DE112011105819T5 - Digital radio receiver - Google Patents

Abstract

A digital broadcast receiver which, when a decision is made that slots of the MOST network 1 have a slot allocation not less than the maximum transfer rate assigned to an MPEG-TS signal, sends a packet from a buffer 72 at a rate equal to the output transfer rate of the Reads out MPEG-TS signals; which asks an administrative unit to expand the number of allocation slots if the transmission rate of the MOST network 1 is lower than the output transmission rate of the MPEG-TS signal, and reads a packet from the buffer after expanding the number of allocation slots ; and which, if the packet read out from the buffer 72 contains PCR, replaces the PCR with a PCR value corresponding to the system clock supplied from a PLL circuit 74 and transmits it to the MOST network 1 as that converted into the protocol of the MOST network 1 MPEG-TS signal outputs.

Description

TECHNICAL AREA

The present invention relates to a digital broadcast receiver coupled to a media networked system transport (MOST) typified ring network.

STATE OF THE ART

Patent Document 1 discloses an apparatus which converts an MMPEG2-TS input at any transmission rate into another transmission rate without corruption of its content. The device comprises a circuit that extracts a PCR (Program Clock Reference) from a packet; a PLL circuit that recovers a 27 MHz system clock from the PCR value; a packet read circuit that reads out a packet at an output transmission rate and a PCR value replacement circuit that, when a packet is a PCR packet, writes a PCR value from the PLL circuit over the packet. In addition, Patent Document 2 discloses a circuit that restricts an output transmission rate by outputting a signal that has erased an invalid hierarchical TSP (Transport Stream Packet) in a multiplex frame TS transmission method described by ISDBT (Integrated Services Digital Broadcasting Terrestrial) , integrated digital service broadcasting ground-based) is used, which is a digital broadcasting system used in Japan.

DOCUMENT OF THE STATE OF THE ART

Patent Document

• Patent Document 1: Japanese Patent Laid-Open Publication No. 11-205789
• Patent Document 2: Japanese Patent Laid-Open Publication No. 2003-115807

DISCLOSURE OF THE INVENTION

PROBLEMS TO BE SOLVED BY THE INVENTION

Recently, a plurality of devices incorporating a video / audio decoder are sometimes connected to MOST, which is a vehicle network, and one of the devices is a digital broadcast receiver. In this case, it is not difficult to imagine that assembling video / audio decoders in the MOST network will lead to a cost reduction of the network.

However, it becomes necessary for such a system to transfer the video / audio data into digital data as in the MOST network, which leads to the problem that the transmission band of the MOST network is reduced. For example, there are some cases where the video / audio data occupy the transmission band, which may prevent the data transfer to control the entire network.

In addition, it is likely that even with continuous data, burst transmission occurs.

In particular, since the video / audio data represents a continuous signal that is inappropriate for a burst transfer when sent over the MOST network as presently, this can sometimes have a negative effect on the communication timing of the others, sometimes have a bad influence from the other equipment, thus losing continuity.

Incidentally, Patent Document 1, which discloses a general device which converts the input rate of the MPEG2-TS to an output rate thereof, refers to P2P (Peer to Peer) transmission and does not assume a network having a plurality of devices connected thereto, such as a ring network, which has occupied a transmission band through these devices. Accordingly, even if the invention of Patent Document 1 is applied to a ring network such as MOST, it has the problem of missing data even if the TS output is temporarily reserved because an output line (network side) of the TS (transport stream) Signal is assigned and the data in this quantity can not be sent.

In addition, the technique of Patent Document 2 is not applicable to a broadcasting system that does not insert invalid hierarchical TSP, such as DVBT (Digital Video Broadcasting-Terrestrial). Accordingly, there is the problem of being unable to cope with various digital broadcasting systems and reducing the transmission rate of discontinuous data.

The present invention has been implemented to solve the above problems. Therefore, it is an object of the present invention to provide a digital broadcast receiver capable of outputting the video / audio data of a reception broadcast signal to a network as digital data so as to allow the reproducing apparatus connected to the ring network allow the video / audio data to be played back properly.

