JP3420006B2 - Data transmission device and communication system using the same - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data transmission device equipped or connected to a terminal or the like and transmitting data from the terminal to a communication network, and a communication system using the same.

[0002]

2. Description of the Related Art In order to transmit data from a terminal or the like to a communication network, it is necessary to transmit data from a data transmission device in a format that can be received by a receiver provided in the communication network. Since receivers included in a communication network have various physical and electrical specifications, data transmitters with various specifications corresponding to those receivers are used.

As shown in FIG. 14, a conventional data transmitting apparatus includes a receiver 141 for receiving data from a terminal and a buffer 1 for temporarily holding data to be transmitted to a communication network.
42 and a transmitter 143 that transmits data in a format that can be received by a receiver included in the communication network.

In the data transmission device 144 configured as shown in FIG. 14, when the receiver 141 receives data from a terminal or the like, the data is temporarily held in the buffer 142 and a communication path for transmitting to the communication network is available. During this time, the received data is sent from the transmitter 143.

In many cases, a data transmitting apparatus equipped with or connected to a portable terminal uses a wireless line as a line with a communication network and a battery as a power source so as not to impair the mobility of the terminal. In such a data transmission device, in order to prevent waste of power supply power, a method of turning on the power of the transmitter only when there is data to be transmitted and turning off the power of the transmitter at other times is used.

However, in actuality, from the state in which data is not transmitted, that is, the state in which power consumption is low, the operation of each unit such as the radio unit of the transmitter is started so that the data can be transmitted, and then the data is transmitted. Therefore, in addition to the power required for data transmission, extra power is consumed when the transmitter such as the wireless unit is started up and shut down.

In particular, as shown in FIG. 4 (a), when data 1, data 2, ... Are intermittently repeatedly sent from the terminal, many pieces of data are fragmented and the radio section There is a problem in that power is wasted because the proportion of the start-up and shut-down parts of the equal transmission section is large.

[0008]

DISCLOSURE OF THE INVENTION The present invention has been made in view of the fact that power is wasted because the ratio of start-up and shut-down of a transmitting section such as a radio section is large as described above. It intended, and an object thereof is to provide a data transmission equipment to perform data transmission with low power consumption.

[0009]

SUMMARY OF THE INVENTION A data transmitting apparatus of the present invention is a buffer device for temporarily holding data to be transmitted.
And the data stored in this buffer means.
It is determined by the transmission means to be trusted and the agreement of communication conditions.
The buffer means depending on the allowable delay time.
Data retention means and delay allowed
Retention time of any of the data in the buffer means
When the time determined by the means has elapsed, the bag is
All data to be transmitted held by the fur means
Control means for controlling the transmission from the transmission means
Characterized by comprising.

Here, when the holding state of the delay-allowed data in the buffer means exceeds the predetermined limit state, for example, when the delay-allowable data is held in the buffer means by a predetermined amount or more. , Or when the holding time of any of the data whose delay is allowed in the buffer means has passed a predetermined time.

With such a configuration, data transmission can be performed with low power consumption. Further, in determining the limit value of the holding time of the buffer device for the data to which the delay is allowed, it is determined according to the allowable delay time defined by the agreement of the communication conditions, or is given to each of the data to be transmitted. It is also possible to detect the allowed delay time taken and to determine accordingly.

With such a configuration, it is possible to perform data transmission with reduced power consumption while maintaining the quality of service in a desired state. In addition, a communication system can be configured using this data transmission device, but in particular,
If the data transmission device and the terminal connected to the data transmission device are housed in the same housing and the transmission from the data transmission device to the communication network is performed via a wireless line, the portable terminal device is It is possible to reduce the capacity of the battery used as the power source of the portable terminal device.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following figures, the same parts or corresponding parts are designated by the same reference numerals. (First Embodiment) FIG. 1 shows the configuration of a communication system according to the first embodiment of the present invention. The terminal 1 is, for example, a data processing terminal having an input / output device and processing data. The terminal 1 is connected to the data transmitting device 2, and the data transmitting device 2 is connected to the communication network 3. In this case, terminal 1
The data transmission device 2 and the data transmission device 2 may be connected to each other via a mechanism such as a connector that can be electrically connected, or may be connected to each other via a wired transmission path to perform data transmission. Further, the terminal 1 and the data transmission device 2 may be provided in the same housing, and the transmission between the data transmission device 2 and the communication network 3 may be configured to use wireless transmission. In such a case, the portability and portability of the terminal 1 and the data transmission device 2 can be realized, and the terminal 1 and the data transmission device 2 can be used as a mobile terminal device.

