JP4791567B2 - Digital broadcast receiver - Google Patents

Description

  The present invention relates to a digital broadcast receiving apparatus that receives terrestrial digital broadcasts and digital broadcasts that are frequency-converted and retransmitted.

  In recent years, satellite broadcasting and cable broadcasting (hereinafter abbreviated as CATV) are becoming widespread in various places, in addition to conventional terrestrial broadcasting that transmits program videos to homes using radio waves in the VHF band and UHF band. Recently, standardization of digital broadcasting has been actively performed, and digital broadcasting (hereinafter abbreviated as CS digital broadcasting) using a communication satellite (CS: Communication Satellite) is currently commercialized. In addition, digital broadcasting (hereinafter abbreviated as “BS digital broadcasting”) and terrestrial digital broadcasting using broadcasting satellites (BS) are aimed at practical use in a few years. The terrestrial digital broadcasting is described in the article “To the start of terrestrial digital broadcasting 2000” (Non-Patent Document 1) on the first page of the radio newspaper on Monday, October 20, 1997. In the original draft, an OFDM (Orthogonal frequency division multiplexing) system is used as a modulation system, and transmission can be performed with a bandwidth of 6 MHz for one RF channel as in the case of the current analog television broadcasting. The OFDM signal in the 6 MHz band has been devised in Japanese Patent Laid-Open No. 7-283806 (Patent Document 1) in order to prevent interference between OFDM signals. Japanese Patent Application Laid-Open No. H8-294098 (Patent Document 2) discloses that the OFDM transmission frequency is converted to a lower frequency in the UHF band, or is changed to a frequency higher than the UHF band when there is no analog broadcasting. And a device that easily corresponds to the addition of a data service linked to a video, for example, a character broadcast or a person's abbreviated calendar.

  Further, the bandwidth of 1RF channel of OFDM terrestrial digital broadcasting is 6 MHz, and the same applies to CATV that mainly retransmits the current analog television broadcasting. It is also possible to transmit to each home through a transmission line.

  The basis of these digital broadcasts is an image compression technique based on MPEG (Moving Picture Experts Group) 2 and a multiplexing method based on a data stream called a transport stream (Transport Stream). According to digital broadcasting, it is possible to send several times the number of programs while maintaining the same image quality and sound quality as those of analog broadcasting. In the current analog broadcasting, since one television broadcast of one program is performed on one RF channel in the 6 MHz band, both can be referred to as channels. However, since digital confusion occurs, hereinafter, the 1 RF channel in the 6 MHz band. Are called physical channels, and those corresponding to a plurality of programs are called logical channels. Also, a system that broadcasts one transport stream on one physical channel (CS, terrestrial or CATV digital broadcast) is a single TS transmission system, and a system that broadcasts two or more transport streams on one physical channel (BS digital broadcast) This is called a multiple TS transmission system.

  To select a program by digital broadcasting of a single TS transmission system, unlike a conventional analog channel selection, a physical channel is selected and a logical channel requested from within one transport stream obtained by the physical channel. It is necessary to perform a two-stage operation of extracting the. An example of this channel selection operation is disclosed on pages 133 to 154 of “Point Illustrated Practice MPEG Textbook” (Non-Patent Document 2), supervised by Hiroshi Fujiwara and published by ASCII Publishing Bureau. In MPEG2, program selection is performed using program usage information called PSI (Program Specific Information).

  PSI includes PAT (Program Association Table), PMT (Program Map Table), NIT (Network Information Table), etc., and PAT indicates the number of the transport stream, the relationship between each logical channel number and PMT, etc. The PMT is composed of information for separating and extracting video, audio, additional data, etc. constituting the program for each logical channel number. The NIT includes information indicating which transport stream number is transmitted on which physical channel.

FIG. 8 is a flowchart of a conventional digital broadcast channel selection method. The conventional reception channel selection operation will be described below with reference to FIG.
In step 801, when a logical channel required for the receiving apparatus (meaning that a desired reception channel is input using a remote controller or the like, hereinafter referred to as a request logical channel) is given, first, in step 802 The PAT of the currently received physical channel is obtained, and it is checked in step 803 whether the requested logical channel number is included in the PAT.

  If “Yes”, that is, if the requested logical channel number is included, it means that the requested logical channel is included in the currently received physical channel. In step 805, the signal of the required logical channel is further separated from the information in the PMT, and the video and audio separated in step 806 are decoded.

