JP2003018132A - Receiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To inform a user of the reception conditions of received signals for receiving transmission data which have Reed-Solomon codes appended thereto. SOLUTION: BS digital broadcast receiver 1 comprises a tuner 11 for demodulating transmission data from received signals, a transmission line decoder 14 for performing a transmission line decoding, such as Viterbi decoding, deinterleaving, etc., of the transmission data demodulated by the tuner 11, an RS decoder 15 for RS-decoding the transmission data outputted from the line decoder 14, and a reception conditions detector 16 for informaing a user of the reception conditions. This detector 16 detects the number of errors in RS blocks, based on the error location information obtained in an error correction process by the RS decoder 15, obtains the degree of margin for the error correction power of the RS decoder, based on the number of errors, and indicates the user of the degree of margin as reception condition of the received signals.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a receiver for receiving digital signals transmitted by ground waves or satellite waves.

[0002]

2. Description of the Related Art When transmitting digital data, the transmitting side performs error correction coding on the transmitted data and then digitally modulates the signal for transmission, and the receiving side digitally demodulates and then decodes the error correcting code. Then, the transmitted data is reproduced. In a digital data transmission system, by adding such an error correction code to the transmission data,
Reliable data transmission is performed.

In general, the error correction code is a convolutional code which can be expected to have an error correction effect even in a low C / N environment, and a block code which can completely remove an error when an error rate higher than a certain level is guaranteed. Often used in conjunction with. In particular, a Reed Solomon (RS) code, which is one of the block codes, is widely used because it has good affinity with Viterbi decoding, which is a decoding process of a convolutional code.

When receiving digital satellite broadcasting,
An antenna must be installed, but it is necessary to adjust the direction of the antenna to the direction in which radio waves are transmitted. That is, the antenna must be installed in the direction of the satellite. Generally, digital satellite broadcasting antennas are installed outdoors, so it is necessary to make sure adjustments when installing the antennas. The direction of this antenna is normally adjusted while monitoring whether or not transmission data can be received.

[0005]

By the way, in an environment where the C / N is high, such as in fine weather, there are few errors itself in transmission. Therefore, even if the direction of the antenna is slightly deviated from the direction of the satellite, the error component due to the direction deviation is R
It is completely corrected by the S decoder. Therefore, when the antenna is installed in fine weather and the antenna orientation is adjusted by determining whether or not the transmission data can be received, the antenna orientation cannot be accurately adjusted to the satellite direction. .

However, if the direction of the antenna is not adjusted accurately, even if reception is possible even in fine weather, the environment in which the received electric field is low due to rainfall, snowfall, etc. will result in C /
When N decreases, the number of errors in the transmission data increases, resulting in a reception state in which error correction is impossible.

Therefore, when adjusting the direction of the antenna,
It is necessary to install the antenna with a margin so that the transmission data can be optimally received from the beginning of the adjustment, instead of just judging whether or not the transmission data can be received.

Further, when transmitting and receiving transmission data transmitted via mobile media such as digital terrestrial broadcasting and mobile phones, generally, a service area covered by one base station is defined and its service is provided. When in the area, transmission / reception is performed with the base station.
As long as the mobile receiver is receiving inside this service area, even if it is at the periphery of the service area,
Since the error correction is performed by the RS code as described above, the transmission error is completely corrected by the RS decoder,
It becomes possible to send and receive transmission data. However, once out of the service area, a number of error bytes exceeding the error correction capability are generated, and a poor reception state occurs. If the user is likely to move out of the service area, the user can take measures such as adjusting the antenna or adjusting the reception channel in the next service area in advance. Therefore, it is desired to notify the user of how much time is left before the current reception state becomes a state where reception is not possible.

The present invention has been made in view of the above circumstances, and is a receiving apparatus for receiving transmission data which is convolutionally coded after the Reed-Solomon code is added, and is accurate with a simple structure. It is an object of the present invention to provide a receiving device that detects the reception state of a received signal.

