JP5147135B2 - Communication device, terminal device, transmission method, reception method, and communication system - Google Patents

Description

  The present invention relates to a communication device, a terminal device, a transmission method, a reception method, and a communication system.

<ST / FBC transmission diversity>
The base station apparatus has a plurality of transmission antennas, and for the terminal apparatus, signals are transmitted using the plurality of antennas to obtain transmission diversity, so that transmission is superior to the case where only one transmission antenna is used. Characteristics can be obtained. Examples of such techniques include block coding such as STBC (Space Time Block Coding) and SFBC (Space Frequency Block Coding).

<STBC>
STBC is a process such as the expression (1) for two or more modulation symbols that are temporally continuous when the base station apparatus transmits a signal to the terminal apparatus using two or more transmission antennas. By applying this technique, a transmission diversity effect can be obtained on the receiving side (Non-patent Document 1).

Here, s (n) is a modulation symbol at a certain time n, and s (n + 1) is a modulation symbol one time later. The * mark indicates a complex conjugate. s _i ′ (n) (i = 1, 2) is a transmission signal after applying STBC, and i indicates a number of a transmission antenna. The terminal apparatus receives both of the transmission signals and STBC decodes the reception signals. Thereby, the same transmission diversity effect as the maximum ratio combining can be obtained.

STBC decoding can be realized by the following linear calculation. A value indicating a channel state (impulse response) from the first antenna of the base station device to the terminal device and a channel state from the second antenna of the base station device to the terminal device at time n and time n + 1, respectively, h ₁ , and h _2. Basically, STBC is used only in an environment in which the channel state time fluctuation is sufficiently small, the channel state at time n and time n + 1 is the same. Therefore, the received signals r (n) and r (n + 1) at time n and time n + 1 at the terminal device are expressed by the following equation (2).

Here, η (n) indicates noise at time n.
Next, the terminal device performs STBC decoding processing indicated by the left two sides of equation (3).

Here, as shown in the rightmost side of the equation (3), the STBC decoding results s (n) and s (n + 1) are expressed as | h ₁ | ² + | in the transmission signals s (n) and s (n + 1). Multiplying h ₂ | ² , that is, combining the maximum ratio based on the two propagation paths h ₁ and h ₂ .

<SFBC>
SFBC is replaced with “modulation symbols assigned to two carriers that are continuous on the frequency axis” instead of “two modulation symbols that are continuous in time” of STBC (Non-patent Document 2).

<Multisite ST / FBC>
In the STBC and SFBC techniques, multi-site diversity can be obtained by regarding two distant base station apparatuses as transmission antennas and transmitting data to one terminal apparatus therefrom. Because the signals transmitted from two base station devices at different positions are combined, even if the reception state of the signal from one base station device deteriorates, the signal from the other base station device can be received. A stable reception environment can be obtained. This technique is particularly effective when a terminal device exists near an intermediate point (near a cell boundary) between two base station devices. Of course, it is possible to obtain a stable communication environment by combining signals from two base station apparatuses even in the vicinity of an intermediate point (Non-Patent Document 1).

<SPC>
In the next-generation mobile communication system, it is necessary to perform communication simultaneously with as many terminal devices as possible in a limited frequency band. Therefore, SPC (Super Position Coding) that can multiplex and transmit data to two terminal devices with one radio resource is considered promising. This SPC is a method of multiplexing signals by adding a power difference to signals to two terminal devices (Non-Patent Document 3). Here, the radio resource is a minimum unit in which one modulation symbol can be placed. In OFDM (Orthogonal Frequency Division Multiplexing), it represents one subcarrier in one OFDM symbol.

  In general, SPC is a means by which a terminal device with good channel characteristics and a terminal device with poor channel characteristics can simultaneously communicate with a base station device using the same radio resource. A modulation symbol is created with a large power for a signal to a terminal device with poor channel characteristics, and a modulation symbol is created with a small power for a signal to a terminal device with good channel characteristics. Thereafter, both modulation symbols are added and transmitted to both terminal apparatuses. At this time, since a terminal device with good channel characteristics can detect both modulation symbol signals from the signal sent by adding both of the above signals, it first detects the signal to the terminal device with poor channel characteristics. Then, by subtracting the signal for the terminal device with poor channel characteristics from the received signal obtained by adding both signals, the signal destined for the terminal device with good channel characteristics can be extracted. On the other hand, in a terminal device with poor channel characteristics, a signal to a terminal device with good channel characteristics is regarded as noise because the signal power is small, and only a signal to the own terminal device with poor channel characteristics can be detected.

According to the above procedure, it is possible to multiplex signals to two terminal apparatuses with one radio resource.
In the above description of the SPC, for the sake of easy understanding, it is assumed that the SPC is performed for the terminal device having good channel characteristics and the terminal device having bad channel characteristics. This is true regardless of whether the terminal device has good channel characteristics.

Inoue, Fujii, Nakagawa “Site Diversity Method Using STTD in OFDM Multiple Base Station System”, IEICE Technical Report, RCS 2002-127 "SPACE-TIME / SPACE-FREQENCY BLOCK CODED OFDM WITH DIAGONALIZED MAXIMUM LIFELIHOOD DECODER (ST / SF-OFDM with DMLD)", IEICE Transactions, Vol. E87-B, NO. 7, pp. 2034-2039, July 2004 “Performance of Superposition Coded Broadcast / Unicast Service Overlay System”, IEICE Transactions, Vol. E91-B, NO. 9, pp. 2933-2939, September 2008

However, when SPC is applied to a system using multi-site block coding that transmits a block-coded signal from two geographically separated antennas, such as a multi-site ST / FBC scheme, the following problems occur. It occurs and cannot be applied.
That is, when data addressed to another terminal device is multiplexed by SPC with respect to a signal transmitted to a certain terminal device by the multi-site ST / FBC method, the data addressed to the former terminal device is, for example, in STBC , Block encoding is performed by any pattern, as is block encoding by the first pattern or the second pattern of the expression (1). For this reason, in the latter terminal device, since it is unclear which pattern is applied to the received signal, it is not possible to detect data to the former terminal station device, There arises a problem that data destined for the terminal device multiplexed by SPC cannot be detected.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a communication device, a terminal device, a transmission method, and a reception method in which SPC can be applied in a system using a multi-site block coding system. And providing a communication system.

  (1) The present invention has been made to solve the above-described problems, and the communication device of the present invention includes a first modulation symbol transmitted to the first terminal device and a first modulation symbol transmitted to the second terminal device. A first transmission signal generation unit that generates a first transmission signal by encoding a modulation symbol obtained by combining two modulation symbols with one of code patterns constituting a block code; A modulation symbol obtained by combining the second modulation symbol multiplied by the coefficient and the second modulation symbol is encoded using another one of the code patterns constituting the block code to generate a second transmission signal A second transmission signal generator for transmitting, a first antenna for transmitting the first transmission signal, and transmitting the second transmission signal simultaneously with transmission of the first transmission signal from the first antenna. And a second antenna It is characterized in.

  (2) Moreover, the communication apparatus of this invention is the above-mentioned communication apparatus, Comprising: The 1st modulation symbol transmitted to a 1st terminal device is used using one of the code patterns which comprise a block code. After encoding, a first transmission signal generation unit that generates a first transmission signal by combining with a second modulation symbol to be transmitted to a second terminal device, and the first modulation symbol is converted into the block code. A second transmission signal generation unit that generates a second transmission signal by combining with the second modulation symbol multiplied by a coefficient after encoding using another one of the code patterns constituting A first antenna that transmits the first transmission signal; and a second antenna that transmits the second transmission signal simultaneously with the transmission of the first transmission signal from the first antenna. It is characterized by.

(3) Moreover, the communication apparatus of this invention is one of the above-mentioned communication apparatuses, Comprising: The said coefficient which multiplies the said 2nd modulation symbol in a said 2nd transmission signal generation part is said 2nd modulation symbol. Is a coefficient that eliminates interference given to reception of the first modulation symbol in the first terminal apparatus.

(4) Further, the communication device of the present invention is the communication device described above, and further includes a first channel state from the first antenna to the first terminal device, and a second channel from the second antenna. A channel information detection unit that receives the second channel state up to one terminal device from the first terminal device, and the second transmission signal generation unit multiplies the second modulation symbol by the coefficient The value obtained by dividing the complex gain indicated by the first channel state by the complex gain indicated by the second channel state is a negative value.

(5) Moreover, the communication apparatus of this invention is one of the above-mentioned communication apparatuses, Furthermore, the code | symbol used when producing | generating the said 1st transmission signal among the code patterns which comprise the said block code | symbol A pattern information generation unit that generates pattern information indicating a pattern is provided, and the pattern information is transmitted from the first antenna.

(6) Moreover, the terminal device of the present invention is a terminal device that receives a signal transmitted from either one of the signals transmitted by the communication device using the first antenna and the second antenna. A wireless reception unit that receives a signal transmitted by the communication device, a pattern information detection unit that detects pattern information indicating one of code patterns constituting a block code from the received signal, and A block code restoration unit that performs block code restoration processing on the received signal based on the pattern information, and first data detection that detects a signal to another terminal device from a result of the block code restoration processing A cancellation unit that removes interference due to the signal to the other terminal device with respect to the received signal using the detected signal to the other terminal device; From the results obtained by removing, characterized in that it comprises a second data detector for detecting a signal to the own terminal device.

