JP2018148575A - Communication device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To demodulate a TMCC carrier signal on a transmission path under unfavorable conditions.SOLUTION: A communication device includes: a transmission device for transmitting modulation data signals different from each other via antennas in two different systems at the same frequency by OFDM system; and a reception device for receiving, via each of antennas in two different systems, and demodulating both pieces of modulation data different from each other transmitted by the transmission device. When a plurality of TMCC carriers are superposed on an OFDM frame to be transmitted, the communication device gives different phase rotation by the group of a plurality of antennas.SELECTED DRAWING: Figure 11D

Description

  The present invention relates to a MIMO (Multiple Input Multiple Output) communication apparatus in which, for example, a communication system provided with a plurality of transmission / reception antennas is an OFDM (Orthogonal Frequency Division Multiplexing) system.

  MIMO transmission uses a plurality of transmission antennas to transmit radio signals at the same frequency. In the transmission path, data transmitted from each antenna is multiplexed in the space. A plurality of receiving antennas are used to receive the signal.

  Equipment for transmitting broadcast material video is called FPU (Field Pick Up) in Japan. Data transmitted by the FPU is OFDM-modulated by a transmission control unit, and video, audio and other data, pilot signals (CP: Continuous Pilot), transmission control information (TMCC: Transmission and Multiplexing Configuration and Control), spare data ( AUX) is configured as one OFDM symbol.

  Data is encoded differently for each system, and TMCC is the same data regardless of the system.

  Also, the phase of the pilot signal of the first system is left as it is and the phase of the pilot signal of the second system is inverted for each symbol so that the pilot signals of the symbols constituting the MIMO OFDM frame are orthogonal to each other. Is modulated (see Patent Document 1).

JP 2010-161585 A

  If the TMCC signals are the same signal, the phase relationship between the systems may be reversed if the conditions of the transmission path are poor after being transmitted from a plurality of antennas to the transmission path.

  In the unfavorable transmission path, the spatially synthesized signals of a plurality of systems are in a state where the TMCC carrier is canceled when viewed from the receiver side, and the signal-to-noise ratio of the TMCC carrier is greatly deteriorated.

  As a result, the receiver cannot demodulate the TMCC carrier signal, and information based on the TMCC carrier including the transmission control information is not known, so that normal data transmission is impossible.

  The present invention has been made in view of such a conventional situation, and an object thereof is to demodulate a TMCC carrier signal in an unfavorable transmission path.

  In order to achieve the above object, the present invention relates to both a transmitting apparatus that transmits different modulated data signals from two different antennas at the same frequency by the OFDM method, and different modulated data transmitted from the transmitting apparatus. In a communication apparatus including a receiving apparatus that receives and demodulates signals by two different antennas, the transmitting apparatus transmits different modulated data signals for each of the two different systems with respect to video and audio data input from the interface unit. A transmission control unit that generates and outputs a signal, a transmission high-frequency unit provided for each of two different systems that amplify and output a signal from the transmission control unit, and two different signals that transmit a signal from the transmission high-frequency unit The transmission control unit includes a plurality of TMCC keys in the OFDM frame. When superimposing the rear, all the phases of a plurality of TMCC carriers are superimposed and output with respect to the modulated data signal of the first system which is one of the two different systems without phase rotation. The phase difference of 360 ° divided by a natural number of 2 or more is sequentially added to the modulated data signal of the second system, which is the other of the two, and superimposed and output. From two different systems of antennas that receive both different modulated data transmitted from the apparatus, and reception high-frequency units respectively provided for two different systems that perform frequency conversion on signals received by the antennas, A reception control unit that performs demodulation processing of the input signal, and the reception control unit performs TMCC carrier by complex addition of a plurality of TMCC carriers obtained by differential demodulation. To mitigate the demodulation error.

