JP2004312361A - Digital broadcast reception system, digital broadcast reception method, and mobile body - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the quality of entire received broadcast by preventing breaks of sounds even in circumstances wherein the reception condition of digital broadcast reception is largely changed and improving the quality of receivable images as much as possible. <P>SOLUTION: A digital broadcast reception device comprises a demodulation part 1 for fixing, a demodulation part 2 for movement, buffer memories 3 and 4 connected to demodulation parts 1 and 2 respectively, a timing detection part 5, a BER monitor part 6, a switching processing part 7, an antenna 8, and a tuner 9. When digital data being broadcasted are received and outputted, one digital sound signal is always utilized as a sound output, and as a video output, mobile broadcast digital image data for mobile bodies and fixed broadcast digital image data for fixed bodies are utilized while being mutually switched in accordance with a reception quality. When the digital broadcast reception device is installed in a moving body, digital image data are switched in accordance with the speed of the mobile body. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a digital broadcast receiving apparatus, a digital broadcast receiving method, and a mobile unit, and more particularly, to a digital TV broadcast receiver mounted on a mobile unit among receivers for receiving digital broadcasts such as digital TV broadcasts. It is suitable.
[0002]
[Prior art]
2. Description of the Related Art In recent years, digital terrestrial broadcasting includes broadcasting for a fixedly installed receiver (hereinafter referred to as fixed broadcasting) and broadcasting for a receiver mounted on a mobile body (hereinafter referred to as mobile broadcasting). And is scheduled.
[0003]
Among them, fixed broadcasts have the advantage of being able to receive high-resolution video, but have the limitation that the receivable area and situation are limited due to the high required received wave quality.
[0004]
On the other hand, broadcasting for mobiles has an advantage that a receivable area can be made extremely wide as compared with fixed broadcasting by adopting a modulation method in consideration of reception of digital broadcasting in mobiles. On the other hand, there is a limitation that the video has a low resolution.
[0005]
[Patent Document 1]
JP 2001-77712 A
[0006]
[Problems to be solved by the invention]
Therefore, it has been difficult to enjoy the advantage of high image quality by digital terrestrial broadcasting only with mobile broadcasting.
[0007]
Therefore, an object of the present invention is to prevent interruption of audio even in a situation where the reception status of digital broadcast changes greatly, such as when the digital broadcast receiver is mounted on a mobile body, and to improve the quality of receivable video. It is an object of the present invention to provide a digital broadcast receiving apparatus and a digital broadcast receiving method capable of improving the quality of a received broadcast as much as possible and improving the overall received broadcast quality.
[0008]
Another object of the present invention is to enable high-quality broadcasts to be received both while moving and when stopped, so that users viewing digital broadcasts on a mobile object can enjoy the services. It is an object of the present invention to provide a mobile object capable of improving the overall quality of a received broadcast.
[0009]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides
When receiving and outputting a digital broadcast, the same digital audio signal is always used for audio output, and the first digital video signal and the second digital video signal are used for video output in accordance with the level of reception quality. Switching between digital video signals
It is characterized by the following.
[0010]
Specifically, the first invention of the present invention is:
Receiving means configured to be able to receive the first digital video signal, the digital audio signal, and the second digital video signal;
A signal synchronization means configured to be able to synchronize the first digital video signal and the digital audio signal, and configured to be able to synchronize the second digital video signal and the digital audio signal;
At least an error monitoring means configured to be able to compare an error rate in the second digital video signal with an error rate threshold value;
Switching processing means configured to switch between the first digital video signal and the second digital video signal,
The audio based on the digital audio signal is always output, and the first digital video signal and the second digital video signal are output based on the magnitude of the error rate and the error rate threshold value compared by the error monitoring means. It is configured to be able to output by switching between digital video signals
A digital broadcast receiving apparatus characterized in that:
[0011]
In the first invention, the received first digital video signal and the second digital video signal are configured to be seamlessly switchable, and the first digital video signal is demodulated as necessary. Typically, the first digital video signal and the digital audio signal are demodulated to enable efficient monitoring of the signal error rate and comparison of the error rate with a predetermined error rate threshold. A first demodulating unit that performs demodulation, a second demodulating unit configured to demodulate at least a second digital video signal, and a buffer that buffers signals demodulated by the first demodulating unit and the second demodulating unit. A first digital video signal and a digital audio signal demodulated by the first demodulation means; and a second digital signal demodulated by the second demodulation means. Buffering means for buffering the first digital video signal and the digital audio signal, or synchronizing the second digital video signal and the digital audio signal with the signal synchronizing means. Synchronization with the signal is configured to be executable. In the first invention, preferably, buffering of various digital data by a buffering means is performed so that switching between the first digital video signal and the second digital video signal can be performed seamlessly. , And synchronization by the signal synchronization means is configured to be executable by frame synchronization such as frame correlation.