(7) Also, the terminal device of the present invention applies multi-site block coding in which a block-coded signal is transmitted from the first antenna and the second antenna to one terminal device, and at the same time, the first antenna A terminal device in a communication system that applies superposition coding in which a signal to be transmitted to another terminal device is multiplexed with a signal transmitted from the first channel state from the first antenna to the terminal device; A channel estimation unit that estimates a second channel state from the second antenna to the terminal device; a channel information generation unit that generates channel information regarding the first channel state and the second channel state; And a wireless transmission unit for transmitting the channel information.

(8) In addition, the transmission method of the present invention is a transmission method in a communication apparatus that transmits a signal to the first terminal apparatus and the second terminal apparatus using the first antenna and the second antenna. A code that constitutes a block code is a modulation symbol obtained by combining the first modulation symbol transmitted from the communication apparatus to the first terminal apparatus and the second modulation symbol transmitted to the second terminal apparatus. A first step of generating a first transmission signal by encoding using one of the patterns, and the communication apparatus comprising: the second modulation symbol multiplied by the first modulation symbol and a coefficient; A second step of encoding the combined modulation symbol using another one of the code patterns constituting the block code to generate a second transmission signal; and Transmit signal from the first antenna Characterized in that it comprises a third step of transmitting simultaneously the second transmission signal from the second antenna.

(9) Further, the transmission method of the present invention is a transmission method in a communication device that transmits a signal to the first terminal device and the second terminal device using the first antenna and the second antenna. The communication apparatus encodes the first modulation symbol to be transmitted to the first terminal apparatus using one of the code patterns constituting the block code, and then transmits the first modulation symbol to the second terminal apparatus. A first step of generating a first transmission signal by combining with a second modulation symbol, and the communication device converts the first modulation symbol into another one of code patterns constituting the block code A second process of generating a second transmission signal by combining with the second modulation symbol multiplied by a coefficient, and the communication device From the first antenna, the second transmission signal is sent to the second antenna Characterized in that it comprises a third step of simultaneously transmitted from antennas.

(10) Further, the reception method of the present invention is a terminal device that receives a signal transmitted from either one of the signals transmitted by the communication device using the first antenna and the second antenna. In the receiving method, the terminal apparatus receives one of a code pattern that constitutes a block code from the received signal and the first process of receiving the signal transmitted by the communication apparatus. A second process of detecting pattern information to be shown, a third process of performing block code restoration processing on the received signal based on the detected pattern information by the terminal apparatus, and the terminal apparatus of A fourth step of detecting a signal to another terminal device from a result of the restoration process of the block code, and the signal received by the terminal device using the detected signal to the other terminal device; A fifth step of removing interference due to a signal to the other terminal device, and a sixth step of detecting a signal to the terminal device from the result of removing the interference by the terminal device. It is characterized by.

  (11) Further, the communication system of the present invention applies the multi-site block coding for transmitting the block-coded signal from the first antenna and the second antenna to the first terminal device, and at the same time, A communication system that applies superposition coding in which a signal to a second terminal apparatus is multiplexed with a signal to be transmitted from an antenna, the first modulation symbol to be transmitted to the first terminal apparatus, and the second A first transmission signal for generating a first transmission signal by encoding a modulation symbol obtained by synthesizing a second modulation symbol to be transmitted to the terminal apparatus using one of code patterns constituting a block code A modulation symbol obtained by combining the first modulation symbol and the second modulation symbol multiplied by a coefficient with a code pattern constituting the block code A second transmission signal generation unit that encodes the other transmission signal to generate a second transmission signal, a first antenna that transmits the first transmission signal, and the second transmission signal. And a second antenna that transmits simultaneously with the transmission of the first transmission signal from the first antenna.

  According to the present invention, super position coding can be applied in a system using a multi-site block coding system.

It is a conceptual diagram of the radio | wireless communications system in 1st Embodiment of this invention. It is a schematic block diagram which shows the structure of the base station apparatus 300 in the embodiment. It is a figure which shows the example of the connection method of the base station apparatus and two antennas in the same embodiment. It is a figure which shows another example of the connection method of the base station apparatus and two antennas in the embodiment. It is a schematic block diagram which shows the structure of the transmission signal generation part 312 in the same embodiment. It is a figure which shows the example of the SPC signal which the SPC part 351 in the embodiment produces | generates. It is a schematic block diagram which shows the structure of the modulation symbol production | generation part 313 in the embodiment. It is a schematic block diagram which shows the structure of the terminal device 100 in the embodiment. FIG. 2 is a schematic block diagram showing a configuration of a first data detection unit 106 in the same embodiment. It is a schematic block diagram which shows the structure of the terminal device 200 in the embodiment. It is a schematic block diagram which shows the structure of the transmission signal generation part 312a of the base station apparatus 300a in 2nd Embodiment of this invention. It is a schematic block diagram which shows the structure of the terminal device 100a in the same embodiment. It is a schematic block diagram which shows the structure of the terminal device 400 in the embodiment. It is a schematic block diagram which shows the structure of the transmission signal production | generation part 312b of the base station apparatus 300b in 3rd Embodiment of this invention. It is a schematic block diagram which shows the structure of the terminal device 100b in the same embodiment.

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a conceptual diagram of a wireless communication system in the present embodiment. In the radio communication system according to the present embodiment, two antennas (first antenna A1 and second antenna A2) are installed in geographically separated locations, and base station apparatus B1 which is one communication apparatus in which they are located. (Not shown) is connected by wire or wirelessly.
The first terminal apparatus T1 receives signals simultaneously transmitted from the first antenna A1 and the second antenna A2 by the multi-site STBC method. The second terminal device T2 is located in an area where communication with the first antenna A1 is possible, and communicates with the first antenna A1 by SPC using the same radio resources as the first terminal device T1. I do. The third terminal apparatus T3 is located in an area where communication with the second antenna A2 is possible, and communicates with the second antenna A2 by SPC using the same radio resources as the first terminal apparatus T1. I do.

  In the present embodiment, the base station apparatus B1 notifies the second terminal apparatus T2 and the third terminal apparatus T3 of information indicating that STBC is being performed (STBC information). Furthermore, information (pattern information) indicating whether the code corresponding to the first pattern or the second pattern in the formula (1) is applied is notified to the second terminal device T2 and the third terminal device T3, respectively. .

  Here, in order for the second terminal apparatus T2 and the third terminal apparatus T3 to communicate simultaneously by SPC as shown in FIG. 1, the signal from the first antenna A1 does not reach the third terminal apparatus T3, The signal from the second antenna A2 needs to be in a state where it does not reach the second terminal device T2, and this state is also assumed in the present invention. Here, “not reach” means a state where the received signal power is small enough to be regarded as noise. In the present embodiment, the second terminal apparatus T2 is located in an area where communication with the first antenna A1 is possible, the signal transmitted from the second antenna A2 does not reach, and the third terminal apparatus T3. Is located in an area where communication with the second antenna A2 is possible, and the signal transmitted from the first antenna A1 does not reach. In addition, the first terminal device T1 is located in an area where it can communicate with both the first antenna A1 and the second antenna A2.

  Hereinafter, communication from the base station apparatus to the terminal apparatus is referred to as downlink, and communication from the terminal apparatus to the base station apparatus is referred to as uplink. In the following embodiments, as an example of applying SPC to multi-site block coding in which block-coded signals such as STBC and SFBC are transmitted from two geographically separated antennas, SPC is applied to multi-site STBC. However, SPC can be similarly applied to other multi-site block coding such as multi-site SFBC.

  FIG. 2 is a schematic block diagram showing the configuration of the base station apparatus 300 in the present embodiment. Base station apparatus 300 includes first antenna A1, second antenna A2 and base station apparatus B1 in FIG. In FIG. 1, the two antennas are illustrated as independent. However, as shown in the schematic block diagram of FIG. 2, the two antennas 311 and 321 may be considered as one base station apparatus 300. For example, the base station apparatus B1 is connected to the first antenna A1 and the second antenna A2 using a wired line such as an optical fiber by a method as shown in FIG. This is because radio signals can be transmitted from the first antenna A1 and the second antenna A2 installed at two locations 300 apart to the terminal device T.

  Also, as shown in FIG. 4, the base station apparatus B1, the first antenna A1, and the second antenna are connected by performing communication between the base station apparatus B1 and the terminal apparatus T using radio resources separated in frequency or time. To the terminal device T from the first antenna A1 and the second antenna A2 which are installed at two locations where one base station device B1 is substantially separated. Because it can be done. Further, the first antenna A1 and the second antenna A2 in FIG. 4 may be relay stations. 3 and 4, the base station apparatus B1, the first antenna A1, and the second antenna A2 are geographically separated from each other, but one antenna and the base station apparatus B1 are located at the same position. And only the other antenna may be arranged at a position away from the base station apparatus B1.

As illustrated in FIG. 2, the base station device 300 includes a modulation symbol generation unit 333 corresponding to the first terminal device T1, a modulation symbol generation unit 313 corresponding to the second terminal device T2, and a third terminal device T3. Corresponding modulation symbol generation unit 323, transmission signal generation unit 312 corresponding to the first antenna A1, transmission signal generation unit 322 corresponding to the second antenna A2, antenna 311 which is the first antenna A1, second antenna Antenna 321, receiving antenna 341, wireless receiving unit 342, and channel information detecting unit 343.
In FIG. 2, the antenna 341 that is a reception antenna is provided separately from the antenna 311 that is the first antenna A1 and the antenna 321 that is the second antenna A2, but the antenna 311 or the antenna 321 or both are provided. You may share with.

