JP2002368834A - Communication device and communication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a communication device that links transmission data while suppressing delay in the transmission data. SOLUTION: A protocol processing section 2 receiving transmission data 5A(a) from a host layer 3 only starts a timer and carries out no data transmission processing. When receiving succeeding transmission data 5A(b) from the host layer 3 after that, the protocol processing section 2 discriminates whether or not the timer makes counting and does nothing when the timer keeps counting. When the timer expires, the protocol processing section 2 links the transmission data 5A(a), 5A(b) having received so far, gives a header to the linked data and gives the linked data 5B(a+b) to a subordinate layer 4. If the protocol processing section 2 also receives succeeding data 5A(c) until the timer expires, the protocol processing section 2 links the transmission data 5(a), 5(b), 5(c), gives a header to the linked data and gives the resulting linked data 5B(a+b+c) to the subordinate layer 4.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication device and a communication method for linking transmission data generated from an upper layer, passing the data to a lower layer, and transmitting the data to a partner terminal.

[0002]

2. Description of the Related Art For example, ITU-T Recommendation X. In a communication device having a data connection / separation transport protocol such as that shown in H.224, etc., it is passed from an upper layer in order to transmit control data for negotiation such as various capability data and synchronization data at the time of negotiation before the start of communication. A plurality of pieces of transmission data such as control data are linked together, a header is added to the transmission data, and the header is passed to a lower layer, and the lower layer can transmit the link transmission data to a partner communication terminal via a network. As a result, the number of transmissions of transmission data from the calling terminal during negotiation is reduced, so that the number of acknowledgment data from the called terminal of the other party is also reduced, thereby shortening the time until the start of communication. It becomes possible.

[0003]

However, in the above-mentioned communication device, no specific method for connecting a plurality of pieces of transmission data passed from an upper layer has been proposed.

Accordingly, an object of the present invention is to provide a communication apparatus and a communication method capable of performing data connection while suppressing delay of transmission data.

[0005]

In order to achieve the above object, according to the present invention, there is provided a communication apparatus for concatenating transmission data generated from an upper layer, passing the data to a lower layer, and transmitting the transmission data to a partner terminal. The communication device includes a data connection control unit that controls data to be connected and passed to a lower layer.

In particular, the data connection control section is provided in a protocol processing section of a layer having a data connection function.

Further, the data connection control unit is provided separately from a protocol processing unit of a layer having a data connection function.

When the transmission data is received from the upper layer when the transmission data from the upper layer is not held, the data connection control unit activates a timer and waits until a predetermined timer value is reached. It is characterized by controlling to link the received transmission data.

[0009] Further, the predetermined timer value is set according to a response time until reception of acknowledgment data from a partner terminal for transmission data.

[0010] Further, when receiving the transmission data from the upper layer, the data connection control unit receives information indicating the presence or absence of the subsequent transmission data, and the information indicates that the subsequent data exists. Is characterized in that the received transmission data is held, and control is performed so that the transmission data is linked when the subsequent transmission data is received.

The data link control unit determines the presence or absence of subsequent transmission data based on the content of the transmission data received from the upper layer. It is characterized in that it is held and controlled so as to be linked when subsequent transmission data is received.

The data link control unit holds the transmission data when it is received from the upper layer, and determines whether or not the total size of the transmission data held each time exceeds a predetermined size. When the total size of the transmitted data exceeds a predetermined size, control is performed to link the currently held transmission data.

The data link control unit holds the transmission data when it is received from the upper layer, and determines whether or not the total size of the transmission data held each time exceeds a predetermined size. The connection of the currently held transmission data is controlled such that the total size of the transmission data does not exceed a predetermined size.

Further, the data link control unit holds the transmission data when it is received from the upper layer, and counts the number of the transmission data held each time, so that the counted number does not exceed a predetermined number. Is characterized in that the connection of the transmission data currently held is controlled.

When the transmission data is received from the upper layer when the transmission data from the upper layer is not held, the data connection control unit connects the received transmission data having a similar occurrence time to the lower layer to receive the transmission data. To the other communication device, and hold the transmission data from the upper layer until receiving the acknowledgment data from the other communication device, and hold the transmission data from the upper layer until receiving the acknowledgment data from the other communication device. If there is transmission data received from the other communication device, when the acknowledgment is received from the other communication device, the transmission data is connected and passed to the lower layer, while the transmission data received from the upper layer is received until the acknowledgment is received from the other communication device. Otherwise, when transmission data is received from the upper layer, the transmission data with a shorter occurrence time is concatenated and passed to the lower layer. Characterized in that it.