  If the requested logical channel number is not included in the PAT in step 803, it means that the requested logical channel is not included in the currently received physical channel. For this reason, in order to check which physical channel includes the requested logical channel, the process proceeds to step 807, where NITs in which the same contents are transmitted in parallel to all physical channels are received, Extracts information about contained physical channels. Then, the channel selection frequency is changed to the obtained physical channel, and in step 808, the PAT of this physical channel is obtained. Thereafter, in step 804, the PMT is extracted from the information in the PAT, the signal of the requested logical channel is separated from the information in the PMT in step 805, and video and audio are decoded from the separated signal in step 806.

  A technique for reducing the time in the channel selection operation is described in Japanese Patent Laid-Open No. 9-9156 (Patent Document 3). This example will be described below with reference to FIG.

  FIG. 9 is a flowchart showing another channel selection method for conventional digital broadcasting. FIG. 8 illustrates the channel selection method in the case where the relationship between the physical channel and the transport number is described in the NIT and the relationship between the transport number and the logical channel number is described in the PAT. An example of channel selection when the relationship between the channel and the transport number and the relationship between the transport number and the logical channel number are described will be shown.

  Table 1 shows the relationship between the physical channel and the transport number in the information described in the NIT, and Table 2 shows the relationship between the logical channel number and the transport number in the information described in the NIT.

ＮＩＴによって、表２に示すトランスポート番号と論理チャネル番号の関係、表１に示す物理チャネルとトランスポート番号の関係が伝送される場合、要求論理チャネル番号がどのトランスポート番号で、そのトランスポート番号はどの物理チャネルで送られているかが分かるので、以下のような流れで受信周波数を変更できる。

When the NIT transmits the relationship between the transport number and the logical channel number shown in Table 2, and the relationship between the physical channel and the transport number shown in Table 1, which transport number is the requested logical channel number, the transport number Since it is known which physical channel is used for transmission, the reception frequency can be changed as follows.

  When the requested logical channel number is requested in step 901, the transport number of the physical channel currently received in step 902 is confirmed, and the process proceeds to step 903, where the table of the relationship between the transport number and the logical channel number is displayed. 8 confirms the transport number of the requested logical channel number. In step 904, it is determined whether the requested transport number matches the currently received transport number. If they match (if yes), go to step 905 to extract the PMT from the information in the PAT, separate the requested logical channel signal from the information in the PMT in step 906, and separate in step 907 Video and audio are decoded from the processed signal.

  If they do not match (in the case of “No”), in Step 908, based on Table 2 showing the relationship between the physical channel and the transport number, the physical channel corresponding to the transport number including the requested logical channel number (NIT description) To change the reception frequency to select a channel. Next, the process proceeds to step 909 to obtain the PAT of the newly received physical channel. In step 905, the PMT is extracted from the information in the PAT. In step 906, the signal of the requested logical channel is separated from the information in the PMT. In step 907, video and audio are decoded from the separated signals.

  In addition, EPG (Electronic Program Guide) is described on page 149 of “Point Illustrated Practical MPEG Textbook” (Non-Patent Document 2), supervised by Hiroshi Fujiwara and published by the ASCII Publishing Bureau. Various additional data called SI (Service Information: service information) is transmitted in addition to the PSI, and by using it, it may be possible to select a program by operating the cursor on the TV screen. Are listed.

As information for the EPG, information called EIT (Event Information Table) is transmitted by SI.
As described above, the bandwidth of one RF channel (hereinafter referred to as a physical channel) of terrestrial digital broadcasting of the OFDM system is 6 MHz, and the same applies to CATV that mainly retransmits the current analog television broadcasting. For this reason, it is also possible to transmit the terrestrial digital broadcast of the OFDM system to each home as it is through the CATV transmission path.

Japanese Patent Laid-Open No. 7-283806 JP-A-8-294098 JP-A-9-9156

Denpa Shimbun, “To the start of digital terrestrial broadcasting in 2000”, Monday, October 20, 1997, first page article Supervised by Hiroshi Fujiwara, “Point Illustration Formula MPEG Textbook”, ASCII Publishing Bureau, p. 133-154

  As described above, even in a digital broadcast receiving apparatus that transmits OFDM terrestrial digital broadcasting as it is to each home through a CATV transmission path, program tuning is performed by the above-described electronic program guide, PAT, NIT, or the like. Become. However, OFDM terrestrial digital broadcasting is scheduled to be broadcast in the UHF band from 470 MHz to 770 MHz, and most of the current CATV transmission line transmission band is from 90 MHz to 450 MHz, and the band is up to 770 MHz. In order to expand, it is necessary to stop the service during the equipment renewal period, change the transmission line amplifier, change the transmission cable, etc., and the renewal cost becomes enormous, which is not considered a realistic method. .

