JP3903578B2 - Signal processing apparatus and method, and recording medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention is a signal processing apparatus and method suitable for application to a modulation / conversion transmission apparatus used when a digital broadcast program broadcast on an arbitrary network is distributed on another network.RecordIt relates to the medium. Specifically, when a predetermined use signal processing unit fails, the spare (redundant) signal processing unit is used as a use signal processing unit, and the failed use signal processing unit is used as a backup signal processing unit, thereby simplifying the configuration. In addition, the present invention relates to a signal processing device and the like that makes management easy and suppresses an unnecessary radiation component that a signal processing unit gives to other devices.
[0002]
[Prior art]
For example, digital broadcasting programs broadcast on any network such as satellite digital multi-channel broadcasts, such as cable television operators using a network in their own facilities and a modulation conversion transmission device etc. It is conceivable to provide a distribution service. For example, a digital CATV (Cable Television) system 10 using satellite digital multi-channel broadcasting as shown in FIG. 12 can be considered.
[0003]
This system 10 uses an antenna 11 for receiving digital broadcast signals from a plurality of transponders (satellite repeaters) of a communication satellite 20 and changes the transmission frequency and modulation method of the received digital broadcast signals for CATV. And a modulation conversion sending device 12 for generating a digital broadcast signal and sending it to the transmission line 13. Note that STBs (Set Top Box) 14-1 to m, which are receiving terminals, are connected to the transmission path 13, and the images of the channels selected by these STBs 14-1 to m are respectively connected to the STBs 14-1 to m. Displayed on the corresponding monitors 15-1 to 15-m.
[0004]
FIG. 13 shows a configuration example of the modulation conversion sending device 12. This modulation conversion transmission device 12A includes a microcomputer, and a SHF (Super High Frequwncy) MHz band transmitted from the control unit 71 that controls the operation of the entire device and the first to N transponders of the communication satellite 20. Signal processing units 72-1 through 72 -N (hereinafter referred to as individual broadcast signals BS 1 through N) for generating CATV digital broadcast signals BS1 through N in a VHF (Very High Frequency) band or UHF (Ultra High Frequency) band. When it is not necessary to distinguish the signal processing units 72-1 to 72 -N, the signal processing unit 72 is simply described), the signal processing unit 73 as a spare (redundant), and the output signal or signal of the signal processing unit 72 Changeover switches 74-1 to N that selectively output the output signal of the processing unit 73 (hereinafter, when there is no need to distinguish the individual changeover switches 74-1 to N), And an adder 75 that adds the output signals of the switch 74 and outputs the added signal to the transmission line 13.
[0005]
The control unit 71 includes one of the signal processing unit 72 such as a reception frequency setting in a tuner (not shown) of the signal processing unit 72 and a conversion frequency setting of a frequency converter (not shown). An operation unit 76 for inputting when a failure occurs or when the failure is removed, and a display unit 77 configured by a liquid crystal display or the like for displaying the status of the sending device 12 are connected. The a-side fixed terminal of each switch 74 is connected to the output side of the corresponding signal processing unit 72, the b-side fixed terminal is commonly connected to the output side of the signal processing unit 73, and the movable terminal thereof. Are respectively connected to the input side of the adder 75.
[0006]
Switching by the switch 74 is controlled by the control unit 71. Normally, the switch 74 is connected to the a side, and the digital broadcast signals BS 1 to N generated by the signal processing unit 72 are supplied to the adder 75.
[0007]
On the other hand, when one of the signal processing units 72-1 to N fails and the user inputs the failure information using the operation unit 76, the switch corresponding to the failed signal processing unit is switched to the b side. Thus, the signal processing unit 73 is used in place of the failed signal processing unit. In that case, the reception frequency of the tuner of the signal processing unit 73, the conversion frequency of the frequency converter, and the like are controlled to coincide with each other, and the signal processing unit 73 is the same as that obtained in the failed signal processing unit. Digital broadcast signals are generated.
[0008]
Further, when the failure of the failed signal processing unit is removed and the user inputs the failure removal information with the operation unit 76, the changeover switch corresponding to the signal processing unit from which the failure has been removed is switched to the a side, Instead of the signal processing unit 73 as a spare, the signal processing unit from which the failure has been removed is used. Thereby, the signal processing unit 73 is returned to a standby state as a spare (redundant).
[0009]
The user determines whether the signal processing units 72-1 to N, 73 have failed or whether the failure has been removed, for example, as shown in the digital broadcast output from each signal processing unit 72, 73. This can be done by supplying a signal to the monitor receiver 80 and checking the received image associated with each digital broadcast signal.