Here, the data transmission device 2 includes a receiver 21 for receiving data from the terminal 1 and a buffer 22 for temporarily holding the data received by the receiver 21 and to be transmitted to the communication network. , A transmission determination means 23 for determining whether or not to transmit the data held in the buffer 22 to a communication network, and a data amount threshold value for holding a predetermined data amount threshold value used in the determination by the transmission determination means 23. The holding unit 24 and the transmitter 25 that transmits the data determined to be transmitted by the transmission determining unit 23 in a format that can be received by the receiver included in the communication network 3.

Next, this operation will be described with reference to the flow chart shown in FIG. 2 and the timing chart shown in FIG. FIG. 2 is a flowchart showing the operation of the data transmission device 2, and the data transmission device 2 waits for data transmission from the terminal 1 (step ST21). When the data is transmitted from the terminal 1, this data is received by the receiver 21, and the received data is sent to the buffer 22 and held in the buffer 22 (step ST22). At this time,
The transmission judging means 23 compares the data amount in the buffer 22 with the threshold value read from the threshold value holding means 24 (step ST23), and if it is smaller than the threshold value, returns to the standby state (step ST21) as it is, but if it is more than the threshold value, the buffer All the data to be transmitted, which is held therein, is read out and sent to the transmitter 25 (step ST24) to start transmission, and returns to the standby state (step ST21).

Therefore, as shown in FIG. 3 (a), the data transmitter 2 transmits the data 1 to 5 sent from the terminal 1,
When the receiver 21 receives intermittently and sequentially, these data are temporarily stored and held in the buffer 22. FIG. 3B shows a change state of the amount of data to be transmitted, which is held in the buffer 22. The transmission determination means 23 is the communication network 3 held in the buffer 22.
Since it is determined that the transmission is not performed while the amount of data to be transmitted to the threshold value holding unit 24 is smaller than the threshold value read from the threshold value holding unit 24, the transmission is not performed at the stage of receiving the data 1 to 3. When the data 4 is received, the amount of data combined with the data received so far exceeds the threshold value read from the threshold value holding means 24. Therefore, the transmission determination means 23 determines that the transmission should be performed, and is stored in the buffer 22. All the stored data, that is, the data 1 to 4 are read out, and those data are supplied to the transmitter 25. The transmitter 25 transmits the data in a format that can be received by a receiver (not shown) provided in the communication network 3 at a timing as shown in FIG. 3C.

As described above, when the data transmitted from the terminal 1 and received by the data transmission device 2 is once held in the buffer 22 and is transmitted when the data amount exceeds a certain amount,
As shown in (b) of FIG. 4, from a state in which data is not transmitted, that is, a state in which power consumption is low, the operation of each unit such as the wireless unit of the transmitter 25 is started so that data can be transmitted, and then the data is transmitted. By sending 1 to 4 together,
A transmitter 2 such as a radio unit required to send these data
It is possible to reduce the number of times of starting and stopping 5 and to transmit the data 1 to 4 with less power consumption as compared with the conventional method of transmitting as shown in FIG. Therefore, particularly when the terminal 1 and the data transmitting device 2 are mobile terminal devices, the capacity of the battery used as a power source can be reduced, which is effective for downsizing the mobile terminal device.

(Second Embodiment) FIG. 5 shows the configuration of a communication system according to a second embodiment of the present invention. Also in this embodiment, as in the first embodiment shown in FIG. 1, the terminal 1, the data transmission device 2, and the communication network 3 may be connected to each other in the same manner as in the first embodiment, but As the configuration of the transmission device 2, the data amount threshold value holding means 2 of FIG.
Instead of 4, an allowable storage time holding means 51 and a timer means 52 for holding a predetermined allowable storage time, which is used for the judgment by the transmission judging means, are provided.

