JP3987846B2 - Pilot broadcast channel processing apparatus for satellite digital broadcast transmitter and signal processing method thereof - Google Patents

Description

  The present invention relates to a satellite digital broadcast transmitter, and more particularly to a pilot broadcast channel processing apparatus for transferring broadcast channel synchronization information and control information necessary for operation, and a signal processing method thereof.

  The existing satellite digital broadcasting standard (ITU-R Rec. BO.1130 System E) proposes a pilot channel for transferring various broadcasting channel information, synchronization information, control information, and the like. The satellite digital transmitter to which such a system is applied has the advantage of free channel selection by always transferring the control information signal of the broadcast channel through the pilot channel during operation.

However, in the broadcast channel information / control signal transferred through such a pilot channel, only the frame counting data that is the order information of the frames in one super frame exists, and the super frame including the current frame is included. There is no order information.
Satellite digital broadcasting standard ITU-R Rec.BO.1130 System E

  The present invention has been derived to solve the above-described problems, and is a pilot broadcast that generates a pilot broadcast channel signal including superframe counting data that is superframe order information in a satellite digital broadcast transmitter. An object of the present invention is to provide a channel processing device and a signal processing method thereof.

Pilot broadcast channel processing unit of the satellite digital broadcasting transmitter for the purposes of the present invention, synchronous data for the synchronization acquisition frame is the control data, and order information of a super frame for the control of the broadcast channel Each of the superframe counting data is time-divided, and a frame generator for generating a frame by inserting the data obtained by the time division into a time slot in the frame, and the unique code of the transferred receiver is Walsh a code assigning unit that by a combination of code and pseudo noise sequence is assigned to the frame, seen including a modulation unit, a modulating said frame the unique code is assigned by the QPSK modulation or PSK modulation scheme, the superframe counting Data is a time slot in the frame The super frame is inserted into a spare time slot, and the super frame is composed of a predetermined number of frames, and the super frame counting data inserted into the spare time slot in the frame is repeated the predetermined number of times in the super frame. Has a structure.

  For example, when the super frame is composed of six frames, the 32-bit super frame counting data inserted into the spare time slot in the frame has a structure that is repeated six times in the super frame. .

  The super-frame counting data has a structure that is repeated a predetermined number of times in the spare time slot. For example, the super-frame counting data has a structure in which the 4-bit super-frame counting data is repeated eight times in the spare time slot. The superframe consisting of a plurality of frames has 24-bit superframe counting data.

On the other hand, a pilot broadcast channel signal processing method for a satellite digital broadcast transmitter according to the present invention includes a synchronization data for acquiring frame synchronization, information data for controlling a broadcast channel, and superframe counting as superframe sequence information. Each of the data is time-divided, and a frame is generated by inserting the data obtained by the time division into a time slot in the frame, and a unique code of the transferred receiver is set as a Walsh code and a pseudo-noise sequence. the method comprising the combination applied to the frame, the unique code look including the the steps of modulating by QPSK modulation or PSK modulation method the frame that has been applied, the superframe counting data, the time in the frame Of the slots, spare time slots Is inserted, the super frame consists of the frame of the predetermined number, the superframe counting data the inserted into the spare time slot within the frame, that it has a structure that is repeated the predetermined times within the superframe Features.

  Therefore, a bidirectional service (for example, a reservation operation service) can be realized by inserting superframe counting data into a spare time slot of the conventional satellite digital broadcasting standard and transferring it.

  According to the present invention, super frame counting data, which is super frame order information, is transferred in a frame transferred through a pilot broadcast channel, so that accurate super frame order information can be transferred without affecting existing standards. By doing so, the quality of the satellite digital broadcasting service can be improved.

  In addition, in the existing standard, the time slot is not subjected to separate encoding for error correction, so that superframe counting data can be used on the receiving side without any additional delay.

Hereinafter, the present invention will be described in more detail with reference to the drawings.
FIG. 1 is a schematic block diagram of a satellite digital broadcast transmitter according to the present invention. The satellite digital broadcast transmitter includes a broadcast channel processing device 100, a pilot broadcast channel processing device 200, and a multiplexer 300.

  The broadcast channel processing apparatus 100 includes a plurality of broadcast channel processing units 110 that respectively process a plurality of broadcast data corresponding to a plurality of broadcast channels.

  The first broadcast channel processing unit 110 encodes broadcast data generated corresponding to the first channel, and I / Q separation that separates the encoded broadcast data of the first channel into an I signal and a Q signal. 113, a code assigning unit 115 for assigning a unique code of a receiver that receives broadcast data of the first channel by a combination of a Walsh code and a pseudo-random sequence (Pseudo Random Sequence), and broadcasting of the first channel A modulation unit 117 that modulates data by a predetermined modulation method is included.

  A plurality of such broadcast channel processing units 110 are provided corresponding to a plurality of broadcast channels that can be supported by the satellite digital broadcast transmitter, and the processing process of each broadcast data is the same.

