JP2004364272A - Receiving apparatus and receiving method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To allow viewing of a program from a broadcasting station even when it is difficult for a receiver to receive the signal transmitted from the broadcasting station. <P>SOLUTION: The receiving apparatus comprises a first receiving means for receiving a broadcasting signal transmitted from the broadcasting station, a second receiving means for receiving a transmitting signal transmitted from a transmitter station in accordance with the broadcasting signal transmitted from the broadcasting station, and a program reproducing means for reproducing video and audio corresponding to the program to be broadcasted in the broadcasting station on the basis of either the broadcasting signal or the transmitting signal. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a receiving device that receives a broadcast signal transmitted from a broadcasting station or a transmission signal transmitted from a wireless communication station, and reproduces video and audio corresponding to the broadcast signal or the transmission signal.

  2. Description of the Related Art Conventionally, a broadcasting station performing digital television broadcasting or the like modulates data corresponding to a program broadcasted by the local station into radio waves of a predetermined frequency band assigned to each broadcasting station, thereby generating a signal corresponding to the data of the program. Send Then, a user who watches the program extracts a signal corresponding to a desired broadcast station from signals transmitted from a plurality of broadcast stations and demodulates the signal by using a receiving device (for example, a television). Thus, the video and audio corresponding to the program are reproduced (for example, Non-Patent Document 1).

Edited by Japan Broadcasting Corporation, "NHK Television Technical Textbook (1)", Japan Broadcasting Publishing Association, April 20, 1991, p. 96-105

  However, the reach of signals transmitted from each broadcasting station is limited. In addition, since the signal is affected by diffraction, reflection, and the like, the position where the signal can be received well is also limited. Therefore, at a certain point, the signal transmitted from the broadcasting station can be received and the program can be viewed, but at another point, the distance from the broadcasting station, diffraction or reflection by a building or the like, and the like. Due to the influence, the reception state of the receiving device may be deteriorated, and the program may not be viewed.

  Therefore, the present invention has been made to solve the above-described problem, and even when it is difficult for a receiving device to receive a signal transmitted from a broadcast station, a program broadcasted by the broadcast station can be transmitted. The purpose is to enable viewing.

  A receiving device according to the present invention includes: first receiving means for receiving a broadcast signal transmitted from a broadcast station; and receiving a transmission signal transmitted from a transmission station in response to the broadcast signal transmitted from the broadcast station. And a program reproducing means for reproducing video and audio corresponding to a program broadcast in the broadcast station based on either the broadcast signal or the transmission signal.

  ADVANTAGE OF THE INVENTION According to the receiver which concerns on this invention, even if it is difficult to receive the signal transmitted from a broadcast station because the reception state of the said receiver is bad, the program broadcasted in the said broadcast station can be watched. .

Embodiment 1 FIG.
FIG. 1 is a block diagram showing a configuration of the receiving apparatus 251 according to Embodiment 1. In the first embodiment, a case will be described where the receiving device 251 is a mobile terminal device (for example, a portable terminal device). Also, a case where the receiving device 251 reproduces video and audio corresponding to digital television broadcasting will be described as an example.

  In FIG. 1, broadcast stations 1A, 1B,... Transmit signals (hereinafter, referred to as broadcast signals) corresponding to programs broadcast at the broadcast stations 1A, 1B,. It is assumed that there are a plurality of the broadcasting stations 1A, 1B,... In accordance with the number of channels set in the receiving device 251, and in the following description, the plurality of broadcasting stations are collectively referred to as a broadcasting station 1. Further, the channel is set for each predetermined frequency band used when each broadcast station transmits a broadcast signal. The broadcast signal is modulated by a predetermined modulation method (for example, 16QAM, 64QAM, QPSK, DQPSK, etc.) at each broadcasting station, and is transmitted by radio waves. The channel and the modulation scheme can be arbitrarily set according to the environment of the system using the receiving device 251.

  The transmitting stations 11A, 11B,... Transmit a signal corresponding to the same data as the data transmitted by the broadcasting station 1 (hereinafter referred to as a transmission signal) in the broadcasting station 1. The signal is modulated by a modulation method different from the used modulation method and transmitted by radio.

  The data corresponding to the transmission signals transmitted from the transmitting stations 11A, 11B,... Is obtained by using a wired line (not shown) for the data corresponding to the broadcast signal transmitted from the broadcasting station 1. get.

  In addition, the transmitting station 11 is installed in a place where the receiving state of the receiving device 251 is likely to be deteriorated, such as a mountain area, inside a building, near a high-rise building, or in a tunnel. Then, a communicable area such as a hot spot is formed using a wireless LAN or the like, and the transmission signal is transmitted to the communicable area. It is assumed that a plurality of transmitting stations 11A, 11B... Are installed corresponding to the number of the broadcasting stations 1, and in the following description, the transmitting stations 11A, 11B. That.