MEANS TO SOLVE THE PROBLEMS

A digital broadcast receiver according to the present invention comprising a broadcast receiving system including a tuner that converts a broadcast wave received through an antenna into an intermediate frequency signal, and a channel decoder that converts the intermediate frequency signal into D-digital data and connected to a ring network in which a management unit manages the allocation of the number of slots, the digital broadcast receiver comprising: a buffer storing a packet of digital data stream converted from the intermediate frequency signal by the digital decoder; a detection circuit that detects a maximum transmission rate of the ring network, information indicative of a maximum transmission rate assigned to the digital data stream, and a slot assignment state of the ring network; a PLL circuit that recovers a system clock from a PCR value of the packet; a read control circuit that, when a decision is made from the slot assignment state of the ring network detected by the detection circuit, that slots of the ring network have a slot allocation not smaller than the maximum transmission rate assigned to the digital data stream the. A buffer at a rate equal to an output transmission rate of the digital data stream according to the maximum transmission rate of the ring network and the information indicating the maximum transmission rate assigned to the digital data stream, when the transmission rate of the ring network is smaller than the output transmission rate of the digital data stream, reads a request to expand the number of allocation slots Management unit sends, and reads a packet from the buffer after the number of assignment slots is extended; a PCR equivalent circuit which, when the packet read out from the buffer contains a PCR, replaces the PCR with a PCR value corresponding to the system clock supplied from the PLL circuit; and a protocol converter circuit that receives the packet output from the PCR equivalent circuit and outputs to the ring network as a digital data stream, with its protocol being converted into that of the ring network.

ADVANTAGES OF THE PRESENT INVENTION

According to the present invention, it offers an advantage of being able to output the video / audio data of the reception broadcasting signal to the network in digital data so as to allow the reproduction apparatus connected to the ring network to adequately reproduce the video / audio data.

BRIEF DESCRIPTION OF THE DRAWINGS

1 Fig. 10 is a diagram showing a configuration of a ring network to which a digital broadcast receiver according to the present invention is connected;

2 Fig. 10 is a block diagram showing a configuration of a digital broadcast receiver of an embodiment 1;

3 Fig. 10 is a block diagram showing the operation of the digital broadcast receiver of an embodiment 1;

4 Fig. 10 is a block diagram showing a configuration of a digital broadcast receiver of an embodiment 2 according to the present invention;

5 Fig. 10 is a flow chart showing the operation of the digital broadcast receiver of Embodiment 2;

6 Fig. 10 is a block diagram showing a configuration of a digital broadcast receiver of an embodiment 3 according to the present invention; and

7 FIG. 12 is a flowchart showing the operation of the digital broadcast receiver of Embodiment 3. FIG.

BEST MODE FOR CARRYING OUT THE INVENTION

The best mode for carrying out the invention will now be described with reference to the accompanying drawings in order to explain the present invention in more detail.

EMBODIMENT 1

1 Fig. 10 is a diagram showing a configuration of a ring network to which a digital broadcast receiver according to the present invention is connected. In 1 is a digital broadcast receiver 2 according to the present invention on a ring network 1 localized. Next to the digital broadcast receiver 2 and an administrative unit 3 are a plurality of electronic devices with the ring network 1 connected and the electronic devices are generally considered other equipment 4 designated. Additionally it is assumed here that the ring network 1 A MOST network is and will be right as a MOST network 1 designated.

The administrative unit 3 , which is a device that exists as an administrator in the network, includes a user interface through which various input devices such as a keyboard and a remote controller are connected, and has a function of distributing one of a user through the user interface on the MOST network 1 entered instruction. In addition, the administrative unit instructs 3 a function of converting an MPEG2 TS signal coming from one with the MOST network 1 connected electronic device, such as the digital broadcast receiver 2 , is output to a video signal (video / audio decoder), and has a display that displays the video signal to a user. In this way, the administrative unit instructs 3 receiving an instruction from the user of a device on the MOST network 1 slot to (manage the number of allocation slots) and controls the overall system.

2 FIG. 10 is a block diagram showing a configuration of the digital broadcast receiver of Embodiment 1. FIG. In 2 includes the digital broadcast receiver 2 a tuner 5 , a channel decoder 6 , a TS processing unit 7 and a network I / F unit 8th , The tuner 5 converts a broadcast radio signal (RF signal) received with an antenna into an intermediate frequency signal (IF signal). The channel decoder 6 demodulates that, the conversion by the tuner 5 passing IF signal, and converts it to an MPEG TS signal. By the way, as for the tuner 5 and the channel decoder 6 two or more sets of them are mounted.

The TS processing unit 7 converts the TS transmission rate of the MPEG-TS signal into a value corresponding to the maximum transmission rate of the MOST network 1 and generates and outputs the so-called "processed TS signal" passing the PCR value replacement. The TS processing unit 7 includes as its components a demultiplex (DeMux) circuit 71 , a buffer 72 , a PCR replacement circuit 73 , a PLL circuit 74 and a read control circuit 75 , the DeMux circuit 71 is a circuit that uses the channel decoder 6 received MPEG-TS signal demultiplexes (DeMux) and detects whether the TS packet of the MPEG-TS signal is a PCR packet or not. The buffer 72 is a buffer that stores the TS packet of the MPEG-TS signal.

