JP4199436B2 - Digital signal receiving apparatus and digital signal receiving system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a digital signal receiving apparatus and a digital signal receiving system.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, when transmitting a digital signal, in order to prevent the occurrence of an error due to transmission interference such as noise, a method of error-coding and transmitting the original information to be transmitted is used in many systems.
[0003]
For example, in the digital television broadcasting standards in Japan and Europe, the original digital stream (MPEG-2 standard transport stream) is error-corrected and transmitted by a concatenated code of a Reed-Solomon code and a convolutional code.
[0004]
Here, the Reed-Solomon code is a block code, and is a total of 16 bytes of parity bytes added to a 188-byte transport stream packet (hereinafter referred to as a TS packet) constituting an MPEG-2 standard transport stream. The code word is 204 bytes.
[0005]
On the other hand, it is considered to prevent the occurrence of errors due to transmission interference by improving the reception characteristics.
[0006]
An example of this method is diversity reception technology.
[0007]
As shown in FIG. 4, in this tie diversity reception technology, for example, in mobile communication, a mobile terminal is provided with a plurality of antennas, and among the received waves received by each, the one with the maximum envelope level is selected. It constitutes.
[0008]
[Problems to be solved by the invention]
However, since normal diversity reception is configured to input a plurality of antenna outputs to the receiving device, in order to receive a high-frequency signal such as an antenna output, each antenna and the receiving device are connected. It is necessary to shorten the cable.
[0009]
In the case of a passenger car or the like, since the antennas are usually arranged on both the left and right sides, the antennas and the receiving device can be arranged relatively close to each other. In the case where the antennas are provided at the foremost part and the rearmost part, the distance between the respective antennas and the receiving device is long, so that it is necessary to lengthen the cables connecting them.
[0010]
For this reason, when transmitting a high-frequency signal such as an antenna output, problems such as signal attenuation and interference signal mixing occur.
[0011]
Accordingly, the present invention has been made in view of the above problems, and an object thereof is to provide a digital signal receiving apparatus and a digital signal receiving system that can reduce errors in received signals.
[0012]
[Means for Solving the Problems]
In order to achieve such an object, the invention according to claim 1 is a digital signal receiving apparatus for receiving a digital signal transmitted using a block error correction code, and is received by a plurality of antennas and the plurality of antennas. A plurality of demodulation units that demodulate a digital signal to create a plurality of digital streams; a stream synchronization unit that synchronizes the plurality of digital streams; and a block that synchronizes between the plurality of digital streams. A reference order is provided in advance, and when there is an error in a certain demodulator, the next demodulator is referred to, and if there is a block that does not contain an error, a block that does not contain the error is selected, and the plurality of If there is no error-free block in all of the demodulator, the block demodulated by the specific demodulator, the previous block The ratio of the block output from the demodulator that outputs the block and the block containing the error in the digital stream output from each demodulator is obtained for each demodulator, and output from the demodulator with the lowest ratio A stream synthesizing unit that selects any one of the blocks and creates a series of digital streams .
[0017]
Thus, according to the first aspect of the present invention, errors in the received signal can be reduced. Furthermore, according to the first aspect of the present invention, since the digital stream has a lower frequency than the antenna output, long-distance transmission from the demodulator to the stream synthesizer is easy.
[0018]
Further, in the invention according to claim 2 , the demodulator outputs one or more of the frame synchronization signal and the block synchronization signal together with the digital stream, and the stream synchronization unit outputs the frame synchronization signal, the block synchronization signal, the digital A plurality of digital streams are synchronized based on any one or more of the streams.
[0019]
Thus, in the invention according to claim 2 , it is possible to reduce errors in the received signal. Further, in the invention according to claim 2 , since the digital stream has a low frequency compared with the antenna output, long-distance transmission from the demodulating means to the stream synthesizing means is easy.