[0010]
[Problems to be solved by the invention]
In the modulation conversion device 12 configured as shown in FIG. 13, since the signal processing unit 73 is fixed as a spare (redundant) signal processing unit, one of the signal processing units 72-1 to 72-N has failed. In this case, it is necessary to switch to use the signal processing unit 73 instead of the failed signal processing unit, and a switch 74 is provided for performing the switching. Therefore, the configuration is complicated, and an expensive high-frequency switch is used as the switch 74, so that the entire apparatus is expensive.
[0011]
Further, since the signal processing unit 73 is fixed as a spare (redundant) signal processing unit, when the failure of the failed signal processing unit is removed, the user inputs the failure removal information with the operation unit 76. Therefore, it is necessary to return the signal processing unit 73 to a standby state as a standby, and there is a disadvantage that management is difficult.
[0012]
Furthermore, in the device corresponding to the multi-channel broadcasting as described above, unnecessary radiation to the outside of the own channel is restricted by passing through a band-pass filter. Unwanted radiation that occurs transiently in the case of changes or the like may leak to adjacent channels and affect them.
[0013]
Accordingly, an object of the present invention is to provide a signal processing apparatus and the like that includes a spare signal processing unit that has a simple configuration and that can be easily managed, and that suppresses unnecessary radiation.
[0014]
[Means for measuring problems]
  A signal processing device according to one aspect of the present invention includes a plurality of signal processing units to which a common broadcast signal is supplied in parallel, each having compatibility with each other, and at least the signal processing units are included therein.of 1 PiecesA plurality of signal processing units used as spare signal processing units and a plurality of signal processing units provided corresponding to each of the plurality of signal processing units and supplied with outputs of the plurality of signal processing units A plurality of switch sections each comprising a variable attenuator whose conduction state is changed by external control, and signals from the plurality of switch sections Adders to be added, outputs of the plurality of signal processing units are supplied, a determination device for determining which signal processing unit has failed, and a determination result by the determination device, The spare signal processing unit is controlled so that the processing state of the spare signal processing unit is equivalent to the processing state before the failure of the failed signal processing unit, and the spare signal processing unit corresponds to the failed signal processing unit. The switch unit is cut-off state, and a control unit for controlling the switch section to the conductive state corresponding to the signal processing section of the preliminary.
[0015]
When the output signal from the signal processing unit is in a transient state, the switch unit may be configured not to input the output signal from the signal processing unit until the output signal reaches a steady state.
The plurality of signal processing units respectively select a first digital broadcast signal having a predetermined transmission frequency from a plurality of digital broadcast signals on a first network, and a first digital modulation related to the first digital broadcast signal Tuner means for obtaining a signal; demodulation means for demodulating the first digital modulation signal to obtain first digital broadcast data; and program specifications information of the first digital broadcast data adapted to a second network Program specification information changing means for changing to specification information to obtain second digital broadcast data, modulation means for modulating the second digital broadcast data to obtain a second digital modulation signal, and the second digital broadcast data Frequency conversion means for frequency-converting the modulated signal to obtain a digital broadcast signal having a predetermined transmission frequency on the second network can be further provided.
The control unit converts at least the reception frequency of the tuner unit of the spare signal processing unit and the conversion frequency of the frequency conversion unit, and converts the reception frequency of the tuner unit of the failed use signal processing unit and the conversion of the frequency conversion unit. Control can be made to match the frequency.
[0016]
  A signal processing method according to an aspect of the present invention includes a plurality of signal processing units to which a common broadcast signal is supplied in parallel, each having compatibility with each other, and at least the signal processing units are included therein.One ofA plurality of signal processing units used as spare signal processing units and a plurality of signal processing units provided corresponding to each of the plurality of signal processing units and supplied with outputs of the plurality of signal processing units A plurality of switch sections each comprising a variable attenuator whose conduction state is changed by external control, and signals from the plurality of switch sections In a signal processing method of a signal processing device including an adder to be added, each output of the plurality of signal processing units is supplied, it is determined which signal processing unit has failed, and based on the determination result, The spare signal processing unit is controlled so that the processing state of the spare signal processing unit is equivalent to the processing state before the failure of the failed signal processing unit, and the failed signal processing unit The switch unit to respond the cut-off state, and controls so that the switch unit corresponding to the signal processing section of the preliminary conductive.
[0017]
  One aspect of the present inventionRecordThe medium is a plurality of signal processing units to which a common broadcast signal is supplied in parallel and each of which is compatible with each other, at least of whichOne ofA plurality of signal processing units used as spare signal processing units and a plurality of signal processing units provided corresponding to each of the plurality of signal processing units and supplied with outputs of the plurality of signal processing units A plurality of switch sections each comprising a variable attenuator whose conduction state is changed by external control, and signals from the plurality of switch sections An output of each of the plurality of signal processing units is supplied to a signal processing device including an adder to be added, and it is determined which signal processing unit has failed, and the spare signal is determined based on the determination result. The spare signal processing unit is controlled so that the processing state of the processing unit is equivalent to the processing state before the failure of the failed signal processing unit, and a switch unit corresponding to the failed signal processing unit is provided. And disconnection state, to execute a process for controlling to the switch unit corresponding to the signal processing section of the preliminary conductive state to the signal processorComputer-readable recording medium having recorded a program for recording.
