JP3975473B2 - Signal processing apparatus, signal processing method, and information recording medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a signal processing apparatus, a signal processing method, and Information record A signal processing apparatus and a signal processing method suitable for use in a case where a digital broadcast program broadcast on a predetermined network is provided for distribution on another network. Information record It relates to the medium.
[0002]
[Prior art]
In recent years, cable TV (CATV) operators have received digital multi-channel programs supplied via satellites and provided distribution services to homes using their own networks (cables). .
[0003]
As described above, when a digital broadcast program broadcast on the first network (satellite) is distributed and serviced on the second network (CATV), the digital broadcast data is NIT (Network Therefore, the distribution service cannot be performed only by converting the modulation method by the modulation conversion device.
[0004]
Therefore, by detecting the NIT of the digital broadcast data in the first network, changing the detected NIT to be compatible with the second network, and replacing the NIT of the digital broadcast data in the first network with the changed NIT. The digital broadcast data in the second network is obtained. At this time, the network ID, which is the network identification code, in the NIT of the digital broadcast data in the first network is also replaced with one indicating the second network.
[0005]
[Problems to be solved by the invention]
However, when the digital broadcast data in the second network is to be obtained from the digital broadcast data from the third network different from the first network by using the modulation conversion device, the network ID in the NIT is used. Is changed to one corresponding to the second network, so that at the receiving terminal of the second network, whether the received digital broadcast data is from the first network or from the third network It becomes difficult to determine whether or not.
[0006]
In addition, since the receiving terminal of the network to which the distribution service is performed determines whether the transmitted digital broadcast data should be received using the network ID in the NIT, the fourth receiving terminal is different from the second network. When a distribution service is provided to this network, a fourth network receiving terminal having a configuration different from that of the second network receiving terminal is required.
[0007]
The present invention has been made in view of such a situation, and there are a plurality of digital broadcast data supplied to the modulation conversion device, one from the first network and one from the third network. In some cases, even if the NIT is changed to be compatible with the second network, whether the digital broadcast data is from the first network or from the third network is received at the second network. This makes it possible to make a judgment on the terminal.
[0008]
In addition, even when there are a plurality of networks to be distributed and the second network and the fourth network, the receiving terminal having the same configuration can be used as it is.
[0009]
[Means for Solving the Problems]
The signal processing device according to claim 1 converts a first digital broadcast signal having a predetermined transmission frequency on the first network into a second digital broadcast signal having a predetermined transmission frequency on the second network. In the signal processing apparatus, the first frequency conversion means for performing a predetermined frequency conversion process on the first digital broadcast signal, and the demodulation for demodulating the first digital modulation signal supplied from the first frequency conversion means Means, a table detection means for detecting a network information table having physical information on the transmission path from the digital broadcast data supplied from the demodulation means, and a network information table supplied from the table detection means, The network ID does not change to the second network, and the first network The table changing means for changing the network ID to match the second network, and the network information table of the digital broadcast data supplied from the demodulating means are supplied from the table changing means. Table replacement means for replacing the network information table, modulation means for modulating the digital broadcast data supplied from the table replacement means, and a second digital modulation signal supplied from the modulation means for converting the second digital modulation signal to a predetermined transmission frequency. And 2 frequency conversion means.
[0010]
The signal processing method according to claim 2, wherein a first digital broadcast signal having a predetermined transmission frequency on the first network is converted into a second digital broadcast signal having a predetermined transmission frequency on the second network. In the signal processing method, a first frequency conversion step for performing a predetermined frequency conversion process on the first digital broadcast signal, and a demodulation for demodulating the first digital modulation signal supplied from the first frequency conversion step A step of detecting a network information table having physical information about a transmission path from digital broadcast data supplied from the demodulation step, and a network information table supplied from the table detection step, Change the network ID to the second network First, the network ID of the first network is used as it is, and the table changing step for changing the others to be compatible with the second network, and the table changing step for the network information table of the digital broadcast data supplied from the demodulation step A table replacement step for replacing the network information table supplied by the network, a modulation step for modulating the digital broadcast data supplied from the table replacement step, and a second digital modulation signal supplied from the modulation step at a predetermined transmission frequency. And a second frequency conversion step for converting to a second frequency conversion step.
