JP6987328B2 - Transmitter, receiver, communication system, control circuit, storage medium and communication method - Google Patents

Description

The present invention relates to a transmitting device, a receiving device, a communication system, a control circuit, a storage medium, and a communication method for continuously transmitting a block-coded signal at a plurality of base stations.

Conventionally, in a wireless communication system, communication quality is deteriorated due to a decrease in electric field strength near the boundary of a cell covered by a base station. To solve such problems, satellite base stations can be installed near the cell boundaries, and the satellite base stations can reduce the effects of weak electric fields by transmitting the same signals as the base stations at the same frequency. can. On the other hand, when the transmission signal from the base station and the transmission signal from the satellite base station have an opposite phase relationship, the transmission signals cancel each other out, and beat interference occurs in which the received power is reduced.

Patent Document 1 discloses a technique for reducing the occurrence of beat interference by transmitting signals having different timings and frequency deviations from two antennas in each of the two base stations. The mobile station that receives the signal performs adaptive equivalence processing to transmit and synthesize signals with different timings.

Japanese Unexamined Patent Publication No. 2002-30097

However, according to the above-mentioned conventional technique, the mobile station that receives the signal requires adaptive equivalence processing, which causes a problem that the amount of calculation increases. Further, when different frequency deviations are given between base stations, there is a problem that the communication quality deteriorates if the resistance of the frequency deviations in the mobile station is low.

The present invention has been made in view of the above, and an object of the present invention is to obtain a transmitting device capable of reducing the influence of beat interference in a receiving device when a plurality of transmitting devices transmit signals.

In order to solve the above-mentioned problems and achieve the object, the transmitter of the present invention performs block coding on two or more transmitting antennas and a modulated signal, and transmits from each of the two or more transmitting antennas. The block coding unit that generates the transmission signal to be transmitted and the block coding unit by the block coding unit are blocks, and a process of adding a different weighting coefficient to the transmission signal for each transmission device is transmitted. It is characterized by including a weighted continuous transmission signal generation unit that repeatedly executes the signal as many times as the number of continuous transmissions.

The transmitting device according to the present invention has an effect that when a plurality of transmitting devices transmit signals, the influence of beat interference in the receiving device can be reduced.

The figure which shows the configuration example of the communication system which concerns on Embodiment 1. A flowchart showing an example of the processing procedure of the transmission device according to the first embodiment. A flowchart showing an example of the processing procedure of the receiving device according to the first embodiment. The figure which shows the structural example of the processing circuit in the case where the processing circuit provided in the transmission device and the reception device which concerns on Embodiment 1 is realized by a processor and a memory. The figure which shows the example of the processing circuit in the case where the processing circuit provided in the transmitting device and the receiving device which concerns on Embodiment 1 is configured by the dedicated hardware. The figure which shows the structural example of the receiving apparatus which concerns on Embodiment 2.

Hereinafter, the transmitting device, the receiving device, the communication system, the control circuit, the storage medium, and the communication method according to the embodiment of the present invention will be described in detail with reference to the drawings. The present invention is not limited to this embodiment.

Embodiment 1.
FIG. 1 is a diagram showing a configuration example of the communication system 3 according to the first embodiment of the present invention. The communication system 3 includes transmission devices 1a and 1b and reception devices 2a. FIG. 1 also shows a configuration example of the transmitting devices 1a and 1b and the receiving device 2a.

The transmission device 1a includes a block coding unit 10a, a weighted continuous transmission signal generation unit 11a, and transmission antennas 12a and 12b. The transmission device 1b includes a block coding unit 10b, a weighted continuous transmission signal generation unit 11b, and transmission antennas 12c and 12d. The transmitters 1a and 1b are examples of two or more base stations. The transmitting antennas 12a to 12d are examples of transmitting antennas provided with two or more transmitting antennas per base station. The transmitters 1a and 1b have the same configuration. In the following description, when the transmission devices 1a and 1b are not distinguished, they are referred to as a transmission device 1, and when the block coding units 10a and 10b are not distinguished, they are referred to as a block coding unit 10 and are referred to as weighted continuous signal generation units 11a and 11b. When is not distinguished, it may be referred to as a weighted continuous transmission signal generation unit 11, and when the transmission antennas 12a to 12d are not distinguished, it may be referred to as a transmission antenna 12.

The block coding units 10a and 10b perform spatiotemporal block coding (hereinafter, referred to as STBC (Space Time Block Coding) coding) for a modulated signal (hereinafter referred to as STBC (Space Time Block Coding) coding) for a modulated signal, which is primarily first-modulated, from the outside (not shown). The block coding unit 10a generates transmission signals transmitted from each of the transmission antennas 12a and 12b, which are two or more transmission antennas. The block coding unit 10b generates transmission signals transmitted from each of the transmission antennas 12c and 12d, which are two or more transmission antennas. The block coding units 10a and 10b output a block coded signal which is a transmission signal generated by performing STBC coding.

The weighted continuous transmission signal generation units 11a and 11b generate continuous transmission signals which are transmission signals for the number of continuous transmissions. Specifically, the weighted continuous transmission signal generation units 11a and 11b use a block coding unit by the block coding units 10a and 10b to be connected as a block, and transmit the block-coded transmission signal with respect to the transmission device. The process of adding a different weighting coefficient for each block is repeated for the number of times of continuous transmission in which the transmission signal is transmitted a plurality of times. That is, the weighted continuous transmission signal generation units 11a and 11b add weights different for each transmission device 1 to the block coded signal for each block coding unit according to the number of continuous transmissions to generate the continuous transmission signal. .. The weighted continuous transmission signal generation unit 11a generates a continuous transmission signal which is a transmission signal transmitted from each of the transmission antennas 12a and 12b. The weighted continuous transmission signal generation unit 11b generates a continuous transmission signal which is a transmission signal transmitted from each of the transmission antennas 12c and 12d.

The transmission antennas 12a and 12b transmit the transmission signal output from the weighted continuous transmission signal generation unit 11a as a radio wave. The transmission antennas 12c and 12d transmit a continuous transmission signal, which is a transmission signal output from the weighted continuous transmission signal generation unit 11b, as a radio wave.

In the present embodiment, the communication system 3 in the case where the number of transmission devices 1 is 2, the number of transmission antennas 12 included in each transmission device 1 is 2, and the number of continuous transmissions is 2 will be described as an example. The communication system 3 is not limited to the case where the number of transmission devices 1 is 2, and can be applied to the case where the number of transmission devices 1 is 3 or more. Further, the communication system 3 is not limited to the case where the number of transmitting antennas 12 included in the transmitting device 1 is 2, and can be applied to the case where the number of transmitting antennas 12 included in the transmitting device 1 is 3 or more. Further, the communication system 3 is not limited to the case where the number of continuous transmissions is 2, and can be applied to the case where the number of continuous transmissions is 3 or more. That is, the communication system 3 may include two or more transmitting devices 1, and each transmitting device 1 may include two or more transmitting antennas 12. Further, in the communication system 3, as will be described later, the receiving device 2a includes a transmitting antenna output power detection unit 21 according to the number of transmitting antennas 12, a continuous transmission block power detecting unit 22 according to the number of continuous transmissions, and a portion thereof. It suffices to include a decoding unit 24.

