frequency conversion at the time of transmission and the local oscillation unit used for the frequency conversion at the time of reception may be shared in the transmission configuration and the reception configuration. Further, for example, the frequency generated by the local oscillation unit 32 is 2.4 GHz, the frequency of the reception signal received by the reception antennas 3 and 4 is 2.4 GHz, and the equivalent base after frequency conversion by the frequency conversion unit 33 is performed. The frequency of the received signal in the band may be 0 GHz. Needless to say, these frequencies are merely examples and are not limited to these.

When the receiving unit 11 receives the reference signal transmitted from the plurality of transmission antennas 5 and 6 by the transmission device 2, the channel estimation unit 12 uses the reference signal and each of the plurality of transmission antennas 5 and 6. A channel estimation value in the frequency domain is acquired for each channel according to the combination with each of the plurality of receiving antennas 3 and 4. That is, a channel estimation value in the frequency domain is acquired for each channel. For example, it is assumed that reference signals r ₁ , r ₂ ,... Are transmitted from the transmission antenna 5. The reference signal is transmitted via a predetermined different frequency. For example, in the case of OFDM, reference signals for the subcarriers of the OFDM are transmitted at a frequency corresponding to each subcarrier. Then, it is assumed that the reference signals r ₁ , r ₂ ,... Are received by the receiving unit 11 via the receiving antenna 3. It is assumed that the received signal after the Fourier transform (that is, the output of the Fourier transform unit 35) is y ₁ , y ₂ ,. Incidentally, _{y n} is the signal of the same frequency as _{r n (n = 1,2, ...} ). Moreover, the propagation characteristics in the propagation frequency of the reference signal _{r n} When _{h n,} a _{y n = r n × h n} . Since the reference signal is a known signal determined in advance, the channel estimation unit 12 can know r ₁ , r ₂ ,. Therefore, the channel estimation unit 12 can calculate channel estimation values h ₁ , h ₂ ,... Between the transmission antenna 5 and the reception antenna 3. Note that the reference signals r ₁ , r ₂ ,... May be transmitted as one signal having signals corresponding to a plurality of frequencies. Therefore, the reference signals r ₁ , r ₂ ,... May be a plurality of separate signals or a single signal. Further, a reference signal is transmitted from the transmission device 2 for each of the transmission antennas 5 and 6 of the transmission device 2, and a channel estimation value is calculated for each of the reception antennas 3 and 4 of the reception device 1 using the reference signal. As described above, the channel estimation unit 12 sets a plurality of sets of channel estimation values (that is, channel estimation values in the frequency domain) for all combinations of the transmission antennas 5 and 6 and the reception antennas 3 and 4. ) Is calculated. This set of channel estimation values is also simply referred to as channel estimation value. In the present embodiment, channel estimation unit 12 acquires channel estimation values for combinations of transmission antennas 5 and 6 and reception antennas 3 and 4 (that is, four combinations). That is, the channel estimation unit 12 includes a channel estimation value h ₁₁ between the transmission antenna 5 and the reception antenna 3, a channel estimation value h ₁₂ between the transmission antenna 5 and the reception antenna 4, and the transmission antenna 6 and the reception antenna 3. channel estimation value h ₂₁ between _to obtain a channel estimate h ₂₂ between transmission antenna 6 and the receiving antenna 4. Note that h _{11 and the} like are a set of a plurality of channel estimation values corresponding to a plurality of frequencies as described above. Further, when the number of transmission antennas is A and the number of reception antennas is B, the channel estimation unit 12 acquires A × B channel estimation values. In addition, the reference signal transmitted by the transmission apparatus 2 via the transmission antenna 5 and the reference signal transmitted via the transmission antenna 6 may be transmitted by time division multiplexing, or may be transmitted by code division multiplexing. Alternatively, it may be transmitted by other methods capable of performing channel estimation. Note that the process of acquiring the channel estimation value is already known. For example, refer to Patent Documents 1 and 2 and Non-Patent Document 1 described above.

  The generation unit 13 performs an inverse Fourier transform on the frequency domain channel estimation value acquired by the channel estimation unit 12 to generate a delay profile including the amplitude, phase, and delay interval of each path constituting the channel. This delay profile is a channel estimation result in the time domain. In addition, the generation unit 13 may generate a delay profile excluding a path having an amplitude smaller than the threshold value. In the present embodiment, a case will be described in which the generation unit 13 generates a delay profile excluding a path having an amplitude smaller than the threshold value. The generation unit 13 according to the present embodiment includes an inverse Fourier transform unit 41, a path removal unit 42, and a delay profile generation unit 43, as shown in FIG.