[0012]
Further, the second invention of the present invention
At least a first digital video signal, a digital audio signal, and a second digital video signal are received by a receiving unit that receives a digital signal;
The signal synchronizing means for synchronizing the signals synchronizes at least one of the synchronization of the first digital video signal and the digital audio signal received by the receiving means and the synchronization of the second digital video signal and the digital audio signal. Run,
Error monitoring means for comparing an error rate in the second digital video signal with an error rate threshold,
The first processing is performed by the switching processing means, which always outputs the sound based on the digital sound signal and switches the input signal based on the comparison between the error rate and the error rate threshold value, which is executed by the error monitoring means. Switching between digital video signal output and second digital video signal input
A digital broadcast receiving method characterized by the following.
[0013]
In the second invention, the received first digital video signal and the second digital video signal are switched seamlessly and, if necessary, the error rate of the demodulated first digital video signal is changed. In order to efficiently monitor and compare the error rate with a predetermined error rate threshold value, typically, the first digital video signal and the first digital video signal are demodulated by first demodulation means for demodulating the compressed signal. A digital audio signal is demodulated, and at least a second digital video signal is demodulated by a second demodulating means, and then the digital signal is buffered by a first demodulating means and a second demodulating means by a buffering means for buffering the digital signal. Buffering the demodulated first digital video signal, second digital video signal and digital audio signal, Synchronization with ring to the first digital video signal and digital audio signal, and performs at least one of synchronous synchronization with the second digital video signal and digital audio signal buffered. Further, in the second invention, in order to enable the switching between the first digital video signal and the second digital video signal to be performed seamlessly, preferably, synchronization of various digital data is performed by using frame correlation or the like. This is performed by using a frame synchronization or a time synchronization signal included in digital data. However, synchronization of various types of digital data is not necessarily limited to frame correlation or use of a time synchronization signal. Synchronizes digital data.
[0014]
Further, the third invention of the present invention
A receiving unit configured to be able to receive the first digital video signal, the digital audio signal, and the second digital video signal; and a first digital video signal and the digital audio signal configured to be synchronized. A second digital video signal and a digital audio signal; a signal synchronization unit configured to be able to synchronize the digital audio signal; an error monitoring unit configured to measure an error rate of the second digital video signal; Switching processing means configured to be able to switch between the second digital video signal and audio data based on the digital audio signal. A digital broadcast receiving apparatus configured to switch and output the first digital video signal and the second digital video signal based on the first digital video signal and the second digital video signal. That
A moving object characterized by the following.
[0015]
In the third invention, preferably, the switching processing means is configured to be capable of inputting speed information, and based on at least one of the speed information and the error rate compared by the error monitoring means, the first digital video image is displayed. It is configured to switch between a signal and a second digital video signal.
[0016]
That is, when the error rate of the second digital video signal detected by the error monitoring means is equal to or higher than a predetermined error rate, and / or when the speed of the moving object detected by the speed detection means is equal to or higher than the predetermined speed. The output digital video signal is switched to the first digital video signal, or the error rate of these second digital video signals is less than a predetermined error rate, and / or When the speed of the moving object becomes lower than the predetermined speed, the moving object is switched to the second digital video signal.