  Furthermore, the present invention provides a transmitter that transmits different modulated data signals from a plurality of antennas of different N (N = 2 or more natural numbers) at the same frequency by the OFDM method, and different modulated data transmitted from the transmitter. In a communication device comprising a receiving device that receives and demodulates all of the signals with a plurality of different antennas, the transmitting device is provided for each of a plurality of N different systems for video and audio data input from the interface unit. A transmission control unit that generates and outputs different modulation data signals, a transmission high-frequency unit provided for each of a plurality of N different systems that amplify and output a signal from the transmission control unit, and a signal from the transmission high-frequency unit And a plurality of N antennas provided for each of the different systems to transmit, and the transmission control unit includes a plurality of OFDM frames. When superimposing the TMCC carriers, among the plurality of N different systems, the phases of the plurality of TMCC carriers are superimposed and output with respect to the modulated data signal of the first system without phase rotation. Among the different systems, for the modulated data signals of the Mth (M = 2 to N) systems, the phase rotation of the plurality of TMCC carriers divided into 360 degrees by the M value of the Mth system is sequentially performed. In addition, the output is superimposed, and the receiving device receives a plurality of different antennas that receive all of the different modulated data transmitted from the transmitting device, and a plurality of different systems that perform frequency conversion on the signals received by the antennas. Each of the reception high-frequency units and a reception control unit that performs demodulation processing on the signal input from the reception high-frequency unit are provided, and the reception control unit combines a plurality of TMCC carriers obtained by differential demodulation. To reduce the demodulation error of the TMCC carrier by adding.

Further, according to the present invention, each of the second system to the M-th system of the transmission apparatus includes a TMCC carrier in phase with the TMCC carrier of the first system.
The transmission control unit of the transmission device outputs an IF signal, and the transmission high-frequency unit of the transmission device converts the IF signal into an RF signal.

  That is, according to the present invention, the transmission control unit gives a phase difference in advance to each TMCC carrier for each system.

  As described above, according to the present invention, transmission characteristics of a radio apparatus using the MIMO-OFDM scheme can be improved by adding a TMCC carrier inversion operation.

  Further, in a receiver that receives a signal obtained by performing phase rotation of a TMCC carrier according to the present invention, the SISO (Single Input Single Output) method for transmitting one signal and the MIMO method for transmitting a plurality of signals are the same. It is sufficient to mount the TMCC demodulator circuit, and since no change on the receiver side is required, this can be realized only by changing the control on the transmitter side.

Explanatory diagram showing a MIMO-OFDM transmission system Explanatory drawing of TMCC carrier arrangement based on ARIB-STD-B33 standard (1k full mode) Explanatory drawing of TMCC carrier arrangement to which phase operation is applied in the present invention (in the case of 1k full mode) (example of phase rotation in odd and even numbers) The block diagram explaining the process of the transmission control part of 1 Example in this invention The block diagram explaining the process of the transmission control part of other one Example by this invention The figure explaining the problem in the conventional MIMO-OFDM system Illustration of mapping arrangement example of data, pilot (CP (Continual Pilot)), TMCC (in case of QPSK (Quadrature Phase Shift Keying)) The figure explaining the amplitude addition for OFDM1 symbol of DBPSK (Differential Binary Phase Shift Keying) demodulation result of TMCC carrier The block diagram explaining the process of the TMCC carrier of one Example in this invention The block diagram explaining the process of the TMCC carrier of other one Example by this invention The figure explaining the TMCC carrier reception in the MIMO-OFDM system of one embodiment of the present invention (transmission path situation in which the phase of the transmission signal 2 is inverted) The figure explaining the TMCC carrier reception in the MIMO-OFDM system of one embodiment of the present invention (transmission path situation in which the phase of the transmission signal 2 does not rotate at all) The figure explaining the TMCC carrier reception in the MIMO-OFDM system of another embodiment of the present invention (digital terrestrial broadcasting) The block diagram explaining the digital processing of the reception control part of one Example in this invention The block diagram explaining the digital processing of the reception control part of other one Example by this invention The figure explaining the transmission and reception of the MISO system according to another embodiment of the present invention (two types for two transmission antennas, phase non-rotation at 0 degrees of the reference phase and 0 degrees of the reference phase) Example of 180 degree (π) phase rotation (inversion) in turn (with odd and even numbers), no phase rotation at 0 degree of reference phase and odd number at 90 degree (π / 2) rotation (orthogonal) of reference phase Example of 180 degree (π) phase rotation (inversion) at even number) The figure explaining the transmission / reception of the MIMO system of other one Example by this invention The figure explaining the TMCC carrier phase rotation of the transmission and reception of the MISO system of another embodiment of the present invention (in order of no phase rotation at 0 degrees of three reference phases with respect to three transmission antennas) Example of 180 degree (π) phase rotation (inversion) and 120 degree (2π / 3) phase rotation in order (with odd and even numbers) The figure explaining the TMCC carrier phase rotation of the transmission and reception of the MISO system according to another embodiment of the present invention (in order of no phase rotation at 0 degrees of four reference phases with respect to four transmission antennas) Example of 180 degree (π) phase rotation (reverse) (with odd and even numbers) and 120 degrees (2π / 3) phase rotation in order and 90 degrees (π / 2) phase rotation in order)