The inverse Fourier transform means 41 performs inverse fast Fourier transform on the frequency domain channel estimation value to convert it into a time domain signal. As described above, the channel estimation value h ₁₁ or the like is a set of a plurality of channel estimation values corresponding to a plurality of frequencies. By performing inverse fast Fourier transform on the channel estimation value, for example, a time-domain waveform as shown in FIG. 5A is obtained. This waveform shows a plurality of paths (a plurality of propagation paths from the antenna on the transmission side to the antenna on the reception side) constituting the channel. The inverse Fourier transform means 41 performs inverse fast Fourier transform for each channel. That is, in the case of the present embodiment, the channel estimation values h ₁₁ , h ₁₂ , h ₂₁ , and h ₂₂ corresponding to the four wireless communication channels between the transmission device 2 and the reception device 1 are reversed. A fast Fourier transform is performed. Note that the inverse Fourier transform means 41 may perform inverse discrete Fourier transform instead of inverse fast Fourier transform.

  The path removing unit 42 removes an amplitude smaller than the threshold value from the time domain signal subjected to the inverse fast Fourier transform by the inverse Fourier transform unit 41. This is because the noise component is removed and the data amount of the delay profile fed back is reduced. For example, when the time-domain signal and the threshold level after the inverse fast Fourier transform are shown in FIG. 5A, the processing by the path removing means 42 is performed as shown in FIG. In addition, a path having a small amplitude is removed. For example, if the path removing unit 42 indicates that the comparator compares the amplitude with a threshold value and the comparison result by the comparator is smaller than the threshold value, the output is set to 0 and the comparison result is the threshold value. If it is not smaller than the value, it is composed of a selector that outputs the signal itself after the inverse fast Fourier transform, and a small path is obtained by sequentially processing these components in the time axis direction. It may be removed. As a result, any method can be used as long as a small path can be removed. Further, the threshold value itself may or may not be included in the amplitude smaller than the threshold value. The threshold value is preferably set to an appropriate value that can appropriately remove the noise component and does not deteriorate the channel estimation result.

Further, the delay profile generation unit 43 generates a delay profile using the result of the inverse fast Fourier transform from which a small path is removed. That is, the delay interval, the amplitude, and the phase of each path constituting the channel are acquired from the waveform after the inverse fast Fourier transform from which the small path is removed, and a delay profile including them is generated. The generated delay profile may be stored in a recording medium (not shown). The delay interval is a time interval between paths (peaks) in the waveform after inverse fast Fourier transform. For example, as shown in FIG. 5B, when there are a plurality of paths (peaks), a plurality of delay intervals indicating the time intervals between the paths are acquired. The delay interval may be other information as long as the time interval between the paths can be known as a result. For example, it may be a time interval between a certain reference time point and each path. The reference time point may be, for example, the time point of the first pass, or may be the time point used for another synchronization or the like. The amplitude is the real number amplitude of the path in the waveform after inverse fast Fourier transform, and the phase is the phase of the path. Here, in the present embodiment, “amplitude” is assumed to be a real amplitude unless otherwise specified as a complex amplitude. Therefore, it can be said that the delay profile includes a delay interval and a complex amplitude. Note that the delay profile generation means 43 has the delay profile DP ₁₁ , from which the small path is removed in each result of the inverse fast Fourier transform of the frequency domain channel estimation values h ₁₁ , h ₁₂ , h ₂₁ , h ₂₂ . DP ₁₂ , DP ₂₁ , and DP ₂₂ are generated. Here, the delay profile corresponding to the frequency domain channel estimation value h _ij is DP _ij . Thus, one delay profile is usually generated from the frequency domain channel estimation value corresponding to one channel.

  Here, as a result, if a delay profile excluding a path having an amplitude smaller than the threshold value can be finally generated, generation of the delay profile and removal of a path having an amplitude smaller than the threshold value are performed. The order of processing is not limited. For example, the delay profile generation unit 43 generates a delay profile from the result after the inverse fast Fourier transform, and for the delay profile, the path removal unit 42 specifies an amplitude smaller than the threshold, and the amplitude and the amplitude If the delay interval needs to be corrected according to the deletion of the amplitude in accordance with the deletion of the amplitude (for example, when the delay interval indicates a time interval between paths), the delay The interval may be corrected (for example, the process of adding the delay intervals on both sides of the removed path is performed for all the removed paths).

The measurement unit 14 measures the number of paths of the delay profile generated by the generation unit 13. Since the number of paths is the same as the number of amplitudes in the delay profile, the measurement unit 14 may measure the number of paths by counting the number of amplitudes in the delay profile. The number of paths is measured for each delay profile. That is, the path numbers PN ₁₁ , PN ₁₂ , PN ₂₁ , and PN ₂₂ are acquired for each of the delay profiles DP ₁₁ , DP ₁₂ , DP ₂₁ , and DP ₂₂ . Note that the number of paths corresponding to the delay profile DP _ij is PN _ij .