[0020]
According to a third aspect of the present invention, in a digital signal receiving system for receiving a digital signal transmitted using a block error correction code, a plurality of antennas and a digital signal received by the plurality of antennas are demodulated. In a plurality of demodulation units that create a plurality of digital streams and a block synchronized between the plurality of digital streams, a reference order is provided in advance in the plurality of demodulation units, and when a certain demodulation unit includes an error, When there is a block that does not include an error, a block that does not include the error is selected, and when there is no block that does not include an error in all of the plurality of demodulation units , a specific demodulation is performed. Block demodulated by the block, the block output from the demodulator that output the previous block, and the digital output from each demodulator Obtains a ratio that contains the block of error for each demodulator in the stream, the blocks in which the ratio is outputted from the lowest demodulator, select one, the stream synthesizing unit for creating a series of digital streams The demodulator and the stream synthesizer each have a bidirectional interface for connecting to a network, and perform bidirectional communication between the demodulator and the stream synthesizer. The digital stream is synchronized.
[0021]
Thus, in the invention described in claim 3 , errors in the received signal can be reduced. Further, according to the third aspect of the present invention, since the digital stream has a lower frequency than the antenna output, long-distance transmission through a large-scale network from the demodulating unit to the stream synthesizing unit is easy.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
[Features of the present invention]
The present invention is for reducing errors in received signals. Therefore, in the present invention, a plurality of sets of antennas and signal demodulation units are provided to synthesize a plurality of demodulated digital streams. Thereby, in the present invention, reception characteristics are improved.
[0023]
DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described in detail with reference to the drawings.
[0024]
[First Embodiment]
First, a first embodiment of the present invention will be described below.
[0025]
FIG. 1 is a block diagram showing the configuration of the digital signal receiving apparatus according to the present embodiment.
[0026]
Referring to FIG. 1, the digital signal receiving apparatus according to the present embodiment is provided with a plurality (N: N is 2 or more) of antennas 11, 12,... , 2N for demodulating the received wave, and stream synchronization units for synchronizing the N digital streams 1, 2,..., N output from the demodulation units 21, 22,. 30 and each of the blocks included in the synchronized digital streams 1, 2,..., N, if there is at least one correct (error-free) block among the corresponding blocks, this correct block , And when there is no correct block, select one of them and output it to form and output a stream of digital streams. It has 0 and, the.
[0027]
Here, the stream synthesizing unit 40 may limit a block output when there is no correct block among mutually corresponding blocks to a block demodulated by a specific demodulating unit, or an arbitrary demodulating unit. It is also possible to use a demodulated block. For example, it can be configured to input a block demodulated in a specific demodulator, or can be configured to input a block output from a demodulator that has output the previous block. It is also possible to obtain a ratio in which a block having an error in the digital stream is obtained for each demodulator, and to select a block output from the demodulator having the lowest ratio. Further, the demodulating units 21, 22,..., 2N are provided with order, and this is round-robin, or the next and following of the demodulating unit that demodulates the previously input block is round-robin-referenced and determined and input. It is also possible to configure as described above. However, in this case, in the present embodiment, the demodulator 21 is the head first, the demodulator 2N is the tail last, and the next to the demodulator 2N is fed back to the demodulator 21 for reference. Good. Furthermore, as another configuration of this configuration, a configuration in which priorities are assigned to the demodulating units 21, 22,...
[0028]
Since the received digital streams are each subjected to block error correction coding, the digital streams 1, 2,..., N demodulated in the demodulating units 21, 22,. This block is configured to identify whether the block is correct or contains an error (cannot be corrected correctly).
[0029]
Here, a configuration for identifying whether or not an error is included will be described using a digital method as an example.
[0030]
In the case of digital broadcasting, TS packets constituting a digital stream are configured as shown in FIG.
[0031]
In this configuration, the “transport error indicator” in the header ('header') is an “error indicator”, and when an error is included in each TS packet, “1” is indicated in the demodulator, and an error occurs. Is not included, “0” is indicated in the demodulator.
[0032]
Therefore, in this embodiment, this “transport error indicator” is used to identify whether or not an error is included in a block.
[0033]
In addition, the N digital streams 1, 2,..., N output from the demodulation units 21, 22,..., 2N are input to the stream synchronization unit 30.
[0034]
However, since the processing time of each demodulator and the transmission time to the stream synchronizer are different, the digital streams 1, 2,..., N are input to the stream synchronizer 30 at different timings.
[0035]
Therefore, the stream synchronization unit 30 synchronizes all the digital streams 1, 2,..., N and outputs them to the stream synthesis unit 40.
[0036]
Here, examples of a method for synchronizing each digital stream include the following methods.
[0037]
First, as a first synchronization method, all digital data in each digital stream is compared to achieve synchronization.