  The modulation symbol generation unit 313 generates a modulation symbol from the input information bits to be transmitted to the second terminal apparatus T2, and inputs the modulation symbol to the transmission signal generation unit 312 and the transmission signal generation unit 322. Similarly, the modulation symbol generation unit 323 generates a modulation symbol from the input information bits to be transmitted to the third terminal apparatus T3 and inputs the modulation symbol to the transmission signal generation unit 322 and the transmission signal generation unit 312. The modulation symbol generation unit 333 generates a modulation symbol from the input information bits to be transmitted to the first terminal apparatus T1, and inputs the modulation symbol to the transmission signal generation unit 312 and the transmission signal generation unit 322. Details of the modulation symbol generation units 313, 323, and 333 will be described later.

The transmission signal generation unit 312 transmits from the antenna 311 using the modulation symbol input from the modulation symbol generation unit 313, the modulation symbol input from the modulation symbol generation unit 323, and the modulation symbol input from the modulation symbol generation unit 333. A signal to be generated is generated and input to the antenna 311.
Transmission signal generation section 322 transmits from antenna 321 using the modulation symbol input from modulation symbol generation section 323, the modulation symbol input from modulation symbol generation section 313, and the modulation symbol input from modulation symbol generation section 333. A signal to be generated is generated and input to the antenna 321. Details of the transmission signal generation units 312, 322 will be described later.
Antennas 311 and 321 transmit the input transmission signals, respectively.

The radio reception unit 342 receives signals from the terminal apparatuses T1, T2, and T3 received by the reception antenna 341, down-converts the radio frequency to the baseband frequency, and inputs the received signal to the channel information detection unit 343.
The channel information detection unit 343 detects channel information reported by the first terminal apparatus T1 from the received signal, and inputs the channel information to the transmission signal generation unit 312 and the transmission signal generation unit 322. Here, the channel information reported by the first terminal apparatus T1 includes the propagation path characteristic h ₁₁ from the antenna 311 to the first terminal apparatus T1, and the propagation path characteristic h ₁₁ from the antenna 321 to the first terminal apparatus T1. ₂₁ .

  FIG. 5 is a schematic block diagram illustrating a configuration of the transmission signal generation unit 312 in the present embodiment. The transmission signal generation unit 312 includes an SPC unit 351, an STBC unit 352, an IFFT (Inverse Fast Fourier Transform) unit 353, a GI insertion unit 354, a pattern information generation unit 355, an STBC information generation unit 356, and a radio transmission unit. 357. The transmission signal generation unit 322 has the same configuration as that of the transmission signal generation unit 312 except for the calculations in the SPC unit 351 and the STBC unit 352, and thus description thereof is omitted. Details of the calculations in the SPC unit 351 and the STBC unit 352 will be described later using mathematical expressions.

  The SPC unit 351 transmits the modulation symbol generated from the information bit transmitted to the first terminal apparatus T1 and the modulation symbol generated from the information bit transmitted to the second terminal apparatus T2 or the third terminal apparatus T3. SPC is performed using the modulation symbol generated from the information bits to be generated, and an SPC signal is generated and input to the STBC unit 352. Whether the modulation symbol generated from the information bit transmitted to the second terminal apparatus T2 or the modulation symbol generated from the information bit transmitted to the third terminal apparatus T3 is used is determined by the processing of the SPC unit 351. The details will be described later. At this time, the SPC unit 351 allocates large power to the modulation symbol generated from the information bits transmitted to the first terminal apparatus T1, and transmits the information to the second terminal apparatus T2 or the third terminal apparatus T3. Allocate small power to the modulation symbols generated from the bits. The ratio of the large power and the small power may be a fixed ratio, a propagation path from the antenna 311 to the second terminal device T2 or the third terminal device T3, and the antenna 311 to the first terminal device T1. It may be determined based on the propagation path.

  FIG. 6 is a diagram illustrating an example of the SPC signal generated by the SPC unit 351. This figure shows that the signal to the first terminal device T1 and the signal to the second terminal device T2 or the third terminal device T3 are both QPSK (Quadrature Phase Shift Keying). 4 shows a method of generating an SPC signal when the modulation symbol is modulated by the above. In FIG. 6, a graph indicated by a symbol is a modulation symbol for the first terminal apparatus T1 represented in a complex plane. A graph indicated by a symbol b is a modulation symbol to the second terminal apparatus T2 or the third terminal apparatus T3 represented on the complex plane. The SPC signal obtained by adding these two signals is as shown by a graph indicated by symbol c. When this point is displayed together with all other possible signal point arrangements, a graph indicated by the symbol d is obtained (signal point arrangements that can be taken by black circles).

  If it is assumed that there is no noise, the second terminal device T2 or the third terminal device T3 that has received the signal represented by the graph indicated by the symbol d is connected to the first terminal device T1 and the second terminal device T2. Alternatively, even if the modulation symbol for the third terminal apparatus T3 is added in one modulation symbol, for example, the signal to the first terminal apparatus T1 can be detected by the quadrant on the complex plane where the signal point is located. Based on the result, a signal addressed to the terminal device can be detected.

  5 performs a process using the first pattern or the second pattern of equation (1) on the SPC signal, STBC-codes the SPC signal, and converts the SPC signal that has been STBC-coded. Input to IFFT unit 353. The IFFT unit 353 performs IFFT on the signal input from the STBC unit 352 and inputs the signal to the GI insertion unit 354. The GI insertion unit 354 generates an OFDM signal by inserting a GI (Guard Interval) into the IFFT signal, and inputs the OFDM signal to the wireless transmission unit 357.

The pattern information generation unit 355 inputs pattern information indicating whether the processing of the first pattern or the second pattern of the expression (1) is performed by the STBC unit 352 to the wireless communication unit 357.
The STBC information generation unit 356 inputs STBC information indicating whether or not the transmitted signal is subjected to STBC to the wireless communication unit 357. In this embodiment, since STBC is performed, the STBC information generation unit 356 inputs STBC information indicating that STBC is performed to the wireless communication unit 357.
The radio transmission unit 357 multiplexes pattern information and STBC information into the OFDM signal input from the GI insertion unit 354 by a method such as time multiplexing, and after up-converting from the baseband frequency to the radio frequency, uses the antenna 311 Wirelessly transmit. At this time, the wireless transmission unit 357 transmits a transmission signal so that signals are received by the first terminal device at the same timing from the two antennas 311 and 312 of the base station device 300 in synchronization.

Here, processing of SPC section 351 and STBC section 352 in transmission signal generation section 312 and transmission signal generation section 322 will be described using mathematical expressions.
The modulation symbol obtained by modulating the information bits for the first terminal device T1 is defined as a (n), the modulation symbol obtained by modulating the information bits for the second terminal device T2 is represented by b ₂ (k), and the third terminal device T3. The modulation symbol obtained by modulating the information bits for use is b ₃ (k). Where k is the largest integer not exceeding n / 2 (k = floor (n / 2)), that is, the rate of modulation symbols of b ₂ (k) and b ₃ (k) is half of a (n), In STBC coding, a (n) uses two modulation symbols, and b ₂ (k) and b ₃ (k) use one modulation symbol. Also, the first channel state from the antenna 311 to the first terminal device T1 included in the channel information reported by the first terminal device T1 is the complex gain h ₁₁ , and the antenna 321 to the first terminal device T1. Is the complex gain h ₂₁ . Details of the channel information will be described later.

First, the SPC unit 351 of the transmission signal generation unit 312 (first transmission signal generation unit) modulates a modulation symbol (first modulation symbol) a (first modulation symbol) to the first terminal apparatus T1 for each unit of the STBC encoding. The modulation symbol (second modulation symbol) b ₂ (k) for the second terminal apparatus T2 is added (combined) to n), and the coefficient is added to the modulation symbol b ₃ (k) for the third terminal apparatus T3 After multiplying by h ₂₁ ^* / h ₁₁ ^* , a process of adding to the modulation symbol a (n + 1) to the first terminal apparatus T1, that is, a process shown in the equation (4) is performed. In addition, the SPC unit 351 of the transmission signal generation unit 322 (second transmission signal generation unit) modulates a modulation symbol (second modulation symbol) b _{2 for} the second terminal apparatus T2 for each unit of the STBC encoding. (K) is multiplied by the coefficient −h ₁₁ / h ₂₁ and then added to the modulation symbol (first modulation symbol) a (n + 1) to the first terminal apparatus T 1 and to the first terminal apparatus T 1. A process of adding the modulation symbol b ₃ (k) for the third terminal apparatus T3 to the modulation symbol a (n), that is, the process of equation (5) is performed.

Next, in the STBC unit 352 of the transmission signal generation unit 312, s ₁ (n) and s ₁ (n + 1) in the equation (4) are converted into the STBC based on the first pattern that is one of the equations (1). Encode. As a result, s ₁ ′ (n) (first transmission signal) and s ₁ ′ (n + 1) shown in Expression (6) are obtained. Further, in the STBC unit 352 of the transmission signal generation unit 322, s ₂ (n) and s ₂ (n + 1) in the equation (5) are converted into STBC based on the second pattern that is one of the equations (1). Encode. As a result, s ₂ ′ (n) (second transmission signal) and s ₂ ′ (n + 1) shown in Expression (7) are obtained.

