JP2000270319A - Device for re-transmitting bs digital satellite broadcast and receiver receiving re-transmitted signal - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simply re-transmit a BS digital satellite broadcast program with an excellent frequency utilizing efficiency to a transmission line for a cable television system that has a sufficiently high C/N but produces burst disturbance. SOLUTION: As to a structure of a frame consisting of each output from a transmission main signal storage section that stores a transmission main signal of a BS digital satellite broadcast, a TMCC signal storage section that stores a signal resulting from adding a power spread signal to the TMCC signal of the BS digital satellite broadcast, a frame synchronization generating section that generates a frame synchronizing signal and an additional information generating section that generates additional information, while consecutive signals in a direction orthogonal to a slot of the frame structure are sequentially generated, the generated signals are transmitted to a multi-value modulation section that applies multi-value modulation to the generated signals to obtain a transmission signal.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a BS digital satellite broadcast retransmitting apparatus for retransmitting a BS digital satellite broadcast to a transmission line that does not require hierarchical transmission, such as a cable television, with high frequency use efficiency. , And a receiving device for receiving the retransmitted signal.

[0002]

2. Description of the Related Art The BS digital satellite broadcasting system stipulated in the Ministry of Posts and Telecommunications Ordinance No. 57 of 1998 uses a satellite transmission line (a transmission line with a low CN ratio but no disturbance other than thermal noise and a non-linear channel in the channel). It has been developed to be able to transmit with high frequency use efficiency. It has a frame structure in units of 48 slots and a superframe structure in units of 8 frames, and allocates another transport stream (a transport stream defined in ISO / IEC 13818-1) to each slot, It is a system that can be operated flexibly, such as being able to assign another modulation system. This makes it possible to prevent service interruption by performing hierarchical transmission (a transmission method that flexibly adapts an optimal modulation scheme according to the type of information or the purpose of broadcasting) in the case of rainfall or the like.

As a specific transmission line coding of the BS digital satellite broadcasting system, the main signal is 203 bytes excluding the sync byte of the (204, 188) Reed-Solomon coded transport stream packet.
The 384 (= 48 × 8) main signals are subjected to power spreading in a superframe (8 frame) period and block interleaving of a depth of 8 in the same slot in the superframe direction to be a transmission main signal. Also, control information such as the modulation scheme for each slot and the relationship between the slot and the transport stream is subjected to (64, 48) Reed-Solomon encoding to produce a TMCC signal. Finally, the transmission main signal and the power-spread TMCC signal are convolutionally coded and
SK modulation is performed.

[0004]

On the other hand, in a transmission path such as a cable television having a high CN ratio and negligible nonlinearity in a channel, a modulation method having a larger number of values than 64QAM has been put to practical use. However, in the digital transmission system put into practical use in cable television, a plurality of transport streams cannot be multiplexed on one channel, and the transmission path coding method is different from that of BS digital satellite broadcasting. There has not yet been a method of making it possible to retransmit BS digital satellite broadcasting to such a transmission path with good frequency utilization by utilizing its features.

An object of the present invention is to retransmit a BS digital satellite broadcast to a transmission line having a sufficiently high CN ratio, such as a cable television, which generates a bursty disturbance, in a simple and efficient manner of frequency use. It is an object of the present invention to provide a BS digital satellite broadcast retransmitting device and a receiving device for receiving a signal retransmitted by the device.

[0006]

In order to achieve the above object, a BS digital satellite broadcast retransmitting apparatus according to the present invention comprises:
By using the frame structure and transmission path coding in digital satellite broadcasting, a signal obtained by reading out the transmission main signal of BS digital satellite broadcasting in the direction orthogonal to the slot for each frame is subjected to multi-level modulation of the carrier wave, so that sufficient This is a device that obtains a depth interleave to make it more resistant to bursty interference, improves the frequency use efficiency by multi-level modulation, and retransmits to a cable television or the like.

A receiving apparatus for receiving a signal transmitted by the retransmitting apparatus of the present invention restores a frame structure of a transmission main signal of a BS digital satellite broadcast from a bit sequence obtained by demodulating the received signal. This is a receiving apparatus that can share the subsequent processing with that of the BS digital satellite broadcast receiver.

That is, a BS digital satellite broadcast retransmitting apparatus according to the present invention includes a transmission main signal storage unit for storing a transmission main signal of a BS digital satellite broadcast, and a signal obtained by adding a power spread signal to a TMCC signal of the BS digital satellite broadcast. , A frame synchronization generation unit for generating frame synchronization, and an output from an additional information generation unit for generating additional information, the frame structure being orthogonal to the slots of the frame structure. While sequentially generating signals continuous in the directions, the generated signals are subjected to multi-level modulation and sent to a multi-level modulation unit for obtaining a transmission signal.