[0018]
  Signal processing apparatus and method according to one aspect of the present invention, andRecordIn a medium program, a common broadcast signal is supplied in parallel, each of which is a plurality of compatible signal processing units, at least of whichOne ofA plurality of switches in which a plurality of signal processing units used as spare signal processing units are provided corresponding to each of the plurality of signal processing units, and the outputs of the plurality of signal processing units are supplied. Each switch unit is connected to a plurality of switch units composed of variable attenuators whose conduction state is changed by external control, and signals from the plurality of switch units are added. Are further connected, the outputs of the plurality of signal processing units are supplied, and a determination device for determining which signal processing unit has failed is also connected. Further, based on the determination result by the determination device, the spare signal processing unit is controlled so that the processing state of the spare signal processing unit is equal to the processing state before the failure of the signal processing unit, and the failed signal Control is performed such that the switch unit corresponding to the processing unit is set in the cut-off state and the switch unit corresponding to the spare signal processing unit is set in the conductive state.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a modulation conversion sending apparatus 12A as an embodiment. This modulation conversion transmission device 12A is used in place of the modulation conversion transmission device 12 in the digital CATV system 10 shown in FIG. The sending device 12A includes a microcomputer, and includes a control unit 31 that controls the operation of the entire device, and signal processing units 32-1 to (N + 1) that generate SHF band digital broadcast signals transmitted from the communication satellite 20. (Hereinafter, when it is not necessary to individually distinguish the signal processing units 32-1 to (N + 1), they are simply referred to as the signal processing unit 32), and switches provided on the output side of the signal processing units 32, respectively. Units 33-1 to (N + 1) (hereinafter simply referred to as switch unit 33 when it is not necessary to individually distinguish the switch units 33-1 to (N + 1)) and the output signals of the switch units 33 are added. And an adder 34 for sending out to the transmission line 13.
[0020]
The control unit 31 sets the transmission frequency of a digital broadcast signal to be received and transmitted from the first to N transponders (satellite repeaters) of the communication satellite 20 and N signal processing units in use. An operation unit 35 for performing input when any of the above malfunctions is connected to a display unit 36 including a liquid crystal display or the like for displaying the state of the sending device 12A.
[0021]
The control unit 31 controls conduction and interruption of the switch unit 33. In this case, among the switch units 33, the switch units corresponding to the N signal processing units in use are in the conductive state, and the switch units corresponding to the one signal processing unit that is in the standby state for the remaining standby units. Is cut off. In the present embodiment, each switch unit 33 is configured by a variable attenuator. The conduction state is realized with a minimum attenuation, and the cutoff state is realized with a maximum attenuation. In this way, by configuring each switch 33 with a variable attenuator, it is possible to suppress the occurrence of noise when the switch unit 33 is changed to a conductive state or vice versa.
[0022]
In one or a plurality of signal processing units 32, when there is a transient state such as when the power is turned on or when the channel is changed, an unnecessary radiation component is mixed with other channels by the adder 34 to avoid an influencing state. In addition, the switch unit 33 is configured to block the input (output to the adder 34) from the signal processing unit 32 until the transient state is settled (becomes a steady state).
[0023]
The operation of switching the signal processing unit of the sending device 12A shown in FIG. 1 will be described. Initially, the SHF band digital broadcast signals transmitted from the first to N transponders of the communication satellite 20 are processed by the signal processing units 32-1 to N, respectively, and the signal processing units 32 to N respectively transmit the transmission frequencies. Assume that VHF band or UHF band digital broadcast signals BS1 to BSN are generated. In this case, the signal processors 32-1 to N are in use, and the switch units 33-1 to N corresponding to the signal processors 32-1 to N are in a conductive state.
[0024]
On the other hand, the signal processing unit 32- (N + 1) is in a standby state, and the switch unit 33- (N + 1) corresponding to the signal processing unit 32- (N + 1) is in a cut-off state. Further, the reception frequencies of the tuners of the signal processing units 32-1 to 32-N are controlled so as to receive the SHF band digital broadcast signals transmitted from the transponders 1 to N of the respective communication satellites 20.
[0025]
In this state, for example, it is assumed that the signal processing unit 32-1 breaks down and the digital processing signal BS1 is not generated satisfactorily by the signal processing unit 32-1. Note that the user determines whether or not the signal processing units 32-1 to (N + 1) have failed, for example, the digital broadcast signals output from the signal processing units 32-1 to (N + 1) as illustrated in FIG. This can be easily done by supplying the monitor receiver 39 and checking the received image relating to each digital broadcast signal.