The determination unit 15 determines whether the number of paths measured by the measurement unit 14 exceeds a threshold value. This determination is made for the number of paths in each delay profile. That is, it is determined whether the threshold value PT is exceeded for each of the path numbers PN ₁₁ , PN ₁₂ , PN ₂₁ , and PN ₂₂ . When the number of passes is the same as the threshold value PT, it may be determined that the threshold value PT has been exceeded or not. As will be described later, when the number of paths PN _ij exceeds this threshold value PT, the frequency domain channel estimation value h _ij (or, as will be described later, the delay profile DP _ij is Fourier-transformed). When the frequency domain channel estimation value) is fed back and the number of paths does not exceed the threshold value PT, the delay profile DP _ij is fed back. In either case, it is preferable that the data amount of the channel estimation result as a feedback target is smaller than the data amount of the channel estimation result that is not fed back. Therefore, it is preferable to set an appropriate threshold value PT so as to obtain such a result.

The Fourier transform unit 16 performs fast Fourier transform on the delay profile generated by the generation unit 13. As a result, it is possible to obtain a frequency domain channel estimation value from which noise components have been removed. Note that the Fourier transform unit 16 performs fast Fourier transform on each of the delay profiles DP ₁₁ , DP ₁₂ , DP ₂₁ , DP _22, and channel estimation values h ₁₁ ^NR , h ₁₂ ^NR , h ₂₁ ^NR , h ₂₂ ^{NR in the} frequency domain. To get. Note that the frequency domain channel estimation value h ₁₁ ^NR and the like may be a set of values corresponding to each frequency of the reference signal, like the frequency domain channel estimation value h ₁₁ and the like. Here, a channel estimation value in the frequency domain after the fast Fourier transform corresponding to the delay profile DP _ij is h _ij ^NR . Further, the channel estimation value h _ij ^NR in the frequency domain is used in the equalization process in the equalizer 36 of the reception unit 11. The equalizer 36 can also use the channel estimation result obtained by the channel estimation unit 12 for equalization processing, but noise is removed from the channel estimation result after the Fourier transform, and therefore the channel estimation result after the Fourier transform is used as the channel estimation result. It is possible to perform a more appropriate equalization process when used. The Fourier transform unit 16 may perform fast Fourier transform on the signal from which the path has been removed by the path removing unit 42. Further, the Fourier transform unit 16 may perform a discrete Fourier transform instead of the fast Fourier transform.

  The feedback unit 17 feeds back the channel estimation result by transmitting the channel domain estimation value in the frequency domain after the Fourier transform by the Fourier transform unit 16 or the delay profile generated by the generation unit 13 to the transmission device 2. Note that the feedback unit 17 feeds back the channel estimation result determined by the control unit 18 described later. The transmission by the feedback unit 17 may be performed by OFDM, for example, or may be performed by other methods. Note that the transmission by the feedback unit 17 is the same as the conventional example except that the transmission target may be a delay profile from the channel estimation value, and detailed description thereof will be omitted. The feedback unit 17 may be realized by hardware, or may be realized by software such as a driver that drives the transmission device.

When the number of paths exceeds the threshold value, the control unit 18 uses the determination result of the determination unit 15 to transmit the channel estimation value in the frequency domain to the feedback unit 17, and the number of paths is set to the threshold value. If not, the delay profile is transmitted to the feedback unit 17. The control unit 18 may make this determination for each channel. That is, for each channel, the control unit 18 determines which of the delay profile DP _ij and the channel estimation value h _ij ^NR is to be fed back, and feedback according to the determination may be performed by the feedback unit 17. . Note that which feedback is performed depends on the number of delay paths, and it is considered that the number of delay paths does not vary greatly for each channel. Therefore, the measurement unit 14 and the determination unit 15 measure and determine the number of paths for one representative channel, and the control unit 18 performs control regarding feedback targets for all channels according to the determination result. You may make it perform. For example, when the number of paths of the delay profile DP ₁₁ exceeds the threshold value PT, the control unit 18 sends the frequency domain channel estimation values h ₁₁ ^NR , h ₁₂ ^NR , h ₂₁ ^NR , h to the feedback unit 17. _{If 22} ^NR is transmitted and the number of paths of the delay profile DP ₁₁ does not exceed the threshold value PT, the feedback unit 17 may transmit the delay profiles DP ₁₁ , DP ₁₂ , DP ₂₁ , DP ₂₂ .

Next, the operation of the receiving apparatus 1 will be described using the flowchart of FIG.
(Step S101) The receiving unit 11 determines whether a reference signal (RS) has been received. If a reference signal is received, the process proceeds to step S102, and if not, the process proceeds to step S109.