When there are three or more transmission devices 1, the same primary modulation symbol is input to each transmission device 1, and each transmission device 1 generates a transmission signal and transmits it from each transmission antenna 12. When there are three or more transmitting antennas 12, each transmitting device 1 generates transmission signals corresponding to the number of transmitting antennas 12 and transmits them from the corresponding transmitting antennas 12. The receiving device 2a measures the received power of the transmission signal transmitted from each transmitting antenna 12 by the corresponding transmitting antenna output power detecting unit 21. When the number of continuous transmissions is 3 or more, each transmission device 1 generates and transmits as many transmission signals weighted by the block coding unit in the weighted continuous transmission signal generation unit 11. The receiving device 2a measures the received power of the transmission signal for each continuous transmission by the continuous transmission block power detection unit 22. Further, in the transmission device 1, the weighted continuous transmission signal generation unit 11 is not limited to the case where the number of transmission antennas 12 is 2 and the number of continuous transmissions is 2, and the number of transmission antennas 12 is 3 or more and continuous transmission. It can also be applied when the number of feeds is 3 or more. In the receiving device 2a, the partial decoding unit 24 and the total decoding unit 25 are not limited to the case where the number of continuous transmissions is 2, and can be applied to the case where the number of continuous transmissions is 3 or more.

FIG. 1 illustrates components related to baseband signal processing among the components actually included in the transmitting devices 1a and 1b, but the transmitting devices 1a and 1b include components not shown in FIG. May be good. For example, the transmission devices 1a and 1b may include a filter, an analog unit that performs analog signal processing, and the like, in addition to the components shown in FIG. Further, although the communication system 3 shown in FIG. 1 includes transmission devices 1a and 1b, the number of transmission times and the transmission antenna in the block coding unit 10 and the weighted continuous transmission signal generation unit 11 of one transmission device 1 You may generate block coded signals for twelve lines.

Further, the signal input to the transmission devices 1a and 1b may be a transmission bit sequence, and the transmission devices 1a and 1b may perform primary modulation on the transmission bit sequence which is an input signal. In this case, the transmission devices 1a and 1b include a primary modulation unit in front of the block coding units 10a and 10b. The primary modulation unit generates a modulation signal for the transmission bit sequence by a modulation method such as an FSK (Frequency Shift Keying) method, and outputs the modulation signal to the weighted continuous transmission signal generation units 11a and 11b. The transmission bit sequence may be a bit sequence that has undergone preprocessing such as interleaving and error correction coding.

In this embodiment, as a transmission diversity scheme, i.e., STBC coding, S.I. M. Alamouti, "A Simple Transfer Technology Technology for Wireless Communications", IEEE Journal on Select Areas in Communications, Vol. 16, No. 8, pp. 1451-1458, October 1998. It is assumed that the Alamouti coding disclosed in the above is used. Further, in the present embodiment, the STBC coding unit is referred to as a “block”, and the primary modulated data unit is referred to as a “symbol”.

The receiving device 2a receives a transmission signal, which is a block-encoded signal continuously transmitted by the transmitting devices 1a and 1b, as a receiving signal. The configuration of the receiving device 2a will be described. The receiving device 2a includes the receiving antenna 20, the transmitting antenna output power detecting units 21a to 21d, the continuous transmission block power detecting units 22a and 22b, the block decoding unit selection unit 23, the partial decoding units 24a and 24b, and the entire decoding. A unit 25 and a continuous feed synthesis unit 26 are provided. In the following description, when the transmission antenna output power detection units 21a to 21d are not distinguished, they are referred to as transmission antenna output power detection units 21, and when the continuous transmission block power detection units 22a and 22b are not distinguished, the continuous transmission block power detection units 22 are used. When the partial decoding units 24a and 24b are not distinguished, the partial decoding unit 24 may be referred to.

The receiving antenna 20 receives the transmission signal transmitted from the transmission devices 1a and 1b as a reception signal. The receiving antenna 20 outputs the received transmission signal to the transmitting antenna output power detecting units 21a to 21d, the continuous transmission block power detecting units 22a and 22b, and the block decoding unit selection unit 23.

The transmission antenna output power detection units 21a to 21d calculate the reception power for each transmission signal transmitted from the transmission antennas 12a to 12d using the reception signals received by the reception antenna 20. For example, the transmission antenna output power detection unit 21a calculates the reception power of the transmission signal transmitted from the transmission antenna 12a of the transmission device 1a, and the transmission antenna output power detection unit 21b transmits the transmission transmitted from the transmission antenna 12b of the transmission device 1a. Calculate the received power of the signal. Further, the transmission antenna output power detection unit 21c calculates the reception power of the transmission signal transmitted from the transmission antenna 12c of the transmission device 1b, and the transmission antenna output power detection unit 21d transmits the transmission transmitted from the transmission antenna 12d of the transmission device 1b. Calculate the received power of the signal.

The continuous transmission block power detection unit 22a, 22b uses the reception signal received by the reception antenna 20 to transmit the transmission signal transmitted from the transmission antennas 12a to 12d of the transmission devices 1a, 1b for each block unit. Calculate the received power of. For example, the continuous transmission block power detection unit 22a calculates the first reception power of the number of continuous transmissions in block units for the transmission signals transmitted from the transmission antennas 12a to 12d. Further, the continuous transmission block power detection unit 22b calculates the second reception power of the number of continuous transmissions in block units for the transmission signals transmitted from the transmission antennas 12a to 12d.

The block decoding unit selection unit 23 selects a block decoding unit based on the received power calculated by the transmission antenna output power detection units 21a to 21d and the continuous transmission block power detection units 22a and 22b. The specific selection method in the block decoding unit selection unit 23 will be described later.

The partial decoding units 24a and 24b perform block decoding using a part of the received signals of the block-encoded signals continuously transmitted by the number of times of continuous transmission, and the decoding result is obtained by the continuous transmission synthesis unit 26 in the subsequent stage. Output to. The overall decoding unit 25 performs block decoding using all the received signals of the block-encoded signals transmitted continuously as many times as the number of times of continuous transmission, and outputs the decoding result. The continuous feed synthesis unit 26 calculates the continuous feed synthesis result using the decoding results partially decoded by the partial decoding units 24a and 24b. Specifically, the continuous transmission synthesis unit 26 is output from the partial decoding units 24a and 24b based on the received power calculated by the transmission antenna output power detection units 21a to 21d or the continuous transmission block power detection units 22a and 22b. Select whether to select or synthesize the decryption result, and calculate the continuous transmission result.

