JP5134487B2 - Wireless signal measuring device, channel sounder - Google Patents

Description

  The present invention relates to a radio signal measuring apparatus and a channel sounder for measuring characteristics of a radio transmission path.

  The MIMO communication system attracts attention as a technology for realizing high-speed wireless transmission, and research and development are being actively promoted. MIMO is an abbreviation for Multiple-Input Multiple-Output, meaning multiple input / multiple output. The MIMO communication system is a system that performs transmission / reception using an array antenna including a plurality of antenna elements, and can increase the transmission capacity in the same bandwidth as the number of antenna elements increases. In MIMO communication, the characteristics of the radio propagation path have a great influence on transmission performance and system design. Therefore, in the research and development of a MIMO communication system, a channel sounder that measures the characteristics of a radio propagation path is required.

As shown in FIG. 1, the channel sounder includes a transmission device 800 and a radio signal measurement device (reception device) 900. The transmission apparatus 800 includes N (N is an integer of 1 or more) transmission antennas 871-1 to 87-N. From each transmission antenna 871-n (n is an integer of 1 to N), a signal s _n ( t) is output. The radio signal measuring apparatus 900 includes M (M is an integer of 2 or more) receiving antennas 971-1 to 971 -M, and each receiving antenna 971 -m (m is an integer of 1 to M) has a signal y _m. (T) is received. The radio waves output from the transmission antennas 871-1 to 87-N are reflected by obstacles 710 such as the earth, trees, and buildings, and arrive at the reception antennas 971-1 to 971-1 as many delayed waves having different directions. Further, when the transmission antennas 871-1 to N, the reception antennas 971-1 to M, or the obstacle 710 moves, a Doppler shift is performed. In FIG. 1, the number of delay paths is R, the radiation angle of the rth delay path is ψ _r , the arrival angle is Ω _r , the attenuation is α _r , the delay time is τ _r , and the Doppler frequency is υ _r . . However, r is an integer of 1-R. Due to these phenomena, the signal y _mn (t) received by the receiving antenna 971-m with respect to the signal s _n (t) output from the transmitting antenna 871-n in the wireless propagation path as shown in FIG. )become that way.

Here, c is an angle characteristic.
From the relationship between s _n (t) and y _mn (t), the characteristics (propagation characteristics) of the wireless transmission path between the transmitting antenna 871-n and the receiving antenna 971-m can be obtained.

Such a radio propagation path including angle characteristics on the transmission side and the reception side is called a spatio-temporal multipath propagation path, and a measurement method has been studied (Non-patent Document 1 and Non-Patent Document 2). Further, there are channel sounders of Non-Patent Document 3 and Non-Patent Document 4 as channel sounders for measuring the characteristics of a wireless transmission path for a MIMO communication system. However, the detailed operation principle of the channel sounders of Non-Patent Document 3 and Non-Patent Document 4 is unknown.
Sakaguchi, Takada, “Measurement device, measurement method, analysis method, and modeling of MIMO propagation characteristics”, IEICE (B), vol.J88-B, no.9, pp.1624-1640, Sept. 2005. T. Matsumoto, S. Thoma, “Turbo Transceiver for MIMO Wireless Communication and Their Performance Verification via Multi-Dimensional Channel Sounding,” IEICE Trans. Commun., Vol. E88-B, no.6 June 2005. MEDAV, Multidimensional Channel Sounder [searched September 12, 2008], Internet <http://www.medav.de/fileadmin/redaktion/documents/English/rusk_mimo_e.pdf> Channelsounder, RUSK Channel Sounder, Multiple ReciveAntennas +, Multiple Recive Antennas-Site2 [searched September 12, 2008], Internet <http://www.medav.de/fileadmin/redaktion/documents/English/rusk_mimo_e.pdf>

In order to measure the characteristics of the wireless transmission path, the signal y _mn (t) received by the receiving antenna 971-m with respect to the signal s _n (t) output from the transmitting antenna 871-n as described above is measured. There must be. The number of wireless transmission paths whose characteristics must be obtained is the product N × M of the number N of transmission antennas 871-n and the number M of reception antennas 971-m. Therefore, when the characteristics of all the wireless transmission paths are measured while selecting the transmitting antenna 871-n and the receiving antenna 971-m one by one, the time required for the measurement becomes enormous as the number N and the number M increase. .

