JPH1118067A - Digital data burst transmitting method for image data communication - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable realtime image transmission, to prevent an image from being interrupted or partially omitted and to improve image transmission throughput by making the quantity of image data information contained in one data burst which is almost equal to one field (one frame) of images to be transmitted. SOLUTION: A data burst is composed at least of a preample (PR) composed of a code for synchronization, a unique word and station identification code or the like, plural data (DATA) and one or plural mid amplifiers(MD) at least composed of a code for synchronization. The frame constitution of the data burst is a so-called train type data burst constitution which links one or plural data (DATA) and mid amplifiers(MD) next to the preample (PR) in the order of DATA-1, MD-1, DATA-2, MD-2,..., MD-n-1 and DATA-n, without sandwiching guard times.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital data burst transmission method for transmitting image information in a burst system.

[0002]

2. Description of the Related Art In recent years, with the spread of multimedia, needs for transmitting digital image data such as still images and moving images have been increasing. Also, with the spread of mobile communication and wireless LAN, devices for wirelessly transmitting digital image data are increasing.

Conventionally, when digital data is transmitted in a time-division burst mode, the frame configuration of the data burst is, for example, a synchronization code (SY) or a unique word (U).
W), a preamble (PR) comprising a station identification code (ID), etc., and a data (DA) arranged in order, followed by a guard time for transmitting nothing, and then having the same frame configuration as the data burst. Transmit the next data burst consisting of FIGS. 3 and 4 show an example of a frame format of a data burst in such a digital communication system.

[0004] On the receiving side receiving such a data burst, for example, processing such as carrier recovery, automatic gain control (AGC) pull-in, and clock synchronization establishment are performed using the synchronization code in the preamble period. Furthermore, when the unique word and the station identification code are detected, and it is recognized that the subsequent data is the desired data applied to the own station, the reproduced carrier, AGC, clock synchronization, etc. are held until the end of the data, and the data is stored. Is demodulated.

[0005] As shown in the figure, in a conventional burst method for transmitting digital data, image data information to be transmitted, for example, image data for one image field (one frame of an image is composed of two field images) is transmitted. The data is divided into a plurality of data and transmitted in a plurality of data bursts.

For example, when digitally transmitting a television signal of the NTSC system, 720 × 480 pixels are 16 bits, and the data amount is 60 fields per second (= 30 frames per second), and the information transmission speed is about 160 Mbit / sec. Therefore, data for one field (or one frame) of an image is divided into a plurality of data bursts and transmitted.

As described above, image information transmission has a larger amount of information than ordinary data transmission. Therefore, in the case of burst transmission, it is necessary to divide the data into many data bursts for transmission.

[0008]

However, when image information, particularly real-time image information, is transmitted by the burst method, 1) when a data burst of another channel enters the guard time between the data burst and the next data burst, Is interrupted, making real-time transmission impossible. 2) During transmission, the quality of the transmission path may deteriorate,
On the receiving side, the image is interrupted in the middle of one field (or one frame), or a part of the image is lost. 3) Since the transmission image information amount does not match the image data amount in the data burst, there is a problem that the throughput is reduced (not optimized).

[0009]

SUMMARY OF THE INVENTION It is an object of the present invention to enable real-time image transmission and to prevent interruption of an image or partial omission of an image due to a decrease in quality of a transmission path during transmission. Another object is to improve the throughput of image transmission.

An object of the present invention is to provide a data burst transmission method having a frame structure including at least image data information and a preamble added to the head thereof, wherein the amount of image data information included in one data burst is determined by the amount of image data to be transmitted. This is achieved by making it approximately equal to one field (or one frame).

Further, an object of the present invention is to divide one field (or one frame) of data of an image into a plurality of pieces and to form each piece of data into a train type using a midamble, thereby forming one data burst. It is achieved by doing.

[0012] Further, an object of the present invention is to provide a burst transmission system in which data burst synchronization and AGC are followed in real time, in a frame configuration in which a data frame length equal to the amount of image data information is arranged at least after a preamble. Achieved by data burst.

[0013]

Embodiments of the present invention will be described below.

FIG. 1 is a configuration diagram showing a frame format of a data burst according to a first embodiment of the present invention.

The data burst of this embodiment is a preamble (PR) comprising at least a synchronization code (SY), a unique word (UW), a station identification code (ID), and the like.
And a plurality of data (DA) and one or a plurality of midambles (MD) composed of at least a synchronization code (SY). The frame configuration of the data burst is one after the preamble (PR). Individual or multiple data (DA) and midamble (MD)
Are DA-1, MA-1, DA-2, MA-2, ...
.., DA- (n-1), MA- (n-1),
Further, a so-called train-type data burst configuration in which the data (DA-n) are connected without a guard time therebetween in the order of the data (DA-n).

Here, the total amount of image data contained in the data (DA) in one so-called train type data burst is equal to the data amount of one frame of an image to be transmitted or one field of an image.