[0010]

In order to solve the above-mentioned problems, a receiving apparatus according to the present invention is transmission data which is digitally modulated with respect to a predetermined carrier signal and has a Reed-Solomon code added thereto. A receiving device for receiving transmission data that has been convolutionally coded later, including demodulation means for demodulating the transmission data from the received signal, and transmission path decoding means for decoding the transmission data demodulated by the demodulation means according to a transmission method. , Using the Viterbi decoding means for Viterbi decoding the transmission data output from the transmission path decoding means, and the Reed-Solomon code added to the transmission data output from the Viterbi decoding means, for error correction of the transmission data. Reed-Solomon decoding means for performing, and a reception state detection means for detecting the reception state of the reception signal, the reception state detection means, The number of error bytes in each Reed-Solomon block is detected based on the error position information obtained in the error correction processing process by the Reed-Solomon decoding means, and the margin for error correction capability is obtained for each Reed-Solomon block based on the above-mentioned error number. It is characterized in that the margin is output as a reception state of the reception signal.

In the receiving device, the number of errors for the Reed-Solomon block is detected based on the error position information obtained in the error correction processing process by Reed-Solomon decoding, the margin for the error correction capability is obtained based on the above-mentioned number of errors, and the above-mentioned margin Is output as the reception state of the reception signal. The output reception state is, for example, notified to the user or used as direction control information of the adaptive antenna.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION A receiver for digital satellite broadcasting (BS digital broadcasting) to which the present invention is applied will be described below as an embodiment of the present invention.

As shown in FIG. 1, the BS digital broadcast receiving apparatus 1 includes a tuner 11, a demodulation section 12, a Viterbi decoding section 13, a transmission path decoding section 14, an RS decoding section 15, and
The reception state detection unit 16, the reception state display unit 17, and the antenna control unit 18 are provided.

The antenna 2 is a so-called adaptive antenna which can control the receiving direction.

The RF signal received by the antenna 2 is input to the tuner 11. The tuner 11 is an amplifier,
It performs frequency conversion, filtering, etc., and outputs an IF signal. The output IF signal is supplied to the demodulation unit 12.

The demodulation section 12 performs digital quadrature demodulation on the IF signal and outputs I and Q signals which are quadrature modulated signals. The output I and Q signals are supplied to the Viterbi decoding unit 13.

The Viterbi decoding unit 13 performs Viterbi decoding on the transmission data that has been convolutionally coded. The Viterbi-decoded transmission data is supplied to the transmission path decoding unit 14.

The transmission path decoding unit 14 includes a deinterleaver, an inverse energy spreader, a TMCC (Transmission and Multipl).
exing Configration Control) Performs transmission channel decoding processing according to the transmission channel method such as signal decoding processing. The transmission data subjected to the transmission path decoding process is supplied to the RS decoding unit 15.

The RS decoding unit 15 performs RS decoding of RS (204, 188) in RS block units each consisting of 204 bytes, corrects error bytes existing in the RS blocks, and outputs a transport packet (TSP). Output. The output transport packet is supplied to an MPEG decoder or the like provided in the subsequent stage of the receiving device 1.

In the case of digital satellite broadcasting, a Reed-Solomon encoding process in which 16 bytes of parity is added to one transport packet of 188 bytes is performed. The RS encoding process of this RS (204,188) is RS
It is a degenerate code of (244, 239). RS (204,
The Reed-Solomon code of 188) is one block (204
It is possible to correct errors of up to 8 bytes present in (byte). That is, this RS (204,188)
The error correction capability of is 8 bytes, and if there is an error of 9 bytes or more in one RS block (204 bytes), that block cannot be corrected.

Here, the decoding of the RS code is performed by the following algorithm. Step 1 A syndrome is calculated from the received codeword to which an error has been added. Step 2 Obtain the error locator polynomial coefficient. Step 3 Solve the error locator polynomial. Step 4 Find the error pattern. Step 5 Subtract the error pattern from the received codeword.

In the RS decoding algorithm, when solving the error locator polynomial (step S3), one RS block (20
4 bytes), the position of the byte in which the error has occurred is specified. In the RS decoding unit 15, error position information obtained by solving this error position polynomial,
That is, information that identifies which byte position in the 1RS block has an error (hereinafter, error flag (Error
Flag). ) Is detected for each block and supplied to the reception state detection unit 16.