As a solution to this problem, the transmitting side outputs a signal s _n (t) from one selected transmitting antenna 871-n, and the receiving side simultaneously outputs a signal y _mn (t) with a plurality of receiving antennas 971-m. Can be considered. For this purpose, a plurality of circuits necessary for signal processing may be provided. However, there is a limit to the number of circuits that can be provided in order to make the radio signal measuring device large and heavy enough to carry.

In general, one transmission antenna 871-n is selected, and the signal y _mn (t) is measured by all the reception antennas 971-m while switching the reception antennas 971-m. Then, the next transmission antenna 871-n + 1 is selected, and the signal y _{mn + 1} (t) is measured by all the reception antennas 971-m while switching the reception antennas 971-m. That is, the transmission side switches the transmission antenna N times, but the reception side switches the reception antenna N × M times. Therefore, if the wasted time associated with switching that occurs on the receiving side can be reduced, the measurement time can be shortened efficiently.

  An object of the present invention is to provide a radio signal measuring apparatus and a channel sounder for measuring characteristics of a large number of radio transmission paths in a short time like a MIMO communication system. In particular, useless time generated by switching the receiving antenna in the radio signal measuring apparatus is reduced.

  The radio signal measuring apparatus of the present invention includes at least a plurality of receiving antennas, a switch unit, and a signal processing unit. The plurality of receiving antennas receive radio waves including measurement signals that are repeated at a predetermined cycle. The switch unit selects one of the reception antennas for a time equal to or longer than one period of the measurement signal. The signal processing unit acquires the measurement signal received by the receiving antenna selected by the switch unit for one period or more. Then, when the signal processing unit receives the measurement signal from the middle of the cycle, the measurement signal generation unit performs the order of the measurement signal of the cycle received from the middle of the measurement signal and the measurement signal of the next cycle. Is replaced, and a measurement signal for one period starting from the beginning of the period is generated. Furthermore, the signal processing unit performs predetermined signal processing on the measurement signal for one period starting from the beginning of the period by the measurement signal processing unit. That is, when the acquired measurement signal starts from the beginning of the cycle, the signal processing unit performs signal processing on the measurement signal. When the acquired measurement signal does not start from the beginning of the cycle, the signal processing unit precedes the beginning of the next cycle. The measurement signal starting from the beginning of the period is generated by arranging the signal in the position, and signal processing is performed on the generated measurement signal.

  Moreover, what is necessary is just to determine the timing which a signal processing part acquires a measurement signal based on the time required for switching of a switch part. For example, the measurement signal may be acquired from a timing obtained by dividing the period of the measurement signal by an integer after the time when the switch unit can be switched reliably.

  The channel sounder according to the present invention includes the above-described wireless signal measurement device and a transmission device having one or more transmission antennas that output radio waves including the measurement signal. The transmitter does not transmit measurement signals from two or more transmission antennas at the same time.

  According to the radio signal measuring apparatus and the channel sounder of the present invention, the measurement signal generating means generates the measurement signal for one period starting from the beginning of the period, and therefore the timing at which the signal processing unit of the radio signal measuring apparatus acquires the measurement signal. Is not required to match the period of the measurement signal. That is, the measurement signal can be measured immediately after the switching of the switch portion of the wireless signal measuring device is completed. Therefore, the characteristics of the wireless transmission path can be measured in a short time. In particular, it is possible to reduce wasted time that occurs due to switching of the receiving antenna in the radio signal measuring apparatus.

  Examples of the present invention are shown below. In addition, the same number is attached | subjected to the structure part which has the same function, and duplication description is abbreviate | omitted.

  FIG. 2 shows a functional configuration example of the transmission apparatus, and FIG. 3 shows a functional configuration example of the wireless signal measurement apparatus according to the first embodiment. The transmission device 100 and the wireless signal measurement device 200 constitute a channel sounder. FIG. 4 is a diagram illustrating signal states in the transmission device 100 and the wireless signal measurement device 200.

