JP3130494B2 - Data transmission method and device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an on-demand type individual communication which is desired to be transmitted as soon as possible, such as an inquiry response, and a continuous type which requires a certain amount of data to be transmitted within a certain period. And a data transmission method for transmitting the same. In particular, while securing continuous broadcast communication at the radio transmitting station,
Communication to reduce waiting time for on-demand individual communication
Related to broadcasting systems.

[0002]

FIG. 16 is a block diagram of a conventional satellite communication system. In the figure, a satellite communication system includes a communication satellite 1, a satellite communication control station 2, a data server 3 for holding reference data, a broadcast data server 4 for managing broadcast data, a data reference terminal 5 for requesting data reference, and A broadcast receiving terminal 6 for receiving, an on-demand individual communication channel 7, and a broadcast channel 8 for broadcast data are provided. For example, a communication band for an on-demand individual communication 11 and a continuous broadcast For data transmission. The continuous broadcast 12 corresponds to multimedia information output in real time, such as video or audio, or broadcast data transmitting the same type of data that can be updated without interruption. On the other hand, in the on-demand individual communication 11, a request for communication is made on demand, the request is generated randomly, and the length of the message is also variable. Data reference terminal 5
Requests the data server 3 to reference information on demand through a wired or wireless communication line. Since the data amount of the individual communication 11 for data reference is relatively small, the bandwidth of the line is small. The data server 3 transmits the individual communication 11 to the satellite communication control station 2, and the satellite communication control station 2 transmits the requested individual communication 11 to the communication satellite 1 via a broadband line. The satellite communication control station 2 acquires the individual communication channel 7 necessary for communication, and communicates with the communication satellite 1 and its individual communication channel 7.
Communication 1 to the target data reference terminal 5 via
1 is output. If the individual communication channel 7 cannot be secured, the communication is waited until the individual communication channel 7 becomes available and the communication is performed again.
Determined that it was busy and terminated the communication. Conventionally, there have been requests for a plurality of individual communications 11, and priorities have been set for the requests of each individual communication 11, and transmission has been performed from the one with the highest priority. On the other hand, when the timing to broadcast the data arrives, the broadcast data server 4 sends the data of the broadcast 12 to be broadcast to the satellite communication control station 2, and outputs predetermined digital information within a fixed time. The satellite communication control station 2 always secures a broadcast channel 8 having a band necessary and sufficient for broadcasting, and distributes data of the broadcast 12 to the broadcast receiving terminal 6 via the communication satellite 1. Was.

FIG. 17 is a block diagram of a conventional frame format for band separation of satellite communication. The on-demand individual communication 11 shown in the upper part of the figure is data of the individual communication 11 having different message lengths, and is composed of one frame of a message including predetermined bits. This individual communication 11
And the broadcast 12 are time-divisionally input to the same communication channel. In this frame format, for example, TDMA (Time Divis
Broadcasting and individual communication 1
1, 12 and the empty slot 13 are transmitted in a predetermined band in a time-division manner, and the timing of the on-demand individual communication 11 and the timing of the broadcast 12 in which the broadcast is performed can reduce the load of the broadcast 12 by 50%. Is set to It is well known to those skilled in the art that a plurality of pieces of communication data are input even in another FDMA system or CDMA system depending on how the band is divided.

FIG. 18 shows, for example, Japanese Patent Laid-Open No. 6-140968.
FIG. 1 is a block diagram of a conventional satellite communication system disclosed in Japanese Unexamined Patent Publication (Kokai) No. H10-26095. In the figure, a satellite communication system is an individual communication 1
1 and a communication satellite 16 having a function of a broadcast communication 12, an individual communication network 20, a receiving station 22 of the individual communication 11, a transmitting station 23 of the individual communication 11, a broadcasting network 30, a broadcast transmitting station 31, a broadcast receiving Stations 32, 33, 34, line control station 4 for controlling lines
0, and the channels of the individual communication 11 and the broadcast communication 12 are centrally managed. When a request for the individual communication 11 from the originating station 23 of the individual communication 11 to the receiving station 22 of the individual communication 11 is transmitted to the communication satellite 16, the line control station 40 uses the line connection control 38 to perform the idle communication under the unified management. A channel is selected and assigned to the transmitting station 23 and the receiving station 22 of the individual communication 11. Also, the transmitting station 23 of the individual communication 11 makes a line connection request to the plurality of receiving stations 22, 32 and the like based on the broadcast communication 12 to the line control station 40. And selects an available communication channel under centralized management for
, And a plurality of receiving stations 22, 32, etc.

FIG. 19 shows, for example, Japanese Patent Application Laid-Open No. 4-241532.
FIG. 1 is a time sequence diagram of a conventional individual broadcast and merge communication system disclosed in Japanese Unexamined Patent Publication (Kokai) Publication. Individual broadcast / merge communication is an individual communication S
D11 and the broadcast MD1 have been mixed and transmitted in the transmission channel. There are a method of transmitting the broadcast MD1 by transmitting the transmission timing of the broadcast MD1 to an empty slot of the transmission channel C and a method of dividing the broadcast MD1 into MD11, MD12 and MD13 for transmission. In addition, communication between the center station and the remote station is performed using a mixture of the individual communication SD11 and the broadcast communication MD1, and transmission is immediately performed from the transmission channel when a transmission request is issued from the remote station and a vacancy occurs in the transmission channel. Was. Further, when the long broadcast message MD1 is divided into several parts, and a request for the individual communication SD12 occurs during the transmission of the broadcast divided part MD11, the broadcast divided part MD1 is transmitted.
With the end of the transmission of No. 1, the transmission of the next divided part MD12 of the broadcast message is interrupted, and the individual communication SD12 is processed with priority.