In the RS decoding algorithm, 1RS
If there are 9 or more error bytes in the block (204 bytes), the RS block cannot be corrected, but the error of the block cannot be corrected, that is, there are 9 or more error bytes. What you are doing can be detected. The RS decoding unit 15
When 9 bytes or more of error bytes exist in one block and an error exceeding the error correction capability exists in the block, the error correction impossible flag is set to the reception state detection unit 1
Supply to 6.

Further, the RS decoding section 15 also supplies a synchronization signal (Sync) indicating the head byte position of the RS block to the reception state detecting section 16.

The reception state detecting section 16 receives the error flag, the error correction impossible flag, and the synchronization signal (Sy).
nc) is input and the reception state of the reception signal received by the antenna 2 is detected based on these pieces of information.

The display unit 17 displays the reception state of the received signal to the user based on the detection result of the reception state detection unit 16.

The antenna control unit 18 includes the reception state detection unit 1
Based on the detection result of 6, the receiving direction of the antenna 2 that functions as an adaptive antenna is controlled. The antenna control unit 18 controls the direction of the antenna 2 to an optimum position so that the detection result by the reception state detection unit 16 becomes the best.

Next, the reception state detection unit 16 and the display unit 1
7 will be further described. FIG. 2 shows a configuration diagram of the reception state detection unit 16 and the display unit 17. Further, FIG. 3 shows a time chart of each signal in the reception state detection unit 16.

The reception state detecting section 16 includes a sync signal (Sync) indicating the head byte position of the RS block as shown in FIG. 3A and which byte in the RS block as shown in FIG. 3B. There is an error flag (Error Flag) that specifies whether there is an error byte in the RS block, and an error uncorrectable flag that indicates that an error exceeding the error correction capability exists in the RS block as shown in FIG. It is input from the decoding unit 15.

The reception state detecting section 16 uses the error counter 2
0, the first selector 21, the error register 22,
The second selector 23 and the error uncorrectable flag register 24 are provided.

The enable terminal (E of the error counter 20
An error flag is input to N).
A synchronization signal (Sync) is input to the load terminal (LD), and an error flag (Er) is input to the load data terminal (LDData).
ror Flag) is input. This error counter 20
When the enable terminal (EN) becomes active (H), the internal count value (Q) is incremented by 1. When the load terminal (LD) becomes active (H), the value input to the load data terminal (LDData) is loaded as the internal count value (Q).

That is, the error counter 20 is shown in FIG.
As shown in (D), an error flag (Error) input to the enable terminal (EN) between the byte position where the sync signal (Sync) is generated and the byte position immediately before the next sync signal.
Flag) counts the number of times it has become active. That is, the error counter 20 counts the number of error bytes generated in the 1RS block. In this error counter 20, the synchronization signal (Sync) is active (H).
Even if the error flag becomes active (H) at the byte position (that is, the first byte position of the RS block), the error flag cannot be counted. Therefore, in this error counter 20, by inputting an error flag (Error Flag) to the load data terminal (LDData), the synchronization signal (Sync) is active (H) and the error flag (Error Flag) is active (H). "1" is loaded to the count value (Q) when the count value is Q, and the count value (Q) is set when the synchronization signal (Sync) is active (H) and the error flag (Error Flag) is not active (L). ) Is loaded with "0".

The first selector 21 includes a count value (Q) of the error counter 20 and an error register 22 in the subsequent stage.
The stored value of and is input. The first selector 21 selects and outputs one of the signals according to the state of the synchronization signal (Sync). The first selector 21 controls the synchronization signal (Sy
nc) is active (H), error counter 2
A count value of 0 is selected and output. Second selector 2
When the synchronization signal is not active (L), 1 selects and outputs the value stored in the error register 22 at the subsequent stage.
The value output from the first selector 21 is stored in the error register 22.