  The transmission apparatus 100 includes a transmission-side input / output unit 110, a transmission-side signal processing unit 120, a transmission-side reference signal generation unit 130, an up-converter unit 140, an amplification unit 150, a transmission-side switch unit 160, and a transmission-side antenna unit 170. The transmission-side input / output unit 110 acquires information necessary for controlling the transmission device 100, outputs the status of the transmission device 100, and the like. The transmission side signal processing unit 120 controls the transmission side switch unit 160 and generates a signal output from the transmission side antenna unit 170. For example, transmission data bits are assigned to symbols of each subcarrier of OFDM (Orthogonal Frequency-Division Multiplexing). Next, the complex signal on the frequency axis is subjected to inverse FFT (Fast Fourier Transform) to generate a complex signal on the time axis. The inverse FFT point may be 128, 256, 512, 1024, 2048, 4096, or the like. Further, after adding a GI (Guard Interval) and performing windowing processing, the signal is converted into an analog signal by D / A conversion to generate a baseband IQ analog signal and output to the up-converter unit 140. This D / A conversion is performed at a sampling timing synchronized with the reference signal generated by the transmission-side reference signal generation unit 130. The transmission side switch unit 160 is also controlled in synchronization with this sampling timing. The up-converter unit 140 converts the baseband IQ analog signal into an RF signal. The amplifying unit 150 amplifies and outputs the RF signal. This output includes a measurement signal that is repeated at a predetermined period. The transmission-side switch unit 160 selects one transmission antenna 171-n (where n is an integer of 1 to N and N is an integer of 1 or more) in the transmission-side antenna unit 170 at a timing described later. The transmission-side antenna unit 170 has N transmission antennas 171-1 to 17-N.

  The radio signal measuring apparatus 200 includes a reception-side input / output unit 210, a reception-side signal processing unit 220, a reception-side reference signal generation unit 230, a down-converter unit 240, a recording unit 250, a reception-side switch unit 260, and a reception-side antenna unit 270. Prepare. The reception-side antenna unit 270 includes M (where M is an integer of 2 or more) reception antennas 271-1 to 271 -M. Receiving antennas 271-1 to 271 -M receive radio waves including measurement signals output from transmitting apparatus 100. The receiving-side switch unit 260 selects one receiving antenna 271 -m (where m is an integer from 1 to M) from the receiving antennas 271-1 to 271 -M. Note that the reception-side switch unit 260 may be selected including polarization (for example, vertical polarization or horizontal polarization) received by one reception antenna 271-m. In this way, when selecting including polarization, it is only necessary to physically consider one receiving antenna as two receiving antennas and select the receiving side switch unit 260. The down-converter unit 240 converts the RF signal received by the reception antenna 271-m selected by the reception-side switch unit 260 into a baseband IQ analog signal. The receiving side reference signal generation unit 230 generates a reference signal.

  The reception side signal processing unit 220 samples the radio wave including the measurement signal in synchronization with the reference signal generated by the reception side reference signal generation unit 230. The reception-side signal processing unit 220 switches the reception-side switch unit 260 in synchronization with the reference signal generated by the reception-side reference signal generation unit 230. The reception side signal processing unit 220 includes a measurement signal generation unit 221 and a measurement signal processing unit 222. In the radio wave sampling including the measurement signal performed by the reception-side signal processing unit 220 described above, a measurement signal for one period or more is acquired for each reception antenna 271-m. When the measurement signal is received from the middle of the cycle, the measurement signal generation means 221 switches the order of the measurement signal of the cycle received from the middle of the measurement signal and the measurement signal of the next cycle. The measurement signal for one period starting from the beginning of the period is generated. The measurement signal processing means 222 performs predetermined signal processing on the measurement signal for one period starting from the beginning of the period. The predetermined signal processing is, for example, when the output of the transmission apparatus 100 is a signal obtained by performing inverse FFT on OFDM, first, a complex signal on the frequency axis is obtained by performing FFT on the measurement signal for one period starting from the beginning of the period. . The obtained complex reception signal of each subcarrier is multiplied by a known complex conjugate of the transmission signal to obtain a propagation characteristic between the transmission and reception antennas. These results are recorded in the recording unit 250. The receiving-side input / output unit 210 acquires information necessary for controlling the radio signal measuring apparatus 200, outputs measurement results, and the like.

  Next, the relationship between the signal included in the radio wave output from the above-described transmission device 100 and the processing in the reception-side signal processing unit 220 of the wireless signal measurement device 200 will be described in detail with reference to FIG. The transmission apparatus 100 sequentially selects the transmission antennas 171-n and outputs one transmission frame 172-n for each transmission antenna 171-n. The transmission frame 172-n is composed of a preamble 173-n, a control signal 174-n, measurement data 175-n, and measurement signals 176-n-1 to P. Before the preamble 173-n, Sufficient time is secured for the side switch unit 160 to switch (the time required for switching is no signal). The preamble 173-n is a signal for the transmission apparatus 100 and the radio signal measurement apparatus 200 to synchronize. The control signal 174-n is a signal including GI information, control method information, and the like. The measurement data 175-n is a signal including information on the measurement signal (for example, FFT size). The measurement signals 176-n-1 to P are signals in which the same measurement signal is repeated P times. In FIG. 4, in order to facilitate the explanation of the subsequent processing, even-numbered measurement signals transmitted by the transmission apparatus 100 are shaded, but all of them are the same signal.