[0006]

In the above-mentioned conventional satellite communication system, even if the communication band is limited and the communication amount is less than the band capacity on average, the communication request is generally random. Therefore, as shown in the theory of the queue buffer, there is a drawback that the waiting time increases according to the communication load. Further, when the band of the broadcast communication 12 and the band of the individual communication 11 are distinguished from each other, the band for communication is limited, so that there is a problem that the tendency of increasing the waiting time becomes remarkable. Further, when the latest information to be broadcast by the broadcast communication 12 is concentrated on the broadcast data server 4, even if an attempt is made to broadcast the information as a message, the output time of the information arrives because the band for broadcasting is limited. Until you do
There is a disadvantage that the user has to wait for a long time to receive.

In the invention described in the above-mentioned Japanese Patent Application Laid-Open No. 6-140968, the individual communication line and the broadcast line are unitarily managed to effectively use the line. Assuming that communication requests are generated at random, waiting by the large number effect is reduced. However, when the broadcast communication 12 must always secure a certain band like the general broadcast, there is a problem that the effect of unifying the individual communication line and the broadcast communication line cannot be obtained. Further, even if the transmitting station tries to broadcast the acquired latest information as a message, there is also a problem that reception is waited until the output time of the information arrives.

Further, according to the invention described in Japanese Patent Application Laid-Open No. 4-241532, an individual communication line and a broadcast line are mixed on the same channel, the waiting time is reduced by a large number effect, and a long broadcast message is divided. In this case, the delay of the individual communication 11 is avoided, but no specific means for avoiding the delay of the transmission of the broadcast message is mentioned. Further, when it is necessary to secure a predetermined band for broadcast transmission, a large number of effects cannot be expected.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and a first object of the present invention is to turn on a broadcast while guaranteeing the amount of continuous broadcast information such as data broadcasting in a predetermined band. An object of the present invention is to provide a data transmission method for shortening a waiting time by giving priority to a request for demand individual communication.

A second object of the present invention is to provide a data transmission method for judging whether or not broadcast communication can be transmitted within a predetermined period, and transmitting the individual communication with priority within an allowable range. .

Further, a third object is to change the frame format of communication data to be transmitted.

A fourth object of the present invention is to observe the traffic on an output line and change the number of broadcast time slots.

A fifth object is to prioritize broadcast communication and individual communication to ensure the quality of broadcast communication,
An object of the present invention is to provide a data transmission device capable of shortening the response time of individual communication.

[0014]

In the data transmission method according to the present invention, a time-division broadcast request is delayed until a predetermined period elapses, and when an individual communication request is made during the predetermined period, the broadcast request is delayed. An individual communication is preferentially input to an output line of a predetermined band, and a broadcast communication delayed after the elapse of the predetermined period is input to the output line.

Also, it is determined whether or not a plurality of time slots obtained by time-sharing the broadcast can be transmitted within a predetermined transmission cycle, and based on the determination result, the individual communication is preferentially transmitted to the output line. It was done.

Further, the length of the transmission cycle is increased or decreased.

Further, the traffic state of the output line is observed, and the number of timeslots of the broadcast transmitted to the output line within the transmission cycle is changed based on the observation result.

Still further, the data transmission apparatus according to the present invention comprises: a first queue buffer for accumulating continuous broadcast communications until a predetermined period elapses; a second queue buffer for accumulating individual communications; The individual communication stored in the second queue buffer is preferentially transmitted to the output line until the predetermined period elapses, and the broadcast communication stored in the first queue buffer is transmitted to the output line after the predetermined period elapses. And a frame format control device for transmission.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment 1 FIG. FIG. 1 is a block diagram of a data transmission system 50 according to the first embodiment of the present invention. In the figure, a data transmission system 50 is connected to a communication satellite 52, a satellite communication control station 54, a telephone, a data server 56 holding the individual communication 11 connected to a computer, a video camera, a telephone, and a computer. 12 includes a broadcast data server 58 for transmitting data 12 in real time or in batch processing, a data reference request terminal 60 for requesting data reference, a broadcast receiving terminal 62 for receiving broadcast data, and a plurality of satellite line channels 64. Thus, it is possible to transmit mixed communication of continuous broadcast communication 12 and on-demand individual communication 11. This system, which preferentially transmits on-demand communication in a wideband channel, is advantageous in that the average waiting time and transmission time due to collision of transmission requests are shorter than in the case of using a band dedicated to on-demand communication. On the other hand, the continuous transmission time guarantees a transmission amount within an allowable fluctuation range, thereby eliminating the problem of indefinite transmission timing caused by simply lowering the transmission priority. In the case where the data updated collectively at the transmission source is continuously transmitted and the data is referred to at the transmission destination, the time at which the latest data can be obtained at the transmission destination can be shortened.