  (Step S102) The channel estimation unit 12 acquires a channel estimation value in the frequency domain corresponding to the reference signal. That is, the channel estimator 12 is configured such that, for example, a channel estimation value corresponding to a plurality of frequencies between the transmission antenna 5 and the reception antennas 3 and 4, and a plurality of transmission antennas 6 and The channel estimation value corresponding to the frequency of is acquired. The obtained frequency domain channel estimation value may be stored in a recording medium (not shown). Note that when two or more reference signals are transmitted, for example, the processes of step S101 and step S102 may be repeated by the number of the reference signals.

  (Step S103) The inverse Fourier transform means 41 of the generation unit 13 performs inverse Fourier transform on the channel estimation value in the frequency domain. Then, the path removing unit 42 of the generating unit 13 removes a path whose amplitude is smaller than the threshold value in the result of the inverse Fourier transform. Thereafter, the delay profile generation unit 43 of the generation unit 13 generates a delay profile from the signal after the inverse Fourier transform from which the path whose amplitude is smaller than the threshold is removed. The delay profile may be stored on a recording medium (not shown).

  (Step S <b> 104) The Fourier transform unit 16 performs a Fourier transform on the delay profile in the time domain and returns it to the channel estimation value in the frequency domain. The channel estimation value after the Fourier transform may be stored in a recording medium (not shown). The channel estimation value is also used for equalization processing in the equalizer 36 as described above.

  (Step S105) The measuring unit 14 measures the number of paths of the delay profile generated by the generating unit 13.

  (Step S106) The determination unit 15 determines whether the number of paths measured by the measurement unit 14 exceeds the threshold value PT. If the number of paths exceeds the threshold value PT, the process proceeds to step S107, and if not, the process proceeds to step S108.

  (Step S <b> 107) The control unit 18 controls the feedback unit 17 to transmit the frequency domain channel estimation value after the Fourier transform by the Fourier transform unit 16. As a result, the channel estimation value in the frequency domain is transmitted to the transmission device 2 by the feedback unit 17. Then, the process returns to step S101.

  (Step S108) The control unit 18 performs control so that the feedback unit 17 transmits the delay profile. As a result, the delay profile is transmitted to the transmission device 2 by the feedback unit 17. Then, the process returns to step S101.

  In steps S105 to S108, these processes may be performed for each channel, or the processes in steps S105 and S106 are performed for the representative channel, and the process is performed for all channels according to the result. The process of S107 or S108 may be performed.

  (Step S109) The receiving unit 11 determines whether a MIMO transmission signal is received. If a MIMO transmission signal is received, the process proceeds to step S110. If not, the process returns to step S101.

  (Step S110) Processing according to the received transmission signal is performed by the receiving unit 11 or other components. Then, the process returns to step S101.

  It should be noted that as a channel estimation result, which of the frequency domain channel estimation value and the delay profile is fed back does not change so frequently. Therefore, the measurement of the number of paths by the measurement unit 14 and the determination by the determination unit 15 may not be performed every time the reference signal is received. For example, the measurement and determination of the number of paths are repeatedly performed with a constant or indefinite period longer than the period of channel estimation, and the control unit 18 determines according to the latest determination result until a new determination is made. You may make it perform control regarding a feedback object. In the flowchart of FIG. 4, the process is terminated by power-off or a process termination interrupt.