  In the radio signal measuring apparatus 200, the receiving antenna 271-m is sequentially selected, and the measurement signal 176-n-p is measured for one period. A measurement signal 276-m received by the reception antenna 271-m is input to the reception-side signal processing unit 220. Between the measurement signal 276-1 and the measurement signal 276-2, there is a time interval at which the reception-side switch unit 260 switches. In FIG. 4, the switching time of the receiving-side switch unit 260 is set to ¼ of one cycle of the measurement signal. That is, the measurement signal 276-m received by the reception antenna 271-m acquired by the reception-side signal processing unit 220 is the measurement signal output by the transmission device 100 for each time (¼ period) that the reception-side switch unit 260 switches. 176-n-p later. Therefore, when the measurement signals 176-n-p are sent for five cycles, the received measurement signals 276-m for four cycles are acquired. In order for the reception-side signal processing unit 220 to acquire the measurement signals 276-1 to M for all reception antennas, the number P of measurement signal repetitions output from the transmission apparatus 100 is P ≧ 5M / 4. There must be. When the received measurement signal 276-m starts from the beginning of the cycle, the measurement signal generation unit 221 outputs the measurement signal as it is. In FIG. 4, the received measurement signals 276-1 and 276-5 are in this case. In addition, when the received measurement signal 276-m starts in the middle of the cycle, the measurement signal generation unit 221 orders the measurement signal in the cycle received from the middle of the measurement signal and the measurement signal in the next cycle. Is replaced, and a measurement signal for one period starting from the beginning of the period is generated. In FIG. 4, the received measurement signals 276-2, 276-3, and 276-4 are in this case, and the measurement signals 277-2, 277-3, and 277-4 for one period starting from the beginning of the period are generated. The The measurement signal processing means 222 performs predetermined signal processing on the measurement signal 277-m for one period starting from the beginning of the period. That is, in the case of the radio signal measuring apparatus 200, the number of repetitions P of the measurement signal output from the transmitting apparatus 100 is approximately 5M / 4.

  Next, in order to show the effect of the radio signal measuring apparatus 200 having the measurement signal generating means 221, the processing of the radio signal measuring apparatus without the measurement signal generating means 221 will be described. FIG. 5 is a diagram illustrating a functional configuration example of a wireless signal measurement device without the measurement signal generation unit 221. The radio signal measuring apparatus 600 is the same as the radio signal measuring apparatus 200 except that there is no measurement signal generating means. FIG. 6 is a diagram illustrating a signal state when the wireless signal measurement device 600 is used. From the transmission device 100, the measurement signal 176-n-p ′ is repeatedly output P ′ times. Radio signal measuring apparatus 600 sequentially selects reception antenna 271-m, and measures measurement signal 176-n-p 'for one period from the beginning of the period. A measurement signal 676-m received by the reception antenna 271-m is input to the reception-side signal processing unit 620. There is an interval of one period of the measurement signal 676-m between the received measurement signal 676-1 and the received measurement signal 676-2. This is because there is no measurement signal generation means 221, and in order to input the measurement signal 677-m for one period starting from the beginning of the period to the measurement signal processing means 222, it is necessary to measure from the beginning of the period. is there. In the example of FIG. 6, the switching time of the receiving side switch unit is ¼ period, so the remaining 3/4 period is a time during which no processing is performed (unnecessary waiting time). . In this example, when the transmitter 100 transmits the measurement signals 176-np ′ for two cycles, the radio signal measurement device 600 acquires the measurement signals 676-m for one cycle (for one receiving antenna). To do. In order for the reception-side signal processing unit 620 to acquire the measurement signals 676-1 to 676 -M for all reception antennas, the number of measurement signal repetitions P ′ output from the transmission apparatus 100 is P ′ ≧ 2M. There must be. That is, in the case of the radio signal measuring apparatus 600, the number of repetitions P ′ of the measurement signal output from the transmitting apparatus 100 is approximately 2M.

  As described above, when the wireless signal measuring apparatus 200 having the measurement signal generation unit 221 is used, the number of measurement signal repetitions P is approximately 5M / 4, whereas the wireless signal measurement unit 200 has no measurement signal generation unit 221. When the signal measuring apparatus 600 is used, the number of measurement signal repetitions P ′ is approximately 2M. That is, it can be seen that by providing the measurement signal generation means 221, the number of repetitions of the measurement signal can be greatly reduced.