  The receiving device 251 includes: a first line interface 3 for receiving a plurality of broadcast signals transmitted by each broadcasting station 1 and arriving at the receiving device 251 via the wireless broadcasting line 2; A first high-frequency amplification / detection unit 4 for extracting and amplifying a broadcast signal corresponding to the broadcast station 1 specified by a channel selection unit 10 described later from the plurality of broadcast signals received by the A first A / D converter 26 that converts a signal into a digital signal; and a first A / D converter that demodulates and decodes the digital signal output from the first A / D converter 26 and outputs a video signal and an audio signal. And a video receiving unit 6 for demodulating the video signal output from the first demodulation / decoding unit 5 into a signal that can be displayed on a monitor 8 and outputting the signal. The audio signal output from the issue unit 5 and an audio receiver unit 7 and outputs the demodulated signals can be reproduced by a speaker 9. In the following description, the video signal output from the video receiver 6 is referred to as a first video signal, and the audio signal output from the audio receiver 7 is referred to as a first audio signal. Further, the wireless broadcasting line 2 means a transmission path from the broadcasting station 1 to the receiving device 251, and the wireless broadcasting line 2 is wireless.

  The receiving device 251 further includes a second line interface 13 for receiving a plurality of transmission signals transmitted by each transmitting station 11 and arriving at the receiving device 251 via the wireless communication line 12; A second high-frequency amplifier / detector 14 for extracting and amplifying a transmission signal corresponding to the transmission station 11 designated by the channel selector 10 from the plurality of transmission signals received by the interface 13; A second A / D converter 27 for converting the transmission signal amplified by the high-frequency amplifier / detector 14 into a digital signal, and demodulating the digital signal output from the second A / D converter 27. A second demodulation / decoding unit 15 that decodes and outputs a video signal and an audio signal, and the video signal output from the second demodulation / decoding unit 15 can be displayed on the monitor 8 A video playback unit 16 that demodulates the signal into a signal and outputs the signal; and an audio playback unit 17 that demodulates the audio signal output from the second demodulation / decoding unit 15 into a signal that can be reproduced by the speaker 9 and outputs the signal. . In the following description, the video signal output from the video playback unit 16 is referred to as a second video signal, and the audio signal output from the audio playback unit 17 is referred to as a second audio signal. Further, the wireless communication line 12 means a transmission path from the transmitting station 11 to the receiving device 251, and the wireless communication line 12 is wireless.

  Further, the receiving device 251 includes a first D / A conversion unit 28 that converts a video signal obtained based on the broadcast signal or the transmission signal into an analog signal, and a first D / A conversion unit 28 based on the broadcast signal or the transmission signal. A second D / A converter 29 for converting the obtained audio signal into an analog signal, and a monitor 8 for displaying an image corresponding to the video signal converted to an analog signal by the first D / A converter 28 And a speaker 9 for reproducing a sound corresponding to the sound signal converted into an analog signal by the second D / A converter 29.

  Further, the receiving device 251 includes a video selecting unit 18 for selecting either a video signal output from the video receiving unit 6 or a video signal output from the video reproducing unit 16, and an audio output from the audio receiving unit 6. An audio selection unit 19 for selecting either a signal or an audio signal output from the audio reproduction unit 16.

  That is, receiving apparatus 251 can select whether to reproduce the video signal and the audio signal corresponding to the broadcast signal or to reproduce the video signal and the audio signal corresponding to the transmission signal. Be composed. The selection in the video selection unit 18 or the audio selection unit 19 is performed by the user operating an operation unit (not shown) of the receiving device 251. More specifically, when a user operates the operation unit, a signal (hereinafter, referred to as a selection signal) is output from the signal selection unit 20, and the video selection unit 18 transmits a broadcast signal or a transmission signal in accordance with the selection signal. A video signal corresponding to any one of the signals is selected and output, and the audio selection unit 19 selects and outputs an audio signal corresponding to any one of a broadcast signal and a transmission signal according to the selection signal. I do.

  Further, as described above, the first high-frequency amplification / detection unit 4 and the second high-frequency amplification / detection unit 14 extract the broadcast signal or the transmission signal specified by the channel selection unit 10, but perform the channel selection. The designation by the unit 10 is also performed by the user operating the operation unit. That is, when a user designates a channel set in the receiving device 251 by operating the operation unit, a signal (hereinafter, referred to as a channel signal) corresponding to the channel is transmitted from the channel selection unit 10 to the first high frequency. The signal is output to the amplification / detection unit 4 and the second high-frequency amplification / detection unit 14.

  Therefore, for example, when the broadcast signal transmitted from the broadcast station 1A and the transmission signal transmitted from the transmission station 11A correspond to each other, the user operates the operation unit to specify the channel corresponding to the broadcast station 1A. Then, the channel signal is output from the channel selection unit 10, and the first high-frequency amplification / detection unit 4 extracts a broadcast signal transmitted from the broadcast station 1A according to the channel signal, and outputs the second high-frequency signal. The amplification / detection unit 14 extracts a transmission signal transmitted from the transmission station 11A according to the channel signal.

  The receiving device 251 receives a broadcast signal transmitted from the broadcast station 1 and reproduces video or audio. Then, the user watches the program broadcast in the broadcast station 1 by the receiving device 251 while moving.

  If the reception state of the receiving device 251 deteriorates while the user is moving, the user operates the operation unit to switch a signal used for reproducing the video and audio from a broadcast signal to a transmission signal. Then, the monitor 8 displays an image based on the video signal corresponding to the transmission signal, and the speaker 9 reproduces the audio based on the audio signal corresponding to the transmission signal.

  The transmitting station 11 that transmits the transmission signal is installed in advance in a place where the receiving state of the receiving device 251 deteriorates, such as a mountain area or a vicinity of a building as described above. Therefore, the user operates the operation unit to switch the signal used for reproducing the video and the audio, so that the user can view a desired program with good video and audio.