Next, the operation of receiving apparatus 1 according to the present embodiment will be described using a specific example.
First, it is assumed that the transmission apparatus 2 transmits the reference signal, and the reference signal is transmitted via the transmission antennas 5 and 6. Then, the reference signal is received by the receiving unit 11 via the receiving antennas 3 and 4 (step S101). Then, the channel estimation unit 12, by obtaining the output of the Fourier transform unit 35 of the receiving unit 11, obtains a channel estimation value _{h 11, h 12, h 21} , h 22 in the frequency domain for each channel, generating unit 13 To the inverse Fourier transform means 41 (step S102). The inverse Fourier transform unit 41 performs inverse fast Fourier transform on the respective channel estimation values h ₁₁ , h ₁₂ , h ₂₁ , and h ₂₂ and passes the results to the path removal unit 42. The path removing unit 42 removes a path having a small amplitude for each result of the inverse fast Fourier transform of each of the channel estimation values h ₁₁ , h ₁₂ , h ₂₁ , and h ₂₂ , and the Fourier transform unit 16 and the delay profile generating unit 43. The delay profile generation means 43 generates delay profiles DP ₁₁ , DP ₁₂ , DP ₂₁ , DP ₂₂ including the amplitude, delay interval, and phase for each result of the inverse fast Fourier transform from which a path having a small amplitude is removed, and a measurement unit 14 and the feedback unit 17 (step S103). These delay profiles are as follows. Note that t1 is a subscript corresponding to the reception of the reference signal. Also, the amplitudes A ₁₁ ^t1 1, A ₁₁ ^t1 2, A ₁₁ ^t1 3, A ₁₁ ^t1 4, etc. are amplitudes corresponding to four paths in the order of time. The delay intervals DI ₁₁ ^t1 1, DI ₁₁ ^t1 2, DI ₁₁ ^t1 3, and the like correspond to three time intervals (see FIG. 5B) between the four paths. The phases P ₁₁ ^t1 1, P ₁₁ ^t1 2, P ₁₁ ^t1 3, P ₁₁ ^t1 4, etc. are phases corresponding to four paths in order of time.
[Delay Profile DP ₁₁ ]
Amplitude: A ₁₁ ^t1 1, A ₁₁ ^t1 2, A ₁₁ ^t1 3, A ₁₁ ^t1 4
Delay interval: DI ₁₁ ^t1 1, DI ₁₁ ^t1 2, DI ₁₁ ^t1 3
Phase: P ₁₁ ^t1 1, P ₁₁ ^t1 2, P ₁₁ ^t1 3, P ₁₁ ^t1 4
[Delay Profile DP ₁₂ ]
Amplitude: A ₁₂ ^t1 1, A ₁₂ ^t1 2, A ₁₂ ^t1 3, A ₁₂ ^t1 4
Delay interval: DI ₁₂ ^t1 1, DI ₁₂ ^t1 2, DI ₁₂ ^t1 3
Phase: P ₁₂ ^t1 1, P ₁₂ ^t1 2, P ₁₂ ^t1 3, P ₁₂ ^t1 4
[Delay Profile DP ₂₁ ]
Amplitude: A ₂₁ ^t1 1, A ₂₁ ^t1 2, A ₂₁ ^t1 3, A ₂₁ ^t1 4
Delay interval: DI ₂₁ ^t1 1, DI ₂₁ ^t1 2, DI ₂₁ ^t1 3
Phase: P ₂₁ ^t1 1, P ₂₁ ^t1 2, P ₂₁ ^t1 3, P ₂₁ ^t1 4
[Delay Profile DP ₂₂ ]
Amplitude: A ₂₂ ^t1 1, A ₂₂ ^t1 2, A ₂₂ ^t1 3, A ₂₂ ^t1 4
Delay interval: DI ₂₂ ^t1 1, DI ₂₂ ^t1 2, DI ₂₂ ^t1 3
Phase: P ₂₂ ^t1 1, P ₂₂ ^t1 2, P ₂₂ ^t1 3, P ₂₂ ^t1 4

Further, the Fourier transform unit 16 performs fast Fourier transform on the result of the inverse fast Fourier transform, which is received from the path removal unit 42 of the generation unit 13 and from which the path having a small amplitude has been removed, so that the channel estimation value h ₁₁ ^NR in the frequency domain is obtained. , H ₁₂ ^NR , h ₂₁ ^NR , and h ₂₂ ^NR are acquired and passed to the equalizer 36 of the receiving unit 11 and the feedback unit 17 (step S104). The channel estimation value in the frequency domain is used for equalization processing and can be a target of feedback.

Further, the measurement unit 14 measures the number of paths according to the delay profiles (step S105). Assume that the number of paths is as follows.
Delay path number PN ₁₁ ^t1 = 4
Delay path number PN ₁₂ ^t1 = 4
Delay path number PN ₂₁ ^t1 = 4
Delay path number PN ₂₂ ^t1 = 4

In this specific example, if the threshold value PT is “5”, the determination unit 15 determines that the number of all paths does not exceed the threshold value, and passes the determination result to the control unit 18 (step S1). S106). Therefore, the control unit 18 controls the feedback unit 17 to transmit the delay profiles DP ₁₁ , DP ₁₂ , DP ₂₁ , DP ₂₂ for all channels. As a result, those delay profiles are transmitted to the transmission device 2 by the feedback unit 17 (step S108). The channel estimation result may be used for, for example, precoding.

  Needless to say, during the reception of the reference signal, the transmission signal may be received and processing corresponding to the reception may be performed (steps S109 and S110).

When the number of paths exceeds the threshold, as described above, the control unit 18 controls the feedback unit 17 to transmit the frequency domain channel estimation value, and the frequency domain channel estimation is performed. The values h ₁₁ ^NR , h ₁₂ ^NR , h ₂₁ ^NR , and h ₂₂ ^NR are transmitted to the transmission device 2 (step S107).

  As described above, according to the receiving apparatus 1 according to the present embodiment, whether the feedback target is the frequency domain channel estimation value or the time domain delay profile according to the number of paths in the delay profile. In order to decide, it is possible to appropriately select and feed back the data having the smaller amount. Therefore, as a result, the accuracy of the channel estimation result to be fed back can be improved while reducing the amount of data to be fed back, and for example, communication with a higher transmission speed can be realized.