Next, this operation will be described with reference to the flow chart shown in FIG. 6 and the timing chart shown in FIG. FIG. 6 is a flowchart showing the operation of the data transmission device 2, and the data transmission device 2 waits for data transmission from the terminal 1 (step ST61). When the data is received from the terminal 1, this data is held in the buffer 22 (step ST62). At this time,
It is judged whether or not this data is held in the buffer which has been empty until now (step ST
63) If the buffer is held in the empty state, the transmission judging means 23 reads the allowable storage time from the allowable storage time holding means and sends it to the timer means 52. The timer means 52 sets the permissible storage time, starts the operation (step ST64), and determines whether the next permissible storage time has elapsed (step ST6).
Proceed to 5). On the other hand, when holding the received data in the buffer, if the data already held in the buffer exists, the timer means is already in operation, and therefore, a step of whether or not the allowable accumulation time has elapsed (step ST65) Proceed to. When the allowable storage time has not elapsed, the process returns to the step of determining whether or not data has been received from the terminal (step ST61). When the data is received, the step of holding it in the buffer 22 (step ST6
If it has not been received, the process proceeds to step (step ST65) of whether or not the count value of the timer means has passed the allowable accumulation time. When such an operation is repeated and the allowable storage time has elapsed, the timer means 52
Sends a transmission request signal to the transmission determining means 23 and ends the operation. Based on this transmission request signal, the transmission judging means 23 reads all the data to be transmitted held in the buffer 22 and sends it to the transmitter 25 to start transmission (step ST66).

Therefore, as shown in FIG. 7A, when the data transmitter 2 sequentially receives the data 1 to 5 sent from the terminal 1, these data are temporarily stored in the buffer 22. At the time of receiving, the allowable storage time is read from the allowable storage time holding means 51, this is set in the timer means 52, and the operation of the timer means 52 is started. Then, when the allowable accumulation time has elapsed, the transmission determination means 2 is generated by the transmission request signal from the timer means 52.
3 reads all the data to be transmitted held in the buffer 22, that is, the data 1 to 4 and sends them to the transmitter 25. The transmitter 25 transmits those data at a timing as shown in FIG. 7B in a format that can be received by a receiver (not shown) provided in the communication network 3.

In this way, the data sent from the terminal 1 and received by the data transmission device 2 is temporarily held in the buffer 22, and when the allowable storage time of the data has elapsed, the data received up to then are collectively and continuously transmitted. Then, similarly to the case shown in FIG. 4B, a state in which the operation of each unit such as the wireless unit of the transmitter 25 is started from a state in which no data is transmitted, that is, a state in which power consumption is low, and data can be transmitted. And then send the data 1 to 4 all at once,
A transmitter 2 such as a radio unit required to send these data
It is possible to reduce the number of times of starting and stopping of the data 5 and it is possible to transmit the data 1 to 4 with less power as compared with the conventional method of transmitting as shown in FIG.

Furthermore, even if the time required to hold a certain amount of data in the buffer becomes long due to the fact that the data transmission device 2 receives data less frequently, etc. Since the data can be transmitted without being held for more than the accumulation time, the maximum delay time can be guaranteed.

In the above description, the data transmission device 2
In the configuration, instead of the data amount threshold value holding means 24,
Although the allowable storage time holding means 51 and the timer means 52 are used, the data amount threshold value holding means 24, the allowable storage time holding means 51, and the timer means 52 are all provided, and the data transmission device 2 is configured as shown in FIG. The operations shown in FIG. 6 may be performed in parallel. In this case, when the transmission of all the data held in the buffer 22 is started by one of the two operations (step ST
24 or step ST66), both operations return to the initial state (step ST21 and step ST61) and restart the operation.