Further, the transmission data is control data transmitted at the time of negotiation before starting communication.

Further, in a communication method for connecting control data generated from an upper layer at the time of negotiation before starting communication and passing the control data to a lower layer, a communication method for connecting the control data having a short generation time and transferring the control data to a lower layer is provided. There is a feature.

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1 FIG. 1 is a configuration diagram illustrating a communication device according to a first embodiment of the present invention. In the figure, 1 is a communication terminal as a communication device of the present invention, 2 is ITU-T Recommendation X. 224, a transport layer protocol processing unit for performing data connection / separation processing according to a data connection / separation transport protocol as shown in FIG. Is a lower layer that is located below the protocol processing unit 2 and transmits and receives data, 5A to 5C are transmission data, 6A to 6C are reception data, and 7 is the data of the protocol processing unit 2 that is pre-installed in the protocol processing unit 2. It is a data link control unit that controls link separation processing. In addition,
The upper layer 3 and the lower layer 4 may be a combination of a plurality of layers defined by OSI.

Next, the operation will be described. In addition, since the communication terminal 1 starts communication with another equivalent communication terminal (not shown) via a network (network) or the like, the communication terminal 1 is connected to another communication terminal (not shown) before starting the communication. Then, a negotiation process for transmitting and receiving control data for negotiation such as various terminal capability data and synchronization data is performed, so in the following description of the operation, during the negotiation before the start of communication, the control data is transmitted and controlled as transmission data. The following describes an example of the case. This is the same in other embodiments 2 and 3.

Assuming that the communication terminal 1 is, for example, the calling side, the communication terminal 1 first performs transmission data transmission processing for negotiation. Specifically, in the communication terminal 1, since the protocol processing unit 2 has a data connection / separation function, the transmission data passed from the upper layer 3 is reduced so as to reduce the number of transmissions and receptions of transmission data and acknowledgment data from the partner terminal. 5A are concatenated, a header is added, and the data is transmitted to the lower layer 4 as transmission data 5B. Lower layer 4 is
By adding a header to the transmission data 5B, the transmission data 5C
And transmits it to another communication terminal (not shown) via the network.

On the other hand, assuming that the communication terminal 1 is, for example, the called side, the communication terminal 1 firstly communicates with the other party's calling side communication terminal.
(Not shown) to receive transmission data for negotiation. That is, in this case, the received data 6C received via the network is processed in the lower layer 4,
The header is removed and passed to the protocol processing unit 2 as received data 6B. The protocol processing unit 2 removes the header, separates the concatenated data into a plurality of received data 6A, and passes each to the upper layer 3.

FIG. 2 is a diagram showing a connection transmission sequence of the transmission data 5A. In the first embodiment, the transmission data 5A (a) and 5A which are passed from the upper
(B) is connected to the lower layer 4 as transmission data 5B (a + b) by adding a header by connecting the
Is controlled by the data connection control unit 7 so as to pass the data. By doing so, the transmission data 5A (a), 5A whose generation time is short
(B) is transferred to the lower layer 4 with a slight delay in the protocol processing unit 2.

When the transmission data 5A (c) is passed from the upper layer 3, the protocol processing unit 2 adds a header without linking the data because there is no transmission data 5A that is close in time. To the lower layer 4 immediately as transmission data 5B (c). In this way, even when there is no transmission data that is close in time, the transmission data 5A (c) is transmitted to the lower layer 4 with a slight delay in the protocol processing unit 2.
Will be passed to.

As described above, according to the first embodiment,
Since the data connection control unit 7 controls the protocol processing unit 2 so as to connect the data that is delivered in a short time in the transmission data group transmitted from the upper layer 3, the delay of the transmission data in the protocol processing unit 2 is extremely large. There is an effect that the data can be connected while preventing the data from becoming large.

In particular, the generation time of transmission data, which is used as a reference when linking transmission data, is determined based on various requirements such as the delay time of transmission data transmitted from the communication apparatus 1 to the partner communication terminal and the allowable range of the delay time. If the setting is made based on the conditions to be performed, there is an effect that data connection can be performed in consideration of various required conditions such as a delay time of transmission data to the partner communication terminal.

When the data link control by the data link control unit 7 is used for transmitting control data exchanged with a partner terminal for a negotiation process before the start of communication, the calling side terminal at the time of the negotiation is used. Since the number of transmissions of transmission data from the other party is reduced, the number of acknowledgment data from the called terminal of the other party is also reduced, and the time until the start of communication can be greatly reduced.