  Also, for communications such as femtocells and picocells where the transmission distance is relatively short, the line of sight, and a small number of scattered waves arrive with a small delay time, the time obtained by inverse Fourier transform of the channel estimation value in the frequency domain The amount of data to be fed back can be reduced by feeding back the delay profile in the region. On the other hand, in communication outdoors or over long distances, the amount of delay profile data increases as the number of delay paths increases, so it is better to feed back the frequency domain channel estimate as a channel estimation result. The amount of target data can be reduced. Therefore, as in the present embodiment, it is possible to reduce the consumption of radio resources in feedback by appropriately switching and transmitting feedback targets. As a result, for example, more accurate channel estimation results can be fed back. As described above, the receiving device 1 and the like according to the present embodiment have conditions such as indoor wireless communication, short-range wireless communication, line-of-sight wireless communication, and the like, such as wireless communication with femtocells and picocells. It can be used for both good wireless communication and wireless communication with poor conditions, such as outdoor wireless communication, long-distance wireless communication, and wireless communication that is not visible.

  Further, in the present embodiment, noise components in the delay profile can be removed by removing the delay path having a small amplitude by the path removing unit 42, and as a result, the channel estimation performance in the time domain is improved. Can be done. Further, according to the removal, the data amount of the delay profile to be fed back can be reduced. In addition, the frequency domain channel estimation value obtained by performing Fourier transform on the delay profile from which the delay path having a small amplitude is removed is used for equalization processing and feedback, thereby improving the performance of the frequency domain channel estimation. It can be done. As a result, for example, the receiving apparatus 1 can more appropriately demodulate the signal.

  In the present embodiment, a case has been described in which the equalizer 36 of the reception unit 11 performs the equalization process using the frequency domain channel estimation value after the Fourier transform by the Fourier transform unit 16, but this is not the case. May be. The equalizer 36 of the reception unit 11 may perform equalization processing using the frequency domain channel estimation value acquired by the channel estimation unit 12.

  In the present embodiment, the feedback unit 17 transmits the frequency domain channel estimation value after the Fourier transform by the Fourier transform unit 16 when transmitting the frequency domain channel estimation value. Not necessarily. The feedback unit 17 may transmit the frequency domain channel estimation value acquired by the channel estimation unit 12 when transmitting the frequency domain channel estimation value.

  In this embodiment, when a channel estimation value in the frequency domain is fed back, the data amount of the channel estimation value in the frequency domain may be reduced and fed back. For example, the data amount may be reduced by compressing the data, or the amount of data may be reduced by reducing the number of samples of the frequency domain channel estimate. Good. Here, the latter case will be explained a little. For example, in the case of OFDM, the number of samples corresponding to the number of subcarriers exists in the frequency domain channel estimation value. Therefore, when reducing the number of samples, for example, channel estimation values corresponding to one or more subcarrier frequencies may simply be deleted, or channel estimation values corresponding to two or more subcarrier frequencies may be interpolated. To resample the channel estimate corresponding to the new frequency, delete the channel estimate corresponding to the frequency of one or more subcarriers, and change the channel estimate corresponding to the resampled new frequency. You may make it add. Note that the number of deleted samples is preferably larger than the number of added samples. As such a reduction in the amount of data, for example, by replacing the samples of two subcarriers adjacent in frequency with the average value of the two samples corresponding to the intermediate frequency of the two samples, The frequency domain channel estimate may be reconstructed. By this processing, the number of samples is reduced by half, and the data amount is halved. This process may be performed by, for example, the generation unit 13, the Fourier transform unit 16, the feedback unit 17, or the like, or may be performed by other components. Note that the compression of the data amount may be performed on a delay profile in the time domain.

Further, in the present embodiment, the case where the generation unit 13 removes a delay path with a small amplitude by the path removal unit 42 has been described, but this need not be the case. The generation unit 13 may generate a delay profile without removing a path with a small amplitude.
In addition, since MIMO is normally performed by OFDM, a case where communication by OFDM is mainly described, but it is needless to say that communication by MIMO other than OFDM may be performed.

  Further, in the present embodiment, the case of mainly performing single user MIMO communication has been described, but as described above, in feedback of multiuser MIMO communication, feedback target switching may be performed so as to reduce the amount of data. . Needless to say, in a system that requires transmission of channel estimation results other than MIMO communication, the channel estimation results to be fed back may be switched as in the present embodiment. Further, as described above, the receiving device 1 may receive data using one receiving antenna, or may receive data using three or more receiving antennas. That is, the receiving unit 11 may receive the reference signal transmitted from the one or more transmission antennas by the transmission device 2 via the one or more reception antennas. And the channel estimation part 12 acquires the channel estimation value of a frequency domain about the channel according to the combination of 1 or more transmission antennas and 1 or more reception antennas using the reference signal which the receiving part 11 received. It may be.

  In the above embodiment, each process or each function may be realized by centralized processing by a single device or a single system, or may be distributedly processed by a plurality of devices or a plurality of systems. It may be realized by doing.