In the present embodiment, the data reference request terminal 60 requests the data server 56 to reference information through a wired or wireless communication line. Generally, since the data amount of the data reference request is small, the bandwidth of the line may be small. The data server 56 can transmit the requested individual communication 11 to the satellite communication control station 54 via the broadband line. On the other hand, the broadcast data server 58 transmits data broadcast in real time to the satellite communication control station 54 in real time. For example, it is video or audio multimedia data. The satellite communication control station 54 mixes the individual communication 11 requested on demand and the periodic broadcast, adds an index, and outputs the result to the common satellite channel 64 through the communication satellite 52. The data reference request terminal 60
Like other telephones or computers connected to the data server 56, the information output from the communication satellite 52 is listened to, the requested information is selected based on the index, and can be taken into the data reference request terminal 60. . Similarly, the broadcast receiving terminal 62 can also listen to the output of the communication satellite, select necessary information, and individually receive the information. Here, when the basic unit of the amount of data output by the communication satellite 52 is called a page, the broadcast data broadcast 12 needs to periodically output a certain amount of data, and the amount is secured. The available band can be set to r (0 <r <1). Further, the output request of the broadcast data broadcast 12 is transmitted to the satellite communication control station 5.
4, the time DT that can be allowed for the transmission delay from the transmission to the actual output can be configured on a page basis.

FIG. 2 is a flowchart showing the procedure of the data transmission method of the present invention. In the figure, data transmission is performed by determining the priority order of the on-demand individual communication 11 and the broadcast data broadcast communication 12. For example, a step 66 for determining whether or not the time-division broadcast 12 request has been delayed until a predetermined period has elapsed, and a step 68 for preferentially outputting the on-demand individual communication 11 requested during the predetermined period. Step 70 for outputting the broadcast 12 delayed after a predetermined period has elapsed
At the time of outputting the next broadcast data, step 72
It is determined whether or not an on-demand output request has occurred. If this condition is satisfied, it is determined in step 74 whether or not the on-demand individual communication 11 can be stored in the output buffer. In step 76, the output request of the on-demand individual communication 11 is registered in the queue buffer. If there is no room in the output buffer, the process immediately branches to step 78 to determine whether there is a wait for another on-demand individual communication 11, and the other on-demand individual communication 11 is registered in the queue buffer. If so, the processing of step 66 described above is executed. On the other hand, when another on-demand individual communication 11 is not registered,
Since the response time of the individual communication 11 has room, step 80
Then, the state of the queue buffer of the broadcast data broadcast 12 is determined. If the broadcast 12 of the broadcast data is registered, the broadcast 12 is output in step 70,
If the broadcast data broadcast 12 is not registered,
The flow branches to step 82 to shift to the next timing. In other words, when the data of the broadcast communication 12 of broadcast data and the data of the individual communication 11 on demand are mixed,
In step 72, it is determined whether or not an on-demand communication request has occurred. If there is a request, in step 74, it is determined whether or not there is room in the queue buffer for registering the request. In step 76, the request is registered as a queue buffer, and the flow returns to step 72 to determine whether there are any more requests. When there is no communication registration request, or when registration becomes impossible and the communication request is discarded, the process proceeds to the next step 78. In this step 78, it is determined whether or not the request is registered in the queue buffer for the output request of the demand communication. If registered, in step 66, it is determined how many pages of broadcast data are waiting. The number of waiting pages is equal to the allowable time DT.
If it is less than that, there is room left. If there is room, on-demand communication data is output in step 68. If there is no demand communication data, step 80
It is determined whether or not there is broadcast data. Step 80
In step 70, if there is no broadcast data, and if there is no room for broadcasting in step 66, the broadcast data broadcast 12 is output in step 70. If neither the on-demand individual communication 11 nor the broadcast communication 12 exists, step 82
Can wait until the next timing.

FIG. 3 is a block diagram of a frame format according to the data transmission method according to the first embodiment of the present invention. In the figure, data transmission in which on-demand individual communication 11 and broadcast data broadcasting 12 are mixed has a time DT = 2 which is allowable for the above-mentioned transmission delay, and a ratio of broadcast data r = 0. 5 is set. The individual communication 11 and the broadcast communication 12 shown in the upper part of FIG.
Are input to the common satellite channel 64, FIG.
, That is, after the first empty slot, individual communication 11
Are input to the output line. next,
After the broadcast 12 and the individual communication 11 are alternately input one frame at a time three times, the broadcast 12 can be continuously input in a period in which the individual communication 11 is interrupted. As a result of the continuous input of the broadcast 12, the delay time of the broadcast 12 can be margined.
2 can be charged alternately. Furthermore, if there is a request for on-demand individual communication 11, this empty slot 13
Alternatively, the response of the individual communication 11 can be improved while ensuring the reliability of the broadcast communication 12 by inserting the frame of the individual communication into the time slot of the broadcast communication 12.

FIG. 4 shows the on-demand individual communication 11 in the case where the band of the on-demand individual communication 11 and the band of the broadcast data broadcast 12 are mixed with each other in the data transmission method of the first embodiment. 3 is a control chart for comparing waiting times. In the figure, on-demand individual communication 11 fixes the load of broadcast data
Delay allowable time DT and on-demand individual communication 11
Is changed. The on-demand individual communication is performed by changing the allowable delay time DT at a rate of 2, 4, 8, 16, 32, and 64 frame times when the band of the broadcast communication 12 and the band of the individual communication 11 are separated and mixed. 11 shows the result of simulating the average delay time of No. 11 by simulation. In this simulation condition, the required band of the broadcast communication 12 was set to 50% of the band including the individual communication 11, the individual communication 11 was generated based on the Poisson distribution, and the length of the communication message was set to a fixed length. Also, the line 70 for setting the load of the on-demand individual communication 11 to 10% of the entire bandwidth, the line 71 for setting 20%, the lines 72, 4 for setting 30%
Each waiting time is indicated by a line 73 that is set to 0%. According to the characteristic result of the waiting time shown, the lighter the total load is, the longer the allowable delay time DT of the continuous broadcast 12 is.
Can be quickly converged even if increases. Also, the higher the ratio of the broadcast type broadcast communication 12 is, the shorter the waiting time of the on-demand individual communication 11 can be. On the other hand, as a whole, the average delay time of the on-demand individual communication 11, that is, the waiting time, is substantially maximized when the band is completely separated, and the allowable delay time DT of the continuous broadcast communication 12 is increased. Thus, the waiting time of the individual communication 11 can be reduced.