  An embodiment according to the present invention will be described with reference to FIGS.

As a first embodiment of the present invention, an FPU transmission system compliant with ARIB-STD-B33 will be described.
In FIG. 1 of the explanatory diagram showing a MIMO-OFDM transmission system, 1 is a transmission control unit, 2 and 3 are transmission high-frequency units, 4 and 5 and 6 and 7 are antennas, 8 and 9 are transmission high-frequency units, Reference numeral 10 denotes a reception control unit. In FIG. 4A of the block diagram for explaining the processing of the transmission control unit in the present invention, 11 is a DVB-ASI (Digital Video Broadcasting-Asynchronous Serial Interface) interface unit, 12 is a data frame synchronization unit, 13 is an energy spreading unit, 14 Is an outer code unit, 15 is a byte interleave unit, 16 is an inner code unit, 17 is a frequency interleave unit, 18 is a time interleave unit, 19 is a mapping unit, 20 is a CP (Continual Pilot), TMCC, and AC (Auxiliary Channel) unit. , 21 is an OFDM frame configuration unit, 22 is an IFFT (Inverse Fast Fourier Transform) unit, 23 is a GI (Guard Interval) addition unit, 24 is a digital orthogonal modulation unit, 25 is a synchronization circuit unit, and 26 is a data frame synchronization unit. is there.
Data to be transmitted by MIMO-OFDM is processed by the same module as 13 to 24 from 26 to 25. In the transmission signal 1 and the transmission signal 2, different processes are performed in the transmission signal system in 16, 19 and 20.
In 16 and 19, the processing for each transmission system is performed so that the distance between the symbols of the two transmission systems becomes large. Refer to Japanese Patent Application Laid-Open No. 2010-161585 of Patent Document 1 for processing on 20 CP carriers.

  A MIMO-OFDM transmission system includes a transmission unit configured by one transmission control unit, two transmission high-frequency units, and two transmission antennas, one reception control unit, two reception high-frequency units, and two reception antennas. A transmission system at a receiving unit is generally used. The transmission control unit transmits an intermediate frequency (IF) signal to the transmission high frequency unit. The transmission high-frequency unit modulates the IF signal into an RF (Radio Frequency) signal, performs power amplification, and then transmits the signal from the transmission antenna to space.

The transmission control unit outputs different IF signals for each of the two systems. The transmission control unit performs signal processing such as adding an error correction code, frequency / time interleaving, or quadrature modulation to a TS signal of video, audio, or other data.
The transmission high-frequency unit modulates the IF signal into an RF (Radio Frequency) signal, performs power amplification, and then transmits the signal from the transmission antenna to space. The two transmission high-frequency units 2 and 3 transmit signals from 4 and 5 at the same frequency.
The two reception high-frequency units 8 and 9 receive the same frequency using 6 and 7. The receiving antenna 6 receives two signals from 4 and 5 that are affected by different transmission paths. Similarly, the receiving antenna 7 receives two signals 4 and 5 that are affected by different transmission paths.