[0026]
When the signal processing unit 32-1 breaks down and the user inputs the failure information through the operation unit 35, first, under the control of the control unit 31, the reception frequency of the tuner of the signal processing unit 32- (N + 1), Control is performed so that the other processing states are equivalent to those of the failed signal processing unit 32-1. As a result, the signal processing unit 32- (N + 1) is in a state of generating the digital broadcast signal BS1. Next, under the control of the control unit 31, the switch unit 33- (N + 1) corresponding to the signal processing unit 32-(N + 1) is turned on and the switch unit 33- corresponding to the failed signal processing unit 32-1. 1 is in a cut-off state. As a result, the signal processing units 32-2 to (N + 1) are in use, while the signal processing unit 32-1 is in a standby state in reserve.
[0027]
As described above, the frequency of the tuner and other processing states of the signal processing unit 32- (N + 1) are controlled, and the digital broadcast signal BS1 is obtained from the signal processing unit 32- (N + 1). By making the unit 33- (N + 1) conductive, it is possible to obtain only the same digital broadcast signal BS1 obtained by the failed signal processing unit 32-1 from the switch unit 33- (N + 1). Note that the failed signal processing unit 32-1 is repaired in the standby state in this way, and the failure is removed.
[0028]
Hereinafter, when any of the N signal processing units in use fails and the user inputs the failure information through the operation unit 35, the failed signal processing unit is newly updated by the same control operation as described above. In the standby state, the signal processing unit that has been in the standby state until then is used instead.
[0029]
Next, the configuration of the signal processing unit 32 will be described. First, a digital broadcast signal transmitted from the communication satellite 20 will be described. In the present embodiment, the digital broadcast signal corresponds to a DVB (Digital Video Broadcasting) system. FIG. 2B shows a frame structure of digital broadcast data in the DVB system, and one frame is composed of eight MPEG2 transport packets (see FIG. 2A). In this case, the synchronization byte (= 47H) in the packet is used, and the synchronization byte is inverted (= B8H) once in 8 packets to obtain frame synchronization. Each MPEG2 transport packet (MPEG2TS packet) is added with an error correction code by Reed-Solomon (204, 188). The digital broadcast data shown in FIG. 2B is modulated by QPSK (Quadrature Phase Shift Keying), and then converted into the SHF band to become a digital broadcast signal transmitted from the communication satellite 20.
[0030]
FIG. 3 shows the packet structure of an MPEG2 transport packet, and the first 4 bytes of the 188 bytes form a packet header. In the packet header, PID (Packet Identification) indicating the attribute of the individual stream (data string) of the packet is arranged. As is well known, a PES (Packetized Elementary Stream) packet showing the packet structure of FIG. 4 is subdivided and arranged in the payload (data part) of the MPEG2 transport packet, and is further defined in the MPEG2 system. Also, PAT (Program Association Table), PMT (Program Map Table), NIT (Network Information Table), etc. are arranged as PSI (Program Specific Information).
[0031]
Here, PSI is information necessary for realizing simple channel selection operation and program selection. The PAT indicates the PID of the PMT that transmits the information of the packets constituting the program for each program name (16 bits), and FIG. 5 shows the table structure of the PAT. As the PID of the PAT itself, PID = “0” is fixedly assigned.
[0032]
The main contents will be described. The table ID indicates the type of table, and is “0 × 00” (hexadecimal notation) in PAT. The TS (Transport Stream) ID identifies a stream (multiplexed encoded data) and corresponds to a transponder in the case of a satellite. The version number is added every time the contents of the table are updated. The current next indicator is used for identification when the old and new versions are transmitted simultaneously. The program number identifies each channel. The network PID indicates the PID of the NIT when the program number is “0 × 0000”. The program map PID indicates the PID of the PMT.
[0033]
The PMT indicates the PID of a packet in which a stream of video, audio, additional data, etc. constituting the program is transmitted for each program number. The PID of the PMT itself is specified by PAT as described above. FIG. 6 shows a table structure of the PMT. The main contents that do not overlap with PAT are explained. The table ID represents the type of the table and is “0 × 02” in the PMT. The PCR PID indicates a packet PID including a clock (PCR) serving as a reference for decoding. The stream type indicates the type of signal transmitted in a stream such as video, audio, and additional data.
[0034]
The NIT indicates physical information on the transmission path, that is, in the satellite, the orbit of the satellite, the polarization, the frequency for each transponder, and the like. The PID of the NIT itself is specified by PAT as described above. FIG. 7 shows the NIT table structure. The main contents not overlapping with PAT and PMT are explained. The table ID indicates the type of the table. The network is “0 × 40” and the other networks are “0 × 41”. The network ID identifies the network. In the case of a satellite, it corresponds to an individual satellite.