In the transmission devices 1a and 1b, the input signal may be subjected to preprocessing such as error correction coding and primary modulation. In this case, the receiving device 2a obtains the demodulation result by performing demodulation corresponding to the primary modulation method for the decoding result obtained by the whole decoding unit 25 or the continuous feed synthesis unit 26, and makes an error with respect to the demodulation result. Decoding processing corresponding to preprocessing such as error correction decoding corresponding to correction coding is performed.

Further, although FIG. 1 shows an example in which the receiving device 2a includes one receiving antenna 20, the receiving device 2a may include a plurality of receiving antennas 20. When the receiving device 2a includes a plurality of receiving antennas 20, in the receiving device 2a, a receiving diversity decoding unit (not shown) provided after the receiving antenna 20 synthesizes the received signals received by the plurality of receiving antennas 20. The transmission antenna output power detection units 21a to 21d and the continuous transmission block power detection units 22a and 22b calculate the reception power using the reception signal synthesized by the reception diversity decoding unit (not shown). That is, the receiving device 2a includes one or more receiving antennas 20.

In FIG. 1, among the components actually included in the receiving device 2a, the components related to the baseband signal processing are shown, but the receiving device 2a may include components (not shown in FIG. 1). For example, the receiving device 2a may include a filter, an analog unit that performs analog signal processing, and the like. The receiving device 2a also performs processing such as time synchronization processing, frequency synchronization processing, and transmission path estimation. However, since general processing can be applied to these processing, the components that perform these processing are Illustrations and explanations are omitted. In the following description of the operation of the receiving device 2a, it is assumed that processing such as time synchronization processing, frequency synchronization processing, and transmission path estimation is ideally performed. If processing such as time synchronization processing, frequency synchronization processing, and transmission path estimation is not ideally performed, an error may occur in the operation of the receiving device 2a, but the countermeasures for dealing with the error are general block decoding and Since it is the same as the receiving device that performs continuous transmission synthesis, the description thereof will be omitted.

Next, the operation of the communication system 3 will be described. First, the operation of the transmission device 1 will be described. FIG. 2 is a flowchart showing an example of the processing procedure of the transmission devices 1a and 1b according to the first embodiment. The details of each process will be described later.

The block coding units 10a and 10b generate a block coded signal by performing block coding on the input primary modulation symbol (step S101). The block coded signal includes symbols corresponding to each of the transmitting antennas 12a to 12d as described later.

The weighted continuous transmission signal generation units 11a and 11b add a weighting coefficient different for each transmission device 1 to the block coded signal according to the number of continuous transmissions, and generate a transmission signal (step S102). The weighted continuous transmission signal generation units 11a and 11b block-encode the weighting coefficients which are different for each transmission device 1 and whose weighting coefficients are orthogonal to each other in the continuous transmission section which is the section in which the continuous transmission signals which are a plurality of transmission signals are transmitted. Add to the signal. The weighting coefficient is a value orthogonal to each other between the transmission devices 1a and 1b in the continuous transmission section and orthogonal to the number of consecutive transmissions of the transmission devices 1a and 1b. The values orthogonal to each other during the number of consecutive transmissions are the transmission signal transmitted from one transmission antenna 12 of the transmission device 1 and the transmission transmitted from the other transmission antenna 12 of the transmission device 1 at each transmission. It is a value orthogonal to the signal. The weighted continuous transmission signal generation units 11a and 11b repeat the process of adding the weighting coefficient to the block coded signal as many times as the number of continuous transmissions. When a plurality of transmitting devices transmit the same signal at the same frequency, beat interference occurs in which the received power of the receiving device is lowered due to the interference between the transmitted signals, and the transmission quality is deteriorated. In the present embodiment, in order to reduce the influence of beat interference, a different weighting coefficient is added to each transmission device 1 in units of block coded signals. The weighted continuous transmission signal generation units 11a and 11b may perform beat interference with respect to the block-encoded transmission signal, for example, based on at least one of the received power in the receiving device 2a and the channel variation in the continuous transmission section. The process of adding a weighting coefficient that reduces the influence is repeated as many times as the number of continuous feeds.

The transmission antennas 12a to 12d transmit the corresponding transmission signals output from the weighted continuous transmission signal generation units 11a and 11b as radio waves. As a result, the transmitting devices 1a and 1b transmit the transmission signal to the receiving device 2a (step S103).

Next, the operation of the transmission devices 1a and 1b will be described in detail. Assuming that the modulation signal vector which is the primary modulation symbol input to the transmitters 1a and 1b is s (bold), s (bold) is a vertical vector having s (m, 1) and s (m, 2) as elements. It becomes. Note that s (m, n) indicates the nth symbol in the mth STBC block. m and n are natural numbers. The maximum value of n is the number of symbols in one block, which is the processing unit of STBC coding, and is determined according to the number of transmission antennas 12 and the transmission rate. When the number of transmitting antennas 12 is 2 and the transmitting rate is 1, the maximum value of n is 2. At this time, the STBC coded signal matrix z (m) (bold), which is the block coded signal output from the block coded units 10a and 10b, can be represented by the following equation (1). z ^(q) (m, n) indicates the nth symbol in the mth STBC block transmitted from the qth transmitting antenna 12. q is a natural number, and in the configuration example shown in FIG. 1, the transmitting antenna 12a and the transmitting antenna 12c are the first transmitting antenna (z ⁽¹⁾ ), and the transmitting antenna 12b and the transmitting antenna 12d are the second transmitting antennas. (Z ⁽²⁾ ). Since the block coding units 10a and 10b perform the same STBC coding for the same modulated signal vector, the block coding units 10a and 10b output the same signal. In equation (1), (・) ^* indicates complex conjugate.

Next, the weighted continuous transmission signal generation units 11a and 11b add weighting coefficients that are different for each transmission device 1 and orthogonal to each other in the continuous transmission section with respect to the STBC coded signal matrix z (m) (bold). The weighted continuous transmission signal generation units 11a and 11b generate a transmission signal by repeating the process of adding a weighting coefficient to the STBC coded signal matrix z (m) (bold) as many times as the number of continuous transmissions, and the transmission antenna 12a. , 12b is output. ^{The transmission signal matrix x (1)} (m) (bold), x ⁽²⁾ (m) (bold) of the m-th STBC block to which the weighting coefficient in the transmission devices 1a and 1b is added is the following equation (2). And can be expressed by the equation (3). Here, x ^(p) (m) indicates a transmission signal matrix in the m-th STBC block in the p-th transmission device 1. p is a natural number.