[0011]
Claim 3 Information record The medium converts a first digital broadcast signal having a predetermined transmission frequency on the first network into a second digital broadcast signal having a predetermined transmission frequency on the second network. In a computer-readable information recording medium in which a program for executing processing is recorded, From a first frequency conversion step for performing a predetermined frequency conversion process on the first digital broadcast signal, a demodulation step for demodulating the first digital modulation signal supplied from the first frequency conversion step, and a demodulation step A network detection table for detecting a network information table having physical information about a transmission path from the supplied digital broadcast data, and the network ID of the network information table supplied from the table detection step is a second network ID. The network information of the digital broadcast data supplied from the table changing step for changing the network ID of the first network to be adapted to the second network, and the other is used without changing to the network. A table replacement step for replacing the network table with the network information table supplied from the table changing step, a modulation step for modulating the digital broadcast data supplied from the table replacement step, and a second digital supplied from the modulation step A second frequency converting step for converting the modulated signal into a predetermined transmission frequency; Records a program to execute It is characterized by that.
[0012]
In the signal processing apparatus according to claim 1, the first frequency conversion unit performs a predetermined frequency conversion process on the first digital broadcast signal, and the demodulation unit is supplied from the first frequency conversion unit. The first digital modulation signal is demodulated, the table detecting means detects a network information table having physical information about the transmission path from the digital broadcast data supplied from the demodulating means, and the table changing means In the network information table supplied from the detection means, the network ID is not changed to the second network, but the network ID of the first network is used as it is, and the rest is adapted to the second network. Change, the table replacement means is digital supplied from the demodulation means The network information table of the transmission data is replaced with the network information table supplied from the table changing means, the modulating means modulates the digital broadcast data supplied from the table replacing means, and the second frequency converting means is The second digital modulation signal supplied from the modulation means is converted to a predetermined transmission frequency.
[0013]
The signal processing method according to claim 2 and the claim 3 according to claim 3. Information record In the medium, a predetermined frequency conversion process is performed on the first digital broadcast signal in the first frequency conversion step, and the first digital modulation signal supplied from the first frequency conversion step is converted in the demodulation step. The network information table having physical information on the transmission path is detected from the digital broadcast data supplied from the demodulation step in the table detection step, and the network supplied from the table detection step is detected in the table change step. In the information table, the network ID is not changed to the second network, the network ID of the first network is used as it is, and other than that, the network ID is changed so as to be compatible with the second network. Supplied from the demodulation step The network information table of the digital broadcast data is replaced with the network information table supplied from the table changing step, the digital broadcast data supplied from the table replacing step is modulated in the modulating step, and the second frequency converting step. The second digital modulation signal supplied from the modulation step is converted to a predetermined transmission frequency.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below. In order to clarify the correspondence between the respective means of the invention described in the claims and the following embodiments, they are shown in parentheses after the respective means. The features of the present invention will be described with the addition of the corresponding embodiment (however, an example). However, of course, this description does not mean that each means is limited to the description.
[0015]
The signal processing device according to claim 1 converts a first digital broadcast signal having a predetermined transmission frequency on the first network into a second digital broadcast signal having a predetermined transmission frequency on the second network. In the signal processing apparatus, the first frequency conversion means (for example, the tuner 40 shown in FIG. 11) for performing a predetermined frequency conversion process on the first digital broadcast signal and the first frequency conversion means are supplied. Demodulating means for demodulating the first digital modulation signal (for example, demodulator 41 shown in FIG. 11) and detecting a network information table having physical information on the transmission path from the digital broadcast data supplied from the demodulating means Table detection means (for example, the NIT detection circuit 47 shown in FIG. 11) and a network supplied from the table detection means In the information table, the network ID uses the network ID of the first network as it is without changing to the second network, and the other table changing means (for example, changes so as to match the second network). 11) and table replacement means for replacing the network information table of digital broadcast data supplied from the demodulating means with the network information table supplied from the table changing means (for example, in FIG. 11). NIT replacement circuit 43), modulation means for modulating digital broadcast data supplied from the table replacement means (for example, modulator 45 shown in FIG. 11), and second digital modulation signal supplied from the modulation means are predetermined. Convert to the transmission frequency of Frequency conversion means (for example, the frequency converter 46 shown in FIG. 11), characterized in that it comprises a.