  FIG. 7 shows an example of a functional configuration of the radio signal measuring apparatus according to the second embodiment. The radio signal measuring apparatus 300 includes Q (where Q is an integer equal to or greater than 2) reception side switch units 360-1 to 360-1 and down converters 340-1 to Q. The reception-side signal processing device 320 includes Q measurement signal generation units 321-1 to Q and measurement signal processing units 322-1 to Q. The transmission device is the same as that in the first embodiment.

  Each reception-side switch unit 360-q (where q is an integer from 1 to Q) selects one reception antenna from M reception antennas, downconverter 340-q, and measurement signal generation means 321. -Q, signal processing is performed by the measurement signal processing means 322-q. The signal processing procedure is the same as in the first embodiment. In this way, by performing the processing for the Q reception antennas in parallel, the number P of repetitions of the measurement signal output from the transmission apparatus 100 can be approximately 5M / 4Q. However, when the value of Q is increased, the radio signal measuring apparatus 300 is increased, which causes a problem of portability. Therefore, the value of Q is limited by the size of the radio signal measuring apparatus 300 and the like.

[Concrete example]
Next, a specific example of a channel sounder composed of the transmission device 100 and the radio signal measurement device 300 will be shown. In this example, Q = 7. That is, the radio signal measuring apparatus 300 includes seven receiving-side switch units 360-1 to 360-7 and down converters 340-1 to 340-7. The reception-side signal processing device 320 includes seven measurement signal generation units 321-1 to 32-1 and measurement signal processing units 322-1 to 32-7.

  FIG. 8 shows (A) a perspective view of the transmitting antenna unit 170 and (B) measurement signals output from the transmitting antennas 171-1 to 16-16. In the transmitting antenna unit 170, eight transmitting antennas 171-1 to 171-16 are arranged in two stages on the upper and lower sides. In addition, dummy antennas 181-1 to 181-4 are arranged at both ends of each stage. The upper eight transmitting antennas 171-1 to 171-8 are vertically polarized transmitting antennas, and the lower eight transmitting antennas 171-9 to 16 are horizontally polarized transmitting antennas. The output measurement signal is a signal having discrete frequency components at an interval f with respect to a width of 50 MHz. The interval f varies depending on the size of the FFT, but is 10 kHz to 1 MHz in this specific example.

  9A is a perspective view of the receiving-side antenna unit 270, FIG. 9B is a cross-sectional view of the plane A, and FIG. 9C is a diagram illustrating the configuration of one receiving antenna block. The reception-side antenna unit 270 has 4 × 24 / stage (total of 96) antenna elements arranged on the circumferential surface of the main body on the cylinder. In addition, dummy antennas 281-1 to 281 are arranged on the upper and lower stages of the antenna element. Furthermore, the reception-side antenna unit 270 includes a monopole antenna 271-193 on the upper surface of the main body on the cylinder. In this specific example, the reception-side switch unit 360-q selects including the polarization (vertical polarization or horizontal polarization) received by each antenna element. Therefore, one antenna element corresponds to two receiving antennas. Although the antenna elements are physically the same, the vertically polarized wave receiving antennas are 271-1 to 96, and the horizontally polarized wave receiving antennas are 271 to 97 to 192. The receiving antennas 271-1 to 192 are divided into six receiving antenna blocks 371 to 376. FIG. 9C shows the configuration of one receiving antenna block. The reception antenna block 371 includes 32 reception antennas 271-1 to 27, 25 to 28, 49 to 52, 73 to 76, 97 to 100, 121 to 124, 145 to 148, and 169 to 172 (physical). The number of antenna elements is 16). The monopole antenna 271-193 is the seventh receiving antenna block 377.

  The transmitting apparatus 100 sequentially selects one from each of the transmitting antennas 171-1 to 16-1, and outputs a transmission frame 172-n. Each of the reception-side switch units 360-q (where q is an integer of 1 to 7) of the wireless signal measurement device 300 corresponds to any one of the reception antenna blocks. Select two receive antennas. For example, the reception-side switch unit 360-1 corresponds to the reception antenna block 371, and includes the reception antennas 271-1 to 4, 25 to 28, 49 to 52, 73 to 76, 97 to 100, 121 to 124, and 145. ˜148, 169˜172, one receiving antenna is sequentially selected. In this example, the reception antenna block 377 supported by the reception-side switch unit 360-7 includes only one monopole antenna 271-193, and thus does not need to be switched (the reception-side switch unit 360-7 is changed). The monopole antenna 271-193 may be directly connected to the down converter unit 340-7.