Next, three examples of a method of linking transmission data having a short generation time passed from the upper layer 3 in the protocol processing unit 2 will be described. [Example Using Timer] First, an example will be described in which a timer is used in order to connect transmission data groups that have a short generation time among transmission data groups passed from the upper layer 3.

FIG. 3 is a diagram showing a connection transmission sequence of transmission data 5A when a timer is used. When the transmission data 5A (a) is passed from the upper layer 3 while the transmission data is not held from the upper layer 3, the protocol connection unit 7 of the protocol processing unit 2 A timer (not shown) is started, the transmission data 5A (a) is held, and the data transmission processing is not performed.

Thereafter, the data link control unit 7 holds the transmission data sent from the upper layer 3 until the timer reaches a predetermined timer value set in advance. FIG.
In the example, the next transmission data 5A (b) from the upper layer 3
Is passed, since the timer is still counting and has not reached the predetermined timer value, the protocol processing unit 2
Holds transmission data 5A (a) and transmission data 5A (b).

When the timer reaches a predetermined timer value set in advance and times out, the data link control unit 7 sends the transmission data passed from the upper layer 3 by the protocol processing unit 2, In the case of example 3, the transmission data 5A (a) and 5A (b) are linked, a header is added, and the data is transmitted to the lower layer 4 as the transmission data 5B (a + b). Here, if the next transmission data 5A (c) is also passed before the timer reaches a predetermined timer value set in advance, the transmission data 5A (c) is transmitted.
(A), 5A (b) and 5A (c) are concatenated, a header is added, and the data is passed to the lower layer 4 as transmission data 5B (a + b + c).

Thereafter, when the next transmission data 5A (c) is passed from the upper layer 3, the data connection control unit 7 similarly activates the timer and, when the timer times out, performs the protocol processing up to that time. If there is transmission data passed to the section 2, the transmission data 5A (c) is concatenated with the transmission data 5A (c) and passed to the lower layer 4, but if there is no other transmission data, the transmission data 5A
Only (c) is passed to the lower layer 4.

For this reason, the group of transmission data 5A passed from the upper layer 3 remains in the protocol processing unit 2 for at most the time of the timer, and is connected or transmitted alone.

As described above, according to this linking method, by controlling the linking of transmission data that is close in time using the timer, the timer is started when the first transmission data is passed from the upper layer 3. By transmitting and transmitting the transmission data group passed until the time-out, the transmission data can be connected while limiting the maximum delay time of the transmission data in the protocol processing unit 2.

The predetermined time until the timer is timed out may be determined in advance, but the predetermined time until the timer is timed out depends on the response time of arrival confirmation data from the partner terminal at the time of negotiation. It may be changed. Accordingly, even in an environment where the communication environment is poor and the transmission delay changes, there is an effect that efficient data link transmission can always be performed according to the environment.

[Use information indicating presence / absence of subsequent data
Example] Next, an example of using information indicating the presence / absence of subsequent data from the upper layer 3 in order to select a transmission data group having a similar generation time from the transmission data group passed from the upper layer 3 will be described.

FIG. 4 is a diagram showing a concatenated transmission sequence of transmission data 5A when information indicating the presence or absence of subsequent data is used. When passing the transmission data 5A (a), the upper layer 3 notifies the protocol processing unit 2 together with information indicating the presence / absence of subsequent transmission data whose occurrence time is short. Here, the information indicating the presence or absence of the subsequent transmission data is the transmission data 5
A (a) or transmission data 5A
It may be in a format passed separately from (a).

When the protocol processing unit 2 receives the transmission data 5A (a), the data connection control unit 7 determines whether there is information indicating the presence or absence of the subsequent transmission data, and indicates whether there is the subsequent transmission data. If there is information, it is possible to recognize that there is subsequent transmission data, so that the next data is passed from the upper layer 3 without transmitting the transmission data 5A (a) just received to the protocol processing unit 2. Control to wait.

Thereafter, when the next transmission data 5A (b) is passed from the upper layer 3, the data link control unit 7 similarly determines whether or not there is information indicating the presence or absence of the subsequent transmission data. If there is no information indicating the presence / absence of data, it recognizes that there is no subsequent transmission data, and connects the transmission data 5 (a) previously passed to the protocol processing unit 2 and the transmission data 5A (b) just passed. Then, control is performed so that a header is added and the data is transmitted to the lower layer 4 as transmission data 5B (a + b). Of course, at this time, if there is information indicating the presence or absence of subsequent transmission data, the transmission data 5 (a) is transmitted to the protocol processing unit 2.
And the transmission data 5A (b) just passed is held until the next transmission data comes.