  The determination as to whether or not the reception state is poor depends on the quality (image quality) of the image displayed on the monitor 8 has deteriorated (the image is disturbed, etc.) or the sound output from the speaker 9 has been disturbed. This is performed by the user.

  As described above, according to receiving apparatus 251 in Embodiment 1, even when the receiving state of receiving apparatus 251 deteriorates, good video and audio can be obtained.

  Further, the receivable area of the receiving device 251 can be substantially enlarged.

Embodiment 2 FIG.
FIG. 2 is a block diagram showing a configuration of the receiving device 252 according to the second embodiment. In FIG. 2, the same components as those of the receiving device 251 of the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.

  2, the first video signal output from the video receiving unit 6 and the second video signal output from the video reproducing unit 16 are input to a first determination circuit 21A. Similarly, the first audio signal output from the audio receiving unit 7 and the second audio signal output from the audio reproducing unit 17 are output to the second determination circuit 21B.

  The first determination circuit 21A compares the first video signal with the second video signal. The first determination circuit 21A determines which signal of the broadcast signal or the transmission signal is satisfactorily received by the receiving device 252 by the comparison, and determines which signal of the broadcast signal or the transmission signal. (Hereinafter referred to as a first determination signal) to the signal selection unit 20.

  Similarly, the determination circuit 21B compares the first audio signal with the second audio signal. A signal indicating which signal of the broadcast signal or the transmission signal is selected by determining which signal of the broadcast signal or the transmission signal is satisfactorily received by the receiving device 252 by the comparison. (Hereinafter, referred to as a second determination signal) to the signal selection unit 20.

  The first determination circuit 21A and the second determination circuit 21B determine whether the reception state is good or bad by, for example, determining the number of erroneous data in the broadcast signal obtained by correcting the broadcast signal and the transmission signal. This may be performed by comparing the number of errors in the transmission signal with the number of errors in the transmission signal, or by calculating a bit error rate from the number of errors and comparing the bit error rates. .

  The signal selection unit 20 determines whether to reproduce the video based on the broadcast signal or the transmission signal based on the first determination signal, and transmits a signal corresponding to the determination to the video selection unit 18. Output. Then, the video selection unit 18 selects the first video signal or the second video signal according to the signal output from the signal selection unit 20, and outputs the selected video signal or the second video signal to the first D / A conversion unit 28. .

  Further, the signal selection unit 20 determines, based on the second determination signal, which of a broadcast signal and a transmission signal is to be used for audio reproduction, and outputs a signal corresponding to the determination to the audio selection unit. 19 is output. Then, the audio selector 19 selects the first audio signal or the second audio signal according to the signal output from the signal selector 20 and outputs the selected signal to the second D / A converter 29. .

  As described above, according to receiving apparatus 252 in the second embodiment, good video and audio can be reproduced even when the receiving state of receiving apparatus 252 is poor.

  Further, the receivable area of the receiving device 252 can be substantially enlarged.

  Further, it is possible to automatically select which of a broadcast signal and a video signal to reproduce video and audio without requiring user operation.

Embodiment 3 FIG.
FIG. 3 is a block diagram showing a configuration of the receiving device 253 according to the third embodiment. In FIG. 3, the same components as those described in the first or second embodiment are denoted by the same reference numerals, and description thereof will be omitted.

  In FIG. 3, the first determination signal output from the first determination circuit 21A and the second determination signal output from the second determination circuit 21B are input to the graphics generator 22. Then, the graphics generator 22 generates a video indicating the reception state of the receiving device 253 based on the input first determination signal and the second determination signal, and adds a signal corresponding to the generated video. Output to the device 33.

  The adder 33 combines the signal output from the graphics generator 22 and the signal output from the video selection unit 18 and outputs the combined signal to the first D / A conversion unit 28. The first D / A converter 28 converts the signal output from the adder 33 into an analog signal and outputs the analog signal to the monitor 8, and the monitor 8 displays an image on a screen based on the analog signal. I do.

  Then, on the screen of the monitor 8, a video corresponding to the video signal output from the video selection unit 18 and a video generated by the graphics generator 22 and indicating the reception state of the receiving device 253 are displayed. Is displayed.

  Then, the user selects which of the broadcast signal and the transmission signal to reproduce the video and audio based on the video indicating the reception state displayed on the monitor 8, and Perform the operation.

  The video generated by the graphics generator 22 has a reception state of 100 when the video and audio can be favorably viewed in the reception device 253, and has a first determination signal and a second determination signal. Based on the determination signal, the result of calculating the numerical value of the reception state with respect to 100 is displayed on a screen in the form of a bar graph. As shown in FIG. 4, the bar graph separately displays a bar graph indicating a reception state for a broadcast signal and a bar graph indicating a reception state for a transmission signal. Therefore, by comparing the two bar graphs, the user can confirm which of the broadcast signal and the transmission signal is being received better. Then, after confirming the reception state, the user can select a signal in a better reception state.

  The display method of the video generated by the graphics generator 22 is not limited to the above-described mode, and may be displayed on the screen of the monitor 8 while being superimposed on the video corresponding to the video signal output from the video receiving unit 6 or the video reproducing unit 16. And other modes may be used as long as it is possible to determine which of the reception state for the broadcast signal and the reception state for the transmission signal is better.