In the above embodiment, the loads of the broadcast data broadcast communication 12 and the on-demand individual communication 11 are changed. However, as shown in FIG.
And broadcast data 12 of broadcast data are mixed in a predetermined band,
The total load of the broadcast communication 12 and the on-demand individual communication 11 can be set to be fixed, and the allowable delay time DT and the load ratio of the on-demand individual communication 11 to the broadcast data broadcast communication 12 can be changed. . In the figure, the waiting time of the on-demand individual communication 11 is represented by a line 76 for setting the ratio of the individual communication 11 to the broadcast communication 2 to 7 and a line 7 for setting the ratio to 5: 4.
Lines 78 for 7 and 7 to 2 indicate the waiting time of the individual communication 11, respectively. When the individual communication 11 and the broadcast communication 12 are not completely separated, the waiting time of the on-demand individual communication 11 becomes the maximum, and the continuous broadcast communication 12
As the delay allowable time DT increases, the waiting time of the individual communication 11 can be reduced. However, in this embodiment, the total communication load is relatively large at 90%, and even if the delay allowable time DT of the continuous broadcast communication 12 is increased, the on-demand type wait of the line 76 having a high ratio of the individual communication 11 is performed. The decrease in time was slight.

FIG. 6 shows a continuous broadcast 12 in the case where the band of the on-demand individual communication 11 and the case of the broadcast data broadcast 12 are mixed with each other by the data transmission method of the first embodiment. It is a control figure which compares a delay time. When the load of the broadcast data broadcast 12 is fixed and the load of the delay allowable time DT and the on-demand communication individual communication 11 are changed, that is, the broadcast data broadcast 12 under the condition of FIG. Indicates the average delay time. Each of the illustrated lines is a line 8 that reduces the load of on-demand individual communication to 10%.
Lines 81 for 0% and 20%, lines 82 for 30%, and lines 83 for 40% indicate the delay time of each broadcast 12. In the figure, the maximum delay time of the broadcast communication 12 is suppressed to be equal to or less than the continuous delay allowable time DT in the system, and the satellite communication control station 54 and the broadcast receiving terminal 62 transmit and receive the continuous delay allowable time DT. A queue buffer is secured, and the broadcast receiving terminal 62 can output with a delay corresponding to the continuous delay allowable time DT time. Even if the value of the continuous delay allowable time DT is increased, the effect of reducing the waiting time of the on-demand individual communication 11 is reduced at a certain point.
It is desirable to determine the optimal continuous delay allowable time DT from T and the predicted communication load. Also, since all broadcasts are received on the common satellite channel 64, it is desirable that the on-demand broadcast communication 12 be encrypted, except for key information indicating a response to which communication request. In this manner, the user of the data reference request terminal 60 and the broadcast receiving terminal 62 that receive data can feel a direct wait while suppressing the delay of the continuous broadcast communication 12 in which a direct delay is not easily felt within a predetermined time. Individual communication of demand 1
It would be advantageous to reduce the latency of one.

Embodiment 2 FIG. The flowchart of FIG.
9 shows a procedure of a data transmission method according to a second embodiment of the present invention. In the figure, the data transmission is step 84 for judging whether or not a plurality of time slots obtained by time-dividing the broadcast 12 can be transmitted within a predetermined transmission cycle, and the individual communication 11 is preferentially output based on the judgment result. Step 85 for transmitting to the line, and the on-demand individual communication 1
1 and the transmission order of the broadcast data 12 of the broadcast data can be determined within the effective range. Specifically, in step 86, an initial value of the cycle count is set. At step 87, it is determined whether or not a request for the on-demand individual communication 11 is generated at that timing. If there is a request for the individual communication 11, the process waits for registering the request for the individual communication 11 at step 88. It is determined whether there is room in the column buffer. If there is room, the request for the individual communication 11 is registered as a queue in step 89, and the flow returns to step 87 to further execute the individual communication 1
It is determined whether there is no request (1). When the registration request for the individual communication 11 is lost, or when the registration of the individual communication 11 becomes impossible and the request for the individual communication 11 is discarded, the process branches to the next step 90. In step 90, it is determined whether an output request for the on-demand individual communication 11 is registered in the queue. If it has been registered, it is determined in step 84 whether or not there is room to output the broadcast data broadcast 12 within the cycle. The timing is Pt, the time interval for transmitting data is PB, and the number of broadcasted broadcast
Assuming d, the relationship of (Pb-Pd) <(PB-Pt) is established, and when this condition is satisfied, it can be determined that there is room to output the broadcast communication 12 within a predetermined period. If there is a margin for the transmission delay of the broadcast communication 12, at step 85, the data of the individual communication 11 is output on demand. If there is no data of the on-demand individual communication 11, it is determined in step 91 whether or not there is the broadcast communication 12 of the broadcast data. If the broadcast data broadcast 12 is present in this step 91, and if there is no room for the data output cycle of the broadcast 12 in step 84, the output of the broadcast data broadcast 12 is made in step 92. I do. If neither the on-demand individual communication 11 nor the broadcast data broadcast communication 12 exists, the process can wait at step 93 until the next timing. In step 94, the timing is counted up. If it is determined in step 95 that the transmission period of the broadcast communication 12 can be transmitted, it is possible to return to the next on-demand output request of the individual communication 11.
When this determination cycle is completed, it is possible to proceed to the next transmission cycle.