Next, from the upper layer 3 to the next transmission data 5
When A (c) is passed to the protocol processing unit 2, it is similarly determined whether there is information indicating the presence or absence of subsequent transmission data. If there is no information indicating presence or absence of subsequent transmission data, there is no subsequent transmission data. Recognizing that, the protocol processing unit 2
Immediately attaches a header to the transmission data 5A (c) and passes it to the lower layer 4 as transmission data 5B (c). Of course, at this time, if there is transmission data held in the protocol processing unit 2, the data connection control unit 7
To the transmission data 5B (c). At this time, if there is information indicating the presence or absence of the subsequent transmission data, the data link control unit 7 transmits the transmission data 5A just passed to the protocol processing unit 2.
(C) is held until the next transmission data comes.

As described above, according to this linking method, when the upper layer 3 passes the transmission data to the protocol processing unit 2, the data indicating the presence or absence of the subsequent transmission data is notified to the data connection control unit 7. Since the connection control unit 7 can control the connection processing of the transmission data in the protocol processing unit 2 based on the information, the generation time can be reduced while suppressing the transmission data delay time in the protocol processing unit 2 without having a timer or the like. There is an effect that connection of transmission data close to each other can be performed.

[From the content of the transmission data,
Example of recognizing presence / absence] Next, in order to select a transmission data group transmitted from the upper layer 3 that has a shortest occurrence time,
An example in which the presence or absence of subsequent transmission data is recognized from the content of transmission data passed from the upper layer 3 will be described.

In this case, the protocol processing unit 2 recognizes the contents of the transmission data 5A passed from the upper layer 3, and
Based on the contents, it is determined whether or not there is subsequent transmission data that should be connected, that is, the transmission time is short, and if it is determined that there is subsequent transmission data to be connected, the next data is waited for connection. Here, as a specific method for judging the presence or absence of subsequent transmission data having a close occurrence time to be concatenated from the content of the transmission data, for example, the control data exchanged at the time of negotiation is performed in advance by its type, data amount, order, and the like. Since certain control data is passed as transmission data from the upper layer 3 to the protocol processing unit 2 as transmission data, the type, the data amount, the order, and the like are recognized by looking at the contents of the header and the like of the transmission data. This is because it is possible to determine whether or not there is control data that lasts for a short time.

Therefore, when the next transmission data is passed from the upper layer 3 to the protocol processing unit 2, the data connection control unit 7 checks the content of the transmission data and determines whether there is any subsequent transmission data to be connected. When it is determined that there is no subsequent transmission data to be connected, the transmission data groups passed from the upper layer 3 are connected, a header is added, and the header is added to the lower layer 4 as transmission data 5B. While passing
If it is determined that there is still subsequent transmission data to be linked, the transmission data group that has been passed from the upper layer 3 is held until the next transmission data is passed from the upper layer 3.

As described above, according to this connection method, the data connection control unit 7 analyzes the transmission data passed from the upper layer 3 to determine whether there is any subsequent transmission data to be connected, and determines whether there is any subsequent transmission data to be connected. When it is determined that the data exists, the protocol processing unit 2 is controlled to wait for the next transmission data to perform the connection processing. Therefore, the data connection is performed while the delay time of the transmission data in the protocol processing unit 2 is suppressed. There is an effect that can be performed.

Embodiment 2 In the first embodiment,
Although transmission data groups that are close in time and passed from the upper layer 3 are connected, a second embodiment in which the transmission data groups to be connected are limited will be described. The configuration of the communication apparatus according to the second embodiment is the same as that of the first embodiment shown in FIG.
Only the operation will be described with reference to FIG.

Next, the operation will be described. FIG. 5 is a diagram showing a connection transmission sequence of transmission data 5A in Embodiment 2 while restricting data to be connected. For example, if all the transmission data 5A (a) to 5A (f) groups that are close in time and passed from the upper layer 3 are to be connected and transmitted by the protocol processing unit 2 as in the first embodiment, the transmission data 5B The data size becomes large. Then, a buffer overflow occurs in the protocol processing unit 2 or the like, and even if the buffer overflow does not occur, the data size of the data transmitted from the lower layer 4 becomes too large, so that the probability of erroneous transmission increases. In addition, there arises a problem that an error equal to or more than an error-correctable bit occurs and error correction becomes impossible.