  For example, only the name of a signal in a better reception state (that is, either a broadcast signal or a transmission signal) may be displayed, or reception of a signal different from the signal corresponding to the currently reproduced video and audio may be performed. When the state becomes good, a mode may be displayed in which a signal switching instruction is displayed.

  The video generated by the graphics generator 22 may be constantly displayed on the screen of the monitor 8, or an instruction button for instructing display of the video may be provided on the operation unit of the reception device 253. The image may be displayed only when the instruction button is operated. Further, only when the reception state of a signal different from the signal corresponding to the video and audio currently being reproduced becomes good, it may be displayed that a signal switching instruction is given for a predetermined time.

  In the third embodiment, the video generated by the graphics generator 22 is displayed on the screen of the monitor 8, and the user manually selects either the broadcast signal or the transmission signal based on the video. Although the case has been described, the signal selection may be automatically performed by combining the receiving device 253 in the third embodiment with the receiving device 252 in the second embodiment.

  Specifically, in receiving apparatus 253 according to the third embodiment, the first determination signal and the second determination signal are input to signal selection section 20, and signal selection section 20 operates as described in the second embodiment. What is necessary is just to comprise so that operation | movement similar to may be performed. In addition, either the broadcast signal or the transmission signal may be automatically switched, and the signal may be switched by a user operation.

  As described above, according to receiving apparatus 253 in the third embodiment, by providing graphics generator 22, the user can visually check the receiving state of receiving apparatus 253. Then, the user can select a signal based on the video indicating the reception state.

Embodiment 4 FIG.
FIG. 5 is a block diagram showing a configuration of the receiving apparatus 254 according to the fourth embodiment. In FIG. 5, the same components as those described in the first to third embodiments are denoted by the same reference numerals, and description thereof is omitted.

  The receiving apparatus according to the first to third embodiments reproduces video and audio based on either a broadcast signal or a transmission signal by the video selection unit 18 and the audio selection unit 19. Is not always synchronized. Therefore, a delay may occur between both signals. The delay causes a break in video displayed on the monitor 8 or audio output from the speaker 9 or the like. Therefore, the receiving apparatus 254 according to the fourth embodiment uses the comparison delay difference calculation unit 23 and the variable buffer 24 in order to eliminate the above-described interruption of the video and audio. Hereinafter, the operation of the receiving device 254 will be described.

  In FIG. 5, the first video signal output from the video reception unit 6 and the second video signal output from the video reproduction unit 16 are input to a first comparison delay difference calculation unit 23A. Further, the first audio signal output from the audio receiving unit 7 and the second audio signal output from the audio reproducing unit 17 are output to the second comparison delay difference calculating unit 23B.

  The first comparison delay difference calculation unit 23A compares the input first video signal and the second video signal to calculate how much delay has occurred between the two signals. Then, a signal (hereinafter, referred to as a first delay signal) corresponding to a delay amount (hereinafter, referred to as a first delay amount) obtained as a result of the calculation is transmitted to the first variable buffer 24A and the second variable buffer 24B. Output to The calculation of the delay amount can be performed, for example, by comparing a time stamp included in the first video signal with a time stamp included in the second video signal.

  On the other hand, the second comparison delay difference calculation unit 23B compares the input first audio signal and the second audio signal, and delays between the two signals (hereinafter, referred to as a second delay). Is calculated. Then, a signal corresponding to the second delay amount (hereinafter, referred to as a second delay signal) is output to the third variable buffer 24C and the fourth variable buffer 24D. The calculation of the second delay amount can also be performed by comparing a time stamp included in the first audio signal with a time stamp included in the second audio signal.

  The first video signal and the first delay signal output from the video receiving unit 6 are input to the first variable buffer 24A. The second video signal and the first delay signal output from the video playback unit 16 are input to the second variable buffer 24B. Each of the variable buffers 24A and 24B gives a delay amount to the input video signal based on a first delay amount corresponding to the first delay signal.

  More specifically, for example, when the second video signal is delayed by the delay amount D1 with respect to the first video signal, the first variable buffer 24A delays the first video signal by the first video signal. The delay amount is given to the second video signal in the second variable buffer 24B.

  Then, the first video signal and the second video signal whose delay has been adjusted based on the first delay amount are input to the video selection unit 18.

  On the other hand, the first audio signal and the second delay signal output from the audio receiving unit 7 are input to the third variable buffer 24C. In addition, the second audio signal output from the audio reproduction unit 17 and the second delay signal are input to the fourth variable buffer 24D. Each of the variable buffers 24C and 24D gives a delay amount to the input audio signal based on a second delay amount corresponding to the second delay signal. Then, the first audio signal and the second audio signal whose delay difference has been adjusted based on the second delay amount are input to the audio selection unit 19.

  As described above, the delay between the first video signal and the second video signal is adjusted by the first variable buffer 24A and the second variable buffer 24B, and the delay is input to the video selection unit 18. The first video signal and the second video signal are synchronized. In addition, the delay between the first audio signal and the second audio signal is adjusted by the third variable buffer 24C and the fourth variable buffer 24D, and the first and second audio signals are input to the audio selector 19. Is synchronized with the second audio signal.

  As described above, according to receiving apparatus 254 in Embodiment 4, even when a delay occurs between a broadcast signal and a video signal, interruption of video or audio caused by the delay is prevented. be able to.