  As a method of reducing the equipment update, a method of converting the frequency from 90 MHz to 450 MHz and transmitting it to the CATV transmission line in the CATV headend facility that retransmits the OFDM terrestrial digital broadcast broadcast in the UHF band. There is. When digital broadcasting is retransmitted in this manner, information such as NIT is transmitted as it is, so that program selection by EPG (Electronic Program Guide), PAT or NIT becomes impossible.

  As a solution, there is a method of converting information such as NIT. In this method, the terrestrial digital broadcast is received and demodulated and returned to the transport stream, the physical channel information described in the NIT in the NIT is converted, the frequency information of the conversion destination is described, and the conversion is further performed. It is necessary to perform OFDM modulation using the transport stream and transmit the signal in a frequency band of 90 MHz to 450 MHz. Even in this method, it is considered that this is not a realistic method when considering a small-scale CATV facility provided for countermeasures against radio wave interference by transmission lines, high-rise buildings, etc. due to the scale of equipment and capital investment of the CATV headend facility. .

  An object of the present invention is to provide a digital broadcast receiving apparatus capable of selecting a program from an electronic program guide, PAT, NIT, or the like for a digital broadcast which is simply frequency-converted and retransmitted.

  In order to solve the above-described problems, in the present invention, as a digital broadcast receiver, a tuner unit is swept to detect a receivable frequency, and an NIT is obtained for each detected frequency, and is described in the NIT. A transport number is acquired, correspondence information is generated by associating the acquired transport number with the receivable frequency different from the broadcast frequency stored in the NIT, and the correspondence information is used. A tuning operation of the digital broadcast signal in the tuner unit is controlled, the selected digital broadcast signal is demodulated to generate a transport stream, and a video signal is separated from the transport stream and decoded.

  According to the present invention, since the transport stream number, the transmitted transmission frequency information, and the received frequency information are stored in a contrast, the transport stream to be selected by an operation from an electronic program guide or the like is stored. The number, transmission frequency information, and reception frequency information to be received can be obtained. As a result, it is possible to select a logical channel of a digital broadcast that has been retransmitted by simply performing frequency conversion at a CATV facility or the like. .

It is a block diagram which shows one Example of the digital broadcast receiver by this invention. 5 is a flowchart for explaining an embodiment of the operation of the digital broadcast receiving apparatus according to the present invention. 6 is a flowchart illustrating an example of an operation in a storing process in a storage unit of the digital broadcast receiving apparatus according to the present invention. It is a block diagram which shows one Example of the head end of the CATV facility which transmits the digital broadcast which can be received with the digital broadcast receiver by this invention. It is a flowchart for demonstrating operation | movement of the other Example of the digital broadcast receiver by this invention. It is a flowchart which shows the operation | movement which memorize | stores in a memory | storage part by EPG storage mode and the flowchart which shows the other Example of the operation | movement in the memory | storage process to the memory | storage part of the digital broadcast receiver by this invention. It is a flowchart for demonstrating operation | movement of further another Example of the digital broadcast receiver by this invention. It is a flowchart of the conventional channel selection method of digital broadcasting. It is a flowchart which shows the other channel selection method of the conventional digital broadcasting.

  Hereinafter, embodiments of a digital broadcast receiving apparatus of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of a digital broadcast receiving apparatus according to the present invention.
In FIG. 1, 101 is an input terminal for a digital broadcast signal, 102 is an input terminal for requesting a desired program, 103 is a control section of a digital broadcast receiving apparatus, 104 is a tuner section for selecting a physical channel, and 105 is a digital section. Demodulating section for demodulating, 106 is a TS separating section for separating information from a transport stream (TS), 107 is a video / audio decoding section, 108 is a video signal output terminal, 109 is an audio signal output terminal, and 1031 is channel selection control. Reference numeral 1032 denotes a storage unit for storing reference information such as a frequency for reception. The channel selection control unit 1031 controls the channel selection frequency supplied to the tuner unit 104, controls data error correction and demodulation of encoded information in the demodulation unit 105, and separates transport streams. Or output information.

  A digital broadcast signal input from the input terminal 101 is sent to the tuner unit 104. The tuner unit 104 selects a necessary physical channel from the digital broadcast signal and converts it to an intermediate frequency. The demodulator 105 receives this signal, performs digital demodulation, correction of a data error generated in the transmission path, and the like to reproduce a transport stream. Video signal and audio signal data are separated from the transport stream reproduced by the TS separation unit 106. The separated video signal and audio signal data is demodulated into a video signal and an audio signal by the video / audio decoding unit 107, and the video signal is output to the video signal output terminal 108 and the audio signal is output to the audio signal output terminal 109.