Therefore, in the second embodiment, the data connection control unit 7 controls the protocol processing unit 2 to perform data connection while limiting the data size to some extent, and the protocol processing unit 2 solves the above problem. It is characterized in that data is linked while avoiding it.

Thus, according to the second embodiment, since the data connection control unit 7 controls the protocol processing unit 2 to perform data connection while restricting the data size to some extent, the probability of an error during transmission is reduced. It is possible to prevent the occurrence of an error that is higher than the number of error-correctable bits or more, thereby enabling normal data communication.

Similarly to the case of the first embodiment, when such data link control by the data link control unit 7 is used for control data exchanged with a partner terminal for negotiation processing before starting communication. In addition, it is possible to prevent the probability of an error during the transmission of control data from being increased, and to prevent an error of more than an error-correctable bit from occurring, enabling normal negotiation and shortening the time until the start of communication. .

Next, four examples of a method of connecting data while limiting the data size to some extent will be described below.

[Example of linking when the data size of the linked data exceeds a certain size] In this case, the protocol processing unit 2 of the second embodiment sequentially transmits the transmission data 5A group passed from the upper layer 3 If the data size of the concatenated transmission data exceeds a certain size, the transmission data up to that point is concatenated, a header is added, and the data is transmitted to the lower layer 4 as transmission data 5B. The connection control unit 7 controls.

In the example of FIG. 5, the protocol processing unit 2 transmits the transmission data 5A (a),
5A (b),..., And the data link control unit 7 transmits the transmission data 5A (a), 5A (b),.
When receiving, the transmission data 5A received so far
It is determined whether or not the data size of (a), 5A (b),... Does not exceed a predetermined size.

In the example of FIG. 5, when the protocol processing unit 2 connects the transmission data 5A (d), the data connection control unit 7 receives and connects the transmission data 5A (a to 5a).
It is determined that the total data size of d) exceeds a predetermined size, the transmission data 5A (a) to 5A (d) up to that is concatenated, a header is added, and the transmission data 5B (a to d) is assigned to the lower layer 4 is passed.

Then, the subsequent transmission data 5A
(E), 5A (f), after the protocol processing unit 2 receives or connects the transmission data 5A (f), the data connection control unit 7 determines that there is no other transmission data 5A whose occurrence time is short, The protocol processing unit 2 transmits the transmission data 5
A (e) to 5A (f) are connected, a header is added, and the data is passed to the lower layer 4 as transmission data 5B (ad).

As described above, according to this concatenation method, the transmission data passed from the upper layer 3 is concatenated, and if the data exceeds a certain size, it is not further concatenated, so that the transmission data passed to the lower layer 4 is transmitted. There is an effect that the data size of data can be limited, and the transmission becomes more resistant to transmission errors and the like.

The protocol processing unit 2 transmits the transmission data 5
Of course, the data size may be measured without connecting B (ad) and the transmission data may be connected when the data size exceeds a predetermined data size.

[Example in which data size of linked data is linked so as not to exceed a certain size] Also, unlike the above-described linking method, data is linked so that the data size of linked data does not exceed a certain size. You may do it.

FIG. 6 shows that while limiting the data to be linked,
It is a figure which shows another example which shows the connection transmission sequence of transmission data 5A. For example, if the lower layer 4 has a function of dividing and assembling data, as a result of linking the data in the protocol processing unit 2, the data size becomes larger as the lower layer 4 divides the data. Since there is no meaning in linking the transmission data, the data link control unit 7 sets the protocol processing unit 2 so that the data linking unit 7 links the data within a range not exceeding the maximum size at which the lower layer 4 performs data division.
Control. Thus, efficient data transfer in consideration of the data division function of the lower layer 4 can be realized. Also,
Even when the lower layer 4 cannot transmit data of a certain data size or more, the data connection control unit 7 may control the protocol processing unit 2 to perform data connection within a range not exceeding the data size. Also, even if the concatenated data size in the protocol processing unit 2 is within the processable range of the lower layer 4, the concatenated data size in the protocol processing unit 2 is set so as not to exceed the data size receivable by the partner communication device at one time. Of course, it is good to control.

In this case, the protocol processing unit 2 sequentially adds the size of the transmission data 5A group passed from the upper layer 3, and when the added data size exceeds a certain size, the data connection control unit 7 Previous transmission data 5
The protocol processing unit 2 is controlled so as to link up to A, add a header, and pass it to the lower layer 4 as transmission data 5B.