The reception high-frequency unit converts the frequency of the RF signal received by the reception antenna into an IF signal.
The reception control unit demodulates the IF signal and outputs a TS (Transport Stream) signal.
The reception control unit performs decoding of an error correction code of demodulated data and frequency / time interleaving signal processing.

4 is a block diagram illustrating the processing of the transmission control unit in the present invention. FIG. 4B is a block diagram illustrating the processing of the TMCC carrier of one embodiment of the present invention in the 20 TMCC units of the CP, TMCC, and AC unit of FIG. The operation will be described with reference to FIG. 8A. In FIG. 8A, 31 is a TMCC carrier generation unit, 32 is a multiplier, and 33 is a phase inversion switch.
The TMCC signal is the TMCC carrier at the beginning of the frame that is the reference for differential amplitude.
Is the same as CP carrier
Given by. Subsequent synchronization words are included in the TMCC data.
Is subjected to DBPSK (Differential Binary Phase Shift Keying) modulation, and is arranged at a position of ± 4/3 on the Q axis in mapping. That is, the conventional TMCC section does not have 32 and 33 in FIG. 8A, and the TMCC is arranged at a position of ± 4/3 on the Q axis and does not reverse or rotate.
In addition, TMCC signals transmit the same information in a total of 10 on one OFDM symbol, and this TMCC signal includes control information of signals transmitted from the transmission system.

In the transmission control unit, after the TMCC signal is generated, control for rotating the phase such as inversion is applied to the second system. FIG. 3 shows an example of phase rotation at odd and even numbers in the explanatory diagram of the TMCC carrier arrangement to which the phase operation according to the present invention is applied in the 1k full mode. In ARIB-STD-B33, a TMCC signal is composed of 10 carriers in one OFDM symbol.
For this TMCC carrier, the first TMCC carrier is configured with the same mapping as the conventional ARIB-STD-B33. On the other hand, for the second TMCC carrier, the odd numbered phase has the same phase as the first numbered system, and the even numbered phase rotates 180 degrees (π) phase rotated (inverted) with respect to the first carrier. To make the configuration alternate on the frequency axis.

The two transmission signals are transmitted from the transmission control unit to the high frequency unit at the same timing.
In the transmission path, when two signals are in antiphase relation and spatially synthesized, out of all ten TMCC carriers, the five subcarrier signals corresponding to the odd number are affected by the transmission path and are transmitted to the two transmission lines. Although the signals cancel each other, the even-numbered carriers whose phases are inverted are spatially synthesized in the vicinity of the same phase, so that the signal amplitude is increased.

FIG. 9A is a diagram for explaining TMCC carrier reception in the MIMO-OFDM system of one embodiment of the present invention (transmission path situation in which the phase of transmission signal 2 is inverted), and MIMO-OFDM of one embodiment of the present invention. 9B is a diagram for explaining TMCC carrier reception in the system (transmission path state in which the phase of the transmission signal 2 does not rotate at all), and a block diagram for explaining the digital processing of the reception control unit according to one embodiment of the present invention. A description will be given using 10A.
Receiving high frequency units indicated by 8 and 9 in FIG. 1 perform digital conversion on each received signal that has been subjected to frequency conversion to IF. Thereafter, digital processing is performed with the configuration of FIG. 10A. The digital processing of the reception control unit includes a digital orthogonal modulation unit 41, an OFDM symbol synchronization unit 42, a GI removal unit 43, an FFT unit 44, an OFDM frame synchronization unit 45, a noise normalization unit 46, a channel estimation unit 47, a time deinterleaving unit. 48, a frequency deinterleaving unit 49, an inner code decoding unit 50, a data frame detecting unit 51, a byte deinterleaving unit 52, an outer code decoding unit 53, an energy despreading unit 54, and a DVB-ASI interface unit 55.
The received signal is converted from the time axis to the frequency axis by the FFT unit. Therefore, the TMCC carrier arranged at a specific position is DBPSK demodulated by the OFDM frame synchronization unit.
Since the TMCC carrier subjected to DBPSK modulation transmits the same information within one OFDM symbol, a diversity effect can be obtained by performing complex addition of all 10 differentially demodulated results. TMCC demodulation errors can be reduced.