Further, in the BS digital satellite broadcast retransmitting apparatus according to the present invention, the transmission main signal stored in the transmission main signal storage section is subjected to deinterleaving, power despreading, and Reed-Solomon decoding in a BS digital satellite broadcast receiver. Go and restore the transport stream packet,
The number of slots in the frame structure is made larger than the number of slots in the frame structure of digital satellite transmission, and a new transport stream packet corresponding to the increased number of slots is added to add Reed-Solomon coding, power spreading in units of superframes, The transmission main signal is generated by performing block interleaving in a slot in the superframe direction.

A receiving apparatus for receiving a signal retransmitted from a BS digital satellite broadcast retransmitting apparatus according to the present invention includes a demodulation section for demodulating a transmitted carrier wave and extracting a bit string, and a bit string demodulated by the demodulation section. A timing extraction unit that extracts timing information from the supplied bit string, a transmission main signal storage unit that stores a transmission main signal portion based on the timing information obtained from the timing extraction unit,
A TMCC signal storage unit for storing a portion of the TMCC signal to which the power spread signal is added according to the timing information, wherein the portion of the transmission main signal stored in the transmission main signal storage portion is rearranged to perform BS digital satellite broadcasting. And reproducing a transport stream from the reproduced transmission main signal in accordance with the TMCC signal.

Further, a receiving apparatus for receiving a signal retransmitted from the BS digital satellite broadcast retransmitting apparatus according to the present invention further includes an additional information storage section for storing a portion of the additional information based on the timing information, and a storage section for storing the additional information. And an additional information decoding unit for extracting additional information relating to an additional slot according to the transmitted signal, and reproducing the transmission main signal of the BS digital satellite broadcast by rearranging the transmission main signal stored in the transmission main signal storage unit. In this case, a transport stream is extracted according to the TMCC signal and the additional information.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below based on embodiments of the present invention with reference to the accompanying drawings. FIG.
FIG. 1 is a block diagram showing a first embodiment of a BS digital satellite broadcast retransmission device of the present invention. FIG. 2 shows an example of a frame structure applied to the BS digital satellite broadcast retransmission apparatus of the present invention shown in FIG. 1 and a transmission order.

In FIG. 1, a transmission main signal obtained by multi-level demodulation by a BS digital satellite broadcast receiver and a signal obtained by adding a power spread signal to a TMCC signal of BS digital satellite broadcast are obtained, and a transmission main signal storage section is provided. 1 and stored in the TMCC signal storage unit 2. These stored signals and the frame synchronization signal and the additional information generated or generated by the frame synchronization generation unit 3 and the additional information generation unit 4 are controlled based on the timing signal obtained from the BS digital satellite broadcast receiver. The transmission order is controlled by the control signal generated by the section 5 and sent to the multi-level modulation section 6.

The frame structure in the present embodiment is as shown in FIG. 2, and the transmission order is indicated by a solid arrow below the frame structure. Note that the broken-line arrow indicates that, when the transmission becomes the signal of the lowermost slot, the signal shifts to the signal of the next uppermost slot adjacent to the right (flyback).

The order of transmission will be described with reference to FIGS. 1 and 2 as follows. First, the frame synchronization signal sequentially generated from the frame synchronization generation unit 3 is continuously transmitted,
Subsequently, the TMCC stored in the TMCC storage unit 2
The signals are sequentially read and transmitted, and subsequently, the frame synchronization signal sequentially generated from the frame synchronization generation unit 3 is continuously transmitted, and then the additional information sequentially generated from the additional information generation unit 4 is continuously transmitted. You. When the above transmission is completed, the transmission main signals stored in the transmission main signal storage unit 1 are sequentially read out, and the transmission continues until the end of the frame.

By making the signal transmission order as described above, the interleaving depth is set to 48 times that of the BS digital satellite broadcasting, so that error correction can be performed even for bursty disturbance that does not exist in the satellite transmission path. ing. This is possible because the transmission path does not need to change the modulation method for each slot and has a high CN ratio. Since the information rate of BS digital satellite broadcasting is 52.17 Mbps, the symbol rate becomes 9.435 Mbps when the multi-level modulation section 6 (see FIG. 1) of the retransmission apparatus of the present invention is 64 QAM multi-level modulation, which is about 11 MHz. It becomes possible to transmit in the band. The additional information can be used to increase the reliability of the TMCC signal by repeatedly transmitting the TMCC signal.