[0016]
FIG. 1 shows the configuration of an embodiment of a digital CATV system to which the signal processing apparatus of the present invention is applied. In this system, a digital broadcast signal transmitted from a plurality of transponders (satellite repeaters) attached to the satellite 1 is received by the antenna 2 and supplied to the modulation conversion device 3. The modulation conversion device 3 changes the transmission frequency and modulation method of the digital broadcast signal supplied from the antenna 2 so as to be compatible with CATV, and then sends them to the transmission line 4. The transmission path 4 is connected to STB (Set Top Box) 5-1 to 5-m which are receiving terminals. Monitors 6-1 to 6-m are connected to STBs 5-1 to 5-m, and an image of the program number selected in each STB is displayed on each monitor.
[0017]
Next, the digital broadcast signal transmitted from the satellite 1 will be described below. In this embodiment, it is assumed that the digital broadcast signal transmitted from the satellite 1 corresponds to a DVB (Digital Video Broadcasting) system as a European digital broadcasting standard.
[0018]
FIG. 2 shows a multimedia multiplexing system based on MPEG2 (Moving Picture Experts Group 2) TS (Transport Stream). Data of each medium constitutes a variable length packet called a PES (Packetized Elementary Stream) packet. The PES packet is further divided into several transport stream packets. The transport stream packet is composed of a header and a payload, and the header contains an identification number of a transport stream packet called a PID (Packet Identifier). Using this PID, data of each medium is identified.
[0019]
FIG. 3 shows a detailed configuration of the above-described MPEG2 TS packet. One packet is composed of 188 bytes, and the first 4 bytes are used as a packet header. The usage of the packet header area in which the sync byte (= '47H'H means hexadecimal) and the PID is basically based on MPEG2. The synchronization byte is an 8-bit synchronization signal and is data for the decoder to detect the head of the TS packet. The transport error indicator indicates whether there is a bit error in the TS packet. The payload unit start indicator indicates that a new PES packet starts from the payload of this TS packet. The transport priority indicates the importance of this TS packet. PID is identification information of a 13-bit TS packet and indicates an attribute of an individual stream of the packet.
[0020]
In the transport scramble control, the presence / absence and type of the payload of this packet is indicated by 2 bits. The adaptation field control indicates the presence / absence of an adaptation field and the presence / absence of a payload in this packet. The continuity index is information for detecting whether or not a packet having the same PID is partially discarded on the way, and is detected by continuity of 4-bit cyclic count information.
[0021]
The payload area (data part) includes a program association table (PAT (Program Association Table)) as a program specific information (PSI (Program Specific Information)), and a program map table (PMT). (Program Map Table)) and network information table (NIT).
[0022]
FIG. 4 shows a frame structure of digital broadcast data in the DVB system. FIG. 4A shows an MPEG2 TS packet. FIG. 4B shows a state in which one frame is formed by collecting eight MPEG2 TS packets shown in FIG. In FIG. 4B, the sync byte is inverted once every 8 packets (= 'B8H') using the sync byte (= '47H'H means hexadecimal) contained in the MPEG2 TS packet. H is a hexadecimal meaning) to synchronize frames. Further, when a frame is constructed, an error correction code of Reed-Solomon (204,188) is added to the data accommodated in each MPEG2 TS packet (thus, one packet is 204 bytes). ) The digital broadcast data shown in FIG. 4B is modulated by QPSK (Quadrature Phase Shift Keying).