That is, even in the state of FIG. 9A in the state of the transmission path in which the phase of the transmission signal 2 is inverted, the amplitude is greatly inclined to either positive or negative by adding 10 amplitudes.
By inverting the phase of the second TMCC carrier in the transmission control unit, it is possible to avoid a situation in which all TMCC carriers cannot be demodulated due to the influence of the transmission path when demodulating on the receiver side. As shown in the figure, even when the phase relationship of the transmission path is exactly the opposite phase relationship between the first system and the second system, the odd-numbered TMCC carrier is offset between the systems and the amplitude However, since the even-numbered TMCC carriers are in-phase combined between the systems, the amplitude increases nearly twice. Therefore, as described above, TMCC demodulation is not disabled by complex addition of the differential demodulation results of these ten TMCC carriers.
Also, the TMCC carrier is DBPSK modulated and the same information is transmitted on one OFDM symbol, so that it is necessary to reverse the phase of the TMCC carrier inverted at the receiver side in the correct direction again. However, it can be shared with a differential demodulation circuit similar to SISO.
For example, as shown in FIG. 9B illustrating the TMCC carrier reception in the MIMO-OFDM system according to one embodiment of the present invention (transmission path condition in which the phase of the transmission signal 2 does not rotate at all), the phases of the transmission signals 1 and 2 are as follows. Even in a transmission path situation in which no rotation occurs, half of the TMCC carrier with a large amplitude remains, so that sufficient information for DBPSK modulation can be obtained.

Therefore, the TMCC signal can be normally determined on the receiver side even if the TMCC carrier that can be demodulated is halved.
Furthermore, as shown in FIG. 8B of the block diagram for explaining the processing of the TMCC carrier of another embodiment of the present invention, the multiplier 32, the phase inversion switch 33 and the multiplier 32 in FIG. Although the number of TMCC carriers that can be demodulated on the receiver side is reduced by providing a phase rotator 34 and rotating on the complex plane instead of inverting TMCC, all TMCC carriers are not demodulated due to the influence of the transmission path. The situation that becomes possible can be avoided. With the complex phase rotator 34, not only 180 degrees (π) (inversion) complex phase rotation that becomes two inversions but also 120 degrees (2π / 3) that becomes three kinds and four kinds with respect to the 0 degree reference. 90 degrees (π / 2) (orthogonal), 6 ways 60 degrees (π / 3), 8 ways 45 degrees (π / 4), and 12 ways 30 degrees (π / 6) complex Phase rotation is easy to implement.
FIG. 11A illustrating the transmission and reception of the MISO system according to another embodiment of the present invention is shown in FIG. 11A for two transmission antennas. Example of 180 degree (π) phase rotation (inversion) in order of 0 degree of phase (with odd and even numbers), no phase rotation at 0 degree of reference phase and 90 degree (π / 2) rotation of reference phase An example of 180 degree (π) phase rotation (inversion) at odd and even numbers in (orthogonal) is shown. FIG. 11A is an example of MIMO. In a MISO system with three transmitting antennas, three receiving antennas, or two transmitting antennas and two receiving antennas, the reference phase of the TMCC carrier is 360 degrees (2π) N (N is Rotate the phase of 180 degrees (π), 120 degrees (2π / 3), 90 degrees (π / 2), 60 degrees (π / 2), etc. in the division of 2 or more natural numbers and invert odd and even numbers of TMCC carriers May be.
The 360 degree (2π) division number N should be larger than the number of transmission antennas. The number of transmission antennas and the 360 ° (2π) division number N may be equal.