Next, the process of selecting a desired program selected by the viewer will be described with reference to FIG.
FIG. 2 is a flowchart for explaining an embodiment of the operation of the digital broadcast receiving apparatus according to the present invention.
In step 201 of FIG. 2, when a logical channel number is requested, that is, when a viewer selects a logical channel to be selected by an operation from an electronic program guide or the like with a remote controller or the like, the request is sent from the input terminal 102 to the digital broadcast receiving apparatus. Of the PAT, PMT, and NIT sent in the transport stream by the TS separation unit 106 and the channel selection control unit 1031 of the control unit 103 from the transport stream obtained by the demodulation unit 105. Perform import processing.

  In step 202, the PAT of the currently received physical channel is fetched, and in step 203, it is examined whether or not the requested logical channel number is included in the PAT. If the requested logical channel number is included (in the case of “Yes”), it means that the requested logical channel is included in the currently received physical channel. The PMT is extracted from the information, and further, in step 205, the signal of the requested logical channel is separated from the information in the PMT. Next, video and audio are decoded from the signal separated in step 206.

  In step 203, if the requested logical channel number is not included (in the case of “none”), it means that the requested logical channel is not included in the currently received physical channel. In order to check whether the channel is included, in step 207, the NIT in which the same contents are transmitted in parallel to all the physical channels is fetched, and the requested physical channel information including the requested logical channel is requested. The transport stream number and the transmitted transmission frequency information are extracted.

  Since the storage unit 1032 stores the reference information such as the frequency for reception, the physical information including the requested logical channel is stored in step 208 using the reference information such as the frequency for reception stored in advance. The requested transport stream number which is channel information is compared with the received frequency information to be received, the frequency of the physical channel corresponding to the transport (TS) number is obtained, and the channel selection is changed to this frequency. Next, in step 209, the transport stream of this physical channel is received and a PAT is obtained. Thereafter, the process proceeds to step 204, where the PMT is extracted from the information in the PAT. In step 205, the signal of the requested logical channel is separated from the information in the PMT by the TS separator 106. The separated video signal and audio signal data is decoded into a video signal and an audio signal by the video / audio decoding unit 107 in step 206, and the video signal is output to the video signal output terminal 108 and the audio signal is output to the audio signal output terminal 109. , The program requested by the viewer can be displayed.

Next, the flow of processing for capturing the reference information such as the frequency for reception stored in advance in the storage unit 1032 that stores the reference information such as the frequency for reception will be described with reference to FIG.
FIG. 3 is a flowchart showing an embodiment of the operation in the storage process in the storage unit of the digital broadcast receiving apparatus according to the present invention.
In order to explain the flowchart of FIG. 3, the relationship between the physical channel of digital terrestrial broadcasting (abbreviated as terrestrial physical channel) transmitted by NIT and the transport number is shown in Table 3, and the logical channel number included in the PAT Table 4 shows the relationship between the transport numbers.

まず、本発明のデジタル放送受信装置は購入したままの状態であり、受信のための周波数設定が何もなされていない場合（デジタル放送受信装置初期状態）について説明する。伝送信号の入力端子１０１にＣＡＴＶの同軸ケーブルを接続し、デジタル放送受信装置に電源を入れる。リモコンなどの操作によってデジタル放送受信装置を記憶設定操作状態にすると、デジタル放送受信装置の制御部１０３は記憶設定モードになり、ステップ３０１に示すように、記憶部１０３２は記憶モードになる。その状態で、ステップ３０２に移行し、受信できる物理チャネルを探すために、受信可能な範囲の周波数を６ＭＨｚ帯域で送られるデジタル放送の周波数条件に合わせて、デジタル放送受信装置の選局制御部１０３１の制御によってチューナ部１０４をチャネル掃引する。次に、ステップ３０３で、そのチャネル掃引に伴って得られた物理チャネルを復調部１０５でデジタル復調可能かどうかを選局制御部１０３１で監視する。デジタル復調が不可能な場合（「いいえ」の場合）、ステップ３０２に戻って受信周波数を変更する。

First, the case where the digital broadcast receiving apparatus of the present invention has been purchased and no frequency setting for reception has been made (initial state of the digital broadcast receiving apparatus) will be described. A CATV coaxial cable is connected to the input terminal 101 of the transmission signal, and the digital broadcast receiver is turned on. When the digital broadcast receiving apparatus is set to the storage setting operation state by operating the remote controller or the like, the control unit 103 of the digital broadcast receiving apparatus enters the storage setting mode, and the storage unit 1032 enters the storage mode as shown in step 301. In this state, the process proceeds to step 302, and in order to search for a physical channel that can be received, the channel selection control unit 1031 of the digital broadcast receiving apparatus is matched with the frequency condition of the digital broadcast in which the frequency within the receivable range is transmitted in the 6 MHz band. The tuner unit 104 performs channel sweeping under the control of the above. Next, at step 303, the channel selection control unit 1031 monitors whether the physical channel obtained with the channel sweep can be digitally demodulated by the demodulation unit 105. When digital demodulation is impossible (in the case of “No”), the process returns to Step 302 to change the reception frequency.