The PCR replacement circuit 73 generated when that is out of the buffer 72 TS-packet is a PCR-packet, a PCR at a value of the PLL-circuit 74 It reads the PCR packet (PCR value replacement) and sends it to the network I / F unit 8th and, if the TS packet is not a PCR packet, delivers the TS packet to the network I / F unit 8th as it is.

The PLL circuit 74 FIG. 12 is a circuit which executes the PLL using the demultiplexed PCR value from the MPEG-TS signal and reproduces the 27 MHz system clock.

The read control circuit 75 is a circuit showing the slot assignment state of the MOST network 1 from the, from a detection circuit 82 supplied assignment state signal, and reading the MPEG-TS signal from the buffer 72 controls according to the slot assignment state.

Incidentally, the slot assignment leads to the MOST network 1 the administrative unit 3 by authorization of the digital broadcast receiver 2 out, slots in accordance with the protocol of the MOST network 1 to use. The detection circuit 82 Supplies the read control circuit 75 with the slot allocation state signal indicating whether the MOST slots have already been subjected to the "slot allocation" or not.

The network I / F unit 8th includes a MOST protocol converter circuit 81 and the detection circuit 82 , The MOST protocol converter circuit 81 converts that through the TS processing unit 7 generated "processed TS signal" in the MOST protocol and gives it to the MOST network 1 out. In addition, the detection circuit detects 82 the maximum assignment send rates of the MOST network 1 , Maximum transmission rate information associated with the MPEG-TS signal and the current slot allocation state of the MOST network 1 and deliver it to the administrative unit 3 ,

Next, the operation will be described.

3 FIG. 12 is a flowchart showing the operation of the digital broadcast receiver of Embodiment 1. FIG. Referring to the flowchart, the processing from the input of the MPEG-TS signal to the TS processing unit 7 until output to the network I / F unit 8th described in detail.

First, the DeMux circuit demultiplexes 71 that from the channel decoder 6 input MPEG-TS signal (step ST1). Next decides the DeMux circuit 71 whether or not a TS packet constituting the input MPEG-TS signal is a PCR packet (step ST2).

If the TS packet is a PCR packet (YES in step ST2), the DeMux circuit provides 71 the PCR value of the PCR packet to the PLL circuit 74 , The PLL circuit 74 performs PLL operation using the DeMux circuit 71 and returns the 27 MHz system clock (reference clock required for MPEG-TS signal reproduction) (step ST3).

If the TS packet is not a PCR packet (NO in step ST2), the DeMux circuit detects 71 the TS transmission rate from the MPEG-TS signal and temporarily stores the MPEG-TS signal in the buffer 72 , The TS transfer rate, which is the DeMux circuit 71 is detected, the read control circuit 75 fed.

In addition, the detection circuit detects 82 the network I / F unit 8th which time slots (time) are assigned via the MOST protocol converter circuit 81 , specifies the slot allocation state of the MOST network 1 and supplies it to the read control circuit 75 ,

By the way, the detection circuit decides 82 for example, from the slot allocation state of the MOST network 1 how much data can be sent and calculates the average transfer rate (average "vacant" rate).

Next, the read control circuit confirms 75 Whether or not the MPEG-TS signal has been input (step ST4). If the MPEG-TS signal is not input (NO in step ST4), it skips the output processing.

Thereafter, the read control circuit confirms 75 the slot allocation state of the MOST network 1 from the, from the detection circuit 82 supplied slot assignment state signal (step ST5).

Here, if it does not decide that the digital broadcast receiver has secured enough MOST slots, the read control circuit will decide 75 in that the MOST slot allocation is insufficient and it is in the output standby mode of the TS packet (NO in step ST5) sends a request to extend the allocation slots from the MOST protocol converter circuit 81 to the administrative unit 3 (Step ST9), temporarily stores the TS packet in the buffer 72 until the extension has been made (step ST10) and terminates the processing (after the transmission band has been saved, causes the PLL circuit 74 the buffer 72 to read in and output the TS package).

On the other hand, if the read control circuit 75 decides that the MOST network 1 has secured sufficient MOST slots, sets the read control circuit 75 if it is not in the output standby mode of the TS packet (YES in step ST5) causes the buffer 72 to read out the TS packet and deliver it to the PCR equivalent circuit 73 ,

The PCR replacement circuit 73 determines if that is out of the buffer 72 The TS packet read out as described above is a PCR packet or not (step ST6).