  The transmission signal generation unit 312 and the transmission signal generation unit 322 respectively IFFT these results, add a guard interval, and the first terminal device T1, the second terminal device T2, or the third terminal device T3. Wirelessly send to

In the present embodiment, the modulation symbol b ₂ (k) for the second terminal device T2 is only multiplexed by the SPC unit 351 of the transmission signal generation unit 312 with the modulation symbol a (n) for the first terminal device T1. Rather, the SPC unit 351 of the transmission signal generation unit 322 removes the interference that the modulation symbol b ₂ (k) gives to the reception of the modulation symbol a (n) to the first terminal device T1 in the first terminal device T1. The modulation symbol b ₂ (k) multiplied by the coefficient “−h ₁₁ / h ₂₁ ” as shown in the equation (5) is multiplexed on the modulation symbol a (n + 1) to the first terminal apparatus T1. doing. Since these are transmitted after the STBC unit 352 performs STBC coding, the modulation symbol b ₂ (k) transmitted from the first antenna A1 by the transmission signal generation unit 312 has a coefficient “1”, and the transmission signal generation The modulation symbol b ₂ (k) in the signal transmitted from the second antenna A 2 by the unit 322 has a coefficient of “−h ₁₁ / h ₂₁ ”, and the transmission signal generation unit 312 determines from the first antenna A 1. The modulation symbol b ₂ (k) to be transmitted is arranged at the same time and frequency.

When the first terminal device T1 receives these signals, the received signal becomes the sum of signals multiplied by the propagation path characteristics h ₁₁ and h ₂₁ from the transmission source antenna to the first terminal device T1, respectively. H ₁₁ b ₂ (k) obtained by multiplying the modulation symbol b ₂ (k) transmitted from the first antenna A 1 by the propagation path characteristic h ₁₁ and the coefficient transmitted from the second antenna A 2 are “−h ₁₁ / h”. ₂₁ ”modulation symbol b ₂ (k) multiplied by propagation path characteristic h ₂₁ to −h ₁₁ b ₂ (k), that is,“ 0 ”, and the first terminal apparatus T1 performs the multiplexing by the SPC. Interference due to modulation symbols to the second terminal apparatus T2 can be reduced.

Further, in the present embodiment, the modulation symbol b ₃ (k) for the third terminal apparatus T3 is also used by the SPC unit 351 of the transmission signal generation unit 312 as the modulation symbol a (n + 1) for the first terminal apparatus T1. , The modulation symbol b ₃ (k) to the third terminal apparatus T3 having the coefficient “h ^* ₂₁ / h ^* ₁₁ ” is multiplexed. Thereby, similarly to the case of the modulation symbol b ₂ (k) to the second terminal apparatus T2, the first terminal apparatus T1 reduces interference due to the modulation symbol to the third terminal apparatus T3 multiplexed by SPC. be able to.

  FIG. 7 is a schematic block diagram illustrating a configuration of the modulation symbol generation unit 313 in the present embodiment. The modulation symbol generation unit 313 includes an encoding unit 361 and a modulation unit 362. Note that the modulation symbol generation units 323 and 333 have the same configuration and will not be described. The encoding unit 361 performs error correction encoding on the input information bits using a turbo code, a convolutional code, an LDPC (Low Density Parity Check) code, and the like. The modulation unit 362 modulates the encoded bits input from the encoding unit 361, generates a modulation symbol, and outputs it. As a modulation method at this time, QPSK, 16QAM (16 Quadrature Amplitude Modulation), 64QAM (64 Quadrature Amplitude Modulation), or the like is used.

  FIG. 8 is a schematic block diagram illustrating the configuration of the terminal device 100 according to the present embodiment. The second terminal device T2 and the third terminal device T3 in FIG. The terminal device 100 includes a radio reception unit 101, a GI removal unit 102, an FFT (Fast Fourier Transform) unit 103, an STBC restoration unit 104, a channel estimation unit 105, a first data detection unit 106, and a replica generation unit 107. A cancellation unit 108, a second data detection unit 109, an STBC information detection unit 110, a pattern information detection unit 111, and an antenna 112.

  The radio reception unit 101 receives a radio signal transmitted from the base station device 300 (antenna 311 or antenna 321) using the antenna 112, and converts the reception signal down-converted from a radio frequency to a baseband frequency, as a GI removal unit 102. The STBC information detection unit 110 and the pattern information detection unit 111 are input. The GI removal unit 102 removes the guard interval from the OFDM signal in the received signal, extracts the signal in the FFT section, and inputs the signal to the FFT unit 103. FFT section 103 performs fast Fourier transform on the signal in the FFT interval received from GI removal section 102 and inputs the signal after fast Fourier transform to STBC restoration section 104 and channel estimation section 105. The STBC information detection unit 110 detects STBC information from the input received signal and inputs the STBC information to the STBC restoration unit 104. The pattern information detection unit 111 detects pattern information from the input received signal and inputs the pattern information to the STBC restoration unit 104.

  The channel estimation unit 105 estimates the channel state (frequency response) from the antenna 311 or 321 to the terminal device 100 based on the signal input from the FFT unit 103, and the first data detection unit 106 and the replica generation unit 107. The channel state estimation value (channel estimation value) is input to the second data detection unit 109. Note that if the terminal device 100 is the second terminal device T2, only the signal from the antenna 311 is received, and therefore the channel estimation unit 105 estimates the channel state from the antenna 311. Similarly, since the third terminal apparatus T3 receives only the signal from the antenna 321, the channel estimation unit 105 estimates the channel state from the antenna 321.

The STBC restoration unit (block code restoration unit) 104, when the STBC information input from the STBC information detection unit 110 is information indicating that the base station apparatus 300 has performed STBC on the transmission signal, the pattern information detection unit 111. STBC restoration is performed based on the pattern information input from.
The first data detection unit 106 detects an information bit for the first terminal device. The second data detection unit 109 detects information bits for the terminal device 100. Details of the first data detection unit 106 and the second data detection unit 109 will be described later.

  When the pattern information includes information indicating that the processing according to the first pattern of Expression (1) has been performed, the STBC restoration unit 104 performs the signals r (n) and r (n + 1) after the fast Fourier transform. On the other hand, the processing shown by the following equation (8), that is, STBC restoration corresponding to the first pattern is performed.

  In addition, when the pattern information includes information indicating that the process according to the second pattern of the expression (1) is performed, the STBC restoration unit 104 performs processing on the received signals r (n) and r (n + 1). Then, the process shown by the following equation (9), that is, STBC restoration corresponding to the second pattern is performed.

Finally, the STBC restoration unit 104 inputs the restored signal to the first data detection unit 106 and the cancellation unit 108. The first data detection unit 106 uses s ^ '(n) and s ^' (n + 1), which are the results of the STBC restoration, as modulation symbols s (n) and s (n + 1) to the first terminal apparatus T1, respectively. to, from the antenna 311 on the assumption that the propagation path characteristic _{h 12} or antenna 321 of the second terminal device T2 in which the propagation path characteristic _{h 23} of the third terminal device T3 is applied, the first terminal device T1 Detect signal to.

The replica generation unit 107 generates a replica (duplicate) of the modulation signal to the first terminal device T1 based on the signal to the first terminal device T1 detected by the first data detection unit 106, and the cancellation unit 108 To enter.
The cancel unit 108 subtracts the replica of the modulation signal to the first terminal apparatus T1 from the signal input from the STBC restoration unit 104. Thereby, the modulated signal to the second terminal device T2 or the third terminal device T3, that is, the terminal device 100 is extracted. The cancel unit 108 inputs a modulation signal to the terminal device 100 to the second data detection unit 109.

In the processing in the replica generation unit 107 and the cancellation unit 108, the signal to the first terminal device T1 is regarded as an interference signal, and the signal to the first terminal device T1 is first detected first. The process of canceling the interference signal by creating a replica of the signal to T1 and subtracting it from the received signal and extracting the signal to the terminal device 100 is performed. This is processing based on the same principle as a decision feedback equalizer for intersymbol interference suppression and inter-stream interference suppression.
The second data detection unit 109 performs channel compensation on the signal restored based on the channel estimation value, performs demodulation and error correction decoding, and detects a signal to the terminal apparatus 100.

  Here, details of the first data detection unit 106 and the second data detection unit 109 will be described. FIG. 9 is a schematic block diagram showing the configuration of the first data detection unit 106. The first data detection unit 106 includes a channel compensation unit 121, a demodulation unit 122, and a decoding unit 123. Channel compensation section 121 performs channel compensation on the input modulation symbol based on the channel estimation value, and inputs the modulated symbol after channel compensation to demodulation section 122. Demodulation section 122 demodulates the modulated symbols after channel compensation according to the modulation scheme by modulation symbol generation section 333, and inputs the demodulation results to decoding section 123. The decoding unit 123 performs error correction decoding corresponding to the error correction code by the modulation symbol generation unit 333 on the demodulated result, detects information bits to the terminal device 100, and outputs the detected information bits .