[0017]
According to a fourth aspect of the present invention,
A receiving unit configured to be able to receive the first digital video signal, the digital audio signal, and the second digital video signal; and a first digital video signal and the digital audio signal configured to be synchronized. A second digital video signal and a digital audio signal; a signal synchronizing means configured to be able to synchronize the digital audio signal; a speed information capable of being input; and a first digital video signal and a second digital video signal being switchable. Switching processing means, configured to be capable of constantly outputting audio based on the digital audio signal, and switching and outputting the first digital video signal and the second digital video signal based on the detected speed information. Digital broadcast receiving device configured to
A moving object characterized by the following.
[0018]
In the present invention, the first digital video signal and the second digital video signal are mutually composed of the same video information as a video output, and the digital audio signal is synchronized with the first digital video signal. It is composed of audio information suitable for one digital video. That is, the first digital video signal, the second digital video signal, and the digital audio signal are digital signals that output the broadcast of the same program.
[0019]
In the present invention, preferably, the magnitude of the error rate is determined by the error monitoring unit after the buffering is performed by the buffering unit. After the buffering means buffers the first digital signal, the second digital signal, and the audio signal, the error monitoring means compares the error rate with the error rate threshold value. Based on this, the switching processing means switches between the first digital video signal and the second digital video signal.
[0020]
In the present invention, typically, when the error rate monitored by the error monitoring means is equal to or more than the error rate threshold, the first digital video signal is output, and the error rate monitored by the error monitoring means is reduced. When the error rate is less than the threshold, the second digital video signal is output.
[0021]
In the present invention, typically, the first digital video signal and the digital audio signal are digital broadcast signals for a mobile object, and the second digital video signal is a digital broadcast signal for fixed.
[0022]
According to the digital broadcast receiving apparatus and digital broadcast receiving method according to the present invention configured as described above, the same digital audio signal is always used for audio information, and the second digital Using the video signal, the first digital video signal is used in a state where the reception quality is low, and the first digital video signal and the first digital video signal are used based on the magnitude of a predetermined error rate threshold value and error rate. By switching between the two digital video signals, it is possible to output the highest quality video within the receivable range for video information, and to interrupt audio output for audio information. Since it is possible to avoid such a situation, the overall broadcast reception quality can be improved.
[0023]
Further, according to the present invention, in a mobile body equipped with the digital broadcast receiving apparatus, when the digital broadcast receiving apparatus can receive a high-quality digital signal, the digital broadcast receiving apparatus outputs a high-quality image, and outputs a high-quality digital signal. When a signal cannot be received, a relatively low-quality video signal can be received and a video based on this video signal can be output. A digital broadcast that can be viewed on a mobile object because it can output high-quality video and can prevent audio interruption, which is an intuitively important factor for mobile users, regarding audio. Can improve the overall broadcast reception quality.
[0024]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In all the drawings of the following embodiment, the same or corresponding parts are denoted by the same reference numerals. FIG. 1 shows a digital receiver according to this embodiment.
[0025]
As shown in FIG. 1, the digital receiving apparatus according to the embodiment includes a fixed broadcast demodulator 1, a mobile broadcast demodulator 2, a fixed broadcast demodulator 1, and a mobile broadcast demodulator. It comprises buffer memories 3 and 4, a timing detector 5, a bit error rate monitor 6 and a switching processor 7, which are connected to the unit 2. The digital receiving apparatus is configured to be able to receive digital data being broadcast from an antenna 8 via a tuner 9.
[0026]
The fixed broadcast demodulation unit 1 performs demodulation processing on digital data compressed and broadcast for fixed broadcast (hereinafter, fixed broadcast). The data demodulated by the fixed broadcast demodulation unit 1 includes fixed broadcast digital audio data (fixed digital audio data) and fixed broadcast digital video data (fixed digital audio data) as a second digital video signal. Video data).
[0027]
Here, in this embodiment, with respect to the digital audio data for fixed broadcasting, when broadcasting to a mobile object is performed, the audio may be interrupted in a device provided in the mobile object. Thus, it is also possible to configure so that the digital audio data for fixing is not demodulated. Note that even in this case, demodulation of at least the digital video data for fixing is necessary.
[0028]
The mobile broadcast demodulator 2 is for performing demodulation processing on digital data compressed and broadcast for mobile (portable) broadcast (mobile broadcast). The data demodulated by the mobile broadcast demodulation unit 2 includes mobile broadcast digital audio data (mobile broadcast digital audio data) as a digital audio signal and mobile broadcast digital audio data as a first digital video signal. Digital video data (mobile broadcast digital video data).
