JP2002232809A - Receiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a receiver for a mobile object corresponding to the digital TV broadcast of a single channel. SOLUTION: A detector 3 detects the error of a video signal I1 outputted by a decoder 21 and outputs the positional information to an extraction device 4. The device 4 outputs a signal at a position to which a video signal I2 corresponds as a corrected video signal IA to a compositing device 5 based on the erroneous positional information of the signal I1 outputted by the detector 3. The device 5 forms a composited video signal IC from the signal I1 and the signal IA and outputs it to a display device 9. Thus, an erroneous pixel in a high resolution video signal I1 is corrected by a pixel at a position corresponding to a low resolution video signal I2 which seldom has an error, thereby the quality of a composited video picture IC to be outputted is improved. Namely, even when receiving environment is poor or when receiving environment is varied such as when an obstacle exists or when a receiver moves, the digital TV receiver can display a natural picture without the occurrence of a cliff effect.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a receiver for digital transmission / reception, and more particularly to a receiver for digital broadcasting, and more particularly, for digital TV broadcasting. The present invention is particularly effective for a digital TV broadcast receiver mounted on a mobile object.

[0002]

2. Description of the Related Art OFDM systems using terrestrial waves (Orthogon
al Frequency Division Multiplexing (orthogonal frequency division modulation) is about to start, but unlike satellite broadcasting, it is susceptible to delays caused by obstacles, so the so-called cliff effect peculiar to digital communications is remarkable. There is a possibility that. That is, the error of a certain limit is corrected by the error correction code technology and the like, and the broadcast becomes extremely high quality, for example, high quality. Playback may not be possible. The cliff effect is caused not only by obstacles in fixed reception, but also by a sudden change in the reception environment of a receiver mounted on a mobile object, and it is urgently necessary to develop a receiver that can cope with those cliff effects.

However, it is not considered that the current analog TV broadcast is immediately and completely switched to digital TV broadcast. That is, it is expected that the viewer will sequentially replace the analog TV receiver with a digital TV receiver or a dual analog / digital receiver.
It is considered that a simulcast system for simultaneously broadcasting the same program by V broadcast and digital TV broadcast is performed for a period of time. Under such a premise, Japanese Patent Laid-Open Publication No. Hei 4-369189 or Japanese Patent Laid-Open Publication No.
The invention described in Japanese Patent Publication No. 00-332632 has been proposed.

[0004]

The above two documents are based on the simultaneous cast system for simultaneously broadcasting the same program in analog TV broadcasting and digital TV broadcasting. However, it cannot deal with the cliff effect in digital reception at all.

The present invention has been made to prevent a cliff effect in one-channel digital TV broadcasting, which is not a simulcast system between analog TV broadcasting and digital TV broadcasting.

[0006]

According to a first aspect of the present invention, there is provided a receiver for receiving a digital TV broadcast using a terrestrial wave. A demodulator for outputting the first and second video stream data, a first decoder and a second decoder for respectively decoding the first and second video stream data and outputting the first and second video signals, A detection device for detecting a position of an error included in the first video signal, and an extraction for extracting, from the second video signal, a corrected video signal corresponding to the error position of the first video signal detected by the detection device And a synthesizing device for synthesizing the first video signal and the corrected video signal into one synthesized video signal. In the present invention, the audio signal may be demodulated by the demodulator, or may be demodulated by another demodulator. The main part of the present invention relates to a video signal, and each component constituting the present invention may be related to demodulation of an audio signal, or may not be related at all. Decoding is generally performed by a transmitting station after performing high-efficiency coding such as MPEG-2 and transmitting the data, and the receiver side decodes the data in response to the coding. The first and second video stream data may be the same, but the first and second video signals are not the same.

According to a second aspect of the present invention, there is provided the receiver according to the first aspect, further comprising a filter for mitigating discontinuity of the synthesized video signal. According to a third aspect of the present invention, in the receiver according to the first aspect, a frequency of an error included in the first video signal is detected from an output of the detection device, and the frequency is set to a threshold value. And a switch for switching and outputting the combined video signal and the second video signal based on the determination of the determiner.

According to a fourth aspect of the present invention, in the receiver according to any one of the first to third aspects, the first video signal and the second video signal have different resolutions. A video of the same object, wherein the first video signal has a higher resolution than the second video signal.