Embodiment 3 In the second embodiment, the time slots are transmitted while monitoring the margin of the queue buffer. However, as shown in FIG. 8, the number of time slots can be increased or decreased to adjust the length of the transmission cycle. FIG.
FIG. 10 is a block diagram of a frame format of a data transmission method according to a third embodiment of the present invention. In the figure, FIG.
When the individual communication 11 and the broadcast communication 12 shown on the upper side of FIG. 7 are input to the common satellite channel 64, the broadcast communication 12 and the individual communication 11
A frame and the next broadcast 12 can be injected. In this 4-frame cycle, individual and broadcast 11,
It is possible to secure a necessary and sufficient data transmission amount of the broadcast communication 12 while inputting the information 12 and determine whether the individual communication 11 can be input to the output line. This individual communication 11
Broadcast 12 which is equivalent to the input
Are output collectively in a batch process, and as a result of the batch process of the broadcast
The individual communication 11 can be continuously input to the empty slot 13 in the subsequent cycle. Therefore, the response of the individual communication 11 can be improved while ensuring the reliability of the broadcast communication 12. This frame format is shown in FIG.
Can be applied to a case where the broadcast data server 58 transmits communication data to the satellite communication control station 54 in a predetermined unit. For example, irregular information such as news, traffic conditions, stock prices, etc. is collected in the broadcast data server 58, the information is rearranged in the broadcast data server 58, and output via the satellite communication control station 54 in a predetermined order. be able to. When the channel line between the broadcast data server 58 and the satellite communication control station 54 can secure an extremely wide band as compared with the band of the wireless broadcast, the ratio r of the band required for the broadcast data is defined as in the first embodiment. be able to. When data is collectively transmitted to the satellite communication control station 54 at a time, the transmission time interval PB is set in units of pages, and the number of pages that must be broadcast during this time interval PB is Pb (Pb = Pb = r · PB). The data transmission of the broadcast data 12 and the individual communication 11 of the broadcast data by such processing can be set to the page unit PB = 4 and the band r = 0.5 in the illustrated frame format.

FIG. 9 shows the individual communication 11 in the case where the bandwidth of the on-demand individual communication 11 and the band of the broadcast data broadcasting 12 by the data transmission method according to the third embodiment of the present invention are separated and mixed. It is a control figure which compares a communication waiting time. In the figure, when the load of the broadcast communication 12 is fixed and the allowable load time DT and the load of the on-demand individual communication 11 are changed, the communication waiting time of the on-demand individual communication 11 is shown. 11 loads to 1
A line 100 for 0%, a line 101 for 20%, a line 102 for 30%, and a line 103 for 40% indicate the waiting time of the on-demand individual communication 11, respectively. When the broadcast 12 is transmitted in continuous batch input units, the lighter the load of the individual communication 11 is, the shorter the waiting time of the on-demand individual communication 11 is, and the time interval for transmitting the broadcast 12 to the satellite communication control station 54. If the PB is lengthened, the waiting time of the on-demand individual communication 11 can be reduced. That is, optimal transmission of mixed data is achieved by changing the transmission cycle. Further, if the transmission interval PB of the broadcast communication 12 is set to 64 or more under the condition of the line 103, the waiting time of the on-demand individual communication 11 is reduced, so that the reliability of the broadcast communication 12 can be ensured. Furthermore, when the band of the broadcast data broadcast 12 and the band of the on-demand individual communication 11 are separated, the transmission interval PB is set to 2, 4, 8, 16, 32, 64, 128, 25.
6 and 512, the average delay time of the on-demand individual communication 11 is simulated by simulation. Set to%,
The on-demand individual communication 11 is generated based on the Poisson distribution, the message length of the individual communication 11 is set to a fixed length, and the load of the on-demand individual communication 11 is set to 10%, 20%, 30%, Each can be adjusted to 40%. As a result of executing the simulation under these conditions, by setting the batch input unit PB of the continuous broadcast 12 to be 64 frames or more, the response of the individual communication 11 is increased and the reliability of the broadcast 12 is maintained. be able to.