That is, in the first selector 21 and the error register 22, when the sync signal is active (H) (that is, the first byte position of the RS block), the count value of the error counter 20 is set in the error register 22.
The stored value in the error register 22 is held at other timings. That is, the error register 22 holds the total number of error bytes generated in the previous RS block, as shown in FIG.

To the second selector 23, the error correction impossible flag and the value stored in the error correction impossible flag register 24 in the subsequent stage are input. The second selector 23 selects and outputs one of the signals according to the state of the synchronization signal (Sync). The second selector 23 controls the synchronization signal (Syn
When c) is active (H), the error correction impossible flag output from the RS decoding unit 15 is selected and output.
When the synchronization signal is not active (L), the second selector 21 receives the error correction impossible flag register 2 in the subsequent stage.
The stored value of 4 is selected and output. The value output from the second selector 23 is stored in the error register 23.

That is, in the second selector 23 and the error uncorrectable flag register 24, when the synchronization signal (Sync) is active (H) (that is, the first byte position of the RS block), the RS decoder 15 inputs the signal. The value (“1” or “0”) of the error uncorrectable flag is stored in the error uncorrectable flag register 24, and the stored value inside the error uncorrectable flag register 24 is held at other timings. That is, as shown in FIG. 3 (F), the error correction impossible flag register 24 holds a value (“0” or “1”) indicating whether or not error correction is impossible in the RS block. If the error correction of the RS block is impossible, the RS decoding unit 15 outputs an error correction impossible flag that becomes active (H) at least at the leading byte position of the RS block.

As described above, in the reception state detecting section 16, R
For each S block, the total error byte number X that has occurred in the RS block and the flag Y that indicates whether or not error correction is impossible in the RS block are output.

The error byte number X and the error uncorrectable flag Y are displayed on the display unit 17 and the antenna control unit 18.
Is supplied to.

The display section 17 includes a first to nth comparator 25-.
1 to 25-n and the first to nth OR circuits 26-1 to 26
-N and the first to (n + 1) th display units 27-1 to 27-
And (n + 1).

The first to nth comparators 25-1 to 25-n
Is provided with an input terminal A and an input terminal B, compares the value input to the input terminal A with the value input to the input terminal B, and the value input to the input terminal A is input. If it is larger than the value input to terminal B, the output is set to High,
When the value input to the input terminal B is larger than the value input to the input terminal A, the output is set to Low. The total number X of error bytes generated in the RS block held in the register 24 is input to the input terminal A of each of the comparators 25-1 to 2-n. Also, the first comparison value C1 is input to the input terminal B of the first comparator 25-1, and the second comparison value C2 is input to the input terminal B of the second comparator 25-2. The third comparator 25-3 is supplied with the third comparison value C3, and similarly the fourth to nth comparison values C4 to Cn, respectively. The comparison values C1 to Cn are threshold values between the levels for dividing the error amount occurring in the RS block into a predetermined number of levels, and the comparison values are C1 <C2 <C3 <.
... <Cn is appropriately determined. For example, if n is 8, C1 to Cn are set to 0 to 8.

That is, the first to nth comparators 25-1 to 25-1
25-n is the total number X of error bytes generated in the RS block held in the register 24 and the comparison values C1 to C1.
Cn is compared, and if the error byte number X is larger than each comparison value C1 to Cn, the output is set to High, and if the error byte number X is smaller than each comparison value C1 to Cn, the output is set to Low. . The output of the first comparator 25-1 is the first
Of the second comparator 25-2.
Is output to the second OR circuit 26-2, and similarly,
After that, the outputs of the comparators 25-3 to 25-n correspond to the corresponding O
It is input to the R circuits 26-3 to 26-n.

The first to nth OR circuits 26-1 to 26-n
Performs an OR logical operation on the outputs of the comparators 25-1 to 25-n and the error uncorrectable flag Y.