  The receiving device 254 in the fourth embodiment can be combined with the receiving devices in the first to third embodiments. For example, when combining with the receiving device 252 in the second embodiment, the first comparison delay difference calculation unit 23A, the first variable buffer 24A, and the second variable buffer 24B are connected in parallel with the first determination circuit 21A. And the second comparison delay difference calculator 23B, the third variable buffer 24C and the fourth variable buffer 24D may be provided in parallel with the second determination circuit 21B.

Embodiment 5 FIG.
FIG. 6 is a block diagram illustrating a configuration of receiving apparatus 255 according to the fifth embodiment. In FIG. 6, the same components as those described in the first to fourth embodiments are denoted by the same reference numerals, and description thereof is omitted.

  In FIG. 6, a signal output from the first demodulation / decoding unit 5 (hereinafter, referred to as a demodulated signal) is output to the first error correction unit 30. The first error correction unit 30 performs an error correction process on the demodulated signal output from the first demodulation / decoding unit 5. Then, if there is data for which error correction is impossible in the data corresponding to the input demodulated signal, a signal corresponding to the data for which error correction was not possible (hereinafter, referred to as an uncorrectable signal). Output to the transmitting station 11.

  For example, when decoding a signal encoded by applying a Reed-Solomon code and correcting errors as in terrestrial digital TV broadcasting in Japan, the input data is corrected by an error locator polynomial or the like. It can be determined whether or not it is possible. The first error correction unit 30 outputs the uncorrectable signal based on the above determination.

  The uncorrectable signal is output to the transmitting station 11 that transmits a transmission signal corresponding to the same data as the data corresponding to the broadcast signal received by the receiving device 255.

  The transmitting station 11 that has received the uncorrectable signal, in accordance with the uncorrectable signal, complements the data for which the first error correction unit 30 could not correct the error (hereinafter, referred to as complementary data). (Hereinafter, referred to as a complementary signal) to the receiving device 255.

  After the complementary signal transmitted from the transmitting station 11 is input to the second line I / F 13 in the receiving device 255, each component from the second high-frequency amplification / detection unit 14 to the second error correction unit 31 Demodulation, error correction, and the like are performed. Then, a video signal obtained as a result of the demodulation or the like is output to the first buffer 41 via the video reproduction unit 16, and an audio signal is output to the second buffer 42 via the audio reproduction unit 17.

  The first buffer 41 combines the first video signal output from the video receiving unit 6 and the second video signal output from the video playback unit 16 to generate the first video signal. The data for which error correction was impossible in the corresponding data is complemented by complementary data corresponding to the second video signal. Then, a signal corresponding to the complemented data is output to the first D / A converter 28.

  On the other hand, the second buffer 42 synthesizes the first audio signal output from the audio receiving unit 7 and the second audio signal output from the audio reproducing unit 17 to generate the first audio signal. The data that cannot be corrected in the data corresponding to the signal is complemented by the complementary data corresponding to the second audio signal. Then, a signal corresponding to the complemented data is output to the second D / A converter 29.

  As described above, according to receiving apparatus 255 in Embodiment 5, as a result of performing error correction on a demodulated signal corresponding to a received broadcast signal, error correction cannot be performed on data corresponding to the demodulated signal. Even if the data is correct, complementary data corresponding to the data for which error correction was not possible can be obtained from the transmitting station 11. Therefore, even if the receiving state of the receiving device 255 with respect to the broadcast signal is poor, the reproduction of the video and the audio can be favorably performed by using the complementary data.

  When transmitting a complementary signal from the transmitting station 11 in response to the uncorrectable signal, the number of error correction packets to be added to complementary data corresponding to the complementary signal may be changed. When the number of error correction packets added to the complementary data is increased when transmitting the complementary signal in response to the uncorrectable signal from the transmitting station 11, the first error correction unit 30 of the receiving device 255 Error correction for the demodulated signal can be performed more reliably. That is, the error correction capability of the first error correction unit 30 can be substantially increased.

  Further, when transmitting a complementary signal from the transmitting station in response to the uncorrectable signal, a modulation method of a carrier to which complementary data corresponding to the complementary signal is allocated may be changed. For example, there are DQPSK, QPSK, 16QAM, 64QAM and the like as a modulation method of the carrier. In general, a modulation scheme with a small number of multi-values is less susceptible to noise. Therefore, for example, when the reception state of the transmission signal of the receiving device 255 becomes worse, the modulation method is changed from 64QAM to 16QAM.

  The reception state of the receiving device 255 is determined, for example, by comparing the number of errors corresponding to the uncorrectable signal obtained in the first error correction unit 30 with a predetermined threshold value. Is greater than the threshold, it can be determined that the reception state is poor, and if the number of errors is smaller than the threshold, the reception state is good.

The change of the modulation scheme is performed by the transmitting station 11, and the selection of the modulation scheme may be performed by the receiving device 255 or the transmitting station 11. The selection of the modulation method in receiving apparatus 255 can be performed as follows. For example, the threshold values Th ₁ , Th ₂ , and Th ₃ are set in the first error correction unit 30 so that Th ₁ > Th ₂ > Th _3, and the correction obtained in the first error correction unit 30 is performed. number of errors e corresponding to disable signal, when is smaller than Th ₃ is 16QAM, when a is Th ₃ or less than Th ₂ is 64QAM, smaller than Th ₁ a is Th ₂ or more QPSK, in the case where Th ₁ or selects a modulation scheme such as DQPSK. FIG. 7 summarizes the relationship between the threshold and the number of errors described above.