[0035]
Furthermore, two descriptors that play an important role as part of the NIT will be described. First, the satellite delivery system descriptor will be described. This descriptor is used as the first of the repeated descriptors according to the TS (transport stream) descriptor length, and is paired with the TSID.
[0036]
FIG. 8 shows the structure of the satellite delivery system descriptor. The descriptor tag is defined by DVB and indicates the type of descriptor. In this descriptor, it is “0 × 43”. The frequency indicates a transmission frequency for each stream (here, transponder). The start / west longitude / east longitude flag / polarization indicates the orbit and polarization of the satellite. The modulation / symbol rate / inner error correction code rate indicates the specifications regarding the transmission method.
[0037]
Next, the service list descriptor will be described. This descriptor is used as the second and subsequent descriptors to be repeated according to the TS descriptor length, and indicates the ID of the service (channel) multiplexed in the stream (here, transponder). That is, a plurality of service list descriptors are attached to one TSID.
[0038]
FIG. 9 shows the structure of the service list descriptor. The descriptor tag is defined by DVB and indicates the type of descriptor. In this descriptor, it is “0 × 41”. 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.
[0039]
An operation example of the receiver that receives the digital broadcast signal transmitted from the communication satellite 20 will be briefly described. In PAT and PMT, the program number corresponds to the channel number selected by the viewer, and in NIT, the service ID corresponds to the channel number. Furthermore, the NIT contains information for the entire network, ie all transponders, and the same table is transmitted in parallel by all transponders, whereas PAT and PMT are only information on the programs in the transponder to which each is transmitted. The contents are different for each transponder.
[0040]
Assume that the viewer selects the “M” channel at the receiver. The receiver searches for “M” for the service ID in the service list descriptor of the NIT after receiving the NIT with a fixed PID. Then, the satellite delivery system descriptor combined before the service list descriptor including the service ID “M” is received, and the frequency of the transponder transmitting the “M” channel is recognized and received. Control the frequency. Then, the PAT is detected from the digital broadcast signal from the transponder transmitting the “M” channel, and “M” is searched for the program number in the PAT.
[0041]
Then, after recognizing the program number “M” in the PAT, the PMT is received by the program map PID attached to the program number “M” in the PAT. After recognizing an elementary PID for each type (video, audio, etc.), a transport stream packet having a PID that matches the elementary PID is separated. The separated packet is decoded by each decoder, and the video signal, audio signal, etc. of the “M” channel selected by the viewer are output.
[0042]
FIG. 10 shows the configuration of the signal processing unit 32. This signal processing unit 32 selects a digital broadcast signal transmitted from a predetermined transponder of the communication satellite 20 from a plurality of SHF band digital broadcast signals received by the antenna 11, and converts the frequency of the digital broadcast signal. A tuner 41 that performs processing to obtain a QPSK modulated signal S1, a demodulator 42 that demodulates the QPSK modulated signal S1 to obtain a signal S2 having a DVB frame configuration, and a DVB frame configuration output from the demodulator 42 And an ECC (Error Correction Code) decoder 43 that sequentially obtains MPEG2 transport packets S3 as digital broadcast data.
[0043]
The signal processing unit 32 also includes an NIT detection circuit 44 that detects an NIT (network information table) from the MPEG2 transport packet S3 sequentially output from the ECC decoder 43, and a table NITa detected by the NIT detection circuit 44. And a memory 46 for storing a table NITb obtained by changing the control unit 31 (see FIG. 1) so as to conform to CATV. The NIT detection circuit 44 detects NIT based on a fixed PID.
[0044]
As described above, since the NIT table structure in the digital broadcast data related to the communication satellite 20 is as shown in FIG. 7, the table structure of the table NITa detected by the NIT detection circuit 44 is the same. In obtaining the table NITb, the control unit 31 changes the satellite delivery system descriptor (see FIG. 8) having the transmission frequency information in the table NITa to the CATV delivery system descriptor whose structure is shown in FIG. Is done.
[0045]
The main contents will be explained. The descriptor tag is defined by DVB and indicates the type of descriptor. In this descriptor, it is “0 × 44”. The frequency indicates a transmission frequency for each stream (multiplexed encoded data) in CATV. FEC (outer code) indicates an error correction code as an outer code, and is “0010” in this descriptor. Modulation / symbol rate / FEC (inner code) indicates a specification regarding a transmission method.