According to a fifth aspect of the present invention, there is provided a receiver for receiving a digital TV broadcast using a terrestrial wave, a demodulator for outputting first and second video stream data from the received wave. A detecting device that detects an error position of the first video stream data, and a corrected video stream data corresponding to the error position of the first video stream data detected by the detecting device from the second video stream data. An extracting device for extracting, a synthesizing device for synthesizing the first video stream data and the corrected video stream data into one synthesized video stream data, and a decoder for decoding the synthesized video stream data and outputting a video signal It is characterized by having.

[0010]

In the digital TV broadcasting by terrestrial broadcasting, the transmitting side (broadcasting station) mainly uses OF.
It is transmitted (broadcast) by a modulation method such as DM. Prior to this modulation, for multiplexing, a method is used in which a bit stream as a video or audio signal sequence is bundled in packet units, and further a packet stream in program units is further bundled. Error correction coding is performed thereafter. In the present application, such a state before modulation is referred to as “video stream data”. That is, a video or audio signal is encoded on the transmission side, extracted into “video stream data”, and then modulated and transmitted. Note that a signal for video reproduction is essential for the “video stream data”, but an audio signal is not necessarily essential.

Therefore, if such a digital TV broadcast is received and the demodulator of the receiver outputs the first and the second video stream data, the digital TV broadcast side pumps up the "video stream" to one channel. It is possible to transmit so that there are substantially two "data", ie two images. The two images may be exactly the same image, or images having different resolutions for the same object, or an arbitrary combination such as a color image and a black and white image. According to the first aspect of the present invention, two video signals are decoded, an error position (pixel unit) of the first video signal is detected, and a corresponding corrected video signal is extracted from the second video signal. And the first
Error portion of the video signal can be corrected by the corrected video signal. Thereby, even when the image based on the first image signal is poor or when the first image signal due to the cliff effect is not reflected at all, a composite image signal can always be obtained from the second image signal. When the demodulator demodulates one video stream data obtained by multiplexing two video stream data, and the two decoders reproduce different video signals, the two video streams are multiplexed into one video stream data. After extracting one video stream data, the video signal is reproduced.

If the synthesized video signal is passed through a filter, even if a discontinuous portion occurs in the synthesized video, it can be mitigated (claim 2). Further, when the frequency of error of the first video signal is equal to or higher than a certain value, by selecting only the second video signal, a more natural image can be obtained (claim 3). If the first video signal and the second video signal are images of the same object having different resolutions, and the first video signal has a higher resolution than the second video signal, if the reception environment is good, A high-resolution image of the first video signal can be displayed, and a low-resolution image of the second video signal can be displayed when the reception environment is poor (claim 4). It is obvious that the error correction code and the like can be more powerfully incorporated in a signal system including a low-resolution image with a small amount of information.

The same effect is obtained when the error detection of claim 1 is performed at two video stream data stages (claim 5).

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [First Embodiment] FIG.
2 shows a specific configuration of a receiver 100 according to a first embodiment.
It is a block diagram. Received wave from antenna goes to demodulator 1
Is forced. Demodulator 1 converts two video streams from the received wave.
Data S₁, S_TwoAnd demodulates the video stream data S ₁
To the decoder 21 and the video stream data S_TwoThe
Output to the application 22. The decoder 21 outputs the video stream data.
TA S₁To decode the video signal I₁, And the decoder 2
2 is video stream data S_TwoDecode the video signal
I_TwoIs output. Here, the video signal I₁Is the video signal I_TwoYo
Video stream data on the modulation side.
S₁, S_TwoHigher resolution when adding error correction code to
Video signal I₁Stream data encoded with
S₁Only the weaker error correcting code with less redundancy
I can't get it. Conversely, the lower resolution video signal I
_TwoStream data S that encodes_TwoIs the redundancy
, And a strong error correction code can be added. Yo
Therefore, on the demodulation side, demodulation and error
Corrected video stream data S₁Is the video stream
Data S_TwoWill be more error-prone. Those
Decoded video signal I₁, I_TwoFor the video signal I
₁Often have errors, but the video signal I_TwoIs extremely rare
Or have no error.

The detecting device 3 detects an error in the video signal I ₁ output from the decoder 21 and detects its position information (pixel position).
Is output to the extraction device 4. Extracting device 4, based on the position information of the error of the video signal I ₁ output from the detecting unit 3 (pixel position), combining the signals of corresponding position of the video signal I ₂ (pixel position) as the corrected image signal I _A Output to the device 5.