  Similar to the first data detection unit 106, the second data detection unit 109 includes a channel compensation unit 121, a demodulation unit 122, and a decoding unit 123. The modulation method in the demodulation processing of the demodulation unit 122, and the decoding unit The error correction code in the error correction decoding process 123 is different from that of the first data detection unit 106. If the terminal device 100 is the second terminal device T2, the demodulation unit 122 and the decoding unit 123 of the second data detection unit 109 perform processing according to the modulation symbol generation unit 313, and the terminal device 100 In the case of the third terminal device T3, the demodulation unit 122 and the decoding unit 123 of the second data detection unit 109 perform processing according to the modulation symbol generation unit 323.

Next, the calculation contents from the STBC restoration unit 104 to the cancellation unit 108 will be described using mathematical expressions.
The SPC signal s (n) that is the output of the SPC unit 351 of the base station apparatus 300 includes a modulation symbol for the first terminal apparatus T1 and a modulation symbol for the second terminal apparatus T2 or the third terminal apparatus T3. It is added and is expressed as in equation (10).

Here, a (n) is a modulation symbol that is modulated by the above-described modulation scheme (QPSK, 16QAM, 64QAM, etc.) after the information bits for the first terminal apparatus T1 are error correction encoded. b (n) is a modulation symbol modulated by the above-described modulation scheme after the information bits for the second terminal apparatus T2 or the third terminal apparatus T3 are error-correction coded.
Now, considering communication from the first antenna A1 (antenna 311) to the second terminal apparatus T2, the signal s ^ '(n) that has been STBC restored by the STBC restoration unit 104 of the second terminal apparatus T2 is: It can be expressed by equation (11).

The channel compensation unit 121 of the first data detection unit 106 applies the inverse characteristic of the propagation path to the STBC reconstructed signal s ′ ′ (n) based on the channel estimation value, thereby obtaining the equation (12). The modulation symbol s (n) represented by

The demodulator 122 of the first data detector 106 demodulates the first term on the right-hand side of equation (12) as a desired signal and the remaining two terms as noise, and further the decoder 123 converts the demodulated bits into demodulated bits. On the other hand, error correction decoding is performed together with other bits in the coding block. As described above, in SPC, a (n) has a larger power than b (n). Therefore, the demodulation unit 122 of the first data detection unit 106 can detect a (n) by performing demodulation / error correction decoding with b (n) regarded as noise.

The replica generation unit 107 converts the information bits for the first terminal apparatus T1 as a result of the error correction decoding process by the decoding unit 123 of the first data detection unit 106 again into the modulation symbol a (n), and further performs channel estimation. by multiplying the values _{h 12,} calculates the _h 12 a (n). As a result, only the component corresponding to the first term on the right side of equation (11), that is, h ₁₂ a (n) can be extracted.

The cancel unit 108 subtracts this h ₁₂ a (n) from the STBC reconstructed signal s ′ ′ (n), that is, the expression (11). As a result, it is possible to obtain a modulation symbol component h ₁₂ b (n) + η (n) to the second terminal apparatus T2 by removing the interference received from the signal to the first terminal apparatus T1 from the STBC reconstructed signal. it can.
Next, the second data detection unit 109 performs channel compensation on the component of the modulation symbol for the second terminal apparatus T2 based on the channel estimation value, and further performs demodulation and error correction decoding, and then to the second terminal apparatus T2. Are detected and output.

  In addition, when the second terminal apparatus T2 cannot detect STBC information indicating that STBC encoding is performed on a signal for the first terminal apparatus T1, the STBC restoration unit 104 does not perform any processing. That is, the input r (n) to the STBC restoration unit 104 and the output s ^ '(n) are exactly the same. Thereby, even if the signal to the first terminal apparatus T1 is not encoded by STBC, the signal for the second terminal apparatus T2 multiplexed by SPC with respect to the signal for the first terminal apparatus T1. Can be detected. The above process is the same in the third terminal device T3.

  FIG. 10 is a schematic block diagram illustrating the configuration of the terminal device 200. The first terminal device T1 in FIG. 1 has the configuration of the terminal device 200. The terminal apparatus 200 receives signals from the antenna 311 and the antenna 321 of the base station apparatus 300 and performs STBC combining. The terminal device 200 includes an antenna 201, a radio reception unit 202, a GI removal unit 203, an FFT unit 204, an STBC synthesis unit 205, a channel estimation unit 206, a data detection unit 207, a channel information generation unit 208, and a radio transmission unit 209. .

  Radio receiving section 202 receives the radio signal transmitted from base station apparatus 300 using antenna 201 and inputs the received signal down-converted from the radio frequency to the baseband frequency to GI removing section 203. The GI removing unit 203 removes the guard interval from the received signal, extracts an FFT section signal, and inputs the signal to the FFT unit 204. The FFT unit 204 performs fast Fourier transform on the signal in the FFT interval, and inputs the fast Fourier transformed signal to the STBC synthesis unit 205 and the channel estimation unit 206.

The channel estimation unit 206 estimates the channel state h ₁₁ of the terminal device 200 from the antenna 311 of the base station device 300 and the channel state h ₂₁ of the terminal device 200 from the antenna 321 based on the signal input from the FFT unit 204. The channel estimation values (h ₁₁ , h ₂₁ ) are input to the STBC synthesis unit 205, the data detection unit 207, and the channel information generation unit 208. The STBC synthesis unit (block code synthesis unit) 205 performs STBC synthesis represented by equation (3) based on the two channel estimation values input from the channel estimation unit 206. The STBC synthesis unit 205 inputs the synthesized signal to the data detection unit 207.

The data detection unit 207 has the same configuration as the first data detection unit 106 shown in FIG. The data detection unit 207 performs channel compensation on the combined signal based on the channel estimation value, further performs demodulation and error correction decoding, and detects and outputs information bits to the terminal device 200. At this time, the combined modulation symbol has a propagation path gain represented by the magnitude of | h ₁₁ | ² + | h ₂₁ | ² corresponding to | h ₁ | ² + | h ₂ | ² in Equation (3). As a result, channel compensation is performed.

The channel information generation unit 208 bases information indicating the channel state h ₁₁ from the antenna 311 of the base station device 300 to the terminal device 200 and the channel state h ₂₁ from the antenna 321 to the terminal device 200 estimated by the channel estimation unit 206. Channel information for reporting to the station device 300 is generated and input to the wireless transmission unit 209. The channel information is information related to the channel state h ₁₁ from the antenna 311 to the first terminal device T1 and the channel state h ₂₁ from the antenna 321 to the first terminal device T1, and the channel state h ₁₁ and the channel information It may be information representing the state h _{21 or} information representing the ratio (h ₁₁ / h ₂₁ or h ₂₁ / h ₁₁ ). Radio transmission section 209 wirelessly transmits channel information to base station apparatus 300 through antenna 201.

Here, processing in the STBC synthesis unit 205 will be described using mathematical expressions.
The radio reception unit 202 through the antenna 201 simultaneously receives the signal from the antenna 311 of the base station apparatus 300 and the signal from the antenna 321 through the respective propagation paths (channel states are h ₁₁ and h ₂₁ ). Here, assuming that the received signals at time n and time n + 1 at terminal device 200 are r (n) and r (n + 1), the signals of equations (6) and (7) transmitted by base station device 300 are received. The received signals r (n) and r (n + 1) are expressed by the equation (13), and the modulation symbols for the second terminal device T2 and the third terminal device T3 that have been SPC disappear.

Here, η (n) is noise at time n. Since the STBC combining unit 205 performs the STBC combining process shown in the equation (3) on the received signal, the STBC combining unit 205 can obtain the modulation symbol for the terminal apparatus 200 in the form of maximum ratio combining.

  As described above, in this embodiment, the base station apparatus 300 transmits pattern information indicating a pattern used to generate a signal to be transmitted from the antenna from each antenna. Is applied to the terminal device T1, the signal to the first terminal device T1 and the signals to the second terminal device T2 and the third terminal device T3 are applied to the same radio by applying SPC. Even if it multiplexes with a resource, 2nd terminal device T2 and 3rd terminal device T3 detect the signal to 1st terminal device T1 based on this pattern information, and also detect the signal to a self-terminal device. Will be able to. In addition, a signal for canceling the signal received by the first terminal device T1 is transmitted from the other antenna to the second terminal device T2 or the third terminal device T3 multiplexed by applying SPC by one antenna. By doing so, it is possible to eliminate the influence of SPC in the first terminal device T1 that performs communication by STBC. Thereby, the utilization efficiency of a radio | wireless resource can be improved.

In the present embodiment, the data sent to the first terminal device T1 is data unique to the first terminal device T1, but the data sent to the first terminal device T1 is broadcast. May be the data. Even for broadcast data, the configurations of the base station device 300 and the terminal devices 100 and 200 are the same as those of the present embodiment.
In the present embodiment, the first terminal apparatus T1 uses STBC in order to obtain a transmission diversity gain. However, other block codes such as SFBC may be used instead of STBC. The portion described as time n and time n + 1 in equation (1) and the like may be replaced with frequency (subcarrier) n and frequency n + 1.

  In the present embodiment, the first terminal device T1 has the configuration of the terminal device 200, and the second terminal device T2 and the third terminal device T3 have been described as having the configuration of the terminal device 100. Any or all of the first terminal device T1, the second terminal device T2, and the third terminal device T3 may have the configurations of the terminal device 100 and the terminal device 200. In this case, it is preferable that the antenna, the radio reception unit, the GI removal unit, the FFT unit, the channel estimation unit, the data detection unit, and the like are shared.