FIG. 3 is a block diagram showing a second embodiment of the BS digital satellite broadcast retransmission apparatus according to the present invention. In the above-described first embodiment of the present invention, the transmission main signal that has only been multi-level demodulated from the BS digital satellite broadcast receiver, that is, deinterleaving, power despreading, and Reed-Solomon decoding are performed in the receiver. A signal that has not been transmitted (a main signal when performed) is directly supplied to and stored in the transmission main signal storage unit 1 shown in FIG. On the other hand, in the second embodiment of the present invention, the transmission main signal is subjected to deinterleaving 7, power despreading 8, and Reed-Solomon decoding 9 as in the case of the BS digital satellite broadcast receiver specified by the Ordinance of the Ministry of Posts and Telecommunications. To correct errors in the satellite transmission path. A Reed-Solomon code is added again to the obtained packet of the transport stream (Reed-Solomon coding) 10, and power spreading 11 and interleaving 12 are performed in the same manner as in the case of obtaining a transmission main signal from a main signal in BS digital satellite broadcasting. Are input to the transmission main signal storage unit 1. Other parts are the same as those shown in FIG.

FIG. 4 is a block diagram showing a third embodiment of the BS digital satellite broadcast retransmission apparatus according to the present invention. In the embodiment, the TMCC signal is power despread 13 and Reed-Solomon decoded 14 to correct the error in the satellite transmission path as in the BS digital satellite broadcast receiver specified by the Ordinance of the Ministry of Posts and Telecommunications. After correcting the error, a Reed-Solomon code is added 15 again, and power spreading 16 is performed in the same manner as in BS digital satellite broadcasting.
The signal is input to the signal storage unit 2. Other parts are the same as those shown in FIG.

FIG. 5 and FIG. 6 are block diagrams showing a fourth embodiment of the BS digital satellite broadcast retransmission apparatus of the present invention. The difference between FIG. 5 and FIG. 3 (second embodiment) and FIGS. 6 and 4 (third embodiment)
Reed-Solomon decoder 9 and Reed-Solomon encoder 1
0, and the TMCC rewriting unit 18 is inserted between the Reed-Solomon decoding unit 14 and the Reed-Solomon encoding unit 15 in the latter case. In addition, these figures (including FIG. 1)
, The same parts are denoted by the same reference numerals.

In the fourth embodiment of the present invention, when a transport stream packet is obtained for each slot from the Reed-Solomon decoding unit 9 by a BS digital satellite broadcast receiver specified by the Ordinance of the Ministry of Posts and Telecommunications, The slot related to the port stream (TS) is replaced with the transport stream (TS-1 ′) in the slot change unit 17. After the replacement, the transmission main signal is obtained from the transport stream as in the second embodiment (see FIG. 3). In this case, for example, the TS-1 assigned to the 43rd to 48th slots is replaced with another TS-1 ′ and transmitted. At that time, TMCC
Slots and transport streams (TS
Since the portion describing the relationship of -1 ′) needs to be changed, the TMCC signal is obtained from the Reed-Solomon decoding unit 14 as in the third embodiment (see FIG. 4).
The rewriting is performed by the rewriting unit 18. After that, Reed-Solomon encoding 15 and power spreading 16 are performed,
The signal is sent to the signal storage unit 2.

FIG. 7 is a block diagram showing a fifth embodiment of the BS digital satellite broadcast retransmission apparatus of the present invention, and FIG. 8 shows a frame structure thereof. In the present embodiment, when a transport stream packet is obtained for each slot from the Reed-Solomon decoding unit 9 by a BS digital satellite broadcast receiver specified by the Ordinance of the Ministry of Posts and Telecommunications, another transport stream (T
S) is added to create a new frame with an increased number of slots. As an example, four slots are added here, and one frame = 48 slots + 4 slots = 52 slots. After adding four slots, each slot is subjected to Reed-Solomon encoding 10 to obtain a main signal excluding the synchronization byte, and 416 (= 52 × 8) main signals are subjected to power spreading 11 with a superframe (8 frame) period. , A block 8 having a depth of 8 between the same slots in the superframe direction to obtain a transmission main signal.