As described above, the TMCC carrier included in the OFDM frame of two receiving antennas with two transmitting antennas has been described. However, the present invention can also be applied to three or more transmitting antennas and receiving antennas by changing the operation of giving a phase to each carrier.
Further, FIG. 11C for explaining the TMCC carrier phase rotation of the transmission / reception of the MISO system according to another embodiment of the present invention is shown in FIG. 11C with three reference phases at three degrees for three transmission antennas. An example of 180 degrees (π) phase rotation (inversion) and 120 degrees (2π / 3) phase rotation in order (with odd and even numbers) in order and no phase rotation is shown. FIG. 11C is an example of MISO that transmits three systems of signals from three base stations, but MISO that transmits three systems of signals from one base station may be used.
Further, FIG. 11D illustrating the TMCC carrier phase rotation of the transmission / reception of the MISO system according to another embodiment of the present invention is shown in FIG. 11D at four reference phases at four degrees for four transmission antennas. Example of phase non-rotation, sequentially (with odd and even numbers) 180 degrees (π) phase rotation (reversal), 120 degrees (2π / 3) phase rotation in sequence, and 90 degrees (π / 2) phase rotation in order Indicates.
11C and 11D have 10 TMCC carriers. For example, when there are 20 TMCC carriers, for example, there are 20 TMCC carriers, 60 degrees (π / 3) in which TMCC carriers are sequentially arranged, 45 degrees which are 8 kinds. (Π / 4), 30 different (π / 6) phase rotations may be used.
Further, FIG. 11C and FIG. 11D are examples of MISO. In the MIMO system of four transmitting antennas, four receiving antennas, three transmitting antennas, three receiving antennas, or two transmitting antennas and two receiving antennas, The TMCC carrier is divided into 360 degrees (2π) of N (N is a natural number of 2 or more) in order, for example, 180 degrees (π), 120 degrees (2π / 3), 90 degrees (π / 2), 60 degrees (π / The phase rotation of 2) may be performed.
FIG. 11D is an example of MISO, but in a MIMO system with four transmit antennas, four receive antennas, three transmit antennas, three receive antennas, or two transmit antennas and two receive antennas, the reference phase of the TMCC carrier. The complex phase rotation may be performed to invert odd and even numbers of TMCC carriers, or the TMCC carriers may be individually complex phase rotated.
The 360 degree (2π) division number N should be larger than the number of transmission antennas. The number of transmission antennas and the 360 ° (2π) division number N may be equal.
That is, in a transmission apparatus that transmits different modulated data signals from a plurality of antennas at the same frequency using the OFDM method, the TMCC carrier included in the OFDM frame is rotated 360 degrees (2π) in order to the non-rotating phase and the TMCC carrier. N (N is a natural number of 2 or more) division (180 degrees (π), 120 degrees (2π / 3), 90 degrees (π / 2), 60 degrees (π / 2), etc.) differs for each of the plurality of antennas. Phase rotation or phase non-rotation and the reference phase of the TMCC carrier are rotated by N degrees of 360 degrees different for each of the plurality of antennas, and the TMCC carriers are sequentially different for each of the plurality of antennas of N degrees of 360 degrees. It is possible to provide phase rotation.

As an assumed environment of the second embodiment, consider the application of the MISO-OFDM system including a TMCC carrier to terrestrial digital broadcasting.
Unlike mobile transmission and FPU transmission that performs temporary relay, digital terrestrial broadcasting mainly uses fixed communication paths.
In the future, in order to increase the radio wave utilization efficiency, MISO-OFDM transmission such as transmission 2 × reception 1 will be performed as shown in FIG. 11A of the block diagram for explaining the transmission and reception of the MISO system of another embodiment of the present invention. In this case, it is easily assumed that there is a receiving station in an environment where the transmission path between the transmission source base station and the receiving antenna cancels the TMCC carrier.

As a possible advantage of the second embodiment, in the case of FPU transmission in which the reception point or the transmission point can be moved, if it is confirmed that such a transmission state is present, the antenna position and the relay point are changed. The proposed method is very effective because it cannot be easily handled in the terrestrial digital broadcasting environment.
As a feature of the second embodiment, it is possible to prevent loss of frame synchronization using TMCC only by operating a transmission signal on the transmitter side. Therefore, it is not necessary to take measures for users of an unspecified number of terrestrial digital broadcast receivers, and it is possible to cope with the problem only by the work of the transmitter that is easy to identify the installation location and the operator.