(Third Embodiment) FIG. 8 shows an outline of the configuration of a communication system according to the third embodiment of the present invention, and FIG. 9 shows the configuration of a part of the data transmission device 2. In FIG. 8, a communication network 3 is a wired communication network having a node 1 such as a gateway and a node 2 such as a wireless base station. The server device 4 is connected to the node 1 via a wired transmission line, and the node 2 is connected to the data transmission device 2 of a mobile terminal device including the terminal 1 and the data transmission device 2 via a wireless transmission line. ing. Therefore, the terminal 1 can communicate with the server device 4. The data transmission device 2 in FIG.
In addition to the configuration of the data transmission device 2 in the second embodiment shown in FIG. 3, a message processing unit 91 for transmitting and receiving information for detecting the maximum value of the delay time required from the reception of data to the transmission thereof is provided. . Further, the data transmission device 2 of FIG. 9 has not only the function of transmitting the data received from the terminal 1 to the node 2 of the communication network 3, but also the node 2 of the communication network 3.
Since it also has a function of transmitting the data received from the terminal 1 to the terminal 1, a first transceiver having a function of receiving data from the node 2 of the communication network 3 corresponding to the transmitter 25 of FIG. 25A, which corresponds to the receiver 21 in FIG. 5 and is the second transceiver 21A which also has a function of transmitting data to the terminal 1. In this way, the data transmission device 2 has a data transmission / reception function between the terminal 1 and the node 2 of the communication network 3, so that the data transmission device 2 can be used for exchanging messages between the terminal 1 and the server device 4. Can be done through.

Next, this operation will be described. FIG. 10 shows a procedure when the terminal 1 communicates with the server device 4, and the communication between the server device 4 and the data transmission device is performed by the node 1
And via node 2. When the terminal 1 wants to receive a service using communication from the server device 4 connected to the communication network 3, a service describing the content of the service to be received and the quality of the service (quality regarding delay, data error, etc.) The request message 101 is transmitted to the server device 4 via the data transmission device 2, the node 2 and the node 1. The server device 4 requests the node 1, the node 2, and the data transmission device 2 from the request condition message 102 regarding the request condition regarding the delay of the transmission data from the terminal, which is necessary for providing the service requested by the terminal 1. Tell terminal 1 via. When the terminal 1 decides to receive the service under these conditions, the terminal 1 transmits an approval message 103 indicating that the service has been approved to the server device 4 via the data transmission device 2, the node 2, and the node 1.

When the server 4 determines the delay time of the data allowed to provide the service to the terminal 1, the server 1, the node 1, the node 2 and the data transmitter 2 of the communication network 3 receive the terminal at the delay time. 1 is inquired as to whether communication is possible between the server device 4 and the server device 4, for example, using the delay time request message 104 in the format shown in FIG. In each node and the data transmission device 2, the delay time request message 104 is sequentially transmitted from the node to which the server is connected to the data transmission device 2.

This delay time request message is shown in FIG.
As shown in FIG. 4, a method of explicitly specifying a node and a data transmission device through which communication is performed between the server device 4 and the terminal 1, and a data transmission device (or connected to the destination terminal) There is a method in which the routing is left to each node only by specifying the data terminal device). Figure 1
1, the destination address (address of the data transmission device 2) is written in the field 111, and the transmission source address (address of the server device 4) is written in the field 112. The first via address (address of node 1) and the second via address (address of node 2) are written in fields 113 and 114, respectively. Field 115
Indicates the type of message (whether it is a delay time request message or not). In the field 116, the time (time stamp) when this message is transmitted from the server device 4, the node 1, and the node 2, respectively is described. A field 117 is a delay time field, and is a field in which the maximum delay time (Td) required for data transmission to the node (or data transmission device) at the time of communication is recorded. Further, in the fields 118 and 119, the delay time allowed for the communication is set to the server device 4
The direction from the terminal 1 to the terminal 1 (downward direction) and the direction from the terminal 1 to the server device 4 (upward direction) are respectively described.

When each node receives the delay time request message 104 sent from the server device, the maximum value of the time required for data transmission processing in that node, and
The time required to transmit data to the next node (determined from the transmission rate of the transmitter) or the time required to transmit data from the previous node (timestamp added to the message (marked in field 116) ) Or the like) is added to the value written in the delay time field 117, this value is newly written in the delay time field 117, and transmitted to the next node.