[0023]
PSI (program specification information) defined in the MPEG2 system is information for simplifying selection of a program (program). PSI consists of a table and descriptors used for each purpose. The table and descriptor will be described with reference to FIGS.
[0024]
FIG. 5 is a diagram for explaining the configuration of PAT. The PAT indicates the PID of a PMT (program correspondence table) (described later) that transmits information on packets constituting the program for each program number (16 bits). As PID of PAT itself, PID = “0x0000” (0x indicates hexadecimal notation) is fixedly assigned.
[0025]
The table ID indicates the type of table and is “0x00” in PAT. The section syntax indicator indicates whether the header of the section is a long form (= “1”) or a short form (= “0”). The reserve indicates a flag that is given meaning in the future. The section length represents the section length in bytes from immediately after this to the end of the section (including CRC32, if any). The TSID identifies a transport stream (multiplexed encoded data), and corresponds to a transponder in the case of a satellite. The version number represents the PAT version and is updated each time the content is updated. The current next indicator indicates which version of the PAT is used when the old and new versions of PAT are transmitted simultaneously.
[0026]
The section number represents the section number. The first section is “0x00” and is incremented by one. The last section number represents the section number of the last section of the same subtable. The program number identifies each channel. The network PID indicates the PIT of the NIT described later when the program number is “0x0000”. The program map PID indicates the PID of the PMT described later. CRC is an error detection code for the entire section.
[0027]
FIG. 6 is a diagram for explaining the configuration of the PMT. The PMT indicates the PID of a packet in which a stream such as video, audio, and additional data constituting the program is transmitted for each program number. The PID of the PMT itself is specified by PAT.
[0028]
The table ID indicates the type of the table and is “0x02” in the PMT. The description of the above-described PAT is omitted. A PCR (Program Clock Reference) PID indicates the PID of a packet including a clock that is a reference for decoding. The program information length describes information common to this service in the immediately following loop. The descriptor describes individual information to complement the section information.
[0029]
The stream type indicates the type of signal transmitted in the stream, such as video, audio, and data. Elementary PID indicates the PID of the elementary stream. The ES information length describes the information of the elementary stream in the immediately following loop.
[0030]
FIG. 7 is a diagram for explaining the configuration of the NIT. The NIT indicates physical information on the transmission path, that is, the satellite orbit, polarization, frequency for each transponder, and the like. The PID of the NIT itself is “0x0010”. As for the above-described PAT and PMT, the details of the data structure are defined in the MPEG2 system, but only the necessity is indicated for the NIT, and the data structure is private.
[0031]
The table ID indicates the type of the table. The network is “0x40” and the other networks are “0x41”. The description of the above-described PAT is omitted. The network ID identifies the network, and in the case of a satellite, corresponds to an individual satellite. The network descriptor length describes common information of the network in the immediately following loop. The TS loop length lists the transport streams belonging to the network in the immediately following loop. The TS descriptor length describes the information of the transport stream in the immediately following loop.
[0032]
FIG. 8 is a diagram for explaining the satellite delivery system descriptor. This descriptor is used as the first descriptor repeated according to the TS descriptor length (see FIG. 7), and is paired with the TS ID (see FIG. 7). The descriptor tag is defined by DVB and indicates the type of descriptor. In this descriptor, it is “0x43”. The frequency indicates a transmission frequency for each stream (here, transponder). The orbit represents the longitude of the orbit position of the satellite. The west longitude / east longitude flag indicates the east longitude / west longitude of the satellite orbital position. The polarization indicates the polarization of the transmitted signal. Modulation indicates a modulation method. The symbol rate indicates the symbol rate. FEC (Forward Error Correction) indicates the convolution rate.