On the receiving side receiving such a data burst, synchronization is established with the preamble synchronization code, and the AGC is pulled in. Subsequently, data is demodulated while maintaining AGC, clock synchronization, and the like. Further, while the midamble synchronization code is being received, clock phase correction or AGC fine adjustment is performed.

FIGS. 5 and 6 show the configurations of the transmitter and the receiver in the present embodiment. In FIG. 5A, the data processing unit 41 on the transmission side generates the data burst shown in FIG. 1 and transmits the data burst to the transmission path via the high-frequency processing unit 42 using radio or the like. Data (DA), station identification code (ID), and the like are sent from the upper layer 40 to the data processing unit 41 as data. The timing generation unit 41A generates predetermined timings constituting a data burst. In accordance with the timing generated by the timing generation unit 41A, the modulation unit 41E outputs the synchronization code SY to the high frequency processing unit 42 without modulating the information during the period of the synchronization code SY. Further, during the period of the unique word UW, the selector 41D selects a signal sequence such as “0101.” generated from the UW generation unit 41C as a transmission signal according to the timing generated by the timing generation unit 41A. The output of the selector 41D is modulated by the modulation unit 41E, and transmitted to the transmission path via the high-frequency processing unit 42 by radio or the like. During the synchronization code SY,
The signal from the upper layer 40 and the UW generation unit 41C is
The selector 41D operates so as not to be supplied to E.

Here, during the synchronization code SY period, the timing generation unit 44F outputs the synchronization code SY to the modulation unit 41.
From E, the unique word UW is output from the UW generation unit 41C during the unique word UW period, and the station identification code ID is output from the upper layer 40 during the data DA period during the unique word UW period. Next, each part is controlled.

Note that the code synchronization CDM is
When the (code division multiplexing) communication system is used, the selector 4
The 1D output is spread spectrum modulated and multiplexed (CDM) using N PN (pseudo noise) codes that are orthogonal to one another. FIG. 5B shows the configuration of the modulation section 41E in this case. Incidentally, a communication method other than the CDM can be used in the present invention. In this case, the modulating unit 41E
During SY period, among the spreading codes PN ₀ to PN _n, select the synchronizing code PN _0, without the code division multiplexing, and outputs the high frequency processing section 42 as SY code.

Here, the code-synchronous CDM communication system is one of spread spectrum communication systems used for improving data throughput, and N orthogonal to each other.
In this method, data is spread and multiplexed on a frequency using these codes and transmitted. Here, the code division multiplexing (CDM)
When receiving and demodulating such data, the gain and synchronization are maintained on the receiving side during data reception.

IDs and UWs other than information data are transmitted without code division using one spreading code.

On the receiving side that has received the data burst, the data processing unit 44 establishes synchronization and demodulates data via the high frequency processing unit 43 shown in FIG. 6A. In the data processing unit 44 in the figure, the demodulation unit 44C performs despread demodulation by the demodulation clock that has established synchronization during the synchronization code SY period in the synchronization unit 44A.
The signal series such as “0101...” Generated from 4D and the demodulated data are compared by the comparator 44E. Demodulation unit 44
If the output of C is data matching the UW, the timing generator 44F generates predetermined timings constituting a data burst, and sends data (DA), station identification code (ID), and the like to the upper layer 45. .

When the CDM communication system is used, the demodulation section 44C demodulates the received signal by CDM using N PN codes orthogonal to each other. In this case, the configuration of the demodulation unit 44C is as shown in FIG.

FIGS. 7 and 8 are flowcharts showing the operation on the receiving side receiving such a data burst. FIG. 7 shows the operation during preamble reception, and FIG. 8 shows the operation during midamble reception. In the initial state, the timing generator 4
4F sets the selector 44G on the UW generation unit 44D side.

On the receiving side receiving the data burst, S
When the demodulation unit 44C receives the preamble PR synchronization code SY at 11, the high frequency processing unit 43 pulls in the AGC at S12 and S13, and the synchronization unit 44A establishes clock synchronization at S14 and S15. Then S1
6. In S17, the high frequency processing unit 43 and the synchronizing unit 44A
The comparator 44E detects the unique word UW in S18 and S19 while finely adjusting the GC and clock synchronization. When the unique word UW is detected, AGC / clock synchronization and the like by the high frequency processing unit 43 and the synchronization unit 44A are held in S20. Then, the timing generation unit 44F sets the selector 44G to the ID generation unit 44B side, and proceeds to S21
The station identification code ID is detected by the decoder 44E, and when it is confirmed that the data is the desired data applied to the own station, the data is demodulated by the demodulation unit 44C.