The operation when the data transmission device 2 receives the delay time request message 104 thus transmitted will be described with reference to the flowchart shown in FIG.
When the transceiver 25A receives the delay time request message 104 (step ST121), this message 104
Is sent to the message processing means 91. In the message processing means 91, the value (Td) written in the delay time field 117 of the delay time request message 104 is read (step ST122), and the maximum time required for data processing in the data transmission device 2 is set to this value. Value (Tp)
And the time (Tt) required to transmit data from the terminal 1 to the data transmitter 2 (this time (Tt) is obtained from the transmission speed of the terminal 1, and this information is obtained from the transceiver 21) is added. (Step ST123), the value (Td + Tp + Tt) is written in the delay time field 117 (step ST124).

Next, in the message processing means, the value (Td + Tp) written in the delay time field 117 is written.
+ Tt) is within the delay time allowed for the communication. That is, the value is the allowable delay time (Tdown) in the direction from the server device 4 to the terminal 1, which is described in the fields 118 and 119 of the delay time request message 104, and the allowable delay time in the direction from the terminal 1 to the server device 4. It is determined whether or not the respective delay times (Tup) are smaller (steps ST125 and ST126).
When it is smaller than any of the values, the value (Tup− (Td + Tp + Tt)) obtained by subtracting the value (Td + Tp + Tt) written in the delay time field 117 from the allowable delay time (Tup) in the direction from the terminal 1 to the server device 4 is used as the data. The allowable storage time in the transmitter is set, and this value is set in the allowable storage time holding means 51 (step ST127).
As indicated by 0, the fact that communication is possible is noted in the delay time response message 105 and transmitted from the transceiver 25A to the server device (step ST128). The value (Td + Tp + Tt) written in the delay time field 117 is the delay time allowed for the communication, that is, the direction from the server device 4 to the terminal 1 described in the fields 118 and 119 of the delay time request message 104. Of the delay time (Tdown) and the allowable delay time (Tup) in the direction from the terminal 1 to the server device 4 are greater than at least one of the values (Td + Tp + Tt) written in the delay time field 117. ) And the fact that communication is not possible are noted in the delay time response message 105 and transmitted from the transceiver 25A to the server device (step ST129).

A delay time response message 10 sent from the data transmission device 2 indicating that communication is possible
When the server device 4 receives 5, the service is started from the server device 4 to the terminal 1 (10 in FIG. 10).
6). When the terminal 1 transmits data to the server device 4 via the data transmission device 2 after the service is started,
In the same manner as the operation described in the second embodiment, data from the terminal 1 is sequentially held in the buffer 22 until the allowable storage time elapses (107 in FIG. 10), and after the allowable storage time elapses. The held data 108 is collectively transmitted to the server device 4 via the nodes 1 and 2.

At this time, when there is a plurality of delay times allowed for communication, such as when the terminal 1 equipped with or connected to the data transmission device 2 simultaneously receives a service using a plurality of communication, By equipping each of the buffer 22, the allowable storage time holding means 51, and the timer means 52 of the data transmission device 2, the transmission timing can be determined for each delay time allowed for each communication.

As described above, based on the delay time allowed when communication is performed between the terminal equipped with or connected to the data transmission device and the server device or the like with which the terminal communicates. By setting the allowable storage time for holding data in the data transmission device, data transmission with reduced power consumption in the data transmission device while maintaining the quality of service using communication between the terminal and the server device It can be performed.

(Fourth Embodiment) FIG. 13 shows a fourth embodiment of the present invention.
2 shows a configuration of a data transmission device 2 in the communication system according to the exemplary embodiment. The overall configuration of the communication system is
It is similar to that shown in FIG. The data transmission device 2 in this embodiment is basically the second transmission device shown in FIG.
In addition to the configuration of the data transmission device 2 in the embodiment of
Permissible delay time detection means 131 for detecting the permissible delay time added to the data received from the terminal 1.
It is equipped with.

Next, this operation will be described. Here, in addition to the configuration shown in FIG. 13, the data transmission device performs the same operations from the reception of data to the transmission as in the case of the third embodiment. A case will be described in which a message processing unit that transmits and receives information for detecting the maximum value of the delay time required for is provided.