FIG. 10 is a comparative diagram comparing the communication waiting time of the individual communication 11 according to the data transmission method in which the bands of the on-demand individual communication 11 and the broadcast data broadcast 12 are mixed according to the third embodiment. is there. The communication waiting time of the illustrated individual communication 11 is set such that the total load of the broadcast communication 12 of the broadcast data and the on-demand individual communication 11 is fixed,
Delay allowable time DT and on-demand individual communication 11
This is a simulation result in which the load ratio of the broadcast data broadcast 12 is changed. Each line indicates the waiting time of the on-demand individual communication 11 by a line 106 for setting the ratio of the individual communication 11 to the broadcast communication 12 to 2: 7, a line 107 for setting the ratio to 5: 4, and a line 108 for setting the ratio to 7: 2. It is a thing. The waiting time of the on-demand type individual communication 11 is the same as the individual communication 11
When the broadcast 12 is completely separated, the waiting time is the longest, and the higher the ratio of the individual communication 11, the shorter the waiting time of the individual communication 11. On the contrary,
If the ratio of the individual communication 11 is lower than the ratio of the broadcast communication 12, the waiting time becomes longer, and under the condition of the line 106, even if the transmission interval PB of the broadcast communication 12 is 80 or more, the waiting time of the on-demand individual communication 11 Since the time does not decrease, it can be seen that it is difficult to ensure the reliability of the broadcast 12 under this condition. Therefore, the ratio of the broadcast communication 12 and the individual communication 11 is set to the condition of the line 107 or 108,
It is necessary to adjust the total load of the individual and the broadcasts 11 and 12 to 90% or less. Further, the transmission interval PB is changed in the same manner as in the simulation of FIG. 9 described above, and the load ratios of the broadcast data broadcast communication 12 and the on-demand individual communication 11 are set to 20% and 70%, respectively. When the ratio is adjusted to 5: 4 to be set to 40% and 40%, and to 7: 2 to be set to 70% and 20%, the simulation result of the average delay time of each on-demand individual communication 11 is the same as that of the first embodiment. Similarly,
When the total load is low, the on-demand waiting time can be shortened as the transmission interval PB is increased. Furthermore, the higher the ratio of the broadcast type broadcast communication 12 is, the shorter the on-demand waiting time is. However, the average delay time of the entire on-demand individual communication 11, that is, the waiting time is the same as when the band is separated. As a maximum, it can be reduced as the transmission interval PB increases.

FIG. 11 shows a continuous data transmission method according to the third embodiment of the present invention, in which the on-demand individual communication 11 and the broadcast data broadcasting 12 are separated from each other and mixed. FIG. 5 is a comparative diagram for comparing delay times of information communication 12; In the figure, broadcast data broadcasting 1
2 in which the load of the delay allowable time DT and the load of the on-demand individual communication 11 are changed while the load of the second communication is fixed.
2, a line 110 for setting the load of the on-demand individual communication 11 to 10%, a line 111 for setting 20%, a line 112 for setting 30%, and a line 11 for setting 40%.
The relative delay time of continuous broadcast 12 is shown by lines 114, which are 3 and 50%. When the broadcast 12 is transmitted in continuous batch input units, the standby time of the continuous broadcast 12 can be reduced as the load of the individual communication 11 is reduced, and the transmission interval PB of the broadcast 12 is set to 6 frames. If the time is longer than this, the waiting time of the continuous broadcast communication 12 becomes significantly longer. For this reason, it is difficult to ensure the reliability of the broadcast communication 12. Therefore, by changing the ratio of the broadcast communication 12 and the individual communication 11 to the condition of the line 113 or 114, or adjusting the total load of the individual and the broadcast communication 11 and 12 to 50% or less, the broadcast communication is performed. 12, the response time of the individual communication 11 can be shortened.

According to the third embodiment, by increasing or decreasing the length of the transmission cycle, the waiting time of the individual communication 11 and the broadcast communication 12 can be adjusted to an optimum value. Output channel load and individual communication 11 and broadcast 1
It can be selected from a ratio of 2.

Embodiment 4 FIG. FIG. 12 shows a data transmission method according to the fourth embodiment of the present invention, and is a block diagram showing a frame format of continuous broadcast 12. In the figure, when batch type input data is broadcast, how to divide the broadcast unit is determined by batch input 11 from the server.
8 can be composed of either a broadcast unit 120 for broadcasting by type or a broadcast unit 122 for combining different types of broadcasts.
That is, irregular information such as the above-mentioned news, traffic conditions, stock prices, etc. is collected in the broadcast data server 58, and this information is rearranged in the broadcast data server 58, and transmitted via the satellite communication control station 54 in a predetermined order. Can be output. For example, when the news information 124 and the traffic situation 126 are broadcast alternately from the server, and when the data is transmitted in the broadcast unit 120 of each type, the data can be output in page units having different data lengths. On the other hand, a broadcast unit 122 in which information is summarized
In the case of, the news information 124 and the traffic condition 126 are individually received from the server, and the news information 124 and the traffic condition 1 are received.
26 is transmitted in a united unit. With this configuration, it is possible to observe the traffic of the line channel and change the number of time slots transmitted to the output line based on the observation result. Therefore, by transmitting the information for each type of information, the continuous broadcast 12
Can be reduced, and the response of individual communication can be improved. On the other hand, by transmitting different kinds of information collectively and collectively, the broadcast 12
Of the individual communication 11 that can be transmitted during this delay time can be increased. Further, by processing the continuous batch input unit shown in FIG. 9 in the broadcast unit of FIG. 12,
The update interval of the broadcast 12 of the broadcast data can be arbitrarily set between 2 frame times and 512 frame times. The transmission amount of the broadcast data is required and sufficiently guaranteed, and the broadcast receiving terminal 62 that receives the broadcast 12 of the data broadcast sends the broadcast data to the broadcast receiving terminal 62 as soon as possible after the broadcast data is updated in the broadcast data server 58. By transmitting the broadcast data of the broadcast receiving terminal 62 and updating the broadcast data, it is possible to improve the probability that a user who refers to the broadcast data of the broadcast receiving terminal 62 can obtain the latest information. As shown in FIG.
% To 40%, the broadcast data broadcast 12
Broadcasting can be performed on average faster than separating bands. In the present embodiment, the unit of the broadcast data collection of the broadcast 12 is not necessarily uniform, and it is needless to say that the unit may vary depending on the type of data to be collected. For example, when a large amount of broadcast data is input collectively at a certain timing, the transmission interval PB can be lengthened, and a small amount of broadcast data can be input collectively at another timing. Broadcasting of broadcast data 1
2 and the nature of the on-demand individual communication 11, the on-demand wait time reduction is more important than the broadcast data delay reduction, and a plurality of types of broadcast data are sequentially transmitted as shown in FIG. In this way, the broadcast data collection unit can be further collected, and the waiting time of the on-demand individual communication 11 as shown in FIG. 9 or 10 can be reduced. At this time, the load of the on-demand individual communication 11 is observed, and the optimum value of the unit of collection can be selected by comparing with the previously measured effect of reducing the waiting time of the on-demand individual communication 11.