The processing of the transmission control unit in the proposed scheme will be described with reference to FIG. 4B of the block diagram illustrating the processing of the transmission control unit of another embodiment of the present invention. 4B, the DVB-ASI interface unit 11, the TS remultiplexing unit 27, the outer coding unit 14, the layer dividing unit 28, the energy spreading unit 13, the delay correcting unit 29, the byte interleaving unit 15, the inner coding unit 16, and the bit interleaving unit. 30, mapping unit 19, layer synthesis unit 36, time interleaving unit 18, frequency interleaving unit 17, SP, CP, TMCC, AC subcarrier generation unit 20, OFDM frame configuration unit 21, IFFT unit 22, GI addition unit 23, A digital quadrature modulation unit 24 and a synchronization circuit unit 25 are included.
Data transmitted by MISO-OFDM is processed by the same module as the transmission signal 1 from the outer code unit 14 to the synchronization circuit 25 of the transmission signal 2. In the transmission signal 1 and the transmission signal 2, each of the transmission signals is characterized by performing different processes in the transmission signal system in the inner encoding unit 16 and the carrier configuration mapping unit 19.

FIG. 9C illustrating the TMCC carrier reception in the MIMO-OFDM system according to another embodiment of the present invention (terrestrial digital broadcasting) is applied to this system with 11 segments in the mode-3 of the synchronous modulation unit. An image diagram is shown. There are 432 subcarriers per segment. On one OFDM symbol, four TMCC carriers are allocated to subcarriers numbered 70, 133, 233, and 433.
In this embodiment, a phase inversion operation of 180 degrees is added to the odd number of all four TMCC carriers.
Since the operation method is as described in the first embodiment, the description is omitted.
The reception signal X received by the reception antenna in a propagation state in which the transmission signal 2 is 180 ° phase-inverted with the transmission signal 1 is a frame using a TMCC carrier in which an even-numbered carrier to which an inversion operation is added at the time of transmission is combined. Synchronization can be performed.
In FIG. 10B of the block diagram for explaining the digital processing of the reception control unit of another embodiment of the present invention, the TMCC carrier decoding unit is implemented by the OFDM frame synchronization unit in the figure. In the difference from FIG. 10A in the block diagram for explaining the digital processing of the reception control unit according to one embodiment of the present invention, FIG. 10B is the same as FIG. 10A, but the order of processing is changed, and the bit deinterleaving unit 56 and the previous hierarchy A dividing unit 28 is added.

The second embodiment can also be applied to a MIMO system for network transmission as shown in FIG. 11B of the block diagram for explaining the transmission and reception of the MIMO system of another embodiment of the present invention.
Even when a similar problem occurs in the phase difference generated in the relay transmission in the network transmission, it can be dealt with.
In addition, even in the MISO system as shown in FIG. 11C for explaining the TMCC carrier phase rotation of the transmission / reception of the MISO system according to another embodiment of the present invention, the transmission of the MISO system according to another embodiment of the present invention is performed. The present invention can also be applied to the MISO system as shown in FIG. 11D illustrating the reception TMCC carrier phase rotation.

1: transmission control unit, 2, 3: transmission high-frequency unit, 4, 5, 6, 7: antenna,
8, 9: Transmission high frequency unit, 10: Reception control unit,
11, 55: DVB-ASI interface unit, 12: data frame synchronization unit,
13: Energy spreading unit, 14: Outer code unit, 15: Byte interleaving unit,
16: Inner code part, 17: Frequency interleave part, 18: Time interleave part,
19: Mapping unit, 20: CP, TMCC, AC unit, 21: OFDM frame configuration unit,
22: IFFT unit, 23: GI adding unit, 24: digital quadrature modulation unit,
25: synchronization circuit unit, 26: data frame synchronization unit,
27: TS remultiplexing unit, 28: Hierarchy division unit, 29: Delay correction unit,
30: Bit interleaving unit, 36: Hierarchical synthesis unit,
31: TMCC carrier generation unit, 32: multiplier, 33: phase inversion switch,
34: Complex phase rotator,
41: Digital quadrature demodulator, 42: OFDM symbol synchronizer, 43: GI remover,
44: FFT unit, 45: OFDM frame synchronization unit, 46: Noise normalization unit,
47: Channel estimation unit, 48: Time deinterleaving unit,
49: Frequency deinterleaving unit, 50: Inner code decoding unit,
51: Data frame detection unit, 52: Byte deinterleaving unit,
53: outer code decoding unit, 54: energy despreading unit,
56: Bit deinterleave part,