(Second Embodiment)
The second embodiment of the present invention will be described below with reference to the drawings. The wireless communication system according to the present embodiment includes a base station device 300a, a terminal device 100a, and a terminal device 200. The base station apparatus 300a according to this embodiment is different from the base station apparatus 300 of FIG. 2 in that transmission signal generation units 312a and 322a are provided instead of the transmission signal generation units 312 and 322.

  FIG. 11 is a schematic block diagram illustrating a configuration of the transmission signal generation unit 312a of the base station device 300a in the present embodiment. The transmission signal generation unit 312a includes an SPC unit 351, an STBC unit 352a, an IFFT unit 353, a GI insertion unit 354, a pattern information generation unit 355, an STBC information generation unit 356, and a wireless transmission unit 357. The transmission signal generation unit 322a has the same configuration as the transmission signal generation unit 312a. The transmission signal generation unit 312a is different from the transmission signal generation unit 312 in that it includes an STBC unit 352a instead of the STBC unit 352. In the figure, the same reference numerals (351, 353 to 357) are assigned to portions corresponding to the respective portions in FIG. Note that the STBC unit 352a is different from the STBC unit 352 in that it performs processing using the third pattern represented by the equation (14) instead of the first pattern of the equation (1). The transmission signal generation unit 322a has the same configuration as the transmission signal generation unit 312a, but the STBC unit 352a of the transmission signal generation unit 322a uses the fourth pattern instead of the third pattern of the equation (14). The difference is that the processing used is performed.

  Even if the STBC encoding is performed with the third pattern or the fourth pattern as shown in the equation (14), the STBC synthesis shown in the left two sides of the equation (3) is performed, so that the first embodiment The same effect can be obtained. Furthermore, when using the third pattern of Equation (14), the STBC unit 352a outputs the input symbol as it is without processing. In the situation as shown in FIG. 1, when a signal processed by the third pattern of the equation (14) is transmitted from the first antenna A1, the second terminal device T2 receives the signal. At this time, the second terminal apparatus T2 can detect the signal to the first terminal apparatus T1 without performing the STBC restoration process, and then outputs the signal to the second terminal apparatus T2 itself. It can be taken out. Here, the base station device 300a must send the STBC information and the pattern information to the third terminal device T3 as in the first embodiment.

  The first terminal device T1 in the present embodiment has the configuration of the terminal device 200 shown in FIG. Even if the STBC unit 352a of the base station device 300a performs STBC using the equation (14), the STBC synthesis unit 205 of the terminal device 200 performs the processing written in the left two sides of the equation (3). As in the first embodiment, the same signal as that on the rightmost side of the equation (3) can be obtained.

  FIG. 12 is a schematic block diagram showing the configuration of the terminal device 100a in the present embodiment. The second terminal device T2 and the third terminal device T3 in the present embodiment have the configuration of the terminal device 100a. The terminal device 100a includes a radio reception unit 101, a GI removal unit 102, an FFT unit 103, an STBC restoration unit 104a, a channel estimation unit 105, a first data detection unit 106, a replica generation unit 107, a cancellation unit 108, and second data. It has a detection unit 109, an STBC information detection unit 110, a pattern information detection unit 111, and an antenna 112. The terminal device 100a is different from the terminal device 100 shown in FIG. 8 in that the terminal device 100a includes an STBC restoration unit 104a instead of the STBC restoration unit 104. In the figure, the same reference numerals (101 to 103, 105 to 112) are assigned to portions corresponding to the respective portions in FIG. 8, and description thereof is omitted.

  When the pattern information input from the pattern information detection unit 111 includes information indicating that the process according to the fourth pattern of Expression (14) has been performed, the STBC restoration unit 104a STBC restoration is performed by the process shown by the equation (15) using r (n) and r (n + 1).

  In addition, when the pattern information includes information indicating that the process according to the third pattern of Expression (14) is performed, the STBC restoration unit 104a performs the signal r (n), r (n) after the fast Fourier transform. (n + 1) is used to perform STBC restoration by the processing shown in equation (16), that is, the signals r (n) and r (n + 1) input from the FFT unit 103 are output as they are.

That is, the second terminal apparatus T2 can perform the SPC process on the assumption that STBC has not been performed. Accordingly, the second terminal device T2 is configured by removing the STBC restoration unit 104, the STBC information detection unit 110, and the pattern information detection unit 111 from the configuration of the terminal device 100 of FIG. 8, like the terminal device 400 shown in FIG. But you can.

  FIG. 13 is a schematic block diagram illustrating a configuration of the terminal device 400 according to the present embodiment. The terminal device 400 includes a radio reception unit 101, a GI removal unit 102, an FFT unit 103, a channel estimation unit 105, a first data detection unit 106, a replica generation unit 107, a cancellation unit 108, a second data detection unit 109, and An antenna 112 is included. In the figure, the same reference numerals (101 to 103, 105 to 109, 112) are assigned to portions corresponding to the respective portions in FIG. 8, and the description thereof is omitted.

As described above, also in this embodiment, the base station apparatus 300a transmits pattern information indicating a pattern used to generate a signal transmitted from the antenna from at least the second antenna. When communication is performed with respect to the first terminal device T1, SPC is applied, and signals to the first terminal device T1, and signals to the second terminal device T2 and the third terminal device T3 are applied. Can be multiplexed with the same radio resource, the third terminal apparatus T3 can detect the signal to the first terminal apparatus T1 and further detect the signal to the own terminal apparatus based on the pattern information. become able to. In addition, a signal for canceling the signal received by the first terminal device T1 is transmitted from the other antenna to the second terminal device T2 or the third terminal device T3 multiplexed by applying SPC by one antenna. By doing so, it is possible to eliminate the influence of SPC in the first terminal device T1 that performs communication by STBC. Thereby, the utilization efficiency of a radio | wireless resource can be improved.
Further, the STBC unit 352a performs STBC using the equation (14), so that the second terminal device T2 that receives the signal using the equation of the third pattern in the equation (14) receives the STBC information and Even without acquiring the pattern information, the signal to the first terminal apparatus T1 multiplexed by SPC can be separated and the signal to the first terminal apparatus T2 can be detected.

In the present embodiment, the data sent to the first terminal device T1 is data unique to the first terminal device T1, but the data sent to the first terminal device T1 is broadcast. May be the data. Even for broadcast data, the configurations of the base station device 300a and the terminal devices 100a and 200 are the same as those in the present embodiment.
In the present embodiment, the first terminal apparatus T1 uses STBC in order to obtain a transmission diversity gain. However, other block codes such as SFBC may be used instead of STBC. The portion described as time n and time n + 1 in equation (1) and the like may be replaced with frequency (subcarrier) n and frequency n + 1.

  In the present embodiment, the first terminal device T1 includes the configuration of the terminal device 200, the second terminal device T2 includes the configuration of the terminal device 400, and the third terminal device T3 includes the terminal device 100a. However, any one or all of the first terminal device T1, the second terminal device T2, and the third terminal device T3 are connected to the terminal device 100a, the terminal device 200, and the terminal device 400. A configuration may be provided. In this case, it is preferable that the antenna, the radio reception unit, the GI removal unit, the FFT unit, the channel estimation unit, the data detection unit, and the like are shared.

(Third embodiment)
The third embodiment of the present invention will be described below with reference to the drawings. The wireless communication system in the present embodiment includes a base station device 300b, a terminal device 100b, and a terminal device 200. In the first embodiment and the second embodiment, the base station apparatuses 300 and 300a perform STBC encoding after generating the SPC signal. In the base station apparatus 300b in the present embodiment, this The order of processing is reversed. The base station apparatus 300b according to the present embodiment is different from the base station apparatus 300 of FIG. 2 in that transmission signal generation units 312b and 322b are provided instead of the transmission signal generation units 312 and 322.

  FIG. 14 is a schematic block diagram illustrating a configuration of the transmission signal generation unit 312b of the base station device 300b in the present embodiment. The transmission signal generation unit 312b includes an STBC unit 352, an SPC unit 351b, an IFFT unit 353, a GI insertion unit 354, a pattern information generation unit 355, an STBC information generation unit 356, and a wireless transmission unit 357. The transmission signal generation unit 312b includes an SPC unit 351b instead of the SPC unit 351, and is different in that the connection order of the SPC unit 351b and the STBC unit 352 is opposite to that of the transmission signal generation unit 312. In the figure, the same reference numerals (352 to 357) are assigned to portions corresponding to the respective portions in FIG. The transmission signal generation unit 322b has the same configuration as the transmission signal generation unit 312b, but the STBC unit 352 of the transmission signal generation unit 322b uses the second pattern instead of the first pattern of the equation (1). The point which performs the process used differs from the coefficient which multiplies when SPC part 351b of transmission signal generation part 322b performs SPC.

  Taking the situation shown in FIG. 1 as an example, the operation of the transmission signal generator 312b will be described. First, the STBC unit 352 performs STBC coding on the modulation symbol for the first terminal apparatus T1 generated by the modulation symbol generation unit 333, based on the first pattern shown in Equation (1), and generates an STBC symbol. Next, SPC section 351b adds the modulation symbol for second terminal apparatus T2 or third terminal apparatus T3 and the STBC symbol for first terminal apparatus T1 to generate an SPC signal, which is input to IFFT section 353. To do. Thereafter, the operation is the same as that of the transmission signal generation unit 312.