At this time, the control section 5 sends the signal to the multi-level modulation section 6 (see FIG. 1) in the direction indicated by the solid arrow (broken arrow is flyback) shown below the frame structure in FIG. Controls the output order of the transmission main signal storage unit 1, the TMCC signal storage unit 2, the frame synchronization generation unit 3, and the additional information generation unit 4 (all shown in FIG. 1). The signals output in this order are subjected to multi-level modulation such as 64QAM. Also,
Since the control information regarding the additional slot is not included in the TMCC signal, the control information is generated from the additional information generating unit 4.

FIG. 9 is a block diagram showing a first embodiment of the receiving apparatus of the present invention for receiving a signal retransmitted by the BS digital satellite broadcasting retransmitting apparatus of the present invention described above. In FIG. 9, for example, a modulated signal transmitted by a cable television is firstly demodulated into a bit string by a demodulation unit 20 of the receiving apparatus of the present invention, and the demodulated signal is branched into three, and a transmission main signal storage unit 21 and a TMCC The signals are input to the signal storage unit 22 and the timing extraction unit 23, respectively.

The timing extracting section 23 extracts timing information such as frame synchronization and superframe synchronization from the demodulated bit string. Based on the extracted timing information, the transmission main signal portion and the TMCC signal portion to which the power spread signal has been added in the demodulated bit string are transmitted by the transmission main signal storage unit 21 and the TM
It is stored in the CC signal storage unit 22. The TMCC signal stored in the TMCC signal storage unit 22 is subjected to power despreading and Reed-Solomon decoding by the TMCC decoding unit 24 from one superframe of the frame structure to extract the TMCC signal.

The portion of the transmission main signal in the demodulated bit string stored in the transmission main signal storage unit 21 is rearranged in the frame reproducing unit 25 to reproduce the frame structure shown in FIG. Deinterleaving in the conversion unit 26,
The main signal is obtained by performing power despreading, and further subjected to Reed-Solomon decoding to obtain a transport stream packet for each slot. From now on, the TS decomposition unit 27
The transport stream (TS) is extracted according to the TMCC signal supplied from the CC decoder unit 23.

FIG. 10 shows a second embodiment of the receiving apparatus according to the present invention.
FIG. 9 is a block diagram showing a configuration of an apparatus for receiving a signal retransmitted by the retransmitting apparatus shown in the embodiment (see FIGS. 7 and 8). In FIG. 10, the same circuit portions as those in FIG. 9 are denoted by the same reference numerals. Also in the present embodiment, the modulation signal transmitted by the demodulation unit 20 is demodulated to extract a bit string, and timing information such as frame synchronization and superframe synchronization is extracted from the timing extraction unit 23. According to the timing information, the transmission main signal portion, the TMCC signal portion, and the additional information portion in the demodulated bit string are stored in the transmission main signal storage portion 21, the TMCC signal storage portion 22, and the additional information storage portion 28, respectively. I do. here,
The additional information storage unit 28 is a part that did not exist in the first embodiment of the receiving apparatus of the present invention shown in FIG.

The information stored in the additional information storage unit 28 is extracted by the additional information decoding unit 29 with respect to the additional slot (see FIG. 8). The signal stored in the TMCC signal storage unit 22 is subjected to power despreading and Reed-Solomon decoding by the TMCC decoding unit 24 from one superframe of the frame structure to extract a TMCC signal. The transmission main signal in the demodulated bit string stored in the transmission main signal storage unit 21 is rearranged in the frame reproduction unit 25 to reproduce the frame shown in FIG. , Deinterleaving, and power despreading to obtain a main signal, and further perform Reed-Solomon decoding to obtain a transport stream bucket for each slot. From this, the TS decomposing unit 27 extracts a transport stream (TS) according to the TMCC signal and the additional information supplied from the TMCC decoding unit 24 and the additional information decoding unit 29, respectively.

[0028]

According to the present invention, BS digital satellite broadcasting can be easily retransmitted to a transmission path that does not require hierarchical transmission such as cable television with high frequency utilization efficiency.

Further, according to the present invention, by increasing the interleaving depth by the number of slots, it is possible to improve the resistance to interference generated in a burst manner.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a first embodiment of a BS digital satellite broadcast retransmission device of the present invention.

FIG. 2 shows an example of a frame structure applied to the BS digital satellite broadcast retransmission device of the present invention and a transmission order.

FIG. 3 is a block diagram showing a second embodiment of the BS digital satellite broadcast retransmission device of the present invention.

FIG. 4 is a block diagram showing a third embodiment of the BS digital satellite broadcast retransmission device of the present invention.

FIG. 5 is a block diagram showing a fourth embodiment of the BS digital satellite broadcast retransmission device of the present invention.