The synthesizing device 5 forms a synthesized video signal I _C from the video signal I ₁ and the corrected video signal I _A, and outputs the synthesized video signal I _C to the display device 9. Thus, the error pixels of the high resolution of the video signal I ₁ is, since it is corrected by the pixel in the corresponding position of rarely having no low-resolution image signal I ₂ errors, quality of the composite video image I _C to be output improves. That is, according to the present embodiment, the cliff effect does not occur even when the reception environment is poor or the reception environment fluctuates, such as when there is an obstacle or when the receiver is moving. The digital TV receiver can display a simple image.

[Second Embodiment] FIG. 2 is a block diagram showing a configuration of a receiver 200 according to a second embodiment of the present invention. The receiver 200 of this embodiment has a configuration in which a filter 6 is added between the synthesizing device 5 and the display device 9 in the receiver 100 of the first embodiment. The filter 6 removes high-frequency components in the image, and may use a low-pass filter such as a Butterworth filter, a frequency analysis by two-dimensional fast Fourier transform, or any other filter. In this manner, in the present embodiment, as in the first embodiment, the synthesized video image I _C output from the synthesizing device 5 has a low resolution in which the erroneous pixels in the high resolution video signal I ₁ rarely have an error. since those corrected by the pixel in the corresponding position of the video signal I ₂ of, it is obtained by improving the image quality. By making this the output I _C ′ through the filter 6,
It is possible to alleviate the discontinuity of the peripheral pixels generated by the replaced high-resolution error pixels in the video signal I ₁ to the pixel in the corresponding position of the low-resolution image signal I _2. Therefore, according to the present embodiment, a digital TV receiver that displays a more natural image than the first embodiment can be provided.

Third Embodiment FIG. 3 shows a specific embodiment of the present invention.
A block showing a configuration of a receiver 300 according to the third embodiment.
FIG. The receiver 300 of the present embodiment is a receiver of the first embodiment.
In the communication device 100, the size is determined between the synthesizing device 5 and the display device 9.
A switching device 8 having an integrator 7 is added.
The output of the unit 3 and the output of the decision unit 7 and the decoder
22 output I _TwoAnd the output I of the synthesizer 5_CAnd enter
It is good.

As in the first embodiment, the synthesized video image I _C output from the synthesizing device 5 is composed of a low-resolution video signal I ₂ in which erroneous pixels in the high-resolution video signal I ₁ rarely have an error. Since the image is corrected by the pixel at the corresponding position, the image quality is improved. However, for reasons such as there are many discontinuities, there may be a case that an unnatural image than the low resolution image signal I _2. Therefore, the output of the detection device 3 that detects an error in the high-resolution video signal I ₁ is tracked by the determiner 7 to measure the frequency of the error. Whether the frequency of this error exceeds the set value (threshold)
The judgment period 7 is output to the switch 8. High resolution video signal I
_If the frequency of errors in ₁ does not exceed the threshold, switch 8
Displays the composite video image I _C output from the composite device 5 on the display device 9.
Output to When the frequency of errors in the high-resolution video signal I ₁ exceeds the threshold, the switch 8 outputs the low-resolution video signal I ₂ output from the decoder 22 to the display device 9.
Thus, such as when the discontinuity occurs a number to a high resolution video signal I ₁ error frequency synthesized video image exceeds the threshold value I _C for in, the more natural low-resolution image signal I ₂ is display device Since it is output, it is possible to prevent the viewer from being unnatural. Therefore, according to the present embodiment, a digital TV receiver that displays a more natural image than the first embodiment can be provided.

Fourth Embodiment FIG. 4 is a block diagram showing a configuration of a receiver 400 according to a fourth embodiment of the present invention. This example for two video stream data S _1, S ₂ output by the demodulator, in which to correct the error position of the video stream data S ₁ from the corresponding position of the video stream data S _2.

The received wave is output from the antenna to the demodulator 1. The demodulator 1 demodulates two pieces of video stream data S ₁ and S ₂ from the received wave, and sends the video stream data S ₁ to the detection device 30 and the synthesis device 50, and to the video stream data S ₂
Is output to the extraction device 40. Here, the video signal I ₁ obtained when the video stream data S ₁ is decoded is
It is assumed that the resolution is higher than the video signal I ₂ obtained when the video stream data S ₂ is decoded.