If the MPEG-TS signal (TS packet) to be output is not a PCR packet (NO in step ST6), the PCR spare circuit supplies 73 the network I / F unit 8th with the MPEG-TS signal as it is (step ST7).

On the other hand, if the MPEG-TS signal (TS packet) to be output is a PCR packet (YES in step ST6), the PCR equivalent circuit is received 73 from the PLL circuit 74 the PCR value used for reproduction of the system clock, writes the PCR value over the PCR packet (replaced by the PCR value) and delivers it to the network I / F unit 8th (Step ST8).

Next, converts the MOST protocol converter circuit 81 that from the PCR equivalent circuit 73 received "processed TS signal" in the MOST protocol and gives it to the MOST network 1 out. Incidentally, with respect to the "processed TS signal", since the delay time due to the replacement of the PCR value, followed by temporary storage in the buffer 72 As described above, time-aligned, asynchronous transmission according to the delay time can be performed.

If the transmission band of the MOST network 1 is insufficient, the digital broadcast receiver broadcasts 2 a request to extend the number of allocation slots to the management unit 3 , temporarily stores the TS signal until the extension has been made, and outputs the TS signal after securing the transmission band. In this case, since the time information adjustment has been made by the replacement of the PCR value, reproduction without special processing on the part of the management unit 3 be performed.

As described above, according to Embodiment 1, it includes the buffer 72 which stores a packet of the MPEG-TS signal converted from the IF signal; the detection circuit 82 , which is the maximum transmission rate of the MOST network 1 , the information indicating the maximum transmission rate assigned to the MPEG-TS signal, and the slot assignment state of the MOST network 1 detected; the PLL circuit 74 which restores the system clock from the PCR value of the packet; the read control circuit 75 which, if a decision from the slot allocation state of the MOST network 1 that through the detection circuit 82 is detected, that is the MOST network 1 has assigned a slot allocation at more than the maximum transfer rate to the MPEG-TS signal, a packet from the buffer 72 at a rate equal to the output transmission rate of the MPEG-TS signal in accordance with the maximum transmission rate of the MOST network 1 and the one which reads the maximum transmission rate assigned to the MPEG-TS signal reads, when the transmission rate of the MOST network 1 is smaller than the output transmission rate of the MPEG-TS signal, sends a request for expanding the number of allocation slots to the management unit and sends the one packet out of the buffer 72 after the number of allocation slots has been expanded, reads the PCR equivalent circuit 73 That if that's out of the buffer 72 the PCR packet contains the PCR value corresponding to that from the PLL circuit 74 replaced system clock, and the MOST protocol converter circuit 81 that's from the PCR equivalent circuit 73 output packet that receives it to the MOST network 1 than that the conversion into the protocol of the MOST network 1 Passing MPEG-TS signal, and performs an expansion request, if a sufficient MOST bandwidth can not be ensured.

With the above-described configuration, the present embodiment 1 can transmit the MPEG-TS signal of the reception broadcasting signal to the MOST network 1 in such a way spend that with the MOST network 1 connected administrative unit 3 the video / audio data can play properly.

EMBODIMENT 2

In the embodiment 2, in addition to the configuration of the above embodiment 1, the TS processing unit classifies into a so-called "partial TS" consisting only of the video / audio signal of the MPEG-TS signal and other data, and limits the output of the others Dates.

4 Fig. 10 is a block diagram showing a configuration of a digital broadcast receiver of Embodiment 2 according to the present invention. In 4 Be the referring to 1 In the above embodiment 1 described components by the same reference numerals and their description is omitted. The digital broadcast receiver 2A Embodiment 2 is one in the MOST network 1 placed digital broadcast receiver, as in the above embodiment 1, and includes the tuner 5 , the channel decoder 6 , a TS processing unit 7A and a network I / F unit 8A ,

The TS processing unit 7A classify this from the channel decoder 6 input MPEG-TS signal into a "partial TS" consisting only of the video / audio signal and other data than the video / audio signal and limits the output of the other data. The TS processing unit 7A includes a DeMux circuit 71A , the component identification information 72 , the PCR equivalent circuit 73 , the PLL circuit 74 , the read control circuit 75 , a data signal buffer 76 and a carousel decision circuit 77 ,

The DeMux circuit 71a is a circuit that uses the channel decoder 6 supplied MPEG-TS signal demultiplexed (DeMux) and classified it into a "partial TS", which consists only of the video / audio signal, and in other data than the video / audio signal. The other data include, for example, an EPG (Electronic Program Guide).