[0029]
Each of the buffer memories 3 and 4 as buffering means temporarily stores demodulated fixed broadcast digital data and demodulated mobile broadcast digital data for a short time, that is, performs buffering. Memory.
[0030]
By temporarily storing the demodulated digital data in these buffer memories 3 and 4, it is possible to continuously transfer the demodulated digital data within a possible range.
[0031]
By buffering various demodulated digital data using the buffer memories 3 and 4, the switching between the fixed broadcast digital data and the mobile broadcast digital data by the switching processing unit 7 described later can be performed seamlessly. It can be performed continuously, so-called seamlessly.
[0032]
Further, the timing detection unit 5 outputs the demodulated fixed broadcast digital data (fixed broadcast digital data) output from the buffer memory 3 and the demodulated mobile broadcast digital data output from the buffer memory 4. This is for detecting a synchronization timing with data (mobile broadcast digital data).
[0033]
The bit error rate monitor 6 monitors the bit error rate. Then, by comparing the error rate relating to the image data with a predetermined error rate threshold value to be described later, the switching timing between the output of the fixed broadcast digital data and the output of the mobile broadcast digital data can be detected. .
[0034]
The switching timing detected by the bit error rate monitoring unit 6 is output as a switching signal. The details of the timing of switching between the output of the fixed broadcast digital data and the output of the mobile broadcast digital data will be described later.
[0035]
The switching processing unit 7 serving as a switching processing unit outputs the fixed digital data and the mobile digital data synchronized by the timing detection unit 5 from the bit error rate monitoring unit 6 serving as an error monitoring unit. This is for performing a switching process based on the switching signal to be performed.
[0036]
That is, the fixed broadcast digital data and the mobile broadcast digital data synchronized by the timing detection unit 5 are supplied to the switching processing unit 7 at the same timing. Then, the switching processing unit 7 selects one of the fixed broadcast digital data and the mobile broadcast digital data based on the switching signal supplied from the bit error rate monitoring unit 6, and selects the selected digital data. Data is output as demodulated data.
[0037]
The demodulated data is supplied to a digital video / audio reproduction device (neither is shown) such as a digital broadcast compatible liquid crystal television or a CRT (Cathode Ray Tube) having a built-in digital / analog (D / A) conversion circuit. Then, audio and video based on the demodulated data are output.
[0038]
A digital broadcast receiving method using the digital broadcast receiving apparatus according to an embodiment of the present invention configured as described above will be described. FIG. 2 shows a flowchart of the digital reception processing method according to this embodiment.
[0039]
First, as a premise, digital terrestrial broadcasting currently includes fixed broadcasting and mobile broadcasting. Among these fixed broadcasts, although extremely high-resolution video can be obtained, the required reception wave quality is high, so that the receivable area and the receivable state are limited.
[0040]
On the other hand, mobile broadcasting employs a modulation method that takes into account reception in a mobile body such as a vehicle or a portable terminal, so that the receivable area and the receivable condition are wider than those of fixed broadcasting. However, the image quality is low.
[0041]
Therefore, a digital broadcast receiving apparatus according to an embodiment of the present invention is provided in a mobile terminal such as a PDA or a portable DTV receiver, or a mobile body such as a vehicle, and the overall digital broadcast reception quality is improved.
[0042]
That is, as shown in FIG. 2, in this embodiment, first, in step ST1, the fixed broadcast digital data is subjected to demodulation processing in the fixed broadcast demodulator 1 in step ST1. At this time, for example, a bit error rate (BER) in error correction using a Reed-Solomon (RS) code is measured.
[0043]
Thereafter, in step ST2, the demodulated fixed broadcast digital data is temporarily stored in the buffer memory 3, and a so-called buffering process is performed.
[0044]
On the other hand, in parallel with the processing on the fixed broadcast digital data, the demodulation unit 2 for mobiles performs the same demodulation processing on the input mobile broadcast digital data (step ST3). . Thereafter, the demodulated mobile broadcast digital data is temporarily stored in the buffer memory 4, and a so-called buffering process is performed (step ST4).