[0038]
As a second synchronization method, when a block synchronization method can be used, first, synchronization is performed for each block, and then all data or a part of data of each block is compared to synchronize between blocks. Plan.
[0039]
Further, as a third synchronization method, when the demodulated digital stream has a frame structure in which a plurality of blocks are collected, first, synchronization is performed for each frame, and then a specific block (for example, the top) in each frame. Are compared with each other in order to synchronize the blocks.
[0040]
In the case of digital broadcasting, it is possible to achieve synchronization between blocks even by the first synchronization method described above, but since packet synchronization can be achieved using synchronization bytes in TS packets, packet synchronization For example, each digital stream is obtained by taking a match between packet identification ('PID': see Fig. 2) and continuity index ('continuity counter': see Fig. 2) between all or some of the packets. Can be synchronized.
[0041]
Furthermore, since digital broadcasting in Europe and Japan has a frame structure in which several TS packets are collected, first, frame synchronization is performed between the digital streams by the third synchronization method, and then the frame is The digital streams can be synchronized with each other by taking a packet match with respect to a specific packet, for example, some packets from the head of the frame, for example, by matching the packet identification with the continuity index.
[0042]
Since the frame synchronization signal and the packet synchronization signal of the digital stream can be demodulated from the demodulation synchronization of the digital broadcast wave, the stream synchronization unit also includes the frame synchronization signal and the packet synchronization signal from the demodulation units 21, 22,. By outputting to 30, it is possible to reduce the processing load of the stream synchronization unit 30.
[0043]
Further, the stream synthesizing unit 40 outputs the correct block if there is at least one correct block among the N blocks input in synchronization. On the other hand, when no correct block exists, the stream synthesizing unit 40 outputs one of the blocks including an error.
[0044]
As described above, by configuring and operating, it is possible to configure and output a series of digital streams with a reduced probability of error.
[0045]
[Second Embodiment]
Further, in the digital signal receiving apparatus exemplified in the first embodiment, the configuration for synchronizing the digital stream input to the stream synthesizing unit 40 is as shown in FIG. It is also possible to configure that the stream composition unit 40 and the stream composition unit 40 have bidirectional interfaces and are connected via a network 70 such as a LAN or the Internet.
[0046]
This configuration will be described below as a second embodiment.
[0047]
Referring to FIG. 3, in this embodiment, as in the first embodiment, the antennas 11, 12,..., 1N and the demodulating units 21, 22,. The digital streams output from the demodulating units 21, 22,..., 2N are synchronized with each other and then input to the stream synthesizing unit 40.
[0048]
Also, in this embodiment, as a configuration for synchronizing each digital stream, one bidirectional interface 51, 52,..., 5N is provided at each output stage of each demodulator 21, 22,. A bidirectional interface 60 is provided at the input stage of the stream synthesis unit 40, and these are connected via a network 70.
[0049]
In this configuration, the bidirectional interfaces 51, 52,..., 5N and the bidirectional interface 60 perform bidirectional communication, and synchronization between the demodulation units 21, 22,.
[0050]
Further, in this bidirectional communication, the bidirectional interface 60 has a demodulator having the correct block as long as there is at least one demodulator having the correct block among the N demodulators 21, 22,. Is selected, and the correct block is output to the bidirectional interface corresponding to the selected demodulator. On the other hand, when there is no demodulator having a correct block, the bidirectional interface 60 selects any demodulator and includes an error with respect to the bidirectional interface corresponding to the selected demodulator. Output the block.
[0051]
In this way, the bidirectional interface 60 reduces the probability that an error is included, and inputs a series of blocks to the stream synthesis unit 40.
[0052]
Here, the method for determining whether an error is included in each block is the same as in the first embodiment.
[0053]
The stream synthesizing unit 40 synthesizes a series of input blocks, creates a series of digital streams, and outputs them.
[0054]
Here, a specific example of this operation will be described with reference to FIG. However, in this example, it is assumed that the bidirectional interface 60 is configured to input a block demodulated by the demodulator 2N when an error is included in all the same blocks.