  In the above embodiment, the information exchange between the components is performed by one component when, for example, the two components that exchange the information are physically different from each other. It may be performed by outputting information and receiving information by the other component, or when two components that exchange information are physically the same, one component May be performed by moving from the phase of the process corresponding to to the phase of the process corresponding to the other component.

  In the above embodiment, information related to processing executed by each component, for example, information received, acquired, selected, generated, transmitted, or received by each component In addition, information such as threshold values, mathematical formulas, addresses, etc. used by each component in processing is retained temporarily or over a long period of time on a recording medium (not shown) even when not explicitly stated in the above description. It may be. Further, the storage of information in the recording medium (not shown) may be performed by each component or a storage unit (not shown). Further, reading of information from the recording medium (not shown) may be performed by each component or a reading unit (not shown).

  In the above embodiment, when information used by each component, for example, information such as a threshold value, an address, and various setting values used by each component may be changed by the user Even if it is not specified in the above description, the user may be able to change the information as appropriate, or it may not be. If the information can be changed by the user, the change is realized by, for example, a not-shown receiving unit that receives a change instruction from the user and a changing unit (not shown) that changes the information in accordance with the change instruction. May be. The change instruction received by the receiving unit (not shown) may be received from an input device, information received via a communication line, or information read from a predetermined recording medium, for example. .

  Moreover, in the said embodiment, when two or more components contained in the receiver 1 have a communication device, an input device, etc., two or more components may have a physically single device. Alternatively, it may have a separate device.

  In the above embodiment, each component may be configured by dedicated hardware, or a component that can be realized by software may be realized by executing a program. For example, each component can be realized by a program execution unit such as a CPU reading and executing a software program recorded on a recording medium such as a hard disk or a semiconductor memory. In addition, the software which implement | achieves the receiver 1 in the said embodiment is the following programs. In other words, this program uses a reference signal received by a receiving unit that receives a reference signal transmitted from a transmission device by one or more transmission antennas via the one or more reception antennas. And a channel estimation unit for acquiring a frequency domain channel estimation value for a channel corresponding to a combination of one or more receiving antennas, and a channel is configured by performing an inverse Fourier transform on the frequency domain channel estimation value acquired by the channel estimation unit. A generation unit that generates a delay profile including the amplitude, phase, and delay interval of each path to be measured, a measurement unit that measures the number of paths in the delay profile generated by the generation unit, and the number of paths measured by the measurement unit exceeds a threshold value If the number of passes exceeds the threshold using the judgment part The channel estimate of the number area is transmitted to the transmission device, when the number of paths does not exceed the threshold value is a program for functioning as a control unit for transmitting a delay profile to the transmitter.

  In the program, the functions realized by the program do not include functions that can be realized only by hardware. That is, functions that can be realized only by hardware are not included at least in the functions realized by the program.

  Further, this program may be executed by being downloaded from a server or the like, and a program recorded on a predetermined recording medium (for example, an optical disk such as a CD-ROM, a magnetic disk, a semiconductor memory, or the like) is read out. May be executed by Further, this program may be used as a program constituting a program product.

  Further, the computer that executes this program may be singular or plural. That is, centralized processing may be performed, or distributed processing may be performed.

  FIG. 6 is a schematic diagram illustrating an example of an external appearance of a computer that executes the program and realizes the receiving device 1 according to the embodiment. The above-described embodiment can be realized by computer hardware and a computer program executed on the computer hardware.

  In FIG. 6, a computer system 900 includes a computer 901 including a CD-ROM (Compact Disk Read Only Memory) drive 905, an FD (Floppy (registered trademark) Disk) drive 906, a keyboard 902, a mouse 903, a monitor 904, and the like. Is provided.

  FIG. 7 is a diagram showing an internal configuration of the computer system 900. In FIG. 7, in addition to the CD-ROM drive 905 and the FD drive 906, a computer 901 is connected to an MPU (Micro Processing Unit) 911, a ROM 912 for storing a program such as a bootup program, and the MPU 911. A RAM (Random Access Memory) 913 that temporarily stores program instructions and provides a temporary storage space, a hard disk 914 that stores application programs, system programs, and data, and an MPU 911 and a ROM 912 are interconnected. And a bus 915. Note that the computer 901 may include hardware for performing the above-described transmission and reception processing, for example, a DA converter, an AD converter, a modulator, a demodulator, or the like. It may be connected. The computer 901 may include a network card (not shown) that provides connection to the LAN.

  A program for causing the computer system 900 to execute the function of the receiving device 1 according to the above embodiment is stored in the CD-ROM 921 or the FD 922, inserted into the CD-ROM drive 905 or the FD drive 906, and transferred to the hard disk 914. May be. Instead, the program may be transmitted to the computer 901 via a network (not shown) and stored in the hard disk 914. The program is loaded into the RAM 913 when executed. The program may be loaded directly from the CD-ROM 921, the FD 922, or the network.