[0045]
Thereafter, in step ST5, the fixed broadcast digital data and the mobile broadcast digital data subjected to the demodulation processing and the buffering processing are supplied from the buffer memories 3 and 4 to the timing detection section 5, respectively. Then, the timing detection section 5 detects the timing of the supplied fixed broadcast digital data and mobile broadcast digital data, and performs a synchronization process.
[0046]
As described above, the demodulated fixed broadcast digital data and the mobile broadcast digital data are buffered using the buffer memories 3 and 4, so that the fixed broadcast digital data temporarily stored in the buffer memories 3 and 4 are buffered. And digital data for mobile broadcasting can be easily synchronized, and when these digital data are mutually switched, they can be seamlessly switched.
[0047]
The process proceeds to step ST6 almost in parallel with the synchronization process. In step ST6, the bit error rate monitoring unit 6 performs a process of determining the bit error rate (BER) of the fixed broadcast digital data stored in the buffer memory 3. Then, a comparison is made as to whether the bit error rate is equal to or higher than a predetermined error rate threshold value.
[0048]
Here, the error rate threshold value is determined as a boundary value for determining whether or not so-called "dropped frames" occurs in a video output using fixed broadcast digital data. In other words, in the fixed broadcast digital data, the error rate at which “frame drop” starts is defined as an error rate threshold for switching from the fixed broadcast digital data to the mobile broadcast digital data.
[0049]
Specifically, in this embodiment, for example, when digital data for Hi-Vision broadcasting with a modulation scheme of 64 QAM (Quadrature Amplitude Modulation), a convolutional coding rate of 7/8, and a transmission mode of 3 is taken as an example, the Reed-Solomon code is used. The BER before decoding (before RS decoding) is 1.0 × 10^-2~ 2.0 × 10^-2And the BER after the composite of the Reed-Solomon code is 5.0 × 10^-4~ 7.0 × 10^-3When the value falls within the range, “dropped frames” occur.
[0050]
Therefore, as the predetermined error rate threshold,
Before RS decoding: 1.0 × 10^-2~ 2.0 × 10^-2
After RS decoding: 5.0 × 10^-4~ 7.0 × 10^-3
It is desirable to select from the range of, in order to reliably prevent "dropped frames" in fixed broadcast digital data, a predetermined error rate threshold,
Before RS decoding: 1.0 × 10^-2degree
After RS decoding: 5.0 × 10^-4degree
It is more desirable to select The BER before RS decoding is 3.0 × 10^-2Above or BER after RS decoding is 7.0 × 10^-3Above the above, an image output failure occurs and a so-called cliff effect occurs, so these ranges are excluded from the selection range.
[0051]
If the error rate is smaller than the error rate thresholds in the comparison by the bit error rate monitoring unit 6, the process proceeds to step ST7, where the currently output demodulated digital data is fixed broadcast data. A determination is made as to whether the data is digital video data or mobile broadcast digital video data.
[0052]
As a result of this determination, if the currently output digital video data is fixed broadcast digital video data, the fixed broadcast digital video data is output as demodulated data via the switching processing unit 7 together with the mobile digital audio data. .
[0053]
Then, the process proceeds to step ST1 and step ST3, where the same processing is sequentially performed, and the output of digital broadcast using fixed broadcast digital video data as video information and mobile broadcast digital audio data as audio information is continued. Is done.
[0054]
If it is determined in step ST7 that the currently output digital video data is mobile broadcast digital video data, the process proceeds to step ST9.
[0055]
On the other hand, if the error rate is equal to or greater than the error rate threshold in the comparison by the bit error rate monitoring unit 6, the process proceeds to step ST8, where the currently output demodulated digital data is fixed broadcast digital video. A determination is made as to whether the data is data or mobile broadcast digital video data.
[0056]
If the result of this determination is that the currently output digital video data is mobile broadcast digital video data, the mobile broadcast digital video data is output as demodulated data via the switching processor 7 together with the mobile digital audio data. Is done. Then, the process proceeds to step ST1 and step ST3, where the same processing is sequentially performed, and digital broadcast output using mobile broadcast digital audio data as audio information and mobile broadcast digital audio data as audio information is performed. To be continued.