The first display section 27-1 emits light when the output of the first OR circuit 26-1 is High, and the first OR circuit 26-1 emits light.
It is turned off when the output of the circuit 26-1 is Low. In the second display section 27-2, the output of the second OR circuit 26-2 is H level.
It emits light when it is high and turns off when the output of the second OR circuit 26-2 is low. Similarly, the third display unit 27-3 to the n-th display unit 27-n have corresponding OR circuits 26-.
Lights up when the output of 3 to 26-n is High, and
Turns off when. In addition, the (n + 1) th display unit 27-
(N + 1) is turned on when the error uncorrectable flag Y is High, and is turned off when the error uncorrectable flag Y is Low. Then, these first to (n + 1) th display units 27-1 to 27- (n + 1) are the same as the receiving device 1
They are installed in a line in order in a place visible to the user, such as outside the casing of.

The operation of the display unit 17 having the above configuration will be described.

The total error byte number X is calculated by each comparator 25-1.
.About.25-n are compared with the respective comparison values C1 to Cn. When the total error byte number X is equal to or less than the comparison value C1, the outputs of all the comparators 25-1 to 25-n are Low. When the total error byte count X is larger than the comparison value C1 and not larger than C2, only the output of the first comparator 25-1 is Hi.
gh, and the outputs of the other comparators are Low.
When the total error byte number X is larger than the comparison value C2 and not larger than C3, the first comparator 25-1 to the second comparator 25-
The output of No. 2 becomes High, and the outputs of the other comparators become Low. Similarly, when X is C3 to C4, the first
To the third comparators 25-1 to 25-3 are High, and when X is C4 to C5, the first to fourth comparators 25-1 to 25-1 are
25-4 are High, ..., And when X is larger than Cn, the first to nth comparators 25-1 to 25-n
All outputs are High.

Further, the RS decoding unit 15 sets an error correction impossible flag to the reception state detection unit 16 for a TS packet in which an error of 9 bytes or more exists in one TS packet and the error cannot be corrected. Issue. When the error uncorrectable flag is issued, all the first to (n + 1) th display units 27 are turned on.

As a result of the above, each display unit 27-1 to 27-
(N + 1) is displayed as shown in FIG.

That is, when the transmission state is good, all the display portions are turned off, and thereafter, as the transmission state deteriorates, the number of display portions that are turned on increases one by one. Then, when the transmission state deteriorates and a TS packet that cannot be completely error-corrected is generated, all the display units of the TS packet are forcibly turned on.

As described above, in the receiving apparatus 1 according to the embodiment of the present invention, the number of errors for the Reed-Solomon block is detected based on the error position information obtained in the error correction processing process by Reed-Solomon decoding, and the error number is calculated as the error number. Based on this, the margin with respect to the error correction capability is obtained for each Reed-Solomon block, and the margin is displayed as the reception state of the received signal.

Therefore, in the receiving apparatus 1 according to the embodiment of the present invention, for example, before the current reception state becomes poor,
The user can be quantitatively notified of how much margin is available, and the user can take action before the reception state becomes completely poor by this notification.

Further, in the receiving apparatus 1 according to the embodiment of the present invention, the error number for the Reed-Solomon block is detected based on the error position information obtained in the error correction processing process by Reed-Solomon decoding, and the error correction is performed based on the error number. The margin with respect to the capability is obtained for each Reed-Solomon block, and the margin is output to the antenna control unit 18 as a reception state. Therefore, the antenna control unit 17 can quantitatively know whether the reception state is good or bad. For example, when the direction of the antenna is set,
That direction can be optimized.

In particular, the receiving apparatus 1 according to the embodiment of the present invention detects the reception state during the Reed-Solomon decoding process after the Viterbi decoding process. Therefore, it is possible to accurately grasp the reception state for all systems. Further, the error rate curve showing the characteristics of the transmission path (the curve showing the error rate with respect to C / N) usually has a steeper change in error rate as C / N increases. Therefore, the error rate becomes low after the Viterbi decoding process, and the residual error after the Viterbi decoding is C / N.
It also fluctuates sharply with respect to the slight fluctuations of. Therefore, for example, the output sensitivity in the direction of the antenna becomes very high,
It is possible to accurately grasp the optimum antenna direction.

Although the embodiment has been described above by taking the digital satellite broadcasting receiving device as an example, the present invention is not limited to the digital satellite broadcasting receiving device, and performs error correction processing using a convolutional code and a Reed-Solomon code. It can be applied to any system as long as it is a transmission system. For example, it can be applied to a digital mobile phone system and the like.