In addition, as the DeMux circuit shown in the above embodiment 1, it detects 71 the DeMux circuit 71a Whether or not the TS packet of the MPEG-TS signal is a PCR packet and supplies the PCR value of the PCR packet to the PLL circuit 74 ,

The data signal buffer 76 is a buffer of the data subjected to the carousel transmission (repetitive transmission of the same contents at fixed intervals) from the other data representing the DeMux circuit 71a classified, stores. In addition, those in the data signal buffer 76 stored data only read when the administrative unit 3 or the other equipment 4 in the MOST network 1 makes a request and is sent through the network I / F unit 8A to the MOST network 1 delivered.

The carousel decision circuit 77 is a circuit, which is about the carousel to be submitted to the data from the data through the DeMux circuit 71a classified other data.

The network I / F unit 8A includes a MOST protocol converter circuit 81a , the detection circuit 82 and a MOST command analysis circuit 83 , As in the above embodiment 1, the MOST protocol converter circuit converts 81a the "processed TS signal" generated by the TS processing unit 7A generated in the MOST protocol and gives it to the MOST network 1 out. In addition, the MOST protocol converter circuit converts 81a those from the data signal buffer 76 The data read into the MOST protocol is transferred to the MOST network 1 from and delivers those from the MOST network 1 received data to the MOST command analysis circuit 83 , The MOST command analysis circuit 83 is a circuit that an instruction from the via the MOST protocol converter circuit 81a extracted data and analyzed the contents of the command.

Next, the operation will be described.

5 FIG. 10 is a flowchart showing the operation of the digital broadcast receiver of Embodiment 2. FIG. Referring to the flowchart, the processing of the input of the MPEG-TS signal to the TS processing unit 7A until output to the network I / F unit 8A described in detail.

First, the DeMux circuit demultiplexes 71a that from the channel decoder 6 input MPEG-TS signal (step ST1a). Next puts the DeMux circuit 71a from the packet identifier, whether or not a TS packet of the MPEG-TS signal is a video / audio packet (step ST2a).

Unless the TS packet is a video / audio packet (NO in step ST2a), the DeMux circuit provides 71a the TS packet to the carousel decision circuit 77 , The carousel decision circuit 77 decides whether or not the TS packet contains the data subjected to the carousel transmission from the packet identifier of the DeMux circuit 71a input TS packets (step ST3a). When the TS packet represents the data subjected to the carousel transmission (YES in step ST3a), the carousel decision circuit stores 77 the data in the data signal buffer 76 according to the type of data transmitted in the TS packet (step ST4a).

In addition, the MOST command analysis circuit extracts 83 the command from the data input from the MOST network 1 via the MOST protocol converter circuit 81a and analyzes the contents of the command. Here, if the command is a data request from the administrative unit 3 or the other equipment 4 is sets the MOST command analysis circuit 83 from those in the data signal buffer 76 stored data, whether they contain the data of the type, by the administrative unit 3 or by the other equipment 4 is requested or not (step ST5a).

If they contain the data of the type provided by the administrative unit 3 or the other equipment 4 is requested (YES in step ST5a), the MOST command analysis circuit 83 the data signal buffer 76 to read the data of the type and supplies the data to the MOST protocol converter circuit 81a , The data signal buffer 76 , the instruction of the MOST instruction analysis circuit 83 follows, supplies the MOST protocol converter circuit 81a with the data of the type of administrative unit 3 or the other equipment 4 requirements.

In step ST6a, the MOST protocol converter circuit is converted 81a those from the data signal buffer 76 supplied data in the MOST protocol and gives them to the MOST network 1 out.

On the other hand, if the TS packet is a video / audio packet (YES in step ST2a), the DeMux circuit decides 71a whether the TS package is a PCR package or not. Thereafter, the processing from step ST3 to step ST8 of FIG 3 designed so that the data in the video / audio packet is converted to the MOST protocol and to the MOST network 1 be issued.