[0046]
In some cases, the number of digital broadcast signals in CATV is smaller than the number of digital broadcast signals in satellite digital broadcast. In other words, when the communication satellite 20 includes L transponders and the number of digital broadcast signals in the satellite digital broadcast is L, CATV uses N (N <L) digital broadcasts of the L digital broadcast signals. The signal may be used selectively. In this case, in obtaining the table NITb, the control unit 31 includes information (TS, transport stream ID to descriptor) related to a TS (transport stream) ID corresponding to a digital broadcast signal not used in CATV in the table NITa. Information is deleted.
[0047]
Writing to and reading from the memories 45 and 46 are controlled by the control unit 31 via the interface 47. The reception frequency of the tuner 41 described above is also controlled by the control unit 31 via the interface 47.
[0048]
In addition, the signal processing unit 32 includes an NIT replacement circuit 48 that detects NIT from the MPEG2 transport packet S3 sequentially output from the ECC decoder 43 and replaces the NIT with a table NITb stored in the memory 46. . The NIT replacement circuit 48 also detects NIT based on a fixed PID. Further, when the table NITb is obtained by the control unit 31, as described above, when information related to a TS (transport stream) ID corresponding to a digital broadcast signal not used in CATV in the table NITa is deleted, the NIT replacement circuit In 48, a dummy bit is inserted into the portion related to the deleted information.
[0049]
Further, the signal processing unit 32 adds an error correction code of Reed-Solomon (204, 188) to the MPEG2 transport packet S4 in which the NIT is replaced by the NIT replacement circuit 48, etc. An ECC encoder 49 that obtains a signal S5 (see FIG. 2B), a modulator 50 that performs modulation processing of 64QAM (Quadrature Amplitude Modulation) on the signal S5 having the DVB frame configuration, and a 64QAM modulated signal output from the modulator 50 And a frequency converter 51 for obtaining a digital broadcast signal for VHF band or UHF band CATV.
[0050]
The operation of the signal processing unit 32 shown in FIG. 10 will be described. The plurality of SHF band digital broadcast signals received by the antenna 11 are supplied to the tuner 41 of the signal processing unit 32. In the tuner 41, a digital broadcast signal transmitted from a predetermined transponder of the communication satellite 20 is selected, and further, a frequency conversion process is performed on the digital broadcast signal to obtain a QPSK modulated signal S1. The QPSK modulated signal S1 is supplied to a demodulator 42, which demodulates the QPSK modulated signal S1 to obtain a DVB frame-structured signal S2 (see FIG. 2B). Then, the DVB frame configuration signal S2 is supplied to the ECC decoder 43. The ECC decoder 43 performs error correction processing on the DVB frame configuration signal S2 to generate MPEG2 transport packet S3 as digital broadcast data. Are obtained sequentially (see FIG. 2A).
[0051]
The MPEG2 transport packet S3 sequentially output from the ECC decoder 43 is supplied to the NIT detection circuit 44, and the NIT detection circuit 44 detects NIT from the MPEG2 transport packet S3. The detected table NITa is supplied to the memory 45 and stored therein.
[0052]
The control unit 31 reads the table NITa from the memory 45, changes the satellite delivery system descriptor (see FIG. 8) in the table NITa to the CATV delivery system descriptor (see FIG. 11), and further changes the table NITa in the table NITa. A table NITb conforming to CATV is obtained by deleting information related to a TS (transport stream) ID corresponding to a digital broadcast signal not used in CATV, and this table NITb is stored in the memory 46.
[0053]
The MPEG2 transport packet S3 sequentially output from the ECC decoder 43 is supplied to the NIT replacement circuit 48. The NIT replacement circuit 48 detects the NIT, and the NIT portion is stored in the memory 46. The table NITb Is replaced by In this case, when the table NITb is obtained by the control unit 31, when information related to a TS (transport stream) ID corresponding to a digital broadcast signal not used in CATV in the table NITa is deleted, the NIT replacement circuit 48 A dummy bit is inserted into the portion related to the deleted information.
[0054]
Further, the MPEG2 transport packet S4 in which NIT is replaced by the NIT replacement circuit 48 is supplied to the ECC encoder 49, and an error correction code of Reed-Solomon (204, 188) is added to the ECC encoder 49. A signal S5 having a DVB frame configuration is formed. The DVB frame-structured signal S5 is supplied to the modulator 50, where the DVB frame-structured signal S5 is subjected to 64QAM modulation processing to obtain a 64QAM modulated signal S6. The 64QAM modulation signal S6 is supplied to the frequency converter 51. The frequency converter 51 performs frequency conversion processing on the 64QAM modulation signal and performs digital broadcasting for CATV with a predetermined transmission frequency in the VHF band or UHF band. A signal is obtained.
[0055]
The PSI (program specification) in the CATV digital broadcasting signal obtained by the signal processing unit 32 is a PSI in satellite digital broadcasting, in which only the NIT is changed so that it can be received by a cable television receiving terminal. It is. Therefore, in the set top boxes 14-1 to 14-m (see FIG. 12) as receiving terminals connected to the CATV transmission line 13, the channel selection is performed in the same manner as the channel selection operation in the satellite digital broadcast receiver described above. The operation will be performed.