Further, a ^{(p) and} (k) indicate the weighting coefficient in the kth continuous transmission in the p-th transmission device 1, and can be expressed by the following equation (4). In equation (4), k is a natural number and j is an imaginary unit. b (p) and c (p) indicate a coefficient that gives a different phase rotation amount and amplitude value for each transmission device 1. At this time, the weighting coefficients a ^(p) (k), b (p) and c (p) are values that satisfy the following conditions.

Here, b (1) ≠ b (2) ≠ ... ≠ b (P), and a ^(p) (bold) = [a ^(p) (0) a ^(p) (1) ... a ^(p) ( When K)] is set, a ⁽¹⁾ (bold), a ⁽²⁾ (bold), ..., A ^(P) (bold) are orthogonal to each other.

In this embodiment, b (1) = 1, b (2) = 2, and c (1) = c (2) = 1. As described above, in the present embodiment, a different weighting coefficient is added to the block coded signal in block units for each transmission device 1, and this is repeated for the number of times of continuous transmission.

Next, the decoding process in the receiving device 2a according to the first embodiment will be described. For the sake of simplification of the description, an example in which the number of receiving antennas 20 is 1 will be described as shown in FIG. FIG. 3 is a flowchart showing an example of the processing procedure of the receiving device 2a according to the first embodiment. The details of each process will be described later.

The transmission antenna output power detection units 21a to 21d use the reception signal received by the reception antenna 20 to obtain the reception power when the transmission signal transmitted from the corresponding transmission antennas 12a to 12d is received by the reception antenna 20. Calculate (step S201).

The continuous transmission block power detection units 22a and 22b use the received signal received by the receiving antenna 20 to obtain the received power for each continuous transmission number of the transmission signals transmitted from the transmission devices 1a and 1b, that is, in the continuous transmission unit. Calculate (step S202).

The block decoding unit selection unit 23 selects a unit for performing block decoding, that is, a block decoding unit, based on the received power calculated by the transmission antenna output power detection units 21a to 21d and the continuous transmission block power detection units 22a and 22b. (Step S203).

When partial decoding is selected as the block decoding unit (step S203: partial decoding), the block decoding unit selection unit 23 outputs the received power and the received signal to the partial decoding units 24a and 24b. The partial decoding units 24a and 24b use block decoding, that is, STBC, using a part of the received signals in the continuous transmission section, specifically, using the received signals received in the first or second continuous transmission. Decryption is performed (step S204). The continuous feed synthesis unit 26 calculates the continuous feed synthesis result using the decoding results output from the partial decoding units 24a and 24b (step S205). The continuous transmission synthesis unit 26 selects the decoding result output from the partial decoding units 24a and 25b based on the received power calculated by the transmission antenna output power detection units 21a to 21d or the continuous transmission block power detection units 22a and 22b. Or, combine and output the continuous transmission composition result.

When the block decoding unit selection unit 23 selects total decoding as the block decoding unit (step S203: total decoding), the block decoding unit selection unit 23 outputs the received power and the received signal to the total decoding unit 25. The overall decoding unit 25 performs block decoding, that is, STBC decoding, using all the received signals in the continuous transmission section, specifically, using the received signals received in the first and second continuous transmissions ( Step S206).

Next, the operation of the receiving device 2a will be described in detail. Assuming that the received signal in the m-th STBC block received by the receiving antenna 20 is r (m) (bold), it can be expressed by the following equation (5) from the equations (1) to (3). Here, r (m, k, n) represents the nth symbol in the kth continuous transmission of the mth STBC block. For the sake of simplification of the explanation, the noise component included in the received signal is omitted. As shown in the equation (5), when the transmission signal from the transmission device 1a and the transmission signal from the transmission device 1b are received in the same phase, that is, h ^(1,1) = h ^(1,2) =. When h ^(2,1) = h ^(2,2) , the signals r (m, 1,1) and r (m, 1, 2) received in the first continuous transmission are transmitted between the transmission devices 1. The signal is offset. On the other hand, the signals r (m, 2, 1) and r (m, 2, 2) received in the second continuous transmission are received by the receiving device 2a with twice the received power. Similarly, when the transmission signal from the transmission device 1a and the transmission signal from the transmission device 1b are received in opposite phases, the reception device 2a receives the signal with twice the reception power in the first continuous transmission. .. In this way, even when beat interference occurs between a plurality of transmitting devices 1 that transmit the same signal, the receiving device 2a is generated by adding a different weighting coefficient to each transmitting device 1 and generating the continuously transmitted transmission signal. Can reliably receive the signal.

Next, the transmission antenna output power detection units 21a to 21d use the reception signal matrix r (m) (bold) represented by the equation (5) to obtain the reception power of the transmission signal transmitted from each transmission antenna 12. calculate. The received power from each transmitting antenna 12 in the m-th STBC block can be expressed by the following equation (7) using the signal sequence x (m) represented by the following equation (6). As described above, the weighted continuous transmission signal generation units 11a and 11b add weighting coefficients that are different for each transmission device 1 and that are orthogonal to each other to the block coded signal. As a result, the transmission antenna output power detection units 21a to 21d of the reception device 2a can calculate the reception power of the transmission signal transmitted from each transmission antenna 12. In addition, the operating status of each transmitting antenna 12 can be observed, which has the effect of simplifying maintenance work.

The continuous transmission block power detection units 22a and 22b use the received signals received for the first or second continuous transmission in the received signal matrix r (m) (bold) represented by the equation (5), respectively. Calculate the received power in the number of continuous transmissions.

Next, the block decoding unit selection unit 23 selects the block decoding unit based on the received power calculated by the transmission antenna output power detection units 21a to 21d and the continuous transmission block power detection units 22a and 22b. For example, when the reception power of the transmission signal transmitted from the transmission device 1a is low in the reception power from each transmission antenna 12 represented by the equation (7), the block decoding unit selection unit 23 selects the overall decoding unit 25. Block decoding may be performed using all the received signals corresponding to the transmitted signals transmitted from the transmitting device 1b in the continuous transmission section. Further, when the received power of the first continuous transmission calculated by the continuous transmission block power detection unit 22a is low, the block decoding unit selection unit 23 performs block decoding using only the received signal of the second continuous transmission. 24b may be selected. The block decoding unit selection unit 23 does not need to select one of the partial decoding units 24a and 24b, and may select a plurality or all of the partial decoding units 24a and 24b.

In the present embodiment, the block decoding unit selection unit 23 selects the block decoding unit based on the received power calculated by the transmission antenna output power detection units 21a to 21d and the continuous transmission block power detection units 22a and 22b. However, it is not limited to this. The block decoding unit selection unit 23 may select a block decoding unit based on the propagation path condition of the continuous transmission section such as the transmission line estimation value calculated by the transmission line estimation unit (not shown in FIG. 1). For example, when the propagation path variation for each block is large, the block decoding unit selection unit 23 may select the partial decoding units 24a and 24b in order to reduce the influence of the propagation path variation. The block decoding unit selection unit 23 selects a block decoding unit based on at least one of the received power and the propagation path condition.