As described above, according to the present embodiment 2, it includes the DeMux circuit 71a representing the MPEG-TS signal, the conversion from the IF signal by the channel decoder 6 goes through, into a packet related to the video and audio data and demultiplexed into a packet of the other data; the carousel decision circuit 77 , which decides the data subjected to the carousel transmission from the others, through the DeMux circuit 71a demultiplexed data; the data signal buffer 76 which stores the packet of data which is decided to be the carousel transmission by the carousel decision circuit 77 be subjected, in conjunction with the data type; and the MOST command analysis circuit 83 showing the contents of the MOST network 1 received command and, if the content of the command is a data transfer request specifying the data type and is made of the equipment connected to the MOST network, the data signal buffer 76 causing the packet of data to be read according to the data transfer request and sent to the MOST protocol converter circuit 81a to deliver, the MOST protocol converter circuit 81a that from the data signal buffer 76 by the MOST command analysis circuit 83 Received packet receives and sends it to the MOST network 1 as the MPEG-TS signal outputs the conversion to the protocol of the MOST network 1 happens. In this way, the present embodiment 2 classifies into the video / audio data requiring synchronous transmission and the other data, and outputs the data subjected to the carousel transmission from the other data to the MOST network 1 only off if a request is made from the network side. Accordingly, it can reduce the transmission rate of the data that does not require synchronous transmission.

EMBODIMENT 3

Embodiment 3 describes in one of a plurality of broadcast receiving systems, all a tuner and a tuner decoder For example, incorporated digital broadcast receivers include the so-called "re-multiplexing mode", which combines common information supplied from the plurality of broadcast receiving systems to the MPEG-TS signals and multiplexes them again into the MPEG-TS signal.

6 Fig. 10 is a block diagram showing a configuration of a digital broadcast receiver of Embodiment 3 according to the present invention incorporating two broadcast receiving systems. In 6 Be the referring to 1 In the above embodiment 1 described components are denoted by the same reference numerals and their description is omitted. The digital broadcast receiver 2 B Embodiment 3 is a digital broadcasting receiver included in the MOST network 1 as in the above embodiment 1, and includes a broadcast receiving system including the tuner 5 and channel decoder 6 and a broadcast receiving system including a tuner 5a and a channel decoder 6a , and a TS processing unit 7B and the network I / F unit 8th , By the way, the tuner is changing 5a which is the same as the tuner 5 , the RF signal received with the antenna is converted to the IF signal. In addition, the channel decoder demodulates 6a which is the same as the channel decoder 6 is that the conversion of the tuner 5a passing IF signal and converts it to the MPEG TS signal.

The TS processing unit 7B converts the transmission rates of the two systems of the channel decoder 6 and the channel decoder 6a input MPEG-TS signals into a value corresponding to the maximum transfer rate of the MOST network 1 and generates and outputs the so-called "processed TS signal" which passes the replacement of the PCR value. In addition, the TS processing unit includes 7B as their components a DeMux circuit 71b , the buffer 72 , a PCR replacement / TS remultiplexing circuit 78 , the PLL circuit 74 and the read control circuit 75 , The DeMux circuit 71b is a circuit that uses the channel decoder 6 or the channel decoder 6a inputted MPEG-TS signals are demultiplexed (DeMux) and detects whether the MPEG-TS signals are a PCR packet or not.

The PCR replacement / TS remultiplex circuit 78 merging processing of the same table information into the two systems of the channel decoder 6 and the channel decoder 6a inputted MPEG-TS signals and generates a multiplexed TS, which is a TS signal, which is obtained by rearranging the MPEG-TS signals into a single MPEG-TS signal. Additionally generated in the same way as the PCR equivalent circuit 73 the PCR replacement / TS re-multiplexing circuit 78 if that's out of the buffer 72 output packet is a PCR packet, a PCR out of the value of the PLL circuit 74 read clock, it writes over the PCR packet (the replacement by the PCR value), supplies to the network I / F unit 8th and, if the output packet is other than the PCR packet, it is available to the network I / F unit 8th out as it is.

Incidentally, with respect to the MPEG-TS signal, the table information indicating relations between a program included in the MPEG-TS signal and the components of the program such as a video or audio stream constituting the program is given. The table information is referred to as PSI (Program Specific Information). The PCR replacement / TS remultiplex circuit 78 refers to the table information (PSI) contained in the MPEG-TS signals inputted from the two broadcast receiving systems for the unifying process of the same table information and re-arranges the MPEG-TS signals defining the table information into single MPEG-TS signal.

Next, the operation will be described.

7 FIG. 12 is a flowchart showing the operation of the digital broadcast receiver of Embodiment 3. FIG. Referring to the flowchart, the processing starts from the input of the two MPEG-TS signals to the TS processing unit 7B until output to the network I / F unit 8th described in detail.

First, the DeMux circuit demultiplexes 71b those from the channel decoder 6 or the channel decoder 6a input MPEG-TS signals (step ST1b). Next decides the DeMux circuit 71b whether TS packets of the MPEG-TS signals are a PCR packet or not (step ST2b).