Next, the timing generation unit 44F performs the processing in S31.
At the timing when the demodulation unit 44C receives the synchronization code SY of the mid ensemble MD, the fine adjustment of the AGC by the high frequency processing unit 43 is performed in S32, and the synchronization unit 4 is determined in S33.
The high-frequency processing unit 43 and the synchronizing unit 44A are set so that the clock fine adjustment by 4A is performed. Here, since the clock synchronization and the AGC are established during the preamble PR period, the midamble MD
Only the phase correction is required for clock synchronization during the period.
C does not require an initial pull-in. Therefore, the synchronization code SY during the midamble MD period is the preamble P
It may be shorter than the synchronization code during the R period.
In S13, the high frequency processing unit 43 increases the gain to pull in the AGC at high speed, and in S16 and S32, reduces the gain and adjusts the AGC with high accuracy. Synchronization unit 4
4A also increases the gain of the pull-in in S15 and S1
7. In S33, the size is reduced. After the elapse of the predetermined time in S34, the AGC performed by the high frequency
-Demodulate data while maintaining clock synchronization. On the receiving side, these processes are performed until the data ends in S22.

As described above, by distributing the data of one frame or one field of an image to one data burst without waste, the throughput can be improved.

Further, since the data burst is configured in a train type, there is no possibility that an interrupt burst is generated from another station, the data throughput can be improved, and real-time transmission can be realized.

Furthermore, since one frame (one field) of an image is continuously transmitted in a train, the image is not transmitted on the receiving side due to deterioration of the quality of the transmission path as in the case of transmitting a plurality of data bursts. It is possible to prevent the image from being interrupted in the middle of the frame (one field) or to prevent a part of the image from being lost.

Further, by making each data (DA) length in the data burst equal to the maximum time capable of maintaining the synchronization accuracy or the AGC accuracy, the data length that can be transmitted in one data burst can be maximized. Thus, the throughput can be improved.

FIG. 2 is a configuration diagram showing a frame format of a data burst according to the second embodiment of the present invention.

The present embodiment is an example of a configuration in a burst transmission system in which data burst synchronization and AGC are followed in real time.

In this embodiment, this is achieved by a data burst having a frame structure in which a data frame length equal to the amount of image data information is arranged at least after the preamble.

With such a configuration, data for one frame or one field of an image is transmitted in one data burst, so that the throughput can be improved.

Furthermore, since there is no possibility of an interrupt burst from another station, data throughput can be improved and real-time transmission can be realized.

Furthermore, since one image frame (one field) is continuously transmitted, one frame (one field) is received on the receiving side due to deterioration in the quality of the transmission path as in the case of transmission using a plurality of data bursts. It is possible to prevent an image from being interrupted in the middle of (one field) or a part of the image from being lost.

[0038]

As described above, the digital data communication method according to the present invention is included in one data burst in a data burst transmission method having a frame structure including at least image data information and a preamble added to the head thereof. By making the amount of image data information substantially equal to one field (or one frame) of the image to be transmitted, real-time image transmission is possible, and the image is interrupted due to a deterioration in the quality of the transmission path during transmission. ,
Alternatively, partial omission of an image can be prevented, and the throughput of image transmission can be improved.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a frame format according to a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a frame format according to a second embodiment of the present invention.

FIG. 3 is a configuration diagram of a data burst format.

FIG. 4 is a configuration diagram of a conventional data burst format.

FIG. 5 is a configuration diagram of a transmission side according to the first embodiment of the present invention.

FIG. 6 is a configuration diagram of a receiving side according to the first embodiment of the present invention.

FIG. 7 is a flowchart on the receiving side according to the first embodiment of the present invention.

FIG. 8 is a flowchart of receiving a midamble on the receiving side according to the first embodiment of the present invention.

[Explanation of symbols]

 43 high frequency processing unit 44A synchronization unit 44C demodulation unit 44E comparator

Claims (8)

[Claims] 1. A digital data burst communication method having a frame configuration including at least image information data and a preamble added to the head thereof, wherein the amount of image data information included in one data burst is equal to one field of an image to be transmitted. A digital data burst transmission method in image data communication, the method comprising: 2. A digital data burst communication method having a frame structure including at least image information data and a preamble added to the head thereof, wherein the amount of image data information included in one data burst is one frame of an image to be transmitted. A digital data burst transmission communication method in image data communication, the method comprising: 3. In a digital data burst communication system having a frame configuration including at least image information data and a preamble added to the head thereof, the amount of image data information included in one data burst is equal to one field of an image to be transmitted or The image information data corresponding to one field of the image or one frame of the image to be transmitted corresponding to one frame is divided into a plurality of data to form a plurality of data constituting a data burst. A digital data burst transmission communication method in image data communication, characterized in that one or more midambles are inserted to form one data burst. 4. A digital data burst transmission communication method in image data communication according to claim 3, wherein said preamble and said midamble include at least a synchronization code. 5. A digital data burst transmission communication method in image data communication according to claim 1, wherein a wireless transmission line is used. 6. A digital data burst transmission communication method in image data communication according to claim 1, wherein said image data is subjected to spread spectrum modulation. 7. A digital data burst transmission communication method in image data communication according to claim 1, wherein said image data is code division multiplexed. 8. The image data is code division multiplexed,
5. The digital data burst transmission communication method according to claim 3, wherein an unmultiplexed signal is used for the preamble and the midamble.