For example, the block decoding unit selection unit 23 receives a large reception power when each reception power is not within the specified first range based on the reception power calculated by the transmission antenna output power detection units 21a to 21d. Partial decoding units 24a and 24b that perform block decoding using signals are selected. When each received power is within the first range, the block decoding unit selection unit 23 selects the entire decoding unit 25 that performs block decoding using all the received signals.

Alternatively, if the block decoding unit selection unit 23 is based on the received power calculated by the continuous transmission block power detection units 22a and 22b and each received power in the continuous transmission section is not within the specified second range, the continuous transmission unit selection unit 23 is continuous. Partial decoding units 24a and 24b that perform block decoding using the received signals of one or a plurality of reception timings having a large received power in the transmission section are selected. When each received power in the continuous transmission section is within the second range, the block decoding unit selection unit 23 selects the overall decoding unit 25 that performs block decoding using the received signals at all reception timings in the continuous transmission section.

Alternatively, if the block decoding unit selection unit 23 is not within the third range in which the fluctuation of the propagation path condition in the continuous transmission section is defined based on the propagation path condition, the fluctuation of the propagation path condition in the continuous transmission section is small. Partial decoding units 24a and 24b that perform block decoding using one or more received signals are selected. The block decoding unit selection unit 23 selects the entire decoding unit 25 that performs block decoding using all the received signals in the continuous transmission section when the fluctuation of the propagation path condition in the continuous transmission section is within the third range.

Next, the partial decoding units 24a and 24b perform block decoding represented by the following equations (8) to (11) using the received signals received at the first and second continuous transmissions. The receiving device 2a shown in FIG. 1 includes, but is not limited to, two partial decoding units 24a and 24b. The receiving device 2a may sequentially perform block decoding at each continuous transmission number by one partial decoding unit 24. Further, the receiving device 2a includes a partial decoding unit 24 that performs block decoding using the received signal received at the second symbol of the first continuous transmission and the received signal received at the first symbol of the second continuous transmission. You may. Further, the receiving device 2a includes three or more partial decoding units 24 when the number of continuous transmissions is three or more, performs block decoding using the received signal at each continuous transmission number, and also performs block decoding using the received signal at each continuous transmission number. Block decoding may be performed using the received signal in.

Next, the overall decoding unit 25 performs block decoding represented by the following equations (12) and (13) using the received signals at all the continuous transmission times in the m-th STBC block.

Comparing the block decoding results of the partial decoding units 24a and 24b represented by the equations (8) to (11) with the block decoding results of the entire decoding unit 25 represented by the equations (12) and (13), they are continuously transmitted. The partial decoding units 24a and 24b that block-decode using a part of the received signals can only obtain the diversity gain in which the channel gains of the transmitting devices 1a and 1b are combined. On the other hand, in the overall decoding unit 25, the channel gains in all four transmitting antennas 12 included in the communication system 3 can be obtained as diversity gains. That is, when compared from the viewpoint of diversity gain, the overall decoding unit 25 is better. However, while the total decoding unit 25 performs block decoding using all channels in the continuous transmission section, the partial decoding units 24a and 24b perform block decoding using only the channels at each transmission count. Generally, in block decoding, decoding is performed on the assumption that the channel variation in the block used for decoding is constant, so that the decoding gain decreases as the channel variation in the block increases. Therefore, when the channel fluctuation in the continuous feed section is large, the decoding characteristics deteriorate in the overall decoding unit 25 that performs block decoding using more symbols. From the above, the receiving device 2a not only reduces the influence of beat interference but also optimally decodes by selecting the block decoding unit according to the received power due to beat interference, the channel variation in each transmitting antenna 12, and the like. Make it possible to acquire characteristics.

Next, the continuous feed synthesis unit 26 compares the block decoding results in the first and second continuous feeds output from the partial decoding units 24a and 24b, and the one with the better decoding gain in each modulation signal is the continuous feed synthesis result. Select as and output. The continuous transmission synthesis unit 26 weights and synthesizes the decoding results in the partial decoding units 24a and 24b based on the received power calculated by the transmission antenna output power detection units 21a to 21d and the continuous transmission block power detection units 22a and 22b. However, it may be output as a continuous feed synthesis result.

Further, in the equations (2), (3), (5), and (6), the continuous transmission signal in the m-th STBC block is assumed to be continuously transmitted and received in time, but the continuous transmission is performed. After the first block-encoded signal matrix is transmitted and received over a plurality of blocks, the second continuous block-encoded signal matrix may be transmitted and received. In the above case, the transmission antenna output power detection units 21a to 21d, the continuous transmission block power detection units 22a and 22b, the block decoding unit selection unit 23, the partial decoding units 24a and 24b, the overall decoding unit 25, and the continuous transmission unit. The synthesizing unit 26 operates using the received signal corresponding to the block number m.

In the present embodiment, the description is based on the premise that Alamouti coding is applied, but the present embodiment is not limited thereto. As the coding, the communication system 3 can be applied with other coding as long as it is a block coding in which a plurality of symbols are coded as a unit.

Next, the hardware configuration of the transmitting device 1 and the receiving device 2a will be described. In the transmitting device 1, the transmitting antenna 12 is realized by the antenna device. The block coding unit 10 and the weighted continuous signal generation unit 11 are realized by a processing circuit. Further, in the receiving device 2a, the receiving antenna 20 is realized by the antenna device. The transmission antenna output power detection unit 21, the continuous transmission block power detection unit 22, the block decoding unit selection unit 23, the partial decoding unit 24, the total decoding unit 25, and the continuous transmission synthesis unit 26 are realized by a processing circuit. The processing circuit may be a processor and memory for executing a program stored in the memory, or may be dedicated hardware. The processing circuit is also called a control circuit.

FIG. 4 is a diagram showing a configuration example of a processing circuit when the processing circuit included in the transmitting device 1 and the receiving device 2a according to the first embodiment is realized by a processor and a memory. The processing circuit 300 shown in FIG. 4 is a control circuit and includes a processor 300a and a memory 300b. When the processing circuit is composed of the processor 300a and the memory 300b, each function of the processing circuit is realized by software, firmware, or a combination of software and firmware. The software or firmware is written as a program and stored in the memory 300b. In the processing circuit, each function is realized by the processor 300a reading and executing the program stored in the memory 300b. That is, the processing circuit includes a memory 300b for storing a program in which the processing of the block coding unit 10 and the weighted continuous signal generation unit 11 is eventually executed in the transmission device 1. Alternatively, in the receiving device 2a, the processing circuit includes a transmitting antenna output power detection unit 21, a continuous transmission block power detection unit 22, a block decoding unit selection unit 23, a partial decoding unit 24, an overall decoding unit 25, and a continuous transmission synthesis unit 26. It is provided with a memory 300b for storing a program in which the processing of the above is executed as a result. It can be said that this program is a program for causing the transmitting device 1 or the receiving device 2a to execute each function realized by the processing circuit. This program may be provided by a storage medium in which the program is stored, or may be provided by other means such as a communication medium.