Here, processing of the SPC unit 351b and the STBC unit 352 in the transmission signal generation unit 312b and the transmission signal generation unit 322b in the present embodiment will be described using mathematical expressions. The variable names in the mathematical formula are the same as those in the first embodiment. First, STBC section 352 of transmission signal generation section 312b performs STBC encoding on a (n) and a (n + 1) based on the first pattern of equation (1). Thereby, STBC symbols s ₁ ′ (n) and s ₁ ′ (n + 1) as shown in the equation (17) are obtained. The STBC unit 352 of the transmission signal generation unit 322b performs STBC encoding on a (n) and a (n + 1) based on the second pattern of Equation (1). As a result, STBC symbols s ₂ ′ (n) and s ₂ ′ (n + 1) as shown in the equation (18) are obtained.

Next, the SPC unit 351b of the transmission signal generation unit 312b applies the modulation symbol b ₂ (k) to the second terminal apparatus T2 with respect to the STBC symbol s ₁ ′ (n) as shown in Expression (17). In addition to multiplying the modulation symbol b ₃ (k) to the third terminal apparatus T3 by the coefficient −h ₁₁ / h ₂₁ , the result is added to the STBC symbol s ₁ ′ (n + 1) as shown in the equation (17). That is, the processing of the equation (19) is performed.

Similarly, the SPC unit 351b of the transmission signal generation unit 322b multiplies the modulation symbol b ₂ (k) for the second terminal apparatus T2 by the coefficient −h ₁₁ / h ₂₁ and then, as shown in the equation (18). In addition to the STBC symbol s ₂ ′ (n + 1), the modulation symbol b ₃ (k) to the third terminal apparatus T3 is added to the STBC symbol s ₂ ′ (n) as shown in the equation (18). That is, the processing of the formula (20) is performed.

In the present embodiment, the STBC symbol s ₁ ′ (n) obtained by STBC encoding the modulation symbol b ₂ (k) to the second terminal apparatus T2 by the SPC unit 351b of the transmission signal generation unit 312b with the first pattern is STBC encoded. In addition, the SPC unit 351b of the transmission signal generation unit 322b applies the modulation symbol b ₂ (k) multiplied by the coefficient “−h ₁₁ / h ₂₁ ” as shown in the equation (20) to the second pattern. And STBC symbols s ₂ ′ (n + 1) that have been STBC encoded. Since these are transmitted, the modulation symbol b ₂ (k) transmitted from the first antenna A1 by the transmission signal generation unit 312b has a coefficient “1”, and the transmission signal generation unit 322b transmits the second antenna A2 from the second antenna A2. modulation symbols _b 2 in the signal to be transmitted (k) is the coefficient _{"-h 11} / _{h 21",} and the modulation symbols _b 2 (k transmitted from the first antenna A1 by the transmission signal generating unit 312b ) At the same time and frequency.

When the first terminal device T1 receives these signals, the received signal becomes the sum of signals multiplied by the propagation path characteristics h ₁₁ and h ₂₁ from the transmission source antenna to the first terminal device T1, respectively. H ₁₁ b ₂ (k) obtained by multiplying the modulation symbol b ₂ (k) transmitted from the first antenna A 1 by the propagation path characteristic h ₁₁ and the coefficient transmitted from the second antenna A 2 are “−h ₁₁ / h”. ₂₁ ”modulation symbol b ₂ (k) multiplied by propagation path characteristic h ₂₁ to −h ₁₁ b ₂ (k), that is,“ 0 ”, and the first terminal apparatus T1 performs the multiplexing by the SPC. Interference due to modulation symbols to the second terminal apparatus T2 can be reduced.

Also, in the present embodiment, for the modulation symbol b ₃ (k) to the third terminal apparatus T3, the STBC symbol s ₁ ′ in which the SPC unit 351b of the transmission signal generation unit 312b is STBC-encoded with the first pattern. In (n + 1), the modulation symbol b ₃ (k) to the third terminal apparatus T3 having the coefficient “h ₂₁ / h ₁₁ ” is multiplexed. Thereby, similarly to the case of the modulation symbol b ₂ (k) to the second terminal apparatus T2, the first terminal apparatus T1 reduces interference due to the modulation symbol to the third terminal apparatus T3 multiplexed by SPC. be able to.

  FIG. 15 is a schematic block diagram showing the configuration of the terminal device 100b in the present embodiment. In the figure, the same reference numerals (101 to 112) are assigned to portions corresponding to the respective portions in FIG. 8, and detailed description thereof is omitted. In the present embodiment, the second terminal device T2 and the third terminal device T3 in the situation as shown in FIG. 1 have the configuration of the terminal device 100b. Similarly to the terminal device 100 in FIG. 8, the terminal device 100b includes a radio reception unit 101, a GI removal unit 102, an FFT unit 103, an STBC restoration unit 104, a channel estimation unit 105, a first data detection unit 106, and a replica generation unit. 107, a cancel unit 108, a second data detection unit 109, an STBC information detection unit 110, a pattern information detection unit 111, and an antenna 112.

However, the terminal device 100b outputs only the first data detection unit 106 without inputting the output of the STBC restoration unit 104 to the cancellation unit 108, and outputs the output of the FFT unit 103 to the STBC restoration unit 104, the channel estimation unit 105, and In addition to the terminal device 100, the input to the cancel unit 108 is different. That is, the cancel unit 108 subtracts the signal component h ₁₂ a (n) for the first terminal apparatus T1 from the received signal r (n), not from the output s ^ ′ (n) of the STBC restoration unit 104. This is because FIG. 14, that is, the base station apparatus 300b performs SPC after STBC encoding.

Thereby, for example, the cancellation unit 108 of the second terminal apparatus T2 obtains the modulation symbol h ₁₂ b (n) + η (n) for the second terminal apparatus T2 excluding the interference received from the signal for the first terminal apparatus T1. Can be obtained. This process is the same in the third terminal device T3.

In the present embodiment, the first terminal device T1 in the situation shown in FIG. 1 has the configuration of the terminal device 200 shown in FIG. Here, processing in the STBC synthesis unit 205 in the present embodiment will be described using mathematical expressions. The variables in the formula are the same as those in the first embodiment. Radio receiving section 202 receives simultaneously, through antenna 201, the signal from antenna 311 of base station apparatus 300b and the signal from antenna 321 that have passed through their respective propagation paths (channel states are h ₁₁ and h ₂₁ ). .

When the signals of the equations (19) and (20) transmitted by the base station device 300b are received, the signal resulting from the fast Fourier transform of the received signal by the FFT unit 204 is expressed by the following equation (21): The modulation symbols for the second terminal apparatus T2 and the third terminal apparatus T3 that have been subjected to SPC as in the first embodiment disappear.

If STBC synthesis of equation (3) is performed on the signals r (n) and r (n + 1) resulting from the fast Fourier transform, modulation symbols for the first terminal device can be obtained in the form of maximum ratio synthesis. It is done.

  As described above, also in the present embodiment, as in the first embodiment, the base station apparatus 300b transmits pattern information indicating a pattern used for generating a signal transmitted from the antenna from each antenna. When the communication by STBC is performed to the first terminal device T1 at the multi-site, the signal to the first terminal device T1, the second terminal device T2, and the third terminal are applied by applying SPC. Even if the signal to the terminal device T3 is multiplexed with the same radio resource, the second terminal device T2 and the third terminal device T3 detect the signal to the first terminal device T1 based on the pattern information. Furthermore, it becomes possible to detect a signal to the terminal device itself.

  In addition, a signal for canceling the signal received by the first terminal device T1 is transmitted from the other antenna to the second terminal device T2 or the third terminal device T3 multiplexed by applying SPC by one antenna. By doing so, it is possible to eliminate the influence of SPC in the first terminal device T1 that performs communication by STBC. Thereby, the utilization efficiency of a radio | wireless resource can be improved.

  In the present embodiment, the data sent to the first terminal device T1 is data unique to the first terminal device T1, but the data sent to the first terminal device T1 is broadcast. May be the data. Even for broadcast data, the configurations of the base station device 300b and the terminal devices 100b and 200 are the same as those in the present embodiment.

  In the present embodiment, the first terminal apparatus T1 uses STBC in order to obtain a transmission diversity gain. However, other block codes such as SFBC may be used instead of STBC. The portion described as time n and time n + 1 in equation (1) and the like may be replaced with frequency (subcarrier) n and frequency n + 1.

In the present embodiment, the first terminal device T1 has the configuration of the terminal device 200, and the second terminal device T2 and the third terminal device T3 have been described as having the configuration of the terminal device 100b. Any or all of the first terminal device T1, the second terminal device T2, and the third terminal device T3 may include the configurations of the terminal device 100b and the terminal device 200. In this case, it is preferable that the antenna, the radio reception unit, the GI removal unit, the FFT unit, the channel estimation unit, the data detection unit, and the like are shared.

Moreover, in each said embodiment, it demonstrated using the structure by which two antennas are connected or included in one base station apparatus. However, each antenna is connected to or included in a different base station apparatus and controlled, and is transmitted between the base station apparatuses to the first terminal apparatus T1, the second terminal apparatus T2, and the third terminal apparatus T3. The configuration may be such that data and channel information are notified or shared, and one or both of the two antennas may be a relay station device that relays wireless communication between the base station device and the terminal device. Further, the two antennas form different communicable areas (cells or sectors) including a partially overlapping area. At this time, the two antennas do not necessarily have to be geographically separated, for example, one base station It may consist of an antenna or a set of antennas that form different cells or sectors under the device.