  The pilot broadcast channel processing device 200 processes information data, control data, and the like for a plurality of broadcast channels that can be supported by the transmitter, and transfers them to the receiver through the pilot broadcast channel. The pilot broadcast channel processing device 200 generates a frame generation unit 210 that generates a frame including superframe counting data that is superframe order information, and an I / Q separation unit 230 that separates the generated frame into an I signal and a Q signal. And a code adding unit 250 for assigning a receiver unique code by a combination of a Walsh code and a pseudo-random sequence, and a modulation unit 270 for modulating with a QPSK modulation method.

The frame generation unit 210 includes a multiplexer 211. The multiplexer 211 includes synchronization data (PS, D1, D2) for acquiring frame synchronization and control data (D3 to D50) for a plurality of broadcast channels encoded by the encoder 213. ) And superframe counting data (D51), which is superframe order information, are time-divided, and a frame is generated by inserting the data obtained by the time-division into a time slot in the frame.

Here, the synchronization data for acquiring frame synchronization includes a pilot symbol (PS), unique word data (Unique Word data) (D1), and frame counting data (D2).
FIG. 2 is a diagram illustrating a structure of a frame generated from the frame generation unit 210. As shown in the figure, one frame structure has 51 data time slots D1 to D51, and pilot time slots PS into which pilot symbols are inserted are provided at the front ends of the respective data time slots D1 to D51. . In one frame, super frame counting data is inserted into the last data time slot D51. Here, the size of one time slot (PS, D1 to D51) has 32 bits.

  Hereinafter, the structure of superframe counting data inserted into the time slot D51 according to the present invention will be described with reference to FIGS.

  FIG. 3 shows the structure of a time slot D51 into which superframe counting data is inserted in the case of the QPSK modulation method as an example.

  As shown in the figure, the time slot D51 has a size of 32 bits. In the case of the QPSK modulation method, since the I channel and the Q channel can be received simultaneously as shown in the figure, the time slot D51 has a total size of 64 bits. Accordingly, the super frame counting data is inserted into the time slot D51 of six frames in a structure that is repeated six times. In this way, transfer errors can be minimized by the repeated data structure.

  Of course, in the case of the PSK modulation method, a 32-bit superframe counting data is inserted into a time slot D51 of one frame, and a 32-bit superframe counting data is repeated six times in the superframe.

FIG. 4 is an example implemented with reference to the structure of frame counting data inserted into a conventional time slot D2 as another example.
The structure of the frame counting data inserted in the conventional time slot D2 is as shown in FIG. A time slot having a size of 32 bits is divided into 8 equal parts, and 4 bits of frame counting data are repeated. Since such a structure is a method that takes into account the transfer error rate in a conventional transmitter, if superframe counting data according to the present invention is transferred using this scheme, the superframe counting data is verified. Transfer with minimum transfer error rate.

  As shown in FIG. 4, 4-bit superframe counting data is repeatedly inserted into the time slot D51 eight times. When applied to each frame in the manner as described above, the super frame counting data transferred to one super frame (FRAME0 to FRAME5) has a size of 24 bits.

  As shown in FIGS. 3 and 4, the transfer error rate of the superframe counting data can be minimized by transferring the data in a repeated structure. In addition, since the superframe counting data is not separately encoded, the receiving side can be used immediately without delay time due to channel decoding.

FIG. 6 is a flowchart for a signal processing method of the pilot broadcast channel processing apparatus according to the present invention.
The frame generator 210 controls the pilot symbols PS, unique word data (D1), frame counting data (D2), and a plurality of broadcast channels encoded by the encoder 213. Data (D3 to D50) and superframe counting data (D51), which is superframe order information, are time-division-divided and data obtained by time-division division is inserted into time slots in the frame to generate a frame (S611).

  At this time, the structure of the super frame counting data inserted into the frame can be applied to various formats. For example, as shown in FIGS. 3 and 4, repeated super frame counting data is inserted and transferred. Minimize the error rate.

  The frame including the super frame counting data (D51) is separated into the I channel and the Q channel through the I / Q separation unit 230 (S613).

In the frame separated into the I channel and the Q channel, the code assigning unit 250 assigns a unique code of the receiver by a combination of a Walsh code and a pseudo noise sequence (S615).
The modulation unit 270 modulates the frame to which the unique code is assigned with the QPSK modulation method (S617).

  As described above, the reserved broadcast service can be realized by inserting and transferring the superframe counting data into the spare time slot D51 of the conventional satellite digital system standard.

  Furthermore, the super-frame counting data on the service provider side is information that can control the service accurately in units of time. If the super-frame counting data is used in conjunction with the frame counting data, the super-frame counting data can be used at any number of times. It is possible to know exactly what time position in the frame exists.

  Accordingly, the service provider can provide broadcast content at a specific time requested by the customer, and since the broadcast information data to be received has time information at regular intervals, the receiver has such time. The desired broadcast information data can be easily searched using the information.

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the specific embodiments described above, and the technical field to which the present invention pertains does not depart from the gist of the present invention claimed in the claims. Anyone who has ordinary knowledge in the field can make various modifications, and such changes are within the scope of the claims.