  Then, when the receiving apparatus 255 that has selected the modulation scheme as described above transmits a non-correctable signal from the first error correction unit 30 to the transmitting station 11, the receiving apparatus 255 converts a signal corresponding to the selected modulation scheme into a signal. Send. The above method can be applied to the case where the transmitting station 11 selects a modulation method.

  In the above description, if the error correction in the first error correction unit 30 results in data that cannot be corrected in the data corresponding to the demodulated signal, the first error correction unit 30 Although the case of transmitting a signal has been described, the first error correction unit 30 periodically outputs a signal corresponding to the result of error correction (hereinafter, referred to as a correction result signal) to the transmitting station 11 and transmits the signal. The receiving transmitting station 11 may be configured to appropriately change the number of error correction packets or the modulation scheme based on the correction result signal input periodically.

Embodiment 6 FIG.
FIG. 8 is a block diagram showing a configuration of receiving apparatus 256 according to Embodiment 6. In FIG. 8, the same components as those described in the first to fifth embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  In FIG. 8, the demodulated signal output from the first demodulation / decoding unit 5 is output to the first error correction unit 30. The first error correction unit 30 performs an error correction process on the demodulated signal, and outputs a video signal or an audio signal obtained based on the demodulated signal to the video receiving unit 6 or the audio receiving unit 7. When the demodulated signal includes data for which error correction is impossible, the first error correction unit 30 outputs a non-correctable signal corresponding to the data to the error information storage unit 31.

  The error information storage unit 31 records the number of errors corresponding to the uncorrectable signal. In the following description, the case where the number of errors is recorded in the error information storage unit 31 will be described. However, the error information storage unit 31 may store, for example, a bit error rate. That is, the error information storage unit 31 only needs to store information corresponding to an error in the data corresponding to the demodulated signal.

  The error information storage unit 31 outputs a signal corresponding to the recorded error number to the reception state prediction unit 32. Then, the reception state prediction unit 32 predicts a temporal change in the reception state of the reception device 256 based on the number of errors corresponding to the signal input from the error information storage unit 31.

  FIG. 9 is an explanatory diagram for explaining the prediction of the reception state in the reception state prediction unit 32. Based on the signal input from the error information storage unit 31, the reception state prediction unit 32 determines the time when the reception device 256 received the broadcast signal and the data corresponding to the broadcast signal, as shown in FIG. The number of errors included is recorded in association with each other.

  The reception state prediction unit 32 predicts a change in the reception state based on the recorded time and the number of errors. Specifically, based on a signal input from the error information storage unit 31 within a predetermined time, the time and the number of errors within the predetermined time are converted into a function, and extrapolation is performed based on the function. Thus, a time when the number of errors exceeds a predetermined threshold value is detected.

  In FIG. 9, the time during which the signal is input three times from the error information storage unit 31 is defined as the predetermined time t, and the time and the number of errors at the predetermined time t are linear functions. By extrapolating the linear function, a time t1 at which the number of errors exceeds a predetermined threshold Th is detected. Therefore, the reception state prediction unit 32 predicts that the reception state of the reception device 256 will be deteriorated at the time t1. Note that the predetermined time and the threshold can be arbitrarily set according to the environment of the system using the receiving device 256.

  Then, as a result of performing the extrapolation, the reception state predicting unit 32 requests the transmitting station 11 in advance for data corresponding to the broadcast signal received by the receiving device 256 at a time when the number of errors exceeds a predetermined threshold value. I do. Specifically, a signal (hereinafter, referred to as a request signal) corresponding to the requested data is transmitted to the transmitting station 11.

  Upon receiving the request signal output from the reception state prediction unit 32, the transmitting station 11 outputs a complementary signal corresponding to the data request signal to the receiving device 256.

  The complementary signal transmitted from the transmitting station 11 is input to the second line I / F 13 in the receiving device 256, and is processed by each unit from the second high-frequency amplification / detection unit 14 to the second error correction unit 31. Demodulation, error correction and the like are performed. Then, a video signal corresponding to the complementary data obtained as a result of demodulation, error correction, and the like is output to the first buffer 41 via the video receiving unit 16. Further, an audio signal corresponding to the complement data is output to the second buffer 42 via the audio receiving unit 17. The operations of the first buffer 41 and the second buffer 42 and thereafter are the same as the operations of the receiving device 255 according to the fifth embodiment, and a description thereof will be omitted.

  As described above, according to receiving apparatus 256 in the sixth embodiment, the complementary data can be acquired in advance based on the output of first error correction section 30. Therefore, even when the receiving state of the receiving device 256 is deteriorated, it is possible to reproduce the video or the audio satisfactorily.

Embodiment 7 FIG.
FIG. 10 is a block diagram showing a configuration of receiving apparatus 257 according to Embodiment 7. In the following description, the same components as those described in the first to sixth embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  In FIG. 10, a first error correction unit 30 performs an error correction process on the demodulated signal output from the first demodulation / decoding unit 5, and performs a process based on the demodulated signal subjected to the error correction process. The obtained video signal and audio signal are output to the video receiving unit 6 or the audio receiving unit 7, respectively. Then, the video receiving unit 6 outputs the first video signal to the first buffer 41, and the audio receiving unit 7 outputs the first audio signal to the second buffer 42. In addition, when there is data that cannot be corrected in the data corresponding to the demodulated signal, the first error correction unit 30 outputs a non-correctable signal corresponding to the data to the error information storage unit 31.