[0056]
As described above, in the present embodiment, when any of the N signal processing units in use fails and the user inputs the failure information using the operation unit 35, the failed signal processing is performed. The unit is newly set in a standby state, and instead, the signal processing unit that has been in the standby state until then is used. Therefore, in the present embodiment, since the spare (redundant) signal processing unit is not fixed, the changeover switches 74-1 to N (see FIG. 13) for switching between the used signal processing unit and the spare signal processing unit are unnecessary. Therefore, it is only necessary to provide each signal processing unit 32-1 to (N + 1), and the configuration can be simplified and can be configured at low cost.
[0057]
In addition, since the standby (redundant) signal processing unit is not fixed, even if the failure of the failed signal processing unit is removed, the signal processing unit is changed from the standby signal processing unit to the used signal processing unit. There is no need to return it, and management becomes easy.
[0058]
Further, in the present embodiment, when the spare signal processing unit is changed to the active signal processing unit, the reception frequency of the tuner of the spare signal processing unit is controlled, and the signal processing unit that has failed from this signal processing unit After switching to a state in which a digital broadcast signal similar to that obtained in step 1 can be obtained, the switch unit provided corresponding to the spare signal processing unit is turned on, and the use signal processing that failed from the switch unit is performed. It is possible to obtain only a digital broadcast signal similar to that obtained in the section.
[0059]
In the present embodiment, each of the switch units 33-1 to (N + 1) is configured by a variable attenuator, so that the switch units 33-1 to (N + 1) are switched from the conductive state to the cut-off state, or Conversely, the generation of noise when changing can be suppressed. Further, the switch units 33-1 to (N + 1) suppress unnecessary radiation components generated by the signal processing units 32-1 to (N + 1) when there is a transient state such as when the power is turned on or when the channel setting is changed. Therefore, since the shut-off state is set until the steady state is reached, it is possible to prevent other circuits and the like from being affected.
[0060]
In the above-described embodiment, the number of signal processing units in use is N, whereas the number of spare (redundant) signal processing units is one. The number is not limited to one. As the number of spare signal processes increases, the configuration becomes redundant, but the number of faults that can be processed at a time can be increased.
[0061]
In the above-described embodiment, the present invention is applied to the modulation conversion transmission device 12A of the digital CATV system 10. However, the present invention includes a plurality of signal processing units and a plurality of signal processing units. The processing unit includes one or a plurality of spare signal processing units, and processes one or a plurality of signals in parallel to one or a plurality of used signal processing units excluding the spare signal processing unit among the plurality of signal processing units. Of course, the present invention can be similarly applied to the signal processing apparatus.
[0062]
In the above-described embodiment, the switch units 33-1 to (N + 1) are automatically switched by the control unit 31. However, the switch units 33-1 to (N + 1) may be manually switched.
[0063]
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 or a CD-ROM, or a transmission medium via a network such as the Internet or a digital satellite may be used. included.
[0064]
【The invention's effect】
  According to the present invention,In order not to fix the redundant (redundant) signal processing unit, the used signal processing unit and the spare signal processing unitofThere is no need for a switch for switching the signal processing section. For example, it is only necessary to provide a switch section for deciding whether or not to output each output signal on the output side of a plurality of signal processing sections. Can be configured. In addition, since the spare (redundant) signal processing unit is not fixed, even if the failure of the failed signal processing unit is removed, the signal processing unit is returned from the spare signal processing unit to the use signal unit. It is not necessary and management is easy.
[0065]
  AlsoAccording to the present invention,From the switchFailedOnly an output signal similar to that obtained by the signal processing unit can be obtained. In addition, when the signal input to the switch unit is in a transient state, the switch is cut off until it reaches a steady state, so that it is possible to suppress the influence on other devices due to unnecessary radiation components. .
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a modulation conversion transmission apparatus constituting a digital CATV system as an embodiment.
FIG. 2 is a diagram illustrating an MPEG2 transport packet and a frame configuration of a DVB system.
FIG. 3 is a diagram illustrating a packet structure of an MPEG2 transport packet.
FIG. 4 is a diagram illustrating a packet structure of a PES packet.
FIG. 5 is a diagram showing a table structure of a program association table (PAT).
FIG. 6 is a diagram showing a table structure of a program map table (PMT).
FIG. 7 is a diagram showing a table structure of a network information table (NIT).
FIG. 8 is a diagram showing a structure of a satellite delivery system descriptor in the NIT.
FIG. 9 is a diagram showing a structure of a service list descriptor in the NIT.
FIG. 10 is a block diagram illustrating a configuration of a signal processing unit included in the modulation conversion transmission device.