[0057]
If it is determined in step ST8 that the currently output digital video data is fixed broadcast digital video data, the process proceeds to step ST9.
[0058]
Then, when the process proceeds from step ST7 or step ST8 described above to step ST9, mutual switching between fixed broadcast digital video data and mobile broadcast digital video data is performed. Specifically, in step ST9, a switching signal is supplied from the bit error rate monitoring unit 6 to the switching processing unit 7, and based on the switching signal, switching from fixed broadcast digital video data to mobile broadcast digital video data is performed. Done.
[0059]
That is, while the fixed broadcast digital video data is being output, when the error rate exceeds a predetermined error rate threshold, switching from the fixed broadcast digital video data to the mobile broadcast digital video data is performed, When the error rate falls below a predetermined error rate threshold while the broadcast digital video data is being output, switching from the mobile broadcast digital video data to the fixed broadcast digital video data is performed.
[0060]
This switching is performed only for digital video data. As for the digital audio data serving as the audio information, the mobile broadcast digital audio data is continuously output.
[0061]
Thus, in various situations, the mobile digital audio data which is easy to receive is continuously used as audio information, so that interruption of audio can be prevented.
[0062]
That is, mobile digital audio data used for broadcasting for mobile objects is not high in quality as compared with fixed digital audio data capable of, for example, surround output. However, in general, a user who watches digital broadcasts on a mobile body does not require high quality as digital audio data used for fixed broadcasts, but is sensitive to "interruption of audio" when viewing. become. Therefore, by making it possible to efficiently prevent the “interruption of audio”, it is possible to improve the overall quality perceived by the user when viewing a digital broadcast on a mobile object or the like.
[0063]
Next, a case where the digital broadcast receiving apparatus according to the embodiment of the present invention is installed on a mobile body such as a vehicle will be described. FIG. 3 shows the relationship between digital broadcast quality and transmission quality in a mobile according to this embodiment.
[0064]
That is, the vehicle has two states, a moving state and a stopped state. In general, the reception state of the broadcast wave is better in the stopped state and the transmission quality is higher in the moving state and the stopped state of the vehicle.
[0065]
When the digital broadcast receiving apparatus according to the embodiment of the present invention is mounted on such a vehicle, as shown in FIG. 3, while the vehicle is moving, the quality of the fixed broadcast (fixed broadcast digital data) is low. Broadcasting (digital data for mobile broadcasting). Therefore, in this embodiment, mobile broadcast digital video data is output as digital video data while the vehicle is moving.
[0066]
On the other hand, when the vehicle is stopped (0 km / h), or when the vehicle is moving at a low speed of, for example, about 20 km / h or less, the transmission quality of the digital broadcast becomes high and the reception becomes easy, and the error rate increases. Is also reduced. Therefore, in this embodiment, while the vehicle is stopped or moving at a low speed, fixed broadcast digital video data is output as digital video data.
[0067]
Such mobile broadcast digital video data and fixed broadcast digital video data are switched at a switching point P shown in FIG. When the digital broadcast receiving apparatus is mounted on a vehicle or the like, the switching at the switching point P can be performed according to the speed of the vehicle.
[0068]
That is, the digital broadcast receiving apparatus shown in FIG. 1 is configured to be able to supply speed information from a speed sensor (not shown) of the vehicle to the switching processing unit 7, and switches the respective digital video data based on the speed information. To do.
[0069]
However, even in the stop state of the vehicle in the stop state, the reception state of the broadcast radio wave may be deteriorated depending on the stop position of the vehicle. In this case, as described above, the switching between the digital video data is performed by the switching signal from the error rate monitoring unit 6. As described above, by switching between the two types of digital video data based on at least one of the vehicle speed and the error rate, it is possible to perform high-precision switching.
[0070]
As described above, according to this embodiment, it is possible to reduce interruption of audio output from a receiving device, which is critical for a user who watches digital broadcasting, and to reduce the quality of output video as much as possible. Since the quality can be improved, the overall reception broadcast quality can be improved. In addition, in the mobile body including the digital broadcast receiving apparatus according to the embodiment, the mobile station receives the highest quality broadcast in the state at that time regardless of whether the mobile body is moving or stopped. Therefore, it is possible to improve the overall audio quality and video quality which are enjoyed by the user who uses the digital broadcasting in the mobile body.