Embodiment 5 FIG. Embodiments 1 and 2 above
Then, the transmitting station that mixes the broadcast data is transmitted to the satellite communication control station 5.
4 shows a method of directly transmitting communication data using the receiving station as the data reference requesting terminal 60 and the broadcast receiving terminal 62. However, the communication data is transmitted via a wired or wireless network 128 as shown in FIG. be able to. In the figure, the network 128 is connected to the transmitting station 13.
0, receiving station 132, relay stations 134, 135, queue buffer 136 of relay station, relay lines 138, 140, and 14
2 to transmit a mixed communication of the continuous communication 12 of the continuous data and the individual communication 11 of the on-demand data. The mixed communication data is transmitted to the transmitting station 130 and the receiving station 1
The transmission can be performed through the relay stations 134 and 135 located between 32, and the same quality as that of the satellite communication system described above can be guaranteed. Also, the broadcast 12 of continuous data is transmitted from the transmitting station 130 to the receiving station 132 by the relay station 13.
4, 135, the relay stations 134, 1
35 and the relay stations 138 and 14 corresponding to the capacity of the queue buffer 136 attached to each of the receiving stations 132.
0 and 142 can be defined. When each of the delay allowable times DT is t1 for the relay line 138, t2 for the relay line 140, and t3 for the relay line 142, the total allowable delay time DT determined from various conditions of the network 128 can be Tmax. That is, the total allowable delay time DT of the network 128 is Tmax ≧ t
When the relationship of 1 + t2 + t3 is satisfied and the allowable delay time of each relay line is set to t1, t2, t3, Tmax <t1
+ T2 + t3 must be satisfied. Under these conditions, each of the trunk lines 138, 140, and 1 is set according to the status of each trunk line.
The allowable delay time of 42 can be set to t11, t22, and t33. However, t11 ≦ t1, t22 ≦ t
2. It is necessary to satisfy the relations of t33 ≦ t3 and t11 + t22 + t33 <Tmax.

If the on-demand individual communication 11 and the broadcast communication 12 are mixed in accordance with the flowchart of FIG. 2 or 7 in consideration of the ability value of the data communication of the network 128, the on-demand individual communication is performed. Can be efficiently reduced.

FIG. 14 is a block diagram of a satellite communication control station 144 applied to the data transmission apparatus according to the fifth embodiment of the present invention. In the figure, a satellite communication control station 144 is connected to a data server 56 and a broadcast data server 58, and stores a first queue buffer 148 for storing continuous broadcast communication 12 until a predetermined period elapses, and an individual communication 11 The second queue buffer 150 to be accumulated and the individual communication 1 accumulated in the second queue buffer 150 until a predetermined period elapses.
And a frame format controller 152 for transmitting the broadcast 12 stored in the first queue buffer 148 to the antenna 146 after a predetermined period of time has passed. , An individual communication 11 from the broadcast data server 58, and a mixture of the individual communication and the broadcast communication to the satellite communication antenna 146. Further, the frame format control device 152 transmits the broadcast 1 to the page areas 154 to 156 in the first queue buffer 148.
2 can be stored in page units, and by receiving control signals from taps 157, 158, and 159 attached to each page, the page storage state of the first queue buffer 148 can be determined. . The second queue buffer 150 can also receive and accumulate the individual communication 11 in page units.
Data can be input / output via the IFO. The second
The queue buffer 150 receives the control signal 160 based on the number of pages of the broadcast 12 determined by the frame format control device 152 and transmits the individual communication 11 to the time slot insertion device 161 by an open drain output. it can. Also, the second queue buffer 150 can report the incoming of the individual communication 11 to the frame format control device 152 through the control signal 162, and in response to this report, the frame format control device 152 The priority of the communication 11 and the broadcasting 12 can be controlled.

Further, the frame format control device 1
52 counts the output delay time while judging the accumulation state of the broadcast 12, outputs a control signal 163 when a predetermined period has elapsed, and outputs a control signal 163 from the first queue buffer 148 to the time slot input device. 161 can output the broadcast communication 12.