[0055]
In FIG. 3, among the blocks included in the digital stream 1 demodulated by the demodulator 21, 3, 5, and 7 include errors, and other than this, no errors are included, and the demodulator 22 Are included in the digital stream N demodulated by the demodulating unit 2N, and errors are included in the blocks 1 and 5 included in the digital stream 2 demodulated in FIG. It is assumed that errors 5 and 8 are included in the block and no error is included in other blocks.
[0056]
In this configuration, the operation until blocks 1 to 5 are input to the bidirectional interface 60 will be described below.
[0057]
In this operation, first, the block 1 demodulated by the demodulator 21 is input to the bidirectional interface 60. Next, since block 2 demodulated by demodulator 21 that demodulated block 1 does not contain an error, block 2 demodulated by demodulator 21 is input to bidirectional interface 60.
[0058]
Next, since an error is included in the block 3 demodulated by the demodulator 21, the bidirectional interface 60 selects the demodulator 21 and subsequent blocks in a round robin manner. Therefore, the demodulator that demodulates the block that is input to the bidirectional interface 60 next becomes the demodulator 22.
[0059]
Further, since the block 4 demodulated by the demodulator 22 does not include an error, the bidirectional interface 60 inputs the block 4 from the demodulator 22.
[0060]
Next, for the block 5, since an error is included in any of the blocks demodulated by the demodulating units 21, 22, 2N (the demodulating units 23 to 2N-1 are omitted), the bidirectional interface 60 includes the demodulating unit. A block 5 including an error demodulated by 2N is fixedly selected and input.
[0061]
By operating in this way, the blocks 1 to 5 are input to the stream synthesizing unit 40, and the stream synthesizing unit 40 synthesizes them to create a series of digital streams and output them.
[0062]
[Summary]
As described above, according to the present invention, in a digital signal receiving apparatus transmitted using a block error correction code, N digital signals output from N (N is an integer of 2 or more) antennas and demodulation units. Synchronize the stream outputs and then select one of the input blocks that is correct for each block in each of the N digital streams that are synchronized and input, and one is correct If there is no block, a block including any error is selected, and a series of digital streams is constructed and output.
[0063]
In this configuration, the demodulator outputs a frame synchronization signal and a block synchronization signal together with the digital stream, and synchronizes a plurality of digital stream outputs using the frame synchronization signal, the block synchronization signal, and the digital stream. Is also possible.
[0064]
Furthermore, each demodulator and the stream synthesizer can be configured to be connected while being synchronized by a bidirectional interface.
[0065]
In such a configuration, since the demodulated digital stream (bit stream) is a low frequency wave, transmission over a long distance becomes easy.
[0066]
Furthermore, since the correct digital stream can be generated by demodulating with a plurality of demodulating units and receiving one correct signal, it is possible to reduce the proportion of errors and substantially receive the signal. The characteristics are improved.
[0067]
【The invention's effect】
As described above, according to the first aspect of the present invention, in a digital signal receiving apparatus that receives a digital signal transmitted using a block error correction code, a plurality of antennas are received by the plurality of antennas. A plurality of demodulating units for demodulating the digital signals to create a plurality of digital streams, a stream synchronizing unit for synchronizing the plurality of digital streams, and a block for synchronizing between the plurality of digital streams. The reference order is provided in advance, and when a demodulator includes an error, the next demodulator is referred to, and if there is a block that does not include an error, a block that does not include the error is selected, If there is no error-free block in all of the multiple demodulation units, the block demodulated by a specific demodulation unit, the previous block For each demodulator, the ratio of the blocks output from the demodulator that output the block and the block containing the error in the digital stream output from each demodulator is obtained and output from the demodulator with the lowest ratio. A stream synthesizing unit that selects one of the blocks and creates a series of digital streams , thereby reducing errors in the received signal. Furthermore, according to the first aspect of the present invention, since the digital stream has a lower frequency than the antenna output, long-distance transmission from the demodulator to the stream synthesizer is facilitated.
[0070]
According to the second aspect of the present invention, the demodulator outputs one or more of the frame synchronization signal and the block synchronization signal together with the digital stream, and the stream synchronization unit outputs the frame synchronization signal and the block synchronization signal. The method is characterized in that a plurality of digital streams are synchronized based on any one or more of the digital streams, thereby reducing errors in the received signal. According to the second aspect of the present invention, since the digital stream has a lower frequency than the antenna output, long-distance transmission from the demodulating means to the stream synthesizing means is facilitated.