  FIG. 10 shows a result obtained by processing with a beamformer and obtaining a radiation angle and a delay from a result measured with a specific example of the channel sounder. FIG. 11 shows the result of separating adjacent delayed waves. The interval between the two peak values shown in FIG. 11 is 0.05 μsec or less. Therefore, it can be seen that the time resolution in this specific example is 0.025 μsec or less.

The figure which shows the structure of the system (channel sounder) which measures the characteristic of the wireless transmission path for a MIMO communication system. The figure which shows the function structural example of the transmitter of this invention. 1 is a diagram illustrating a functional configuration example of a wireless signal measurement device according to Embodiment 1. FIG. The figure which shows the state of the signal in the transmitter of Example 1, and a radio signal measuring device. The figure which shows the function structural example of the radio | wireless signal measuring apparatus without a measurement signal production | generation means. The figure which shows the state of a signal at the time of using the radio signal measuring apparatus without a measurement signal production | generation means. FIG. 6 is a diagram illustrating a functional configuration example of a wireless signal measurement device according to a second embodiment. The perspective view of a transmission side antenna part, and the figure which shows the measurement signal output from a transmission antenna. The perspective view of a receiving side antenna part, sectional drawing of a receiving side antenna part, and the figure which shows the structure of one receiving antenna block. The figure which shows the result of having processed with the beam former and calculated | required the radiation angle and the delay from the result measured with the channel sounder shown in the specific example. The figure which shows the isolation | separation result of the delay wave which adjoined.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Transmission apparatus 110 Transmission side input / output part 120 Transmission side signal processing part 130 Transmission side reference signal generation part 140 Up converter part 150 Amplification part 160 Transmission side switch part 170 Transmission side antenna part 171 Transmission antenna 181 Dummy antenna 200, 300 Radio signal Measurement device 210 Reception side input / output unit 220, 320 Reception side signal processing unit 221, 321 Measurement signal generation unit 222, 322 Measurement signal processing unit 230 Reception side reference signal generation unit 240, 340 Down converter unit 250 Recording unit 260, 360 Reception Side switch unit 270 Reception side antenna unit 271 Reception antenna 281 Dummy antennas 371 to 377 Reception antenna block

Claims (5)

A plurality of receiving antennas for receiving radio waves including a measurement signal repeated at a predetermined cycle;
A switch unit for selecting one of the reception antennas for a time of one period or more of the measurement signal;
A measurement signal received by the receiving antenna selected by the switch unit for one period or more, and a signal processing unit that performs signal processing of the measurement signal, and
The signal processing unit
When the measurement signal is received from the middle of the cycle, one cycle starting from the beginning of the cycle is obtained by switching the order of the measurement signal of the cycle received from the middle of the measurement signal and the measurement signal of the next cycle. Measurement signal generating means for generating a measurement signal for minutes;
A radio signal measurement device comprising: a measurement signal processing means for performing predetermined signal processing on a measurement signal for one cycle starting from the beginning of a cycle. The radio signal measuring device according to claim 1,
The radio signal measurement device, wherein the timing at which the signal processing unit acquires the measurement signal is determined based on a time required for switching the switch unit. The radio signal measuring device according to claim 1 or 2,
A transmission device having one or more transmission antennas for outputting radio waves including the measurement signal, and not transmitting the measurement signal from two or more transmission antennas simultaneously;
With channel sounder. A channel sounder according to claim 3,
The measurement signal is an orthogonal frequency division multiplexing signal (hereinafter referred to as “OFDM signal”),
The measurement signal processing means includes
For each transmitting antenna and each receiving antenna, fast Fourier transform the measurement signal for one period starting from the beginning of the period to obtain a complex amplitude for each subcarrier of the OFDM signal,
A channel sounder, wherein a propagation characteristic for each combination of the transmission antenna and the reception antenna is obtained using a complex conjugate for each subcarrier of the transmitted OFDM signal for each transmission antenna. A channel sounder according to claim 3 or 4,
In a state where radio waves including measurement signals are output from one transmitting antenna,
The switch unit maintains the selection of one of the reception antennas over the time when the signal processing unit acquires one period of the measurement signal, and then switches to select the next reception antenna,
The signal processing unit repeats starting acquisition of a measurement signal received by the next reception antenna after a time necessary for the switch unit to switch, and for each of the one transmission antenna and the reception antenna A channel sounder characterized by obtaining propagation characteristics.