In the above embodiment, the mixed transmission of the continuous broadcast 12 and the on-demand individual communication 11 of the satellite broadcast exclusively by the communication satellite 52 has been described. However, in other regions, office premises, buildings and the like. It goes without saying that the same effect can be obtained also in the application example of broadcasting and individual communication in each covered area such as a room. For example, when performing data transmission on the network 166 as shown in FIG.
The data server 56 communicates with the broadcast data network 170, the facsimile network 171 and the carrier network 1 through the communication control device 168.
72, the international communication network 173, the mobile communication network 174, and the telephone network 175, the individual communication 11 and the broadcast communication 12 can be mixed among the communication terminals to perform data transmission through a single communication channel. In addition, the present invention can be applied to on-demand video distribution and data transmission to limited members, such as a remote video conference, in addition to the continuous broadcast communication 12 such as the illustrated broadcast. In addition, video
In addition to audio multimedia information transmission and data broadcasting,
The data transmission device of the present invention can also be applied to applications such as contact data for transmitting a fixed amount of data within a unit period and file updating.

[0038]

Since the present invention is configured as described above, it has the following effects.

The response time of the individual communication can be shortened by inputting the individual communication to the output line within a predetermined period prior to the broadcast communication. , The broadcast can be prevented from being interrupted.

In addition, by judging whether or not a desired broadcast communication can be transmitted within a predetermined transmission cycle, the individual communication is preferentially transmitted, whereby the individual communication can be performed while ensuring the reliability of the broadcast communication. Response time can be shortened.

Further, since the length of the transmission cycle is increased or decreased, the waiting time between the broadcast communication and the individual communication can be shortened.

Since the number of time slots for broadcast communication is made variable while observing data traffic, it is possible to obtain a waiting time for individual communication adapted to the amount of data transmission.

Further, since the queue buffers for storing the broadcast communication and the individual communication are provided, the individual communication can be preferentially transmitted while measuring the delay time of the broadcast communication.
The waiting time for individual communication can be reduced while securing the communication volume of broadcast communication.

[Brief description of the drawings]

FIG. 1 is a block diagram of a data transmission system according to a first embodiment of the present invention.

FIG. 2 is a flowchart of data transmission according to the first embodiment of the present invention.

FIG. 3 is a block diagram of a frame format according to the first embodiment of the present invention.

FIG. 4 is a control chart for comparing waiting times according to the first embodiment of the present invention;

FIG. 5 is a control chart for comparing waiting times according to the first embodiment of the present invention;

FIG. 6 is a control chart for comparing delay times according to the first embodiment of the present invention;

FIG. 7 is a flowchart of data transmission according to the second embodiment of the present invention.

FIG. 8 is a block diagram of a frame format according to a third embodiment of the present invention.

FIG. 9 is a control chart for comparing waiting times according to the third embodiment of the present invention.

FIG. 10 is a control chart for comparing waiting times according to the third embodiment of the present invention.

FIG. 11 is a comparative diagram comparing delay times according to the third embodiment of the present invention.

FIG. 12 is a block diagram of a frame format according to a fourth embodiment of the present invention.

FIG. 13 is a block diagram of a network according to a fifth embodiment of the present invention.

FIG. 14 is a block diagram of a data transmission device according to a fifth embodiment of the present invention.

FIG. 15 is a block diagram of a network showing another embodiment of the present invention.

FIG. 16 is a block diagram of a conventional satellite communication system.

FIG. 17 is a block diagram of a conventional band separation frame format.

FIG. 18 is a block diagram of a conventional satellite communication system.

FIG. 19 is a conventional time sequence diagram.

[Explanation of symbols]

11 individual communication, 12 broadcast communication, 13 empty slot,
52 communication satellite, 54 satellite communication control station, 56 data server, 58 broadcast data server, 60 data reference request terminal, 62 broadcast receiving terminal, 64 satellite channel,
146 antennas, 148 first queue buffer, 15
0 second queue buffer, 152 frame format control device, 161 time slot input device.

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) H04L 12/18 H04B 7/15 H04H 1/00

Claims (5)

(57) [Claims] 1. A data transmission method in which continuous broadcast communication and on-demand individual communication are mixed and transmitted on the same output line, wherein a time-division broadcast request is delayed until a predetermined period elapses. When an individual communication request is made during the predetermined period, the individual communication is preferentially input to an output line of a predetermined band, and after the predetermined period has elapsed, the delayed broadcast communication is output to the output line. A data transmission method characterized by inputting and transmitting. 2. A data transmission method in which continuous broadcast communication and on-demand individual communication are mixed and transmitted on the same output line, wherein a plurality of time-division broadcasts are divided within a predetermined transmission cycle. A data transmission method comprising: determining whether a time slot can be transmitted; and prioritizing individual communication based on a result of the determination to transmit to an output line. 3. The data transmission method according to claim 2, wherein the length of the transmission cycle is increased or decreased. 4. The method according to claim 2, wherein a traffic state of the output line is observed, and the number of timeslots of broadcast transmitted to the output line within the transmission cycle is changed based on the observation result. Data transmission method as described. 5. A data transmission apparatus for transmitting continuous broadcast communication and on-demand individual communication in a mixed manner on the same output line, wherein the data transmission apparatus stores continuous broadcast communication until a predetermined period elapses. A first queue buffer, a second queue buffer for storing the individual communication, and the individual communication stored in the second queue buffer being transmitted to the output line with priority until the predetermined period elapses. A data transmission device, comprising: a frame format control device that transmits a broadcast stored in the first queue buffer to the output line after a predetermined period has elapsed.