If the TS packets are a PCR packet (YES in step ST2b), the DeMux circuit provides 71b the PCR value of the PCR packets to the PLL circuit 74 , The PLL circuit 74 performs the PLL operation using the DeMux circuit 71b supplied PCR value and reproduces the 27 MHz system clock (reference clock, which is required for playback of the MPEG-TS signal) (step ST3b).

If the TS packets are not a PCR packet (NO in step ST2b), the DeMux circuit detects 71b each time the TS transfer rates from the two MPEG-TS signals and temporarily stores the MPEG-TS signals in the buffer 72 , The transfer rates of the DeMux circuit 71b detected TS signals are the read control circuit 75 fed.

In addition, the detection circuit detects 82 the network I / F unit 8th which time slots (time) via the MOST protocol converter circuit 81 assigned specifies the slot allocation state of the MOST network 1 and supplies it to the read control circuit 75 ,

By the way, the detection circuit decides 82 from the slot allocation state of the MOST network 1 for example, if it has a sufficient transmission band, which enables the output of the MPEG-TS signal.

Next, the read control circuit decides 75 whether the MPEG-TS signal has been inputted or not (step ST4b), and then confirms the slot assignment state of the MOST network 1 using the from the detection circuit 82 supplied slot allocation state signal (step ST5b).

Here, if she decides that the other equipment 4 the MOST slots used and the MOST network 1 now has no sufficient transmission band, decides the read control circuit 75 in that it is in the output-ready mode of the TS packet (NO in step ST5b), and disables the buffer 72 for reading the TS package. In addition, the MOST protocol converter circuit does 81 a request to extend the number of allocation slots to the management unit 3 (Step ST10b) and temporarily stores the MPEG-TS signal in the buffer 72 (Step ST11b).

If, on the other hand, it decides that the MOST network 1 has a sufficient transmission band (in such a case as slots of the management unit 3 in response to the above request), the read control circuit decides 75 in that it is not in the output-ready mode of the TS packet (YES in step ST5b).

When the TS transmission rate of the MPEG-TS signal is less than the MOST network average "vacancy" rate, the read control circuit determines 75 the by the detection circuit 82 detected maximum MPEG-TS signal transmission rate, controls the buffer 72 to set as the output transmission rate the maximum transmission rate which is not larger than the MOST network average vacancy rate and assigned to the MPEG-TS signal causes the buffer 72 to read out the TS packet at the output transmission rate and to the PCR replacement / TS re-multiplexing circuit 78 to deliver.

On the other hand, if the transmission rate of the MPEG-TS signal is not less than the MOST network average vacancy rate after the transmission through the MOST protocol converter circuit 81 When a given slot allocation extension request is permitted, the read control circuit controls 75 the buffer 72 so as to cause the buffer to read out the TS packet and to the PCR replacement / TS re-multiplexing circuit 78 to deliver.

The PCR replacement / TS remultiplex circuit 78 decides if that is out of the buffer 72 The TS packet read out is a PCR packet or not, as described above (step ST6b).

When the MPEG-TS signal to be output (TS packet) is a PCR packet (YES in step ST6b), the PCR spare / TS re-multiplexing circuit writes 78 for restoring the system clock by the PLL circuit 74 PCR value used (PCR value replacement) (step ST9b).

If the MPEG-TS signal (TS packet) to be output is not a PCR packet (NO in step ST6b) or if it is the one through the PLL circuit 74 recovered PCR value is written via the PCR packet in step ST9b, and if the contents of the table information included in the MPEG-TS signals input from the two broadcast receiving systems are the same, the PCR replacement / TS re-multiplexing circuit is merged 78 the two pieces of the table information of the MPEG-TS signals into a single table information and re-arranges the TS (demultiplexes) MPEG-TS signals (n) into a single MPEG-TS signal (step ST7b).

The PCR replacement / TS remultiplex circuit 78 performs the TS-Remultiplexing MPEG-TS signal passing through the network I / F unit 8th to (step ST8b). On the other hand, if the contents of the table information differ, it carries the MPEG-TS signals of the network I / F unit 8th to as they are.

Next, converts the MOST protocol converter circuit 81 that from the PCR replacement / TS remultiplex circuit 78 supplied TS signal in the MOST protocol and gives it to the MOST network 1 out. Incidentally, with respect to the TS signal, since the time adjustment has been made, the delay due to the replacement of the PCR value and the temporary storage in the buffer 72 To compensate, an asynchronous transmission for the delay time is possible.