  When the uncorrectable signal is input, the error information storage unit 31 stores the number of errors corresponding to the uncorrectable signal. Further, it outputs the input uncorrectable signal to the transmitting station 11. The transmitting station 11 that has received the uncorrectable signal transmits a complementary signal corresponding to the uncorrectable signal to the receiving device 257 (hereinafter referred to as charging information). Billing signal) is output to the error information storage unit 31.

  When receiving the billing signal transmitted from the transmitting station 11, the error information storage unit 31 outputs the billing signal and the uncorrectable signal to the graphics generator 22.

  The graphics generator 22 generates a first image indicating the reception state of the receiving device 257 and a second charge indicating the charge corresponding to the charge information, based on the charge signal and the uncorrectable signal output from the error information storage unit 31. Are generated, and signals corresponding to these images are output to the adder 33.

  The adder 33 combines the signal output from the first buffer 41 and the signal output from the graphics generator 22. Note that, by performing the synthesis by the adder 33, three images, that is, the image corresponding to the broadcast signal transmitted from the broadcast station, the first image, and the second image are, for example, as shown in FIG. Is displayed on the screen of the monitor 8.

  Then, the user of the receiving device 257 checks the receiving state of the receiving device 257 based on the first video. As a result of the confirmation, if the reception state of the receiving device 257 is poor, the user confirms the fee required when the complementary data is obtained from the second video, and responds to the error-correctable data. It is determined whether supplementary data is to be obtained from the transmitting station 11 or not.

  As a result of the determination, when acquiring the complementary data from the transmitting station 11, the user operates the operation unit of the receiving device 257 to input that the complementary data is acquired. When the user operates the operation unit, a signal is input to the error information storage unit 31 from the operation unit.

  When receiving the signal from the operation unit, the error information storage unit 31 outputs the stored uncorrectable signal to the transmitting station 11 again. The transmitting station 11 that has received the uncorrectable signal again outputs a complementary signal corresponding to the uncorrectable signal to the receiving device 257.

  The complementary signal is received by the second line I / F 13, and demodulation, error correction, and the like are performed by the components from the second high-frequency amplification / detection unit 14 to the second error correction unit 31. Then, a second video signal obtained as a result of demodulation, error correction, and the like is input to the first buffer 41. Further, the second audio signal is output to the second buffer 42. The operations after the first buffer 41 and the second buffer 42 are the same as the operations of the receiving device 255 according to the fifth embodiment, and a description thereof will be omitted.

  As described above, according to receiving apparatus 257 in the seventh embodiment, when the receiving state of receiving apparatus 257 is poor, whether or not to obtain complementary data from transmitting station 11 is determined on the screen of monitor 8. Can be performed by the user based on the video indicating the fee displayed on the screen.

  That is, the user looks at the video displaying the fee displayed on the screen of the monitor 8 and when the displayed fee is high, says "Let's watch the video by the broadcast signal even if the video quality is poor." In the case where the fee is low, it is possible to determine that "let the supplementary data be obtained from the transmitting station 11 and watch the video."

  Therefore, when the supplementary signal transmitted from the transmitting station 11 is charged, the user can freely select whether to obtain the supplementary signal. In addition, unnecessary expenditure of the user accompanying the acquisition of the complementary data can be suppressed.

  In the above description, a case has been described in which an image indicating the billing information is displayed on the monitor 8. However, not only the billing information but also the sum of the fees corresponding to the actually acquired complementary data (hereinafter referred to as the total amount). ) May be displayed.

  When displaying the video indicating the total amount, the charging signal is stored in the error information storage unit 31, and when the error correction signal is transmitted from the error information storage unit 31 to the transmitting station 11 again, The error information storage unit 31 outputs the accounting signal stored in the graphic generator 22.

  Then, the graphic generator 22 further adds the charge corresponding to the received charge signal to the total amount of charge corresponding to the charge signal already input, generates a video indicating the total amount after the addition, The signal corresponding to the video is output to the adder 33.

FIG. 2 is a block diagram showing a configuration of a receiving device according to Embodiment 1 of the present invention. FIG. 9 is a block diagram showing a configuration of a receiving device according to Embodiment 2 of the present invention. FIG. 13 is a block diagram showing a configuration of a receiving device according to Embodiment 3 of the present invention. It is an explanatory view for explaining a bar graph. FIG. 14 is a block diagram showing a configuration of a receiving apparatus according to Embodiment 4 of the present invention. FIG. 15 is a block diagram showing a configuration of a receiving apparatus according to Embodiment 5 of the present invention. FIG. 4 is an explanatory diagram for explaining a relationship between a threshold and a modulation scheme. FIG. 15 is a block diagram showing a configuration of a receiving apparatus according to Embodiment 6 of the present invention. FIG. 4 is an explanatory diagram for explaining an operation of a reception state prediction unit. FIG. 21 is a block diagram showing a configuration of a receiving device according to Embodiment 7 of the present invention. FIG. 4 is an explanatory diagram for describing a first video and a second video.