The means for notifying the user of the reception status is not limited to the means for displaying and notifying, but any means can be used to notify the user quantitatively how much margin is available for error correction processing. It may be a means. For example, when the antenna is adjusted or when a user pushes a predetermined button or the like, the notification may be given by voice or text. Further, the display content is not limited to the volume display as shown in FIG. 4, but, for example, as shown in FIG. 5, a plurality of display lights are arranged in a line, and when the reception state deteriorates, the lighting positions are changed one by one. A display method that shifts may be used. In the case of such a display system, as shown in FIG.
26-n, and AND circuits 28-1 to 28-n,
Inversion circuits 29-1 to 29-n and OR circuits 30-1 to 30-3
The control circuit may be configured using 0- (n-1).

[0055]

In the receiving apparatus according to the present invention, the number of errors for the Reed-Solomon block is detected based on the error position information obtained in the error correction processing process by Reed-Solomon decoding, and the margin for the error correction capability is detected based on the number of errors. And the margin is output as the reception state of the reception signal.

Therefore, the receiving apparatus according to the present invention can accurately detect the reception state of the received signal with a simple structure. The detected reception state can be used for, for example, notifying the user or controlling the direction of the adaptive antenna. In particular, the reception state of the reception signal detected by the present invention is directly obtained based on the margin of the number of error occurrences with respect to the error correction capability of Reed Solomon. Therefore, for example, before the current reception status becomes poor,
You can see how much you can afford. Therefore, the user can take action before the reception state becomes completely poor. For example, even when reception is possible, it is possible to detect whether the reception condition is better or worse, and the direction of the antenna can be optimized based on the detection result, or the reception channel can be previously set. Can be switched.

[Brief description of drawings]

FIG. 1 is a block configuration diagram of a digital satellite broadcast receiving apparatus according to an embodiment of the present invention.

FIG. 2 is a diagram for explaining a configuration of a reception state detection unit of the reception device.

FIG. 3 is a diagram for explaining signal timing in the reception state detection unit.

FIG. 4 is a diagram for explaining display contents for notifying a user of a transmission state.

FIG. 5 is a diagram for explaining another display example of the transmission state.

FIG. 6 is a diagram for explaining a configuration example of a reception state display control unit for displaying in another display example shown in FIG.

[Description of Reference Signs] 1 receiving device, 2 antennas, 11 tuners, 12
Demodulation unit, 13 Viterbi decoding, 14 transmission path decoding unit, 15
RS decoding unit, 16 reception state detection unit, 17 display unit, 1
8 Antenna control unit

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H04L 1/00 H04L 1/00 B

Claims (3)

[Claims] 1. A receiving device for receiving transmission data digitally modulated with respect to a predetermined carrier signal, which is convolutionally encoded after being added with a Reed-Solomon code. Demodulation means for demodulating the transmission data, a transmission path decoding means for decoding the transmission data demodulated by the demodulation means according to a transmission method, a Viterbi decoding means for Viterbi decoding the transmission data output from the transmission path decoding means, and the Viterbi Reed-Solomon decoding means for performing error correction on the transmission data using the Reed-Solomon code added to the transmission data output from the decoding means, and reception state detection means for detecting the reception state of the reception signal. The receiving state detecting means is obtained in the error correction processing process by the Reed-Solomon decoding means. The number of error bytes in each Reed-Solomon block is detected based on the error position information, the margin for error correction capability is calculated for each Reed-Solomon block based on the number of errors, and the margin is output as the reception state of the received signal. A receiver characterized by being. 2. The receiving device according to claim 1, further comprising notifying means for notifying a user of the reception state of the reception signal detected by the reception state detection means. 3. An antenna control means for controlling the directivity of an antenna for receiving the received signal is provided, wherein the antenna control means has an optimum receiving state based on the receiving state of the received signal detected by the receiving state detecting means. The receiving apparatus according to claim 1, wherein the orientation of the antenna is controlled so that