  When a physical channel that can be digitally demodulated under the monitoring (in the case of “Yes”), the process proceeds to step 304, the channel sweep is interrupted once, and the TS separation unit is separated from the transport stream obtained by the demodulation unit 105. 106 and the channel selection control unit 1031 perform processing for capturing PAT, PMT, and NIT transmitted in the transport stream.

  As shown in Table 3, the NIT includes transmission frequency information of a plurality of terrestrial physical channels and the number of transport streams sent on each physical channel (transmission stream information is transmitted from UHF 15ch to UHF 21ch. Numbers 1 to 4) are described in contrast. Further, as shown in Table 4, the number of the currently received transport stream (the number of the transport stream is 1) is described in the PAT transmitted on the physical channel where the channel sweep is interrupted. From these pieces of information, the transmission frequency information of a plurality of physical channels transmitted on this network, the number of transport streams sent on each physical channel, and the number of the transport stream currently received can be known. Next, the process proceeds to step 305, and the current reception frequency at which the channel sweep is interrupted is known from the control information (channel selection information) of the channel selection control unit 1031 that interrupted the channel sweep of the tuner unit 104 once. The received frequency is compared with the transport number obtained in step 304 and stored in the storage unit 1032.

  Further, returning to step 302 again, the reception frequency is changed to search for a physical channel that can be demodulated. If there is a physical channel that can be demodulated, the reception frequency and transport number are stored in step 305.

  Table 5 is an example of the storage information of the storage unit 1032 obtained in this way.

表５に示すように、記憶部１０３２に記憶する情報は、例えば、受信周波数がＣＡＴＶ３１ｃｈであり、そのトランスポートストリームの番号が１であり、その本来の送信周波数であるＵＨＦ１５ｃｈであるという情報である。

As shown in Table 5, the information stored in the storage unit 1032 is, for example, information that the reception frequency is CATV31ch, the transport stream number is 1, and the original transmission frequency is UHF15ch. .

  At the same time, transmission frequency information from UHF 17ch (transport stream number 2) to UHF 21ch (transport stream number 4) obtained by NIT is mixed with information that cannot be received at the receiving location of the CATV facility that is retransmitting. Or the information may not be retransmitted by the CATV facility, and when the corresponding transport stream numbers 2 to 4 are received by the channel sweep, the information is stored in the storage unit 1032 for the first time. Is desirable.

  When these information processes are completed, the channel sweep that has been temporarily stopped is restarted as described above, and an operation for searching for the next receivable physical channel is performed in steps 302 to 305. In the example of Table 5, it is then possible to demodulate with CATV33ch.

The same operation is performed in the reception state, and the reception frequency CATV33ch, the transport stream number 2 and the original transmission frequency UHF17ch are additionally stored in the storage unit 1032.
Furthermore, by repeating the same channel sweep and operation, the information shown in Table 5 can be stored in the storage unit 1032.

  The above operation is performed by the operation of the viewer according to the description of the manual of the digital broadcast receiving apparatus, the operation by the service person when purchasing the digital broadcast receiving apparatus, or the operation of the construction personnel when joining the CATV. There is also a method in which a key such as an automatic storage setting mode is provided on a remote control or the like of the digital broadcast receiving apparatus for automatic setting.

  Further, it is more convenient to set the storage unit 1032 so that a plurality of the same reference information (a plurality of display contents of Table 5) can be stored. For example, the destruction of the reference information in the storage unit 1032 due to a trouble during the update of the storage unit 1032 due to a change in the reception status due to a failure of the CATV transmission path or a forced stop due to a viewer operation during the storage operation in FIG. In addition, as described in JP-A-8-294098 (Patent Document 2), the schedule for changing the transmission frequency of OFDM is determined, and the frequency information and the change time information after the change are changed. It is also effective to store the information in advance when it is sent as other information of the NIT.

  This stored information is the “contrast information such as the frequency for reception stored in advance in the storage unit 1032” shown in FIG. 1 or 2, and the processing shown in FIG. 1 or 2 is possible. This is the basis.

  As described with reference to FIG. 3, according to the present embodiment, as shown in Table 5, the transport stream number and transmission frequency information obtained by NIT or PAT are represented by the demodulator 105 and the TS separator 106. Since the transport stream number and the received frequency information are compared with each other through the channel selection control unit 1031 and stored in the storage unit 1032, the digital broadcast that has been simply subjected to frequency conversion at a CATV facility or the like is directly transmitted. As with reception, the program can be selected by PAT or NIT.