In the transmission device 1, in the first program, which is the above program, the block coding unit 10 performs block coding on the modulated signal and generates a transmission signal transmitted from each of the two or more transmission antennas 12. The block coding step to be performed and the weighted continuous transmission signal generation unit 11 use the block coding unit by the block coding unit 10 as a block, and add a different weighting coefficient for each transmission device 1 to the transmission signal in block units. It can be said that this is a program for causing the transmission device 1 to execute a weighted continuous transmission signal generation step of repeating the processing for the number of consecutive transmissions of transmitting the transmission signal a plurality of times.

Further, in the receiving device 2a, in the second program, which is the above program, the transmitting antenna output power detection unit 21 uses the received signal to transmit each of the two or more transmitting antennas 12 included in the transmitting device 1. Regarding the transmission antenna output power detection step that calculates the reception power for each transmission signal, and the transmission signal that the continuous transmission block power detection unit 22 is block-encoded in the transmission device 1 using the reception signal and transmitted from the transmission device 1. It can also be said that the program causes the receiving device 2a to execute the continuous transmission block power detection step of calculating the received power for each continuous transmission in the block coding block unit. Further, in the second program, the block decoding unit selection unit 23 determines the received power and the propagation path condition of the continuous transmission section in which the continuous transmission signal which is a plurality of transmission signals is transmitted from the transmission device to the reception device. A block decoding unit selection step for selecting a block decoding unit based on at least one of them, and a partial decoding unit 24 block decoding using a part of the received signals of the continuously transmitted block coded signals. The partial decoding step of performing block decoding by the total decoding unit 25 using all the received signals of the continuously transmitted block-encoded signals, and the partial decoding unit 26 of the continuous transmission synthesis unit 26. It can be said that this is a program for causing the receiving device 2a to execute the continuous transmission synthesis step of calculating the continuous transmission synthesis result using the decoding result partially decoded by the decoding unit 24.

Here, the processor 300a is, for example, a CPU (Central Processing Unit), a processing device, an arithmetic unit, a microprocessor, a microcomputer, a DSP (Digital Signal Processor), or the like. The memory 300b is, for example, non-volatile or volatile such as RAM (Random Access Memory), ROM (Read Only Memory), flash memory, EPROM (Erasable Programmable ROM), EEPROM (registered trademark) (Electrically EPROM). This includes semiconductor memory, magnetic disk, flexible disk, optical disk, compact disk, mini disk, DVD (Digital Versatile Disc), and the like.

FIG. 5 is a diagram showing an example of a processing circuit in the case where the processing circuit included in the transmitting device 1 and the receiving device 2a according to the first embodiment is configured by dedicated hardware. The processing circuit 300c shown in FIG. 5 is, for example, a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), or a combination thereof. The thing is applicable. As for the processing circuit, a part may be realized by dedicated hardware and a part may be realized by software or firmware. As described above, the processing circuit can realize each of the above-mentioned functions by the dedicated hardware, software, firmware, or a combination thereof.

As described above, according to the present embodiment, the transmission devices 1a and 1b block-encode a plurality of primary-modulated symbols, and for each transmission device 1 for the block-coded signal as many times as the number of continuous transmissions. The operation of adding different weighting coefficients is repeated. The receiving device 2a measures the received power for each transmission antenna 12 or the number of times of continuous transmission, performs block decoding in a unit selected based on the received power, and continuously synthesizes the decoding result. In the transmitting devices 1a and 1b, by adding weighting coefficients that are different for each transmitting device 1 and orthogonal to each other to the block coded signal by the number of times of continuous transmission, the receiving device 2a receives the same signal. Even when beat interference occurs between a plurality of transmission devices 1 that transmit at time, the signal can be reliably received.

Embodiment 2.
In the first embodiment, the weighting coefficient added in the weighted continuous signal generation units 11a and 11b is fixed. In the second embodiment, the weighting coefficient in each transmitting device 1 is adaptively changed based on the received power in the receiving device. A part different from the first embodiment will be described.

FIG. 6 is a diagram showing a configuration example of the receiving device 2b according to the second embodiment. The receiving device 2b is a device in which a weighting coefficient control unit 27 is added to the receiving device 2a. The communication system 3 of the present embodiment is the same as the communication system 3 of the first embodiment except that the weighting coefficient control unit 27 is additionally provided for the receiving device 2a shown in FIG.

The operation of the weighting coefficient control unit 27 will be described in detail. The weighting coefficient control unit 27 uses the received powers calculated by the transmission antenna output power detection units 21a to 21d and the continuous transmission block power detection units 22a and 22b to generate weighted continuous transmission signals in the transmission devices 1a and 1b. The weighting coefficient is specified for 11a and 11b. For example, when the received power of the first continuous transmission calculated by the continuous transmission block power detection unit 22a is small, it means that the signal from the transmission device 1a and the signal from the transmission device 1b are received in the same phase with each other. .. Therefore, the weighting coefficient control unit 27 instructs the transmission devices 1a and 1b so that the weighting coefficients of the weighted continuous signal generation units 11a and 11b are a ^{(p) (k) = 1 in the equation (2).} .. As a result, the receiving device 2b has the effect that the signal is received with twice the received power at any continuous transmission time, and the continuous transmission combined gain is further increased. The weighting coefficient control unit 27 may notify the weighting continuous transmission signal generation units 11a and 11b of the weighting coefficient, and the transmission antenna output power detection units 21a to 21d and the continuous transmission block power detection units 22a and 22b. The received power calculated in 1 may be notified. Further, the weighting coefficient control unit 27 may notify other parameters such as indicating the weighting coefficient.

In FIG. 6, the weighting coefficient control unit 27 is provided in the receiving device 2b, and the weighting continuous signal generation units 11a and 11b are notified, but the present invention is not limited to this. In the communication system 3, the weighting coefficient control unit 27 may be provided in the transmission devices 1a and 1b, respectively. In this case, the receiving device 2b transmits the received power received by the receiving antenna 20, the received power calculated by the transmitting antenna output power detecting units 21a to 21d and the continuous transmission block power detecting units 22a, 22b, and the like. Notify the weighting coefficient control unit 27 provided in 1b. The weighting coefficient control unit 27 exerts the same effect by instructing the weighting continuous signal generation units 11a and 11b to have a weighting coefficient.