The detecting device 30 outputs the video stream data S
_One error is detected, and the position information is output to the extraction device 40. Meanwhile the video stream data S ₁ is the data of a so-called packet unit, detector 30 detects the position of the packet containing the error. Based on the position information of the erroneous packet of the video stream data S ₁ output from the detection device 30, the extraction device 40 converts the signal at the corresponding packet position of the video stream data S ₂ as a corrected video data stream signal S _A Output to 50. Synthesizer 50
From the video stream data S ₁ and the correction video data stream signal S _A, to form a composite stream data S _C, and outputs to the decoder 20. The decoder 20 decodes the composite video stream data S _C to form a video signal I, and outputs the video signal I to the display device 9. Thus, since the errors in the video stream data S ₁ having a video signal I ₁ of the high resolution is corrected by the corresponding position of the small stream data S ₂ erroneous having a low resolution video signal I _2, is output that the video signal I having a combined video stream data image S _C is the image quality is improved than that by decoding the video stream data S ₁ having an error. That is,
According to the present embodiment, even if the reception environment is poor or the reception environment fluctuates, such as when there is an obstacle or the receiver is moving, a natural image that does not cause a cliff effect Can be displayed as a digital TV receiver.

In the first to third embodiments, the error correction of the video signal is performed in units of pixels. However, the correction may be performed in units of blocks, fields, or frames of a plurality of pixels. When a plurality of screens are transmitted as one unit of video stream (time slot), a correction between screens (on a time axis) may be performed. Further, in the configurations of the first and second embodiments, there is a possibility that the image is substantially replaced with a low-resolution image for each screen, and it is natural that the operation may be similar to that of the third embodiment.

In the first to third embodiments, the demodulator is 2
Although the two different video stream data are output to the decoder, the demodulator demodulates the two different video stream data in the form of one multiplexed video stream data, and outputs the one video stream data to the decoder. , And each decoder extracts different video stream data therefrom and decodes the same, which is also included in the present invention.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a receiver according to a first specific example of the present invention.

FIG. 2 is a block diagram showing a configuration of a receiver according to a second specific example of the present invention.

FIG. 3 is a block diagram showing a configuration of a receiver according to a third specific example of the present invention.

FIG. 4 is a block diagram showing a configuration of a receiver according to a fourth specific example of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Demodulator 21,22,20 Decoder 3,30 Detection device 4,40 Extraction device 5,50 Synthesis device 6 Filter 7 Judge 8 Switching device 9 Display device 100,200,300,400 Receiver

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H04N 7/24 (72) Inventor Junji Imai 41, Chukuji Yokomichi, Oku-cho, Nagakute-cho, Aichi-gun, Aichi Inside Toyota Central Research Laboratory Co., Ltd. (72) Inventor Noriyuki Shibata 41-41, Ochi-cho, Yokomichi, Nagakute-cho, Aichi-gun, Aichi Prefecture F-term in Toyota Central Research Laboratory Co., Ltd. 5C025 AA30 BA03 BA30 DA01 DA07 5C059 KK01 RA04 RB02 RF05 RF07 SS02 UA05 UA17 5C063 AB03 AB06 AB11 AC01 DA01

Claims (5)

[Claims] 1. A receiver for receiving a digital TV broadcast using a terrestrial wave, a demodulator for outputting first and second video stream data from a received wave, the first and second video streams A first decoder and a second decoder that respectively decode data and output first and second video signals; a detection device that detects an error position included in the first video signal; An extraction device for extracting a corrected video signal corresponding to a position of an error of the first video signal detected by the detection device from the video signal, and synthesizing the first video signal and the corrected video signal And a synthesizing device for generating one synthesized video signal. 2. The receiver according to claim 1, further comprising a filter for mitigating discontinuity of the composite video signal. 3. A determiner for detecting a frequency of an error included in the first video signal from an output of the detection device, and determining whether the frequency exceeds a set threshold value, and the composite video signal. The receiver according to claim 1, further comprising: a switch that switches and outputs the second video signal and the second video signal based on the determination of the determiner. 4. The video signal according to claim 1, wherein the first video signal and the second video signal are images of the same target having different resolutions, and
4. The receiver according to claim 1, wherein the video signal has a higher resolution than the second video signal. 5. 5. A receiver for receiving a digital TV broadcast using a terrestrial wave, a demodulator for outputting first and second video stream data from a received wave, and an error in the first video stream data. A detection device for detecting a position of the first video stream data; and an extraction device for extracting, from the second video stream data, corrected video stream data corresponding to an error position of the first video stream data detected by the detection device; A synthesizing device for synthesizing first video stream data and the corrected video stream data into one synthesized video stream data; and a decoder for decoding the synthesized video stream data and outputting a video signal. Features receiver.