[0033]
FIG. 9 is a diagram for explaining the service list descriptor. This descriptor is used as the second and subsequent descriptors repeated according to the TS descriptor length (see FIG. 7), and indicates the ID of the service (channel) multiplexed in the stream (here, transponder). That is, a service list descriptor is attached to one TS ID. The descriptor tag is defined by DVB and indicates the type of descriptor. In this descriptor, it is “0x41”. The service ID identifies a service. Usually, the service matches the channel that the viewer selects. The service type indicates the contents of the service such as video, audio, and data. $
FIG. 10 is a diagram for explaining the cable delivery system descriptor. The descriptor tag is defined by DVB and indicates the type of descriptor. In this descriptor, it is “0x44”. The frequency indicates a transmission frequency for each CATV stream (here, a CATV channel). The FEC (Forward Error Correction) outer code indicates an error correction code as an outer code, and is “0010” in this descriptor. Modulation indicates a modulation method. The symbol rate indicates the symbol rate. FEC indicates the convolution rate.
[0034]
FIG. 11 is a block diagram showing a configuration of an embodiment of the modulation conversion apparatus 3 of the present invention. The modulation conversion device 3 changes the transmission frequency and modulation method of a digital broadcast signal (a plurality of channels are multiplexed) transmitted from a transponder (satellite repeater) attached to the satellite 1, and is used for CATV. A digital broadcast signal is generated and supplied to the transmission line 4.
[0035]
The modulation conversion device 3 processes a digital broadcast signal in the SHF (Super High Frequency) band transmitted from the satellite 1 and performs a digital broadcast signal BS1 for CATV in the VHF (Very High Frequency) band or the UHF (Ultra High Frequency) band. Thru | or the signal processing part 30-1 thru | or 30-m which generate | occur | produces BSm, the control part 31 which controls the whole apparatus, and the operation part 32 which performs the setting of the receiving frequency of the tuner etc. which signal processing part 30-1 thru | or 30-m incorporate. The display unit 33 displays the status of the apparatus, and the adder 34 adds the digital broadcast signals BS1 to BSm and sends them to the transmission line 4.
[0036]
The configuration of the signal processing unit 30-1 will be described. The tuner 40 selects a digital broadcast signal transmitted from the first transponder from the digital broadcast signals supplied from the antenna 2, performs frequency conversion processing on the selected digital broadcast signal, and performs QPSK (Quadrature (Phase Shift Keying) is supplied to the demodulator 41.
[0037]
The demodulator 41 demodulates the QPSK signal supplied from the tuner 40, converts it to a DVB frame configuration signal, and supplies the signal to an ECC (Error Correction Code) decoder 42.
[0038]
The ECC decoder 42 performs error correction on the DVB frame configuration signal supplied from the demodulator 41 and supplies an MPEG2 TS packet as digital broadcast data to the NIT replacement circuit 43 and the NIT detection circuit 47.
[0039]
The NIT detection circuit 47 detects NIT1 from the MPEG2 TS packet supplied from the ECC decoder 42, writes it in the memory 48, and stores it.
[0040]
The control unit 31 reads NIT1 stored in the memory 48 through the interface 50 as necessary, changes it to conform to CATV, and writes and stores the NIT2 obtained as a result in the memory 49. When changing NIT1 to NIT2, the control unit 31 changes the satellite delivery system descriptor (see FIG. 8) to the cable delivery system descriptor (see FIG. 10). At this time, the network ID of the received satellite is used as it is without changing the network ID for identifying the network. The control unit 31 also controls the reception frequency of the tuner 40 via the interface 50.
[0041]
In addition, when the satellite 1 has L transponders and the number of digital broadcast signals in the satellite digital broadcast is M (M <L), CATV selectively uses M digital broadcast signals. There is. In this case, when changing NIT1 to NIT3, the control unit 31 deletes information (TS ID or descriptor information in FIG. 7) related to a TS ID corresponding to a digital broadcast signal not used in CATV in NIT1.
[0042]
The NIT replacement circuit 43 replaces NIT1 of the MPEG2 TS packet supplied from the ECC decoder 42 with NIT2 or NIT3 supplied from the memory 49, and supplies the NIT1 to the ECC encoder 44. Further, the NIT replacement circuit 43 inserts a dummy bit into the deleted portion when replacing the NIT3 with the information related to the TS ID deleted with the NIT1.