[0071]
According to a third aspect of the present invention, in a digital signal receiving system for receiving a digital signal transmitted using a block error correction code, a plurality of antennas and a digital signal received by the plurality of antennas are demodulated. In a plurality of demodulating units that create a plurality of digital streams and a block synchronized between the plurality of digital streams, a reference order is provided in advance in the plurality of demodulating units, and an error is included in a certain demodulating unit. If there is a block that does not contain an error , refer to the next and subsequent demodulator , select a block that does not contain the error, and if there is no block that does not contain an error in all of the plurality of demodulator , specify Blocks demodulated by the demodulator, blocks output from the demodulator that output the previous block, and data output from each demodulator It obtains a ratio that contains the block of errors in digital streams each demodulator, the blocks in which the ratio is outputted from the lowest demodulator, select one, the stream synthesizing to create a set of digital streams The demodulation unit and the stream synthesis unit each have a bidirectional interface for connecting to a network, and performing bidirectional communication between the demodulation unit and the stream synthesis unit, It is characterized by synchronizing a plurality of digital streams, which makes it possible to reduce errors in the received signal. According to the third aspect of the present invention, since the digital stream has a lower frequency than the antenna output, long-distance transmission through a large-scale network from the demodulator to the stream synthesizer is facilitated.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a digital signal receiving apparatus according to a first embodiment of the present invention.
FIG. 2 is a block diagram showing a configuration of an MPEG-2 transport stream (TS) applied in the first embodiment of the present invention.
FIG. 3 is a block diagram showing a configuration of a digital signal receiving system according to a second embodiment of the present invention.
FIG. 4 is a block diagram showing a configuration of a diversity receiving apparatus according to the prior art.
[Explanation of symbols]
1, 2, N Digital streams 11, 12,..., 1 N Antennas 21, 22,..., 2 N Demodulator 30 Stream synchronizer 40 Stream synthesizers 51, 52, ..., 5 N, 60 Bidirectional interface 70 Network 100 Diversity Receiver

Claims (3)

In a digital signal receiving apparatus for receiving a digital signal transmitted using a block error correction code,
A plurality of antennas; a plurality of demodulation units that demodulate digital signals received by the plurality of antennas to create a plurality of digital streams; a stream synchronization unit that synchronizes the plurality of digital streams; and the plurality of digital streams In a block synchronized between
A reference sequence is provided in advance in the plurality of demodulation units, and when there is an error in a certain demodulation unit, the next and subsequent demodulation units are referred to, and if there is a block that does not include an error, a block that does not include the error And when there is no error-free block in all of the plurality of demodulation units, the block demodulated by the specific demodulation unit, the block output from the demodulation unit that output the previous block, and each demodulation unit For each demodulator, the ratio of the erroneous block in the output digital stream is obtained for each demodulator, and one of the blocks output from the demodulator with the lowest ratio is selected to obtain a series of digital streams. A digital signal receiving apparatus comprising: a stream synthesizing unit; The demodulator
One or more of a frame synchronization signal and a block synchronization signal are output together with the digital stream, and the stream synchronization unit is based on one or more of the frame synchronization signal, the block synchronization signal, and the digital stream. Te, the digital signal receiving apparatus according to claim 1, wherein the synchronizing the plurality of digital streams. In a digital signal receiving system for receiving a digital signal transmitted using a block error correcting code,
A plurality of demodulation units for demodulating digital signals received by the plurality of antennas to create a plurality of digital streams;
In a block synchronized between the plurality of digital streams, a reference order is provided in advance in the plurality of demodulation units, and when a certain demodulation unit includes an error, the next and subsequent demodulation units are referred to, and no error is included. If there is a block, select a block that does not contain the error, and if there is no block that does not contain an error in all of the plurality of demodulation units , output the block demodulated by the specific demodulation unit and the previous block The block output from the demodulator, and the ratio of the block having an error in the digital stream output from each demodulator is obtained for each demodulator, among the blocks output from the demodulator with the lowest ratio, A stream synthesizing unit that selects one and creates a series of digital streams,
The demodulator and the stream combiner each have a bidirectional interface for connecting to a network,
A digital signal receiving system, wherein the plurality of digital streams are synchronized by performing bidirectional communication between the demodulator and the stream combiner.

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