In both cases where the weighting coefficient control unit 27 is provided in the receiving device 2b and the weighting coefficient control unit 27 is provided in the transmitting devices 1a and 1b, the receiving device 2b transmits using a transmission function (not shown). It is possible to communicate with the devices 1a and 1b. Similarly, the transmitting devices 1a and 1b can communicate with the receiving device 2b by using a receiving function (not shown).

As described above, according to the present embodiment, the receiving device 2b changes the phase rotation amount given to the transmitting device 1 according to the received power and the received power at each time. As a result, the communication system 3 can receive the signal at any time, and can improve the continuous transmission synthesis gain, that is, the transmission quality.

The configuration shown in the above-described embodiment shows an example of the content of the present invention, can be combined with another known technique, and is one of the configurations as long as it does not deviate from the gist of the present invention. It is also possible to omit or change the part.

1a, 1b transmitter, 2a, 2b receiver, 3 communication system, 10a, 10b block coding unit, 11a, 11b weighted continuous signal generator, 12a-12d transmit antenna, 20 receive antenna, 21a-21d transmit antenna output Power detection unit, 22a, 22b continuous transmission block power detection unit, 23 block decoding unit selection unit, 24a, 24b partial decoding unit, 25 total decoding unit, 26 continuous transmission synthesis unit, 27 weighting coefficient control unit.

Claims (21)