  The program does not necessarily include an operating system (OS), a third-party program, or the like that causes the computer 901 to execute the functions of the receiving device 1 according to the above-described embodiment. The program may include only a part of an instruction that calls an appropriate function (module) in a controlled manner and obtains a desired result. How the computer system 900 operates is well known and will not be described in detail.

  Further, the present invention is not limited to the above-described embodiment, and various modifications are possible, and it goes without saying that these are also included in the scope of the present invention.

  As described above, according to the receiving apparatus and the like according to the present invention, an effect that the amount of data to be fed back can be reduced is obtained, and for example, it is useful as a receiving apparatus that transmits a channel estimation result.

DESCRIPTION OF SYMBOLS 1 Receiving device 2 Transmitting device 3, 4 Receiving antenna 5, 6 Transmitting antenna 11 Receiving unit 12 Channel estimating unit 13 Generating unit 14 Measuring unit 15 Judging unit 16, 35 Fourier transform unit 17 Feedback unit 18 Control unit 31 Low noise amplifying unit 32 Local oscillator 33 Frequency converter 34 AD converter 36 Equalizer 37 Demodulator 38 P / S converter 41 Inverse Fourier transform means 42 Path removal means 43 Delay profile generation means

Claims (7)

A receiving unit that receives a reference signal transmitted from one or more transmission antennas by one or more transmission antennas via one or more reception antennas;
A channel estimation unit that obtains a frequency domain channel estimation value for a channel corresponding to a combination of the one or more transmission antennas and the one or more reception antennas using a reference signal received by the reception unit;
A generation unit that performs inverse Fourier transform on the frequency domain channel estimation value obtained by the channel estimation unit, and generates a delay profile including the amplitude, phase, and delay interval of each path constituting the channel;
A measurement unit that measures the number of paths of the delay profile generated by the generation unit;
A determination unit for determining whether the number of paths measured by the measurement unit exceeds a threshold;
A feedback unit for transmitting a frequency domain channel estimate or delay profile to the transmitter;
If the number of paths exceeds the threshold value using the determination result of the determination unit, the frequency domain channel estimation value is transmitted to the feedback unit, and the number of paths does not exceed the threshold value. In this case, a receiving device comprising: a control unit that causes the feedback unit to transmit a delay profile. The receiving device according to claim 1, wherein the generation unit generates a delay profile excluding a path having an amplitude smaller than a threshold value. A Fourier transform unit for Fourier transforming the delay profile generated by the generation unit;
The receiving device according to claim 2, wherein the feedback unit transmits a frequency domain channel estimation value obtained by performing a Fourier transform of a delay profile to the transmitting device as a frequency domain channel estimation value. The receiving apparatus according to claim 3, wherein the receiving unit performs an equalization process using a frequency domain channel estimation value obtained by Fourier-transforming the delay profile by the Fourier transform unit. The transmission device and the reception device perform communication by MIMO (Multiple Input Multiple Output),
The receiving apparatus according to claim 1, wherein the transmitting apparatus performs transmission using two or more antennas. A reception step of receiving a reference signal transmitted from one or more transmission antennas by one or more transmission antennas via one or more reception antennas;
Using the reference signal received in the reception step, a channel estimation step of obtaining a frequency domain channel estimation value for a channel corresponding to a combination of the one or more transmission antennas and the one or more reception antennas;
A step of generating a delay profile including an amplitude, a phase, and a delay interval of each path constituting the channel by performing an inverse Fourier transform on the frequency domain channel estimation value obtained in the channel estimation step;
A measurement step of measuring the number of paths of the delay profile generated in the generation step;
A determination step of determining whether the number of paths measured in the measurement step exceeds a threshold;
If the number of paths exceeds the threshold using the determination result in the determination step, the channel estimation value in the frequency domain is transmitted to the transmitter, and the number of paths exceeds the threshold. If not, a feedback step of transmitting a delay profile to the transmitting device. Computer
The one or more transmission antennas and the one or more reception antennas are received by using a reference signal received by a receiving unit that receives the reference signals transmitted from the one or more transmission antennas via the one or more reception antennas. A channel estimation unit that obtains a frequency domain channel estimation value for the channel according to the combination with
A generation unit that performs inverse Fourier transform on the frequency domain channel estimation value acquired by the channel estimation unit, and generates a delay profile including the amplitude, phase, and delay interval of each path constituting the channel;
A measurement unit that measures the number of paths of the delay profile generated by the generation unit;
A determination unit for determining whether the number of paths measured by the measurement unit exceeds a threshold;
If the number of paths exceeds the threshold using the determination result of the determination unit, the channel estimation value in the frequency domain is transmitted to the transmission device, and the number of paths does not exceed the threshold. In the case, a program for causing a delay profile to be transmitted to the transmission device as a control unit.

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