FIG. 11 is a diagram showing a structure of a CATV delivery system descriptor.
FIG. 12 is a block diagram showing a digital CATV system configuration.
FIG. 13 is a block diagram illustrating a configuration example of a modulation conversion transmission apparatus that constitutes a digital CATV system.
[Explanation of symbols]
10 CATV system, 11 antenna, 12A modulation conversion transmission device, 13 CATV transmission line, 14 set top box, 15 monitor, 20 communication satellite, 31 control unit, 32 signal processing unit, 33 switch unit, 34 adder, 35 operation unit, 36 display unit, 39 monitor receiver, 41 tuner, 42 demodulator, 43 ECC decoder, 44 NIT detection circuit, 45, 46 memory, 47 interface, 48 NIT replacement circuit, 49 ECC encoder, 50 modulator, 51 Frequency converter

Claims (6)

A plurality of signal processing units that are supplied with a common broadcast signal in parallel and are compatible with each other, at least one of which is used as a spare signal processing unit When,
A plurality of switch units provided corresponding to each of the plurality of signal processing units and supplied with outputs of the plurality of signal processing units, each switch unit being controlled by an external control A plurality of switch parts composed of variable attenuators whose conduction state is changed;
An adder to which signals from the plurality of switch units are added;
A determination device for determining which signal processing unit has failed, each output of the plurality of signal processing units is supplied;
Based on the determination result by the determination device, the spare signal processing unit is controlled so that the processing state of the spare signal processing unit is equivalent to the processing state before the failure of the failed signal processing unit, and And a control unit that controls the switch unit corresponding to the failed signal processing unit to be in a cut-off state and the switch unit corresponding to the spare signal processing unit to be in a conductive state. 2. The switch unit according to claim 1, wherein when the output signal from the signal processing unit is in a transient state, the switch unit does not input the output signal from the signal processing unit until the output signal becomes a steady state. Signal processing device. The plurality of signal processing units respectively select a first digital broadcast signal having a predetermined transmission frequency from a plurality of digital broadcast signals on the first network, and a first digital modulation related to the first digital broadcast signal Tuner means for obtaining a signal;
Demodulation means for demodulating the first digital modulation signal to obtain first digital broadcast data;
Program specification information changing means for changing the program specification information of the first digital broadcast data into program specification information suitable for a second network to obtain second digital broadcast data;
Modulation means for modulating the second digital broadcast data to obtain a second digital modulation signal;
2. The signal processing apparatus according to claim 1, further comprising: frequency conversion means for converting the frequency of the second digital modulation signal to obtain a digital broadcast signal having a predetermined transmission frequency on the second network. The control unit converts at least the reception frequency of the tuner unit of the spare signal processing unit and the conversion frequency of the frequency conversion unit, and converts the reception frequency of the tuner unit of the failed use signal processing unit and the conversion of the frequency conversion unit. The signal processing device according to claim 3, wherein the signal processing device is controlled so as to match the frequency. A plurality of signal processing units that are supplied with a common broadcast signal in parallel and are compatible with each other, at least one of which is used as a spare signal processing unit When,
A plurality of switch units provided corresponding to each of the plurality of signal processing units and supplied with outputs of the plurality of signal processing units, each switch unit being controlled by an external control A plurality of switch parts composed of variable attenuators whose conduction state is changed;
In a signal processing method of a signal processing device comprising: an adder that adds signals from the plurality of switch units;
Each output of the plurality of signal processing units is supplied to determine which signal processing unit has failed,
Based on the determination result, the spare signal processing unit is controlled such that the processing state of the spare signal processing unit is equivalent to the processing state before the failure of the failed signal processing unit, and the failed signal processing A signal processing method for controlling so that a switch unit corresponding to a unit is in a cut-off state and a switch unit corresponding to the spare signal processing unit is in a conductive state. A plurality of signal processing units that are supplied with a common broadcast signal in parallel and are compatible with each other, at least one of which is used as a spare signal processing unit When,
A plurality of switch units provided corresponding to each of the plurality of signal processing units and supplied with outputs of the plurality of signal processing units, each switch unit being controlled by an external control A plurality of switch parts composed of variable attenuators whose conduction state is changed;
An adder to which signals from the plurality of switch units are added;
Each output of the plurality of signal processing units is supplied to determine which signal processing unit has failed,
Based on the determination result, the spare signal processing unit is controlled so that the processing state of the spare signal processing unit is equivalent to the processing state before the failure of the failed signal processing unit, and the failed signal processing A computer-readable recording recording a program for causing the signal processing device to execute a process for controlling the switch unit corresponding to the unit to be in a cut-off state and the switch unit corresponding to the spare signal processing unit to be in a conductive state. Medium .

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