With two or more transmitting antennas,
A block coding unit that performs block coding on the modulated signal and generates a transmission signal transmitted from each of the two or more transmission antennas.
The block coding unit by the block coding unit is a block, and the process of adding a weighting coefficient different for each transmission device to the transmission signal in block units is the number of consecutive transmissions in which the transmission signal is transmitted a plurality of times. Weighted continuous signal generation unit that repeats as many times as
A transmitter characterized by comprising. The weighting coefficient is orthogonal between the plurality of transmission devices in the continuous transmission section which is the section in which the continuous transmission signal which is the plurality of transmission signals is transmitted, and is orthogonal between the continuous transmission times of the transmission device. To be the value to be
The transmitting device according to claim 1. The weighted continuous transmission signal generation unit is in a continuous transmission section in which the received power in the receiving device for receiving the transmission signal and the continuous transmission signal which is a plurality of the transmission signals are transmitted with respect to the transmission signal. Based on at least one of the channel fluctuations, the process of adding the weighting coefficient that reduces the influence of beat interference is repeated as many times as the number of continuous feeds.
The transmitter according to claim 1 or 2. A receiving device that receives a transmission signal, which is a block-coded signal continuously transmitted by the transmitting device according to any one of claims 1 to 3, as a receiving signal.
One or more receiving antennas that receive the transmitted signal as the received signal, and
A transmission antenna output power detection unit that calculates the reception power of each transmission signal transmitted from two or more transmission antennas included in the transmission device using the reception signal.
A continuous transmission block power detection unit that calculates the reception power for each continuous transmission in the block-encoded block unit for a transmission signal that is block-encoded in the transmission device and transmitted from the transmission device using the reception signal. When,
The block decoding unit is set based on at least one of the received power and the propagation path condition of the continuous transmission section in which the continuous transmission signal which is the plurality of transmission signals is transmitted from the transmission device to the reception device. Block decoding unit selection unit to be selected and
A partial decoding unit that performs block decoding using a part of the received signals of the continuously transmitted block-encoded signals, and
An overall decoding unit that performs block decoding using all the received signals of the continuously transmitted block-encoded signals, and
A continuous transmission synthesis unit that calculates a continuous transmission synthesis result using the decoding result partially decoded by the partial decoding unit, and a continuous transmission synthesis unit.
A receiving device characterized by comprising. Based on the received power calculated by the transmitting antenna output power detecting unit, the block decoding unit selection unit uses a received signal having a large received power when each received power is not within the specified first range. A partial decoding unit that performs block decoding is selected, and when each received power is within the first range, a total decoding unit that performs block decoding using all received signals is selected.
The receiving device according to claim 4. The block decoding unit selection unit is a section in which a plurality of continuous transmission signals, which are transmission signals, are transmitted from the transmission device to the reception device based on the reception power calculated by the continuous transmission block power detection unit. When each received power in the continuous transmission section is not within the specified second range, a partial decoding unit that performs block decoding using one or more reception timing reception signals having a large reception power in the continuous transmission section is provided. Select, and when each received power in the continuous transmission section is within the second range, select an overall decoding unit that performs block decoding using the reception signals of all reception timings in the continuous transmission section.
The receiving device according to claim 4 or 5. Based on the propagation path condition, the block decoding unit selection unit determines the propagation path condition in the continuous transmission section in which the continuous transmission signal, which is a plurality of transmission signals, is transmitted from the transmission device to the reception device. When the fluctuation is not within the specified third range, a partial decoding unit that performs block decoding using one or a plurality of received signals having a small fluctuation in the propagation path condition in the continuous transmission section is selected, and the continuous transmission section is selected. When the fluctuation of the propagation path condition in the transmission section is within the third range, the entire decoding unit that performs block decoding using all the received signals in the continuous transmission section is selected.
The receiving device according to any one of claims 4 to 6, wherein the receiving device is characterized by the above. Whether the continuous transmission synthesis unit synthesizes or selects the decoding result partially decoded by the partial decoding unit based on the received power calculated by the transmission antenna output power detection unit or the continuous transmission block power detection unit. Select and calculate the continuous feed synthesis result,
The receiving device according to any one of claims 4 to 7, wherein the receiving device is characterized by the above. The transmitter according to any one of claims 1 to 3,
The receiving device according to any one of claims 4 to 8.
A communication system characterized by being provided with. It is a control circuit of the transmitter,
A block coding unit that performs block coding on the modulated signal and generates a transmission signal transmitted from each of two or more transmission antennas.
The block coding unit by the block coding unit is a block, and the process of adding a weighting coefficient different for each transmission device to the transmission signal in block units is the number of consecutive transmissions in which the transmission signal is transmitted a plurality of times. Weighted continuous signal generation unit that repeats as many times as
A control circuit characterized by being provided with. A control circuit of a receiving device that receives a transmission signal, which is a block-encoded signal continuously transmitted by the transmitting device having the control circuit according to claim 10, as a receiving signal.
Using the received signal received by one or more receiving antennas that receive the transmitted signal as the received signal, the received power for each transmitted signal transmitted from the two or more transmitting antennas included in the transmitting device. Transmission antenna output power detector to calculate
A continuous transmission block power detection unit that calculates the reception power for each continuous transmission in the block-encoded block unit for a transmission signal that is block-encoded in the transmission device and transmitted from the transmission device using the reception signal. When,
The block decoding unit is set based on at least one of the received power and the propagation path condition of the continuous transmission section in which the continuous transmission signal which is the plurality of transmission signals is transmitted from the transmission device to the reception device. Block decoding unit selection unit to be selected and
A partial decoding unit that performs block decoding using a part of the received signals of the continuously transmitted block-encoded signals, and
An overall decoding unit that performs block decoding using all the received signals of the continuously transmitted block-encoded signals, and
A continuous transmission synthesis unit that calculates a continuous transmission synthesis result using the decoding result partially decoded by the partial decoding unit, and a continuous transmission synthesis unit.
A control circuit characterized by being provided with. A storage medium in which the first program to be executed by the transmitter is stored.
The first program is
A block coding step in which the block coding unit performs block coding on the modulated signal and generates a transmission signal transmitted from each of the two or more transmission antennas.
The weighted continuous transmission signal generation unit sets the unit of the block coding by the block coding unit as a block, and adds a weighting coefficient different for each transmission device to the transmission signal in the block unit. A weighted continuous signal generation step that repeats as many times as the number of continuous transmissions
A storage medium, characterized in that the transmitter is made to execute. A receiving device including one or more receiving antennas that receive a transmission signal, which is a block-encoded signal continuously transmitted by a transmitting device that executes the first program stored in the storage medium according to claim 12, as a receiving signal. Is the storage medium in which the second program to be executed is stored.
The second program is
A transmission antenna output power detection step in which the transmission antenna output power detection unit calculates the reception power for each transmission signal transmitted from two or more transmission antennas included in the transmission device using the reception signal.
The continuous transmission block power detection unit uses the received signal to block-encode the transmission signal in the transmission device and transmit the received power for each number of consecutive transmissions in the block-coded block unit. The continuous feed block power detection step to be calculated and
The block decoding unit selection unit determines at least one of the received power and the propagation path status of the continuous transmission section in which the continuous transmission signal which is a plurality of the transmission signals is transmitted from the transmission device to the reception device. Based on the block decoding unit selection step, which selects the block decoding unit,
A partial decoding step in which the partial decoding unit performs block decoding using a part of the received signals of the continuously transmitted block-encoded signals, and
A whole decoding step in which the whole decoding unit performs block decoding using all the received signals of the continuously transmitted block coded signals, and
A continuous feed synthesis step in which the continuous feed synthesis unit calculates a continuous feed synthesis result using the decoding result partially decoded by the partial decoding unit.
A storage medium, characterized in that the receiver is made to execute. A communication method for a transmitter equipped with two or more transmitting antennas.
A block coding step in which the block coding unit performs block coding on the modulated signal and generates a transmission signal transmitted from each of the two or more transmission antennas.
The weighted continuous transmission signal generation unit sets the unit of the block coding by the block coding unit as a block, and adds a weighting coefficient different for each transmission device to the transmission signal in the block unit. A weighted continuous signal generation step that repeats as many times as the number of continuous transmissions
A communication method characterized by including. The weighting coefficient is orthogonal between the plurality of transmission devices in the continuous transmission section which is the section in which the continuous transmission signal which is the plurality of transmission signals is transmitted, and is orthogonal between the continuous transmission times of the transmission device. To be the value to be
14. The communication method according to claim 14. In the weighted continuous transmission signal generation step, the weighted continuous transmission signal generation unit transmits the received power of the receiving device for receiving the transmission signal and the continuous transmission signal which is a plurality of the transmission signals to the transmission signal. Based on at least one of the channel fluctuations in the continuous transmission section, which is the section to be performed, the process of adding the weighting coefficient that reduces the influence of beat interference is repeated as many times as the number of continuous transmissions.
The communication method according to claim 14 or 15. A receiving device including one or more receiving antennas that receive a transmission signal, which is a block-encoded signal continuously transmitted by a transmitting device that implements the communication method according to any one of claims 14 to 16, as a receiving signal. It ’s a communication method,
A transmission antenna output power detection step in which the transmission antenna output power detection unit calculates the reception power for each transmission signal transmitted from two or more transmission antennas included in the transmission device using the reception signal.
The continuous transmission block power detection unit uses the received signal to block-encode the transmission signal in the transmission device and transmit the received power for each number of consecutive transmissions in the block-coded block unit. The continuous feed block power detection step to be calculated and
The block decoding unit selection unit determines at least one of the received power and the propagation path status of the continuous transmission section in which the continuous transmission signal which is a plurality of the transmission signals is transmitted from the transmission device to the reception device. Based on the block decoding unit selection step, which selects the block decoding unit,
A partial decoding step in which the partial decoding unit performs block decoding using a part of the received signals of the continuously transmitted block-encoded signals, and
A whole decoding step in which the whole decoding unit performs block decoding using all the received signals of the continuously transmitted block coded signals, and
A continuous feed synthesis step in which the continuous feed synthesis unit calculates a continuous feed synthesis result using the decoding result partially decoded by the partial decoding unit.
A communication method characterized by including. In the block decoding unit selection step, the block decoding unit selection unit receives when each received power is not within the specified first range based on the received power calculated by the transmission antenna output power detection unit. A partial decoding unit that performs block decoding using a high-power received signal is selected, and when each received power is within the first range, a total decoding unit that performs block decoding using all the received signals is selected.
17. The communication method according to claim 17. In the block decoding unit selection step, the block decoding unit selection unit receives the continuous transmission signal, which is a plurality of transmission signals, from the transmission device based on the reception power calculated by the continuous transmission block power detection unit. If each received power in the continuous transmission section, which is the section transmitted to the device, is not within the specified second range, the reception signal of one or more reception timings having a large reception power in the continuous transmission section is used. A partial decoding unit that performs block decoding is selected, and when each received power in the continuous transmission section is within the second range, total decoding that performs block decoding using the reception signals of all reception timings in the continuous transmission section is performed. Select a part,
The communication method according to claim 17 or 18. In the block decoding unit selection step, the block decoding unit selection unit is a section in which a plurality of continuous transmission signals, which are transmission signals, are transmitted from the transmission device to the reception device based on the propagation path condition. A portion in which block decoding is performed using one or a plurality of received signals in which the fluctuation of the propagation path condition is small in the continuous transmission section when the fluctuation of the propagation path condition in the transmission section is not within the specified third range. A decoding unit is selected, and when the fluctuation of the propagation path condition in the continuous transmission section is within the third range, the entire decoding unit that performs block decoding using all the received signals in the continuous transmission section is selected.
The communication method according to any one of claims 17 to 19, wherein the communication method is characterized in that. In the continuous transmission synthesis step, the continuous transmission synthesis unit is a decoding result partially decoded by the partial decoding unit based on the received power calculated by the transmission antenna output power detection unit or the continuous transmission block power detection unit. Select whether to synthesize or select, and calculate the continuous feed synthesis result.
The communication method according to any one of claims 17 to 20, wherein the communication method is characterized in that.

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