Next, a head-end device in a CATV facility that simply performs frequency conversion and retransmits a digital broadcast will be described with reference to FIG.
FIG. 4 is a block diagram showing an embodiment of a head end of a CATV facility that transmits a digital broadcast that can be received by the digital broadcast receiver according to the present invention.
In FIG. 4, 401 is a digital broadcast signal input terminal, 402 is a signal distributor, 403a to 403d are frequency converters, 404 is a synthesizer for frequency multiplexing, and 405 is an output terminal for CATV signals.

  A digital broadcast reception signal is input from the digital broadcast signal input terminal 401. This received signal is distributed by the signal distributor 402 by the number of digital terrestrial broadcasts that can be received at the receiving point or the number of RF channels (physical channels) that are to be transmitted by this CATV equipment. A plurality of terrestrial digital broadcast UHF channels are converted into a plurality of different frequency bands by frequency converters 403 a to 403 d, respectively, and frequency-multiplexed by a combining unit 404. The frequency-multiplexed signal is transmitted to the CATV transmission line via the CATV signal output terminal 405.

  Fig. 4 shows the frequency conversion of UHF15 channel for digital terrestrial broadcasting to 31 CATV channel, UHF17 channel for terrestrial digital broadcasting to 33 CATV channel, UHF19 channel for terrestrial digital broadcasting to 35 CATV channel, and UHF21 channel for terrestrial digital broadcasting to 41 CATV channel An example is shown.

  As described above, the bandwidth of 1 RF channel (physical channel) of the terrestrial digital broadcasting of the OFDM system is 6 MHz, and the same applies to CATV that mainly retransmits the current analog television broadcasting. For this reason, it is possible to frequency-convert OFDM terrestrial digital broadcasting as it is in the RF TV unit at the head end of the CATV facility and transmit it to each home via the CATV transmission path.

  Table 6 shows another example of information stored in the storage unit 1032 constituting one embodiment of the present invention. In this example, the logical channel number (program number) obtained by the PAT in the operation shown in FIG. 3 is also stored. When a request for the logical channel shown in FIG. 2 occurs, which reception frequency should be selected. There is an advantage to understand immediately.

図５は、本発明によるデジタル放送受信装置の他の実施例の動作を説明するためのフローチャートである。この実施例において、記憶部１０３２には表６に示す記憶情報が記憶されているものとする。

FIG. 5 is a flowchart for explaining the operation of another embodiment of the digital broadcast receiving apparatus according to the present invention. In this embodiment, it is assumed that the storage unit 1032 stores the storage information shown in Table 6.

  First, in step 501, when a viewer selects a logical channel number (program number) to be selected by an operation from a remote controller or the like and requests a logical channel number, in step 502, the transport of the currently received physical channel is performed. In step 503, the transport number of the requested logical channel number is confirmed. In step 504, it is checked whether the transport number of the requested logical channel matches the currently received transport number. If the requested requested logical channel number is included in the currently received transport number (in the case of “Yes”), the process proceeds to step 505 to extract the PMT from the information in the PAT, and In step 506, the signal of the required logical channel is separated from the information in the PMT, and in step 506, video and audio are decoded from the separated signal.

  In step 504, if the requested logical channel number is not included (in the case of “No”), the physical channel corresponding to the transport number including the requested logical channel is confirmed, and in step 509, the storage unit 1032 is stored. From the stored logical channel number (program number), transport stream number, and reception frequency information, the channel selection frequency is immediately changed to the physical channel and received. Next, in step 510, the PAT is obtained from the newly received physical channel. Furthermore, by moving from step 505 to step 506, decoded video and audio can be obtained.

  FIG. 6A is a flowchart showing another embodiment of the operation in the storing process in the storage unit of the digital broadcast receiving apparatus according to the present invention, and FIG. 6B is stored in the storage unit in the EPG storage mode. It is a flowchart which shows operation | movement. Table 7 is another example of the stored information stored in the storage unit 1032 by the flowchart shown in FIG. 6A, and EPG (electronic program guide) information is also stored in the storage unit 1032.

図６（ａ）のフローチャートでは、図３のフローチャートに加えて、受信している物理チャネルからＥＰＧ情報を記憶する動作が加わっている。この動作によって、受信可能なチャネルのＥＩＴ情報からＥＰＧのための情報を記憶部１０３２に逐次記憶することができる。

In the flowchart of FIG. 6A, in addition to the flowchart of FIG. 3, an operation for storing EPG information from the received physical channel is added. By this operation, information for EPG can be sequentially stored in the storage unit 1032 from EIT information of receivable channels.