As described above, according to the present embodiment 3, it includes the plurality of broadcast receiving systems; and the PCR replacement / TS re-multiplexing circuit 78 which, in terms of the MPEG-TS signals having common pieces of information (table information such as PSI) in the MPEG-TS signals input from the plurality of broadcast receiving systems, combines the common pieces of information into a single piece of information, and the MPEG-TS signals Signals with the common information rearranged into a single stream. With such a configuration, the present embodiment 3 can reduce the transmission rate required for reproducing a plurality of programs because the MPEG-TS signals input from the plurality of broadcast receiving systems are again multiplexed into the single MPEG-TS signal, the common information is unified.

Incidentally, it should be understood that a free combination of the individual embodiments, variations of any components of the individual embodiments, or omission of any components of the individual embodiments are possible within the scope of the present invention.

INDUSTRIAL APPLICABILITY

A digital broadcast receiver according to the present invention can output the video / audio data of the received broadcast signal to the network as digital data so as to enable a reproducing apparatus connected to the ring network to properly reproduce the video / audio data. Accordingly, it is suitably applied to an on-board digital broadcast receiver connected to a vehicle network such as MOST.

DESCRIPTION OF REFERENCE SIGNS

• 1 Ring network (MOST network); 2 . 2A . 2 B Digital broadcast receiver; 3 Administrative unit; 4 other equipment; 5 . 5a Tuner; 6 . 6a Channel decoder; 7 . 7A . 7B TS-processing unit; 8th . 8A Network I / F unit; 71 . 71a . 71b DEMUX (demultiplexer) circuit; 72 Buffer; 73 PCR equivalent circuit; 74 PLL circuit; 75 Read control circuit; 76 Data signal buffer 77 Carousel decision circuit; 78 PCR replacement / TS Remultiplexschaltung; 81 . 81a MOST protocol converter circuit 81 ; 82 Detection circuit; 83 MOST command analysis circuit.

Claims (3)

A digital broadcast receiver comprising a broadcast receiving system including a tuner that converts a broadcast wave received through an antenna into an intermediate frequency signal, and a channel decoder that converts the intermediate frequency signal into D digital data, and connected to a ring network in which a management unit allocates the broadcast Number of slots, the digital broadcast receiver comprising: a buffer storing a packet of digital data stream converted from the intermediate frequency signal by the digital decoder; a detection circuit that detects a maximum transmission rate of the ring network, information indicative of a maximum transmission rate assigned to the digital data stream, and a slot assignment state of the ring network; a PLL circuit that recovers a system clock from a PCR value of the packet; a read control circuit that, when a decision is made from the slot assignment state of the ring network detected by the detection circuit, that slots of the ring network have a slot allocation not smaller than the maximum transmission rate assigned to the digital data stream the buffer reads at a rate equal to an output transmission rate of the digital data stream according to the maximum transmission rate of the ring network and the information indicating the maximum data rate assigned to the digital data stream when the transmission rate of the ring network is smaller than the output transmission rate of the digital data stream, a request to extend the number of allocation slots sends to the management unit and reads a packet from the buffer after the number of allocation slots is extended; a PCR equivalent circuit which, when the packet read out from the buffer contains a PCR, replaces the PCR with a PCR value corresponding to the system clock supplied from the PLL circuit; and a protocol converter circuit that receives the packet output from the PCR equivalent circuit and outputs it to the ring network as a digital data stream with its protocol converted to that of the ring network. The digital broadcast receiver according to claim 1, further comprising: a demultiplexing circuit that demultiplexes the digital data stream resulting from the conversion of the intermediate frequency signal by the channel decoder into a video and audio data related packet and a packet of other data; a decision unit which detects, from the other data demultiplexed by the demultiplexing circuit, data subjected to a carousel transmission; a data signal buffer storing a packet of the decided data subjected to the decision by the decision circuit as the carousel transmission in association with a data type; and an instruction analyzing circuit which analyzes contents of a command received via the ring network and which, when the content of the command is a data transfer request, sends out an equipment connected to the ring network Data type, reads a packet of data corresponding to the data transfer request from the data signal buffer, and delivers the packet to the protocol converter circuit, wherein the protocol converter circuit receives the packet read from the data signal buffer by the command analysis circuit and outputs it to the ring network as a digital data stream passing protocol conversion for the ring network , A digital broadcast receiver according to claim 1 or 2, further comprising: a plurality of broadcast receiving systems; and a stream re-arrangement processing unit for digital data streams having common information objects from digital data streams input from the plurality of broadcast receiving systems, combining the common information objects into a single information object, and rearranging the digital data streams having the common information objects into a single stream.

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