Claims (4)

A transmitter that transmits different modulated data signals from two different antennas at the same frequency using the OFDM method, and two different antennas that receive different modulated data transmitted from the transmitter, respectively. In a communication device comprising a receiving device that demodulates in
The transmitter is
A transmission control unit that generates and outputs different modulated data signals for each of two different systems for video and audio data input from the interface unit;
A transmission high-frequency unit provided for each of the two different systems for amplifying and outputting a signal from the transmission control unit,
An antenna provided for each of the two different systems for transmitting signals from the transmission high-frequency unit,
When the transmission control unit superimposes a plurality of TMCC carriers on an OFDM frame,
For the modulated data signal of the first system that is one of the two different systems, all the phases of the plurality of TMCC carriers are superimposed and output without phase rotation,
For the modulated data signal of the second system which is the other of the two different systems, a phase rotation obtained by dividing 360 degrees by a natural number of 2 or more is sequentially added and superimposed on the phase of the plurality of TMCC carriers, and output.
The receiving device is:
Two different antennas for receiving both different modulated data transmitted from the transmitter;
A reception high-frequency unit provided for each of the two different systems for frequency-converting a signal received by the antenna;
A reception control unit that performs demodulation processing of a signal input from the reception high-frequency unit,
The reception control unit
A communication apparatus that reduces a demodulation error of a TMCC carrier by complex addition of a plurality of TMCC carriers obtained by differential demodulation. A transmitter that transmits different modulated data signals from a plurality of N (N = 2 or more natural numbers) different antennas at the same frequency by the OFDM method, and a plurality of different modulated data transmitted from the transmitter In a communication device comprising a receiving device that receives and demodulates each antenna of different systems,
The transmitter is
A transmission control unit that generates and outputs different modulation data signals for each of the N different systems with respect to video and audio data input from the interface unit;
A transmission high-frequency unit provided for each of the plurality of N different systems for amplifying and outputting a signal from the transmission control unit,
An antenna provided for each of the plurality of N different systems for transmitting a signal from the transmission high-frequency unit,
When the transmission control unit superimposes a plurality of TMCC carriers on an OFDM frame,
Among the plurality of N different systems, all the phases of the plurality of TMCC carriers are superimposed on the modulated data signal of the first system and output without phase rotation,
Among the plurality of N different systems, for the modulated data signal of the Mth (M = 2 to N) systems, 360 degrees are divided into the phases of the plurality of TMCC carriers by the M value of the Mth system The phase rotations that have been added are sequentially added and output,
The receiving device is:
A plurality of different antennas that receive all of the different modulated data transmitted from the transmitter, and
A reception high-frequency unit provided for each of the plurality of different systems for frequency-converting a signal received by the antenna;
A reception control unit that performs demodulation processing of a signal input from the reception high-frequency unit,
The reception control unit
A communication apparatus that reduces a demodulation error of a TMCC carrier by complex addition of a plurality of TMCC carriers obtained by differential demodulation. The communication device according to claim 1, wherein
Each of the second system to the M-th system of the transmission device includes a TMCC carrier in phase with the TMCC carrier of the first system. The communication device according to any one of claims 1 to 3,
The transmission control unit of the transmission device outputs an IF signal,
The communication device, wherein the transmission high-frequency unit of the transmission device converts the IF signal into an RF signal.