First, the digital broadcast receiving apparatus of the present invention is in a purchased state, and when no frequency setting for reception is made (initial state of the digital broadcast receiving apparatus), the CATV coaxial is connected to the transmission signal input terminal 101. Connect the cable and turn on the digital broadcast receiver. When the digital broadcast receiving apparatus is set to the storage setting operation state by operating the remote controller or the like, the control unit 103 of the digital broadcast receiving apparatus is in the storage setting mode, and as shown in step 601, the storage unit 1032 is in the storage mode. In this state, the process shifts to step 602, and in order to search for a receivable physical channel, the channel selection control unit 1031 of the digital broadcast receiving apparatus is matched with the frequency condition of the digital broadcast transmitted in the 6 MHz band in order to search for a receivable frequency. The tuner unit 104 performs channel sweeping under the control of the above. Next, in step 603, the channel selection control unit 1031 monitors whether the physical channel obtained with the channel sweep can be digitally demodulated by the demodulation unit 105.
When digital demodulation is impossible (in the case of “No”), the process returns to Step 302 to change the reception frequency.

  When a physical channel capable of digital demodulation is obtained under the monitoring (in the case of “Yes”), the process proceeds to Step 604, the channel sweep is interrupted once, and the TS separation unit 106 is transported from the transport stream obtained by the demodulation unit 105. The channel selection control unit 1031 performs processing for taking in the PAT, PMT, and NIT sent in the transport stream.

  As shown in Table 3, the NIT includes transmission frequency information of a plurality of terrestrial physical channels and the number of transport streams sent on each physical channel (transmission stream information is transmitted from UHF 15ch to UHF 21ch. Numbers 1 to 4) are described in contrast. Further, as shown in Table 4, the currently received transport stream number (the transport stream number is 1) is described in the PAT transmitted on the physical channel where the channel sweep is interrupted. . From these pieces of information, the transmission frequency information of a plurality of physical channels transmitted on this network, the number of transport streams sent on each physical channel, and the number of the transport stream currently received can be known. Next, in step 605, EIT is obtained from the received physical channel, EPG is obtained from EIT, and this is stored. Next, the process proceeds to step 606, and the current reception frequency at which the channel sweep is interrupted is known from the control information (channel selection information) of the channel selection control unit 1031 that interrupted the channel sweep of the tuner unit 104 once. The reception frequency and the transport number obtained in step 604 are stored in the storage unit 1032.

  Further, returning to step 602 again, the reception frequency is changed to search for a physical channel that can be digitally demodulated. If there is a physical channel that can be demodulated, the EPG information is stored in step 605, and the reception frequency is received in step 606. And the transport number. Table 7 is an example of the storage information of the storage unit 1032 obtained in this way.

  According to the present embodiment, even if the information (EIT) of the unreceivable physical channel is described in the receivable transport stream, only the receivable physical channel obtained by the operation of FIG. Information (EIT) is stored in the storage unit 1032. In other words, since information on physical channels that cannot be received can be discarded, only the EPG (electronic program guide) of a logical channel (program) transmitted on the receivable physical channel can be displayed.

  Also, since not all the information (EIT) of the receivable physical channel is described in the received transport stream, the receivable channel EIT information obtained by the operation of FIG. 6A is stored. By sequentially storing the data in the unit 1032, Table 7 is obtained, and the stored contents can be displayed as an EPG (Electronic Program Guide).

  The EPG information is about 8 days from the day, and is generally updated every day and transmitted as EIT information or the like. For this reason, as shown in FIG. 6B, the EPG information of the logical channel transmitted through the physical channel that can be received from the EPG information in the transport stream received when viewing the program can be stored. As described above, the EPG storage mode is provided, and the EPG mode is set in step 610. In step 612, EIT is obtained from the physical channel each time, and EPG information is stored in the storage unit 1032 from this EIT. By sequentially storing EIT information of a channel capable of receiving the latest information obtained by this operation in the storage unit 1032, the table 7 can be updated with the latest information, and the stored contents can be changed to an EPG (electronic program guide). ) Can be displayed.

  Table 8 shows still another example of stored information in the storage unit 1032 constituting one embodiment of the present invention. In this example, when the transmission frequency (terrestrial RF channel) information obtained from NIT and the current reception frequency (in this example, UHF15ch) where the channel sweep in FIG. This is an example of storing the coincidence information “1” indicating that the information is present in step 305 in FIG. 3. If the frequencies do not match, “0” is stored in the storage unit 1032. Therefore, the reception frequency can be determined directly from the received frequency information stored in the storage unit 1032 when the match information is “0”, and directly from the NIT information when the match information is “1”. If the NIT information coincides with the transmission frequency obtained from the NIT, there is an advantage that it is possible to respond immediately even when the transmission NIT information is changed.