When the terminal 1 wants to receive a service using communication from the server device 4 connected to the communication network 3, by exchanging between the terminal 1 and the server device 4,
In the same manner as in the above embodiment, the data transmission device 2 uses the value written in the delay time field of the received delay time request message to transmit data between the server device 4 and the data transmission device 2. Maximum time required (T
You can know d). Next, in the data transmission device 2,
The maximum value (Tp) of the time required for data processing in the data transmitter 2 and the data transmitted from the terminal 1 to the data transmitter 2 are added to the value (Td) written in the delay time field of the delay time request message. Time (Tt) required for writing, the value (Td + Tp + Tt) is written in the delay time field, and it is returned to the server device 4 as a delay time response message.

The server device 4 which has received the delay time response message indicates that the value described in the delay time field is the delay time allowed for the communication, that is, the allowable delay time in the direction from the server device 4 to the terminal 1. (Tdown) and terminal 1
If it is smaller than any of the allowable delay times (Tup) from the direction to the server device 4, the service is started.

After the service is started, the terminal 1 gives the data addressed to the server device an allowable delay time of the data and transmits the data to the data transmission device 2. In the data transmission device 2, when the receiver 21 receives the data from the terminal 1, the data is held in the buffer 22, and the allowable delay time detecting means 121 adds the allowable delay time (Tup) to the data. ) Read. This value (Tu
The value (Tup− (Td + Tp + Tt)) obtained by subtracting the maximum delay time (Td + Tp + Tt) required for data transmission from the terminal 1 to the server device 4 from p) is set as the allowable storage time of the data, and the allowable storage time is maintained. It is set in the means 51. After that, similarly to the operation described in the second embodiment, the data from the terminal 1 is sequentially held in the buffer 22 until the allowable storage time elapses, and is held until the allowable storage time elapses. The data is collectively transmitted to the server device 4 via the nodes 1 and 2.

At this time, when there are a plurality of delay times allowed for communication, such as when the terminal 1 equipped with or connected to the data transmission device 2 simultaneously receives a service utilizing a plurality of communication, By equipping each of the buffer 22, the allowable storage time holding means 51, and the timer means 52 of the data transmission device 2, the transmission timing can be determined for each delay time allowed for each communication.

Next, another procedure for setting the allowable storage time holding means 51 by the data transmitting apparatus 2 in FIG. 13 will be described. When the terminal 1 equipped with or connected to the data transmission device 2 is communicating with a wired terminal or the like connected to the communication network, the data transmitted from the terminal 1 is the delay time allowed by the content of the data. May be different.
For example, when the data transmitted from the terminal 1 is data carrying voice call information or data carrying document file information, it is necessary to send the voice call information to the communication partner without delay. In some cases, the information may be slightly delayed. In such a case, the data transmission device 2 needs to set a deadline for holding the data in the buffer so that the data reaches the communication partner within the allowable delay time.

Therefore, the data transmission device 2 detects the maximum value (Td) of the delay time required for transmitting data between the communication partner and the data transmission device 2 by using the above-described method or the like. And every time it receives data from the terminal 1,
At the same time that the data is held in the buffer 22, the permissible delay time detecting means 131 reads the permissible delay time (Tup) given to the data. A value (Tup- (Td + Tp + Tt)) obtained by subtracting the maximum delay time (Td + Tp + Tt) required for data transmission from the terminal 1 to the communication partner from this value (Tup) is set as the allowable storage time of the data It is set in the time holding means 51. Then, this value is sent to the transmission determining means 23. The transmission judging means 23 compares the value of this allowable storage time with the value indicated by the timer means 52 at that time, and when the value indicated by the timer means 52 is smaller (than the holding time limit of the data held now) , The timer operation is continued as it is when the holding time of the data already held comes earlier, but the value indicated by the timer means 52 is higher than the value of the allowable storage time of the data. When the data is large, the retention date of the data
(When it comes earlier than the retention period of the data already held), the value of the allowable storage time of the data is sent to the timer means 52 to set the allowable storage time to the timer means 52, and this setting The timer means 52 carries out the subsequent operation according to the value, but the operation is continued (each time the data from the terminal 1 is received, the value of the allowable storage time is compared with the value indicated by the timer means 52 at that time. However, except that the timer means 52 is reset when the value indicated by the timer means 52 is larger than the value of the allowable storage time of the data), it is the same as the case of the second embodiment. .