  Also, modulation symbol generation sections 313, 323, and 333, channel information detection section 343 in FIG. 2, and SPC section 351, STBC section 352, IFFT section 353, GI insertion section 354, pattern information generation section 355, and STBC information in FIG. 356, GI removal unit 102, FFT unit 103, STBC restoration unit 104, channel estimation unit 105, first data detection unit 106, replica generation unit 107, cancellation unit 108, second data detection unit in FIG. 109, STBC information detection unit 110, pattern information detection unit 111, and GI removal unit 203, FFT unit 204, STBC synthesis unit 205, channel estimation unit 206, data detection unit 207, channel information generation unit 208 in FIG. 11 SPC unit 351, STBC unit 352a IFFT section 353, GI insertion section 354, pattern information generation section 355, STBC information generation section 356, and GI removal section 102, FFT section 103, STBC restoration section 104a, channel estimation section 105, first data detection section in FIG. 106, replica generation unit 107, cancellation unit 108, second data detection unit 109, STBC information detection unit 110, pattern information detection unit 111, and GI removal unit 102, FFT unit 103, channel estimation unit 105 in FIG. 1 data detection unit 106, replica generation unit 107, cancellation unit 108, second data detection unit 109, and SPC unit 351b, STBC unit 352, IFFT unit 353, GI insertion unit 354, pattern information generation unit 355 in FIG. , STBC information generation unit 356, and FIG. GI removal section 102, FFT section 103, STBC restoration section 104, channel estimation section 105, first data detection section 106, replica generation section 107, cancellation section 108, second data detection section 109, STBC information detection section 110 The program for realizing the function of the pattern information detection unit 111 is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into the computer system and executed to execute the processing of each unit. You may go. Each of these units may be realized by dedicated hardware. Here, the “computer system” includes an OS and hardware such as peripheral devices.

  The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory in a computer system serving as a server or a client in that case, and a program that holds a program for a certain period of time are also included. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes design changes and the like within a scope not departing from the gist of the present invention.

  The present invention is suitable for use in a mobile communication system using a mobile phone device as a terminal device, but is not limited thereto.

300, 300a, 300b ... base station apparatuses 311, 321, 341 ... antennas 312, 312 a, 312 b, 322 ... transmission signal generation unit 342 ... radio reception units 313, 323, 333 ... modulation symbol generation unit 343 ... channel information generation unit 351 , 351b ... SPC section 352, 352a ... STBC section 353 ... IFFT section 354 ... GI insertion section 355 ... pattern information generation section 356 ... STBC information generation section 357 ... wireless transmission section 361 ... encoding section 362 ... modulation section 100, 100a, DESCRIPTION OF SYMBOLS 100b, 200, 400 ... Terminal device 101 ... Radio | wireless receiving part 102 ... GI removal part 103 ... FFT part 104, 104a ... STBC restoration part 105 ... Channel estimation part 106 ... 1st data detection part 107 ... Replica production | generation part 108 ... Cancel Unit 109 ... second data detection unit 1 DESCRIPTION OF SYMBOLS 10 ... STBC information detection part 111 ... Pattern information detection part 112 ... Antenna 121 ... Channel compensation part 122 ... Demodulation part 123 ... Decoding part 201 ... Antenna 202 ... Radio | wireless reception part 203 ... GI removal part 204 ... FFT part 205 ... STBC synthetic | combination part 206 ... Channel estimation unit 207 ... Data detection unit 208 ... Channel information generation unit 209 ... Wireless transmission unit

Claims (10)

A modulation symbol obtained by combining the first modulation symbol transmitted to the first terminal apparatus and the second modulation symbol transmitted to the second terminal apparatus is used as one of code patterns constituting a block code. A first transmission signal generation unit that encodes and generates a first transmission signal;
A modulation symbol obtained by synthesizing the first modulation symbol and the second modulation symbol multiplied by a coefficient is encoded using another one of the code patterns constituting the block code, and second transmission is performed. A second transmission signal generator for generating a signal;
A first antenna for transmitting the first transmission signal;
And a second antenna that transmits the second transmission signal simultaneously with the transmission of the first transmission signal from the first antenna. The first modulation symbol to be transmitted to the first terminal apparatus is encoded using one of the code patterns constituting the block code, and then combined with the second modulation symbol to be transmitted to the second terminal apparatus A first transmission signal generation unit that generates a first transmission signal;
The first modulation symbol is encoded using the other one of the code patterns constituting the block code, and then combined with the second modulation symbol multiplied by a coefficient to generate a second transmission signal. A second transmission signal generator for generating
A first antenna for transmitting the first transmission signal;
And a second antenna that transmits the second transmission signal simultaneously with the transmission of the first transmission signal from the first antenna. The coefficient multiplied by the second modulation symbol in the second transmission signal generation unit is configured to remove interference that the second modulation symbol gives to reception of the first modulation symbol in the first terminal apparatus. The communication device according to claim 1, wherein the communication device is a large coefficient. Furthermore, a first channel state from the first antenna to the first terminal device and a second channel state from the second antenna to the first terminal device are defined as the first terminal device. A channel information detection unit for receiving from
The coefficient multiplied by the second modulation symbol by the second transmission signal generation unit multiplies the value obtained by dividing the complex gain indicated by the first channel state by the complex gain indicated by the second channel state. The communication device according to claim 3, wherein the communication device is a predetermined value. Furthermore, a pattern information generating unit that generates pattern information indicating a code pattern used when generating the first transmission signal among the code patterns constituting the block code,
The communication apparatus according to claim 1, wherein the pattern information is transmitted from the first antenna. A terminal device that receives a signal transmitted from either one of the signals transmitted from a communication device using a first antenna and a second antenna,
A wireless receiver that receives a signal transmitted by the communication device;
From said received signal, a portion constituting the block code, and the pattern information detector for detecting the pattern information of a portion corresponding to one of said antenna,
A block code restoration unit that performs a block code restoration process on the received signal based on the detected pattern information;
A first data detection unit for detecting a signal to another terminal device from a result of the restoration process of the block code;
A cancellation unit that removes interference due to the signal to the other terminal device with respect to the received signal using the detected signal to the other terminal device;
A terminal device comprising: a second data detection unit that detects a signal to the terminal device from a result of removing the interference. A transmission method in a communication device that transmits a signal to a first terminal device and a second terminal device using a first antenna and a second antenna,
The communication apparatus combines a first modulation symbol transmitted to the first terminal apparatus and a modulation symbol obtained by combining the second modulation symbol transmitted to the second terminal apparatus with a code pattern constituting a block code. A first step of encoding with one of them to generate a first transmission signal;
The communication apparatus encodes a modulation symbol obtained by synthesizing the first modulation symbol and the second modulation symbol multiplied by a coefficient using another one of code patterns constituting the block code. A second process of generating a second transmission signal
And a third step of simultaneously transmitting the first transmission signal from the first antenna and the second transmission signal from the second antenna. A transmission method in a communication device that transmits a signal to a first terminal device and a second terminal device using a first antenna and a second antenna,
The communication apparatus encodes the first modulation symbol to be transmitted to the first terminal apparatus using one of the code patterns constituting the block code, and then transmits the first modulation symbol to the second terminal apparatus. A first step of generating a first transmission signal by combining with a modulation symbol of
The communication apparatus encodes the first modulation symbol using another one of code patterns constituting the block code, and then combines the first modulation symbol with the second modulation symbol multiplied by a coefficient. A second process of generating a second transmission signal;
And a third step of simultaneously transmitting the first transmission signal from the first antenna and the second transmission signal from the second antenna. A reception method in a terminal device that receives a signal transmitted from either one of signals transmitted from a communication device using a first antenna and a second antenna,
A first process in which the terminal device receives a signal transmitted by the communication device;
The terminal apparatus, from the signal received, the second step a portion constituting the block code, to detect the pattern information indicating a portion corresponding to one of said antenna,
A third process in which the terminal device performs a block code restoration process on the received signal based on the detected pattern information;
A fourth process in which the terminal device detects a signal to another terminal device from a result of the restoration process of the block code;
A fifth step in which the terminal device uses the detected signal to the other terminal device to remove interference caused by the signal to the other terminal device with respect to the received signal;
A reception method comprising: a sixth process in which the terminal device detects a signal to the terminal device from a result of removing the interference. Applying multi-site block coding for transmitting a block-coded signal from the first antenna and the second antenna to the first terminal device, and at the same time, a signal transmitted from the first antenna to the second terminal device A communication system that applies superposition coding in which a plurality of signals are multiplexed,
A modulation symbol obtained by combining a first modulation symbol to be transmitted to the first terminal apparatus and a second modulation symbol to be transmitted to the second terminal apparatus is used as one of code patterns constituting a block code. A first transmission signal generation unit that encodes the first transmission signal using the first transmission signal;
A modulation symbol obtained by synthesizing the first modulation symbol and the second modulation symbol multiplied by a coefficient is encoded using another one of the code patterns constituting the block code, and second transmission is performed. A second transmission signal generator for generating a signal;
A first antenna for transmitting the first transmission signal;
A communication system comprising: a second antenna that transmits the second transmission signal simultaneously with transmission of the first transmission signal from the first antenna.