[0071]
As described above, one embodiment of the present invention has been specifically described. However, the present invention is not limited to the above-described embodiment, and various modifications based on the technical idea of the present invention are possible.
[0072]
For example, the numerical values given in the above-described embodiment are merely examples, and different numerical values may be used as needed.
[0073]
Further, for example, in the above-described embodiment, switching between fixed broadcast digital video data and mobile digital video data is performed by supplying a switching signal from the bit error rate monitoring unit 6 to the switching processing unit 7. However, besides supplying the switching signal from the bit error monitoring unit 6 at the time of switching, for example, a so-called binary signal such as “0” and “1” is always transmitted from the bit error monitoring unit 6. By supplying the signal to the switching processing unit 7, it is also possible to control digital video data to be output. Specifically, the signal always supplied from the bit error monitoring unit 6 to the switching processing unit 7 is set to, for example, “0” when outputting fixed broadcast digital video data, and when outputting mobile broadcast digital video data. For example, it is possible to set the digital video data to each other in accordance with the binary signal.
[0074]
Further, for example, in the mobile according to the above-described embodiment, switching between fixed broadcast digital video data and mobile broadcast digital video data is performed according to the speed of the vehicle and according to the error rate. However, it is also possible to adopt only one of the method of switching according to the speed of the vehicle and the method of switching according to the comparison between the error rate and the error rate threshold value.
[0075]
In the above-described embodiment, a fixed error rate threshold is adopted as the error rate threshold of the fixed broadcast digital video data. Instead of the fixed error rate threshold, As the error rate threshold, the error rate of mobile broadcast digital video data at the time of measurement may be employed.
[0076]
【The invention's effect】
As described above, according to the present invention, in the case of receiving and outputting a digital broadcast, the same digital audio signal is always used for audio output, and the video output depends on the level of reception quality. In addition, by switching between the first digital video signal and the second digital video signal for use, it is possible to prevent interruption of the sound and to reduce the quality of the receivable video within the range possible. , The highest quality broadcast can be received, and the overall received broadcast quality can be improved.
[0077]
Further, according to the moving object of the present invention, it is possible to watch the highest quality digital broadcast in the possible range without interruption of the sound regardless of whether the moving object is moving or stopped. Thus, it is possible to obtain a mobile body equipped with a digital broadcast receiving device capable of improving the overall quality of digital broadcast enjoyed by the user.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a digital receiving apparatus according to an embodiment of the present invention.
FIG. 2 is a flowchart illustrating an operation of the digital receiving apparatus according to the embodiment of the present invention.
FIG. 3 is a graph showing an operation principle when a digital receiver according to one embodiment of the present invention is provided on a mobile object.
[Explanation of symbols]
1 Broadcast demodulation unit for fixed
2 Broadcast demodulator for mobile
3,4 buffer memory
5 Timing detector
6 Bit error rate monitor
7 Switching unit
8 Antenna
9 Tuner

Claims (13)

Receiving means configured to be able to receive the first digital video signal, the digital audio signal, and the second digital video signal;
Signal synchronization means configured to be able to synchronize the first digital video signal and the digital audio signal, and configured to be able to synchronize the second digital video signal and the digital audio signal;
At least an error monitoring means configured to be able to compare an error rate in the second digital video signal with an error rate threshold value;
Switching processing means configured to switch between the first digital video signal and the second digital video signal,
The audio based on the digital audio signal is configured to be constantly output, and the first digital video is output based on the magnitude of the error rate and the error rate threshold value compared by the error monitoring means. A digital broadcast receiving apparatus characterized in that the digital broadcast receiving apparatus is configured to be capable of switching and outputting a signal and the second digital video signal. First demodulating means for demodulating the first digital video signal and the digital audio signal;
A second demodulation means configured to be able to demodulate at least the second digital video signal;
Buffering means for buffering the signal demodulated by the first demodulation means and the second demodulation means;
The first digital video signal and the digital audio signal demodulated by the first demodulation unit and the second digital video signal demodulated by the second demodulation unit are combined by the buffering unit. While being configured to be bufferable,