As described above, according to the fourth embodiment, the data transmission device has the internal delay based on the allowable delay time given to the data transmitted by the terminal equipped with or connected to the data transmission device. By setting the permissible storage time for holding the data, the data transmission with reduced power consumption in the data transmission device can be performed while maintaining the quality of service according to the content of each data.

[0043]

According to the present invention, data transmission with reduced power consumption can be performed. Furthermore, in the case of a portable terminal device in which the data transmission device and the terminal connected thereto are housed in the same housing, and transmission from the data transmission device to the communication network is performed via a wireless line, Since the capacity of the battery used as the power source of the portable terminal device can be reduced, it is effective for downsizing the portable terminal device.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a communication system according to a first embodiment of the present invention.

FIG. 2 is a flowchart showing an operation of the data transmission device according to the first embodiment.

FIG. 3 is a timing chart for explaining the operation of the data transmission device according to the first embodiment.

FIG. 4 is an explanatory diagram showing a comparison of the start-up and shut-down times of the transmitter in the conventional method and the embodiment of the present invention.

FIG. 5 is a block diagram showing a configuration of a communication system according to a second embodiment of the present invention.

FIG. 6 is a flowchart showing an operation of the data transmission device according to the second embodiment.

FIG. 7 is a timing chart for explaining the operation of the data transmission device according to the second embodiment.

FIG. 8 is a block diagram showing an outline of a configuration of a communication system according to a third embodiment of the present invention.

FIG. 9 is a block diagram showing details of the configuration of a data transmission device according to a third embodiment.

FIG. 10 is a sequence diagram showing a communication procedure in the communication system according to the third embodiment.

FIG. 11 is a diagram showing a format of a delay time message used in the communication system according to the third embodiment.

FIG. 12 is a flowchart showing an operation of the data transmission device according to the third embodiment.

FIG. 13 is a block diagram showing a configuration of a data transmission device in a communication system according to a fourth embodiment of the present invention.

FIG. 14 is a block diagram showing the configuration of a conventional data transmission device.

[Explanation of symbols]

1 ... Terminal 2 ... Data transmission device 3 ... communication network 4 ... Server device 21 ... Receiver 22 ... Buffer 23 ... Transmission judging means 24 ... Data amount threshold value holding means 25 ... Transmitter 51 ... Allowable storage time holding means 52 ... Timer means 91 ... Message processing means 131 ... Allowable delay time detection means

Front page continued (72) Inventor Katsuya, Komukai-shi Toshiba Town, Kawasaki-shi, Kanagawa 1 Komukai Toshiba R & D Center Co., Ltd. (72) Inventor Eiji Kamagata, Komukai-shi Toshiba Town, Kawasaki-shi, Kanagawa Prefecture Toshiba Research and Development Center (72) Inventor Kiyoshi Toshimitsu Komukai-shi, Kawasaki-shi, Kanagawa 1 Komukai Toshiba-cho, Toshiba Research and Development Center (56) Reference JP-A-7-261869 (JP, A) Kaihei 1-220554 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) H04L 13/08 H04L 29/08 H04Q 7/38

Claims (2)

(57) [Claims] 1. A buffer means for temporarily holding data to be transmitted, a transmitting means for transmitting the data held in the buffer means, and an allowable delay time determined by an agreement of communication conditions. Means for determining the time for holding the data in the buffer means, and one of the data for which delay is allowed is held in the buffer means when the holding time in the buffer means exceeds the time determined by the means. And a control means for controlling all the data to be transmitted from the transmission means. 2. A buffer means for temporarily holding data to be transmitted, a transmitting means for transmitting the data held in the buffer means, and an allowable delay time given to each of the data to be transmitted. Detecting means for detecting
A means for determining a time for holding data in the buffer means according to the permissible delay time detected by the detection means, and a holding time of any of the data for which delay is allowed in the buffer means by the means. A data transmission device comprising: a control unit that controls all the data to be transmitted, which is held in the buffer unit, to be transmitted from the transmission unit when a predetermined time has elapsed.