[0043]
The ECC encoder 44 adds an error correction code of Reed-Solomon (204, 188) to the MPEG2 TS packet in which the NIT is replaced, and supplies it to the modulator 45 with a DVB frame configuration.
[0044]
The modulator 45 modulates the DVB frame configuration signal supplied from the ECC encoder 44 with 64 QAM (Quadrature Amplitude Modulation) and supplies the modulated signal to the frequency converter 46.
[0045]
The frequency converter 46 converts the 64QAM signal supplied from the modulator 45 into a predetermined transmission frequency in the VHF band or UHF band, and supplies the signal BS1 to the adder 34.
[0046]
Each of the signal processing units 30-2 to 30-m has a configuration in which the NIT detection circuit 47, the memory 48, and the memory 49 are removed from the signal processing unit 30-1. In the signal processing units 30-2 to 30-m, digital broadcast signals corresponding to the second to m-th transponders are selected from the digital broadcast signals supplied from the antenna 2, and the NIT stored in the memory 49 is read. NIT replacement is performed, and BS2 to BSm having different transmission frequencies are supplied to the adder 34.
[0047]
The adder 34 adds the CATV digital broadcast signals BS1 to BSm and sends the added signal to the transmission line 4.
[0048]
FIG. 12 is a flowchart for explaining the operation of an STB (receiving terminal) that receives a digital broadcast signal transmitted from the satellite 1. The program number in PAT and PMT, and the service ID in NIT correspond to the channel number selected by the viewer. Furthermore, the NIT contains information for the entire network, i.e. all transponders, and the same table is transmitted in parallel by all transponders. On the other hand, PAT and PMT are composed only of program information in the transponder to which each is transmitted, and have different contents for each transponder.
[0049]
First, in step S1, the viewer inputs a channel number with the STB (here, the “X” channel is selected).
[0050]
Next, in step S2, the STB receives the NIT, and proceeds to step S3. In step S3, it is determined whether or not the channel exists in the currently received transponder. If it is determined in step S3 that “X” does not exist, the process proceeds to step S4.
[0051]
In step S4, "X" is searched for the service ID in the NIT service list descriptor (see FIG. 9). After identification, the frequency of the transponder transmitting “X” by receiving the satellite delivery system descriptor (see FIG. 8) combined before the service list descriptor including the service ID “X”. Is recognized, and the process proceeds to step S5.
[0052]
In step S5, the STB receives the PAT after changing the reception transponder, and proceeds to step S6.
[0053]
If it is determined in step S3 that “X” exists, the process proceeds to step S6. In step S6, the STB receives the PMT by the program map PID associated with the program number “X” in the PAT, and proceeds to step S7.
[0054]
In step S7, after recognizing the elementary PID for each stream type (video, audio, etc.) corresponding to the program number “X” in the PMT, the TS packet having the PID that matches the elementary PID is separated, and step Proceed to S8. In step S8, the separated packet is decoded by each decoder and output to the monitor.
[0055]
In the present specification, as a providing medium for providing a user with a computer program for executing the above processing, an information recording medium such as a magnetic disk and a CD-ROM, and a network transmission medium such as the Internet and a digital satellite are also included. included.
[0056]
【The invention's effect】
As described above, the signal processing device according to claim 1, the signal processing method according to claim 2, and the signal processing method according to claim 3. Information record According to the medium, when changing the NIT, only the network ID is not changed. Therefore, when receiving digital broadcast data from a third network different from the first network, the receiving terminal of the second network It is possible to determine whether the digital broadcast data received in step 1 is from the first network or the third network. Further, when the delivery service is performed using a fourth network different from the second network, the configuration of the receiving terminal for the first network (or the third network) can be used as it is.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of an embodiment of a digital CATV system to which a modulation conversion apparatus of the present invention is applied.
FIG. 2 is a diagram for explaining a multimedia multiplexing scheme based on MPEG2 TS;
FIG. 3 is a diagram for explaining the MPEG2 TS packet of FIG. 2;
FIG. 4 is a diagram for explaining a frame configuration of a DVB system.