The signal synchronizing means is configured to be capable of synchronizing the first digital video signal with the digital audio signal or synchronizing the second digital video signal with the digital audio signal. 2. The digital broadcast receiving device according to claim 1, wherein: 3. The digital broadcast receiving apparatus according to claim 2, wherein the determination of the magnitude of the error rate by the error monitoring means is performed after execution of buffering by the buffering means. When the error rate monitored by the error monitoring means is equal to or greater than the error rate threshold, the first digital video signal is output, and the error rate monitored by the error monitoring means is equal to the error rate threshold. 3. The digital broadcast receiving device according to claim 1, wherein the second digital video signal is output when the value is less than the value. The first digital video signal and the digital audio signal are mobile-oriented digital broadcast signals,
4. The digital broadcast receiving apparatus according to claim 1, wherein the second digital video signal is a fixed digital broadcast signal. At least a first digital video signal, a digital audio signal, and a second digital video signal are received by a receiving unit that receives a digital signal;
A signal synchronization unit that performs signal synchronization, wherein the synchronization of the first digital video signal and the digital audio signal received by the reception unit and the synchronization of the second digital video signal and the digital audio signal, Perform at least one sync,
Error monitoring means compares the error rate in the second digital video signal with an error rate threshold,
While always outputting a sound based on the digital sound signal, based on a comparison between the error rate and the error rate threshold value executed by the error monitoring means, a switching processing means capable of switching an input signal. A digital broadcast receiving method for switching between the output of the first digital video signal and the input of the second digital video signal. After the first digital video signal and the digital audio signal are demodulated by the first demodulating means for demodulating the compressed signal, and at least the second digital video signal is demodulated by the second demodulating means,
The first digital video signal, the second digital video signal, and the digital audio signal demodulated by the first demodulation means and the second demodulation means are buffered by a buffering means for buffering the digital signal. Buffering,
The signal synchronization means is configured to synchronize at least one of the buffered first digital video signal and the digital audio signal and the buffered second digital video signal and the digital audio signal. 7. The digital broadcast receiving method according to claim 6, wherein synchronization is performed. 8. The digital broadcast receiving method according to claim 7, wherein said error monitoring means compares said error rate with said error rate threshold value after said buffering means executes buffering. When the error rate compared by the error monitoring means is equal to or more than the error rate threshold, the first digital video signal is output. When the error rate is less than the error rate threshold, 9. The digital broadcast receiving method according to claim 7, wherein the second digital video signal is output. The first digital video signal and the digital audio signal are mobile-oriented digital broadcast signals,
The digital broadcast receiving method according to any one of claims 7 to 9, wherein the second digital video signal is a fixed digital broadcast signal. Receiving means configured to receive the first digital video signal, the digital audio signal, and the second digital video signal; and configured to be able to synchronize the first digital video signal and the digital audio signal. A signal synchronizing means configured to synchronize the second digital video signal and the digital audio signal, an error monitoring means configured to measure an error rate in the second digital video signal, Switching processing means configured to be able to switch between the first digital video signal and the second digital video signal. The switching processing means is configured to be able to constantly output audio based on the digital audio signal. The first digital video signal and the second digital video signal are switched and output based on an error rate compared by monitoring means. Mobile, characterized in that configured digital broadcast receiving apparatus is installed. The switching processing means is configured to be capable of inputting speed information, and based on at least one of the speed information and an error rate compared by the error monitoring means, the first digital video signal and the second digital The moving body according to claim 11, wherein the moving body is configured to switch between a video signal and a video signal. Receiving means configured to receive the first digital video signal, the digital audio signal, and the second digital video signal; and configured to be able to synchronize the first digital video signal and the digital audio signal. A signal synchronizing means configured to be able to synchronize the second digital video signal and the digital audio signal, and capable of inputting speed information, and transmitting the first digital video signal and the second digital video signal to each other. Switching processing means configured to be switchable, and configured to constantly output audio based on the digital audio signal, and based on detected speed information, the first digital video signal and the second digital video signal. A digital broadcast receiving apparatus configured to switch and output the digital video signal.

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