  The present invention can be applied to a pilot broadcast channel processing apparatus for transferring broadcast channel synchronization information and control information necessary for operation.

1 is a schematic block diagram of a satellite digital broadcast transmitter according to the present invention. FIG. 2 is a frame structure diagram generated by the pilot broadcast channel processing apparatus of FIG. 1. It is an example of the data structure of the time slot D51 in the frame which concerns on this invention. It is another example figure of the data structure of time slot D51 in the frame concerning the present invention. It is a data structure figure of time slot D2 in the frame concerning the conventional satellite digital broadcasting standard. 3 is a flowchart for a signal processing method in which superframe counting data is inserted by a pilot broadcast channel processing apparatus according to the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Broadcast channel processing apparatus 200 Pilot broadcast channel processing apparatus 210 Frame generation part 230 I / Q separation part 250 Code provision part 270 Modulation part

Claims (12)

Synchronization data for acquisition of frame synchronization, control data for broadcast channel control, and superframe counting data, which is superframe order information, are each time-divided, and the data obtained by time division is included in the frame. A frame generation unit for generating a frame by inserting it into a time slot of
A code adding unit for adding a unique code of a transferred receiver to the frame by a combination of a Walsh code and a pseudo-noise sequence ;
See containing and a modulator for modulating the frame in which the unique code is assigned by the QPSK modulation or PSK modulation scheme,
The super frame counting data is inserted into a spare time slot among the time slots in the frame,
The super frame includes a predetermined number of the frames, and the super frame counting data inserted into the spare time slot in the frame has a structure that is repeated the predetermined times in the super frame. A pilot broadcast channel processing device for a satellite digital broadcast transmitter. The super frame has six frames, and the 32-bit super frame counting data inserted into the spare time slot in the frame has a structure that is repeated six times in the super frame. The pilot broadcast channel processing apparatus of the satellite digital broadcast transmitter according to claim 1 . When the satellite digital broadcast transmitter uses the QPSK modulation method, the spare time slot has 64 bits for the I channel and the Q channel, and the 64-bit superframe counting data is repeated 6 times in the superframe. 3. The pilot broadcast channel processing apparatus for a satellite digital broadcast transmitter according to claim 2 , wherein the pilot broadcast channel processing apparatus has a structure. 2. The pilot broadcast channel processing apparatus of a satellite digital broadcast transmitter according to claim 1 , wherein the super frame counting data has a structure that is repeated a predetermined number of times within the spare time slot. The super-frame counting data of 4 bits is repeated eight times in the spare time slot, and thereby the super-frame counting data of 24 bits is included in the super-frame consisting of 6 frames. Item 5. A pilot broadcast channel processing apparatus for a satellite digital broadcast transmitter according to Item 4 .   2. The satellite digital broadcast transmitter pilot broadcast channel processing apparatus according to claim 1, wherein the satellite digital broadcast transmitter is applied to a satellite digital broadcast standard ITU-R Rec. BO.1130 System E. Synchronization data for acquisition of frame synchronization, information data for broadcast channel control, and superframe counting data, which is superframe order information, are each time-divided, and the data obtained by time division is included in the frame. Generating a frame by inserting into a time slot of
Providing the frame with a unique receiver code to be transferred by a combination of Walsh code and pseudo-noise sequence ;
Look including the the steps of modulating the frame in which the unique code is assigned by the QPSK modulation or PSK modulation scheme,
The super frame counting data is inserted into a spare time slot among the time slots in the frame,
The super frame includes a predetermined number of the frames, and the super frame counting data inserted into the spare time slot in the frame has a structure that is repeated the predetermined times in the super frame. A pilot broadcast channel signal processing method for a satellite digital broadcast transmitter. The super frame has six frames, and the 32-bit super frame counting data inserted into the spare time slot in the frame has a structure that is repeated six times in the super frame. The pilot broadcast channel signal processing method of the satellite digital broadcast transmitter according to claim 7 . When the satellite digital broadcast transmitter uses the QPSK modulation method, the spare time slot has 64 bits for the I channel and the Q channel, and the 64-bit superframe counting data is repeated 6 times in the superframe. 9. The pilot broadcast channel signal processing method of a satellite digital broadcast transmitter according to claim 8 , wherein the pilot broadcast channel signal process method has a structure. The pilot broadcast channel signal processing method of a satellite digital broadcast transmitter according to claim 7 , wherein the super frame counting data has a structure that is repeated a predetermined number of times in the spare time slot. The super-frame counting data of 4 bits is repeated eight times in the spare time slot, and thereby the super-frame counting data of 24 bits is included in the super-frame consisting of 6 frames. Item 11. A pilot broadcast channel signal processing method for a satellite digital broadcast transmitter according to Item 10 . 8. The satellite digital broadcast transmitter pilot broadcast channel signal processing method according to claim 7 , wherein the satellite digital broadcast transmitter is applied to a satellite digital broadcast standard ITU-R Rec. BO.1130 System E.

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