FIG. 5 is a diagram for explaining a program association table;
FIG. 6 is a diagram for explaining a program map table;
FIG. 7 is a diagram for explaining a network information table;
FIG. 8 is a diagram for explaining a satellite delivery system descriptor.
FIG. 9 is a diagram for explaining a service list descriptor;
FIG. 10 is a diagram for explaining a cable delivery system descriptor.
FIG. 11 is a block diagram showing a configuration of an embodiment of the modulation conversion apparatus 3 of the present invention.
FIG. 12 is a flowchart for explaining the operation of a receiving terminal using the modulation conversion apparatus 3 of the present invention.
[Explanation of symbols]
1 satellite, 2 antenna, 3 modulation conversion device, 4 transmission line, 5-1 to 5-m STB, 6-1 to 6-m monitor, 30-1 to 30-m signal processing unit, 31 control unit, 32 operation Unit, 33 display unit, 34 adder, 40 tuner, 41 demodulator, 42 ECC decoder, 43 NIT replacement circuit, 44 ECC encoder, 45 modulator, 46 frequency converter, 47 NIT detection circuit, 48, 49 memory, 50 interface

Claims (3)

In a signal processing apparatus for converting a first digital broadcast signal having a predetermined transmission frequency on a first network into a second digital broadcast signal having a predetermined transmission frequency on a second network,
First frequency conversion means for performing a predetermined frequency conversion process on the first digital broadcast signal;
Demodulation means for demodulating the first digital modulation signal supplied from the first frequency conversion means;
A table detection means for detecting a network information table having physical information about a transmission path from the digital broadcast data supplied from the demodulation means;
Of the network information table supplied from the table detecting means, the network ID of the first network is used as it is without changing the network ID to the second network, otherwise the second network is used. Table changing means to change to conform to
Table replacing means for replacing the network information table of the digital broadcast data supplied from the demodulating means with the network information table supplied from the table changing means;
Modulation means for modulating digital broadcast data supplied from the table replacement means;
And a second frequency conversion means for converting the second digital modulation signal supplied from the modulation means into a predetermined transmission frequency. In a signal processing method for converting a first digital broadcast signal having a predetermined transmission frequency on a first network into a second digital broadcast signal having a predetermined transmission frequency on a second network,
A first frequency conversion step of performing a predetermined frequency conversion process on the first digital broadcast signal;
A demodulation step for demodulating the first digital modulation signal supplied from the first frequency conversion step;
A table detection step for detecting a network information table having physical information about a transmission path from the digital broadcast data supplied from the demodulation step;
Of the network information table supplied from the table detection step, the network ID of the first network is used as it is without changing the network ID to the second network, and otherwise the second network. A table change step that changes to conform to
A table replacement step of replacing the network information table of the digital broadcast data supplied from the demodulation step with the network information table supplied from the table changing step;
A modulation step of modulating the digital broadcast data supplied from the table replacement step;
A signal processing method comprising: a second frequency conversion step of converting the second digital modulation signal supplied from the modulation step into a predetermined transmission frequency. A program for executing a process of converting a first digital broadcast signal having a predetermined transmission frequency on the first network into a second digital broadcast signal having a predetermined transmission frequency on the second network is recorded. In a computer-readable information recording medium,
A first frequency conversion step of performing a predetermined frequency conversion process on the first digital broadcast signal;
A demodulation step for demodulating the first digital modulation signal supplied from the first frequency conversion step;
A table detection step for detecting a network information table having physical information about a transmission path from the digital broadcast data supplied from the demodulation step;
Of the network information table supplied from the table detection step, the network ID of the first network is used as it is without changing the network ID to the second network, and otherwise the second network. A table change step that changes to conform to
A table replacement step of replacing the network information table of the digital broadcast data supplied from the demodulation step with the network information table supplied from the table changing step;
A modulation step of modulating the digital broadcast data supplied from the table replacement step;
A second frequency conversion step of converting the second digital modulation signal supplied from the modulation step into a predetermined transmission frequency;
The computer-readable information recording medium which recorded the program for performing.

Images