Explanation of reference numerals

REFERENCE SIGNS LIST 1 broadcast station, 2 radio broadcast line, 3 first line interface, 13 second line interface, 4 first high-frequency amplifier / detector, 14 second high-frequency amplifier / detector, 5 first demodulation / decoding Unit, 15 second demodulation / decoding unit, 6 video receiving unit, 7 audio receiving unit, 8 monitor, 9 speaker, 10 channel selecting unit, 11 transmitting station, 12 wireless communication line, 16 video reproducing unit, 17 audio reproducing unit , 18 video selection unit, 19 audio selection unit, 20 signal selection unit, 21A first determination circuit, 21B second determination circuit, 22 graphics generator, 23A first comparison delay difference calculation unit, 23B second comparison Delay difference calculator, 24A first variable buffer, 24B second variable buffer, 24C third variable buffer, 24D fourth variable buffer, 26 first A / D converter, 27 2nd A / D converter, 28 1st D / A converter, 29 2nd D / A converter.

Claims (16)

First receiving means for receiving a broadcast signal transmitted from a broadcast station,
Second receiving means for receiving a transmission signal transmitted from the transmitting station,
And a program reproducing means for reproducing video and audio corresponding to a program broadcast in the broadcast station based on one of the broadcast signal and the transmission signal.   The receiving device according to claim 1, wherein the data corresponding to the broadcast signal and the data corresponding to the transmission signal are the same data. Further comprising signal selection means for selecting any one of the broadcast signal or the transmission signal,
3. The program reproducing apparatus according to claim 1, wherein the program reproducing means reproduces a video and an audio corresponding to a program broadcast in the broadcasting station based on the signal selected by the signal selecting means. Receiver. Determining means for comparing a signal corresponding to the broadcast signal received by the first receiving means with a signal corresponding to the transmission signal received by the second receiving means to determine a receiving state of the receiving apparatus; In addition,
4. The receiving apparatus according to claim 3, wherein the signal selection unit is configured to select a signal based on a result of the determination by the determination unit. Determining means for comparing a signal corresponding to the broadcast signal received by the first receiving means with a signal corresponding to the transmission signal received by the second receiving means to determine a receiving state of the receiving apparatus;
The receiving device according to any one of claims 1 to 3, further comprising a video generating unit that generates a video indicating a receiving state of the receiving device based on a result of the determination by the determining unit.   The receiving device according to claim 4, further comprising: a video generating unit that generates a video indicating a receiving state of the receiving device based on a result of the determination by the determining unit.   The reception apparatus according to claim 5, wherein the image generation unit separately generates an image corresponding to a reception state for a broadcast signal and an image corresponding to a reception state for a broadcast signal in the receiving device. apparatus. Delay amount calculating means for calculating a delay amount between a broadcast signal received by the first receiving means and a transmission signal received by the second receiving means;
The receiving device according to any one of claims 1 to 7, further comprising a buffer that gives the delay amount calculated by the delay amount calculating means to the broadcast signal or the transmission signal. Complementary data for performing error correction processing on data corresponding to a broadcast signal received by the first receiving means, and as a result of the error correction processing, complementing data for which error correction cannot be performed on the data. Further comprising error correction means for requesting the transmitting station to transmit
3. The apparatus according to claim 1, wherein the second receiving unit is configured to receive, as a transmission signal, a signal corresponding to complementary data transmitted from the transmitting station in response to the request of the error correction unit. Receiver.   The error correction means is configured to select a modulation method used for modulating the complementary signal corresponding to the complementary data at the transmitting station, and to transmit a signal corresponding to the selected modulation method to the transmitting station. 10. The receiving device according to 9. Error correction means for performing error correction processing on data corresponding to the broadcast signal received by the first reception means, and outputting a signal corresponding to information on the data for which error correction is impossible in the data;
Error information storage means for storing information on the data for which error correction is impossible, corresponding to the signal output from the error correction means,
And a reception state prediction unit that predicts a reception state of the reception device based on the information stored in the error information storage unit, and requests a transmission station to transmit complementary data according to a result of the prediction. The receiving device according to claim 1, further comprising:   The receiving apparatus according to claim 11, wherein the information on the data for which error correction cannot be performed, obtained in the error correction unit, is the number of error data in data corresponding to the transmission signal.   The receiving apparatus according to claim 11, wherein the information on the data for which error correction is not possible, obtained in the error correction unit, is a bit error rate corresponding to data corresponding to the transmission signal. Error correction means for performing error correction processing on data corresponding to the broadcast signal received by the first reception means, and outputting a signal corresponding to information on the data for which error correction is impossible in the data;
And, transmitted from the transmitting station in response to the signal output from the error correction means, based on the billing information corresponding to the complementary data, based on the signal corresponding to the information about the error-impossible data, The receiving device according to claim 1, further comprising a video generating unit configured to generate a video in which a fee generated when the receiving device acquires the complementary data is displayed.   15. The receiving device according to claim 14, wherein the video generating means is configured to generate a video displaying a total amount of a fee corresponding to the supplementary data acquired by the receiving device. Receiving a broadcast signal transmitted from a broadcast station,
Receiving the transmission signal transmitted from the transmitting station,
A receiving method including reproducing video and audio corresponding to a program broadcast in the broadcast station based on one of the broadcast signal and the transmission signal.

Images