図７は、本発明によるデジタル放送受信装置の更に他の実施例の動作を説明するためのフローチャートである。
以下、記憶部１０３２に表８の情報が記憶されている場合のデジタル放送受信装置の動作について説明する。
ステップ７０１において、論理チャネル番号の要求があると、ステップ７０２において、現在受信している物理チャネルのトランスポート番号を確認し、ステップ７０３において、要求論理チャネル番号のトランスポート番号を確認する。そして、ステップ７０４において、要求トランスポート番号と現在受信しているトランスポート番号との一致を見る。一致している場合（「はい」の場合）、ステップ７０５に移行して、受信しているトランスポートのＰＡＴ内の情報からＰＭＴを得る。そして、ステップ７０６において、ＰＭＴ内の情報から要求論理チャネルの信号を分離し、ステップ７０７において、分離された信号から映像と音声とを映像・音声復号部１０７で復号する。

FIG. 7 is a flowchart for explaining the operation of still another embodiment of the digital broadcast receiving apparatus according to the present invention.
Hereinafter, an operation of the digital broadcast receiving apparatus when the information in Table 8 is stored in the storage unit 1032 will be described.
If there is a request for a logical channel number in step 701, the transport number of the currently received physical channel is confirmed in step 702, and the transport number of the requested logical channel number is confirmed in step 703. Then, in step 704, a match is found between the requested transport number and the currently received transport number. If they match (in the case of “Yes”), the process proceeds to Step 705, and the PMT is obtained from the information in the PAT of the received transport. In step 706, the requested logical channel signal is separated from the information in the PMT. In step 707, the video / audio decoding unit 107 decodes video and audio from the separated signal.

  If they do not match in step 704 (“NO”), the process moves to step 708 to check whether the match information is “1”, that is, matches, or “0”, that is, does not match. If they match (in the case of “Yes”), after confirming the transport number of the physical channel including the requested logical channel number, the received physical channel is changed to the frequency described in the NIT description. In step 712, the PAT of the newly received physical channel is obtained. Thereafter, the decoded video and audio are obtained through steps 705 to 707.

  In step 708, if the coincidence information is “0” (in the case of “no”), the process proceeds to step 710, and the physical channel corresponding to the transport number including the requested logical channel is confirmed. After confirmation, in step 711, the frequency of the physical channel corresponding to the TS number stored in the storage unit 1032 is obtained, and the frequency of the tuner unit 104 is changed to this. Thereafter, the decoded video and audio can be obtained through steps 712 to 707.

  According to the present invention, the storage unit 1032 stores the number of the transport stream received by the PAT that is information in the received transport stream. Further, the transmission frequency information transmitted together with the number of the transport stream by the NIT is compared and stored. Furthermore, the reception frequency information of the number of the transport stream received from the channel selection information of the channel selection receiving means is stored in contrast. Therefore, the number of the transport stream to be selected, the transmission frequency information, and the reception frequency information to be received can be obtained by an operation from an electronic program guide or the like. The digital broadcasting can be selected by EPG (Electronic Program Guide), PAT, NIT or the like in the same manner as receiving direct terrestrial digital broadcasting.

101, 102 ... input terminals,
103 ... control unit,
104 ... tuner section,
105. Demodulator,
106 ... TS separator,
107: Video / audio decoding unit,
108: Video signal output terminal,
109 ... Audio signal output terminal,
1032: Storage unit.

Claims (2)

An NIT for storing a transport number and a transmission frequency, and an input unit for inputting a digital broadcast signal including a video signal after being frequency-converted with the same modulated signal;
A tuner for selecting a channel for the input digital broadcast signal;
A demodulator that demodulates a digital broadcast signal of a frequency selected by the tuner unit to generate a transport stream;
A separation unit that separates the NIT from a transport stream generated by the demodulation unit;
The tuner unit is swept to detect a receivable frequency, a NIT is acquired for each receivable frequency, a transport number described in the acquired NIT is acquired, and stored in the NIT Correspondence information is generated by associating the receivable frequency, which is a frequency different from the broadcast frequency, with the acquired transport number, and the tuning operation of the tuner unit is controlled using the correspondence information. A control unit;
The demodulator demodulates and generates a transport stream for the digital broadcast signal selected by the channel selection operation using the correspondence information of the tuner unit under the control of the control unit, and the separation unit generates the transport A decoding unit for decoding the video signal separated from the stream;
A digital broadcast receiving apparatus comprising: The digital broadcast receiver according to claim 1,
A digital broadcast receiver characterized in that correspondence information between all receivable frequencies and transport numbers is generated by repeatedly performing the receivable frequency detection process and frequency change.

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