FIG. 6 is a block diagram showing a fourth embodiment of the BS digital satellite broadcast retransmission device of the present invention.

FIG. 7 is a block diagram showing a fifth embodiment of the BS digital satellite broadcast retransmission device of the present invention.

FIG. 8 is a block diagram showing a fifth embodiment of the BS digital satellite broadcast retransmission device of the present invention.

FIG. 9 is a block diagram showing a first embodiment of the receiving apparatus of the present invention for receiving a signal retransmitted by the BS digital satellite broadcasting retransmitting apparatus of the present invention.

FIG. 10 is a block diagram showing a second embodiment of the receiving device of the present invention.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 main transmission signal storage unit 2 TMCC signal storage unit 3 frame synchronization generation unit 4 additional information generation unit 5 control unit 6 multi-level modulation unit 7 deinterleave unit 8 power despreading unit (of transmission main signal) 9 Reed-Solomon decoding unit (For transmission main signal) 10 Reed-Solomon encoding section (for transmission main signal) 11 Power spreading section (for transmission main signal) 12 Interleave section 13 Power despreading section (for TMCC signal) 14 Reed-Solomon decoding section (for TMCC signal) 15) Reed-Solomon encoder (for TMCC signals) 16 Power spreader (for TMCC signals) 17 Slot switching unit 18 TMCC rewriting unit 19 Slot addition unit 20 Demodulation unit 21 Transmission main signal storage unit 22 TMCC signal storage unit 23 Timing extractor 24 TMCC decoder 25 Frame reproducer 26 Transmission path decoder 27 TS Solution 28 additional information storage unit 29 the additional information decoding unit

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Mikio Maeda 1-10-11 Kinuta, Setagaya-ku, Tokyo Japan Broadcasting Corporation Research Institute (72) Inventor Hiroshi Miyazawa 1-110, Kinuta, Setagaya-ku, Tokyo No. Japan Broadcasting Corporation Broadcasting Technology Laboratory F-term (reference) 5C064 DA01 DA03 DA09 DA14

Claims (4)

[Claims] A transmission main signal storage unit for storing a transmission main signal of a BS digital satellite broadcast, a TMCC signal storage unit for storing a signal obtained by adding a power spread signal to a TMCC signal of a BS digital satellite broadcast, For a frame structure composed of each output from the frame synchronization generation unit that generates the additional information and the additional information generation unit that generates the additional information, while sequentially generating a signal that is continuous in a direction orthogonal to the slot of the frame structure, A BS digital satellite broadcast retransmission apparatus, wherein the generated signal is subjected to multi-level modulation and sent to a multi-level modulation unit for obtaining a transmission signal. 2. The BS digital satellite broadcast retransmitting apparatus according to claim 1, wherein the transmission main signal stored in the transmission main signal storage unit is deinterleaved, despreads, and read in a BS digital satellite broadcast receiver. After recovering the transport stream packet by performing Solomon decoding, the number of slots in the frame structure is made larger than the number of slots in the frame structure transmitted by digital satellite, and a new transport stream packet corresponding to the increased number of slots is added. A BS digital satellite broadcast retransmitting device characterized by being a transmission main signal generated by performing Reed-Solomon coding, power spreading in superframe units, and block interleaving in a slot in the superframe direction. 3. A demodulator for demodulating a transmitted carrier and extracting a bit sequence, a timing extractor for extracting timing information from the bit sequence supplied with the bit sequence demodulated by the demodulator, and a timing extractor. A transmission main signal storage unit for storing a transmission main signal portion based on the obtained timing information; and a TMC for storing a TMCC signal portion to which a power spread signal is also added based on the timing information.
A C signal storage unit for reproducing a transmission main signal of the BS digital satellite broadcast by rearranging a portion of the transmission main signal stored in the transmission main signal storage unit, according to the TMCC signal from the reproduced transmission main signal. BS configured to extract a transport stream
A receiving device that receives a signal retransmitted from a digital satellite broadcast retransmitting device. 4. The receiving device according to claim 3, wherein the receiving device further stores an additional information storage unit that stores a portion of the additional information based on the timing information, and additional information regarding an additional slot based on a signal stored in the storage unit. And an additional information decoding unit for extracting a transmission main signal of the BS digital satellite broadcast by rearranging a transmission main signal portion stored in the transmission main signal storage unit. A receiving apparatus for receiving a signal retransmitted from a BS digital satellite broadcast retransmitting apparatus, wherein the receiving apparatus is configured to extract a transport stream according to the following.