In the example of FIG. 6, each time the protocol processing unit 2 receives the data 5A (a), 5A (b)... Sequentially, the data connection control unit 7 adds the data size.
At the time when the data size of the transmission data 5A (d) is added, if it is determined that the data size exceeds a predetermined data size that can be transmitted by the lower layer 4, the data connection control unit 7 transmits the immediately preceding transmission data. The protocol processing unit 2 is controlled so that data 5A (c) is concatenated, a header is added, and the data is passed to the lower layer 4 as transmission data 5B (ac). For this reason, the concatenated transmission data 5B (ac) passed to the lower layer 4 is smaller than the maximum size at which the lower layer 4 performs data division or the maximum data size that the lower layer 4 can transmit. Efficient data transfer in consideration of the data division function and the transmission function can be realized.

Then, the subsequent transmission data 5A (d)
If the total of the data sizes does not exceed a certain size, the protocol processing unit 2 connects under the control of the data connection control unit 7 as the transmission data 5B (d to f) and Will be passed to.

As described above, according to this linking method, the data size of the transmission data passed from the upper layer 3 is added, and when the size exceeds a certain size, the data up to the previous one is linked. Accordingly, the data size of the transmission data to be passed to the lower layer 4 can be limited, and when the data size of the transmission packet in the lower layer 4 is limited, the data can be always transmitted within the size that can be transmitted.

[Example of Linking by Limiting the Number of Data to be Linked] Further, the number of data to be linked may be limited to control the linking of data. This is because, by transmitting data in a linked manner, it becomes necessary for the partner communication device to process a plurality of data at one time. This is because there is a possibility that normal data reception processing cannot be performed when the data is sent. Of course, as described above, even when the data division function and the transmission capacity of the lower layer 4 of the own apparatus have a limit on the number of data, the number of data to be linked is limited to control the linking of data. Of course, it is also good.

Therefore, in this case, the communication terminal 1 on the transmitting side
In the data connection control unit 7, the number of data connections that can be processed by the other communication device is set in advance, or the number of data connections that can be processed by the other communication device is received from the other communication device by exchanging control data at the time of negotiation. Then, based on the setting, the protocol processing unit 2 is controlled to limit the number of data to be linked.

As a result, the interval between the data transmitted by the protocol processing unit 2 is increased, so that the other communication device without sufficient processing capability can normally perform the receiving process.

As described above, according to this linking method, by limiting the maximum number of linked data in the transmission data group passed from the upper layer 3, even if the other communication device does not have sufficient processing capability, the normal There is an effect that it becomes possible to perform a proper receiving process.

[Example of Linking Using Communication Protocol Having Delivery Confirmation Function] In addition, the delivery confirmation data from the partner terminal is used to limit the number of linked data or the linked data size to link the data. May be.

In a communication protocol in which the next data is transferred after waiting for a data delivery confirmation or the like, the data transmission from the upper layer 3 takes place between the time when the data is transmitted and the time when the delivery confirmation is received. Even if a transmission request is received, it cannot be transmitted immediately. In such a case, the transmission data passed from the upper layer 3 is waited in the protocol processing unit 2 while waiting for the delivery confirmation. When data is retransmitted in the lower layer 4 due to an error in the transmission path, a long time is required.
Therefore, the transmission data group passed from the upper layer 3 while waiting for the acknowledgment is connected and transmitted immediately after receiving the acknowledgment. In other words, it does not wait for the next data to be passed for further connection.

FIG. 7 is a diagram showing a connection transmission sequence of transmission data 5A in a protocol having a delivery confirmation function. In this case, the protocol processing unit 2 controls the transmission data 5A (a), 5A,
A (b) is concatenated, a header is added, and the transmission data 5B
It is passed to lower layer 4 as (a + b). The transmission data 5A (a) and 5A (b) may be connected by using the timer described in the first embodiment, by using information indicating the presence or absence of subsequent data, or by determining the contents of the transmission data. There is a way.

Thereafter, in the example of FIG. 7, the transmission data 5A (c) and 5A (d) are passed from the upper layer 3, but since the protocol processing unit 2 has not received the delivery confirmation from the partner communication terminal, Transmission data 5 passed from upper layer 3
A (c) and 5A (d) are held and not transmitted. Then, upon receiving the acknowledgment of transmission from the partner communication terminal, the data link control unit 7 controls the protocol processing unit 2 so that the protocol processing unit 2 transmits the transmission data previously passed from the upper layer 3, as shown in FIG. In the example, the transmission data 5A (c),
5A (d) is concatenated, a header is added, and the transmission data 5B
It is passed to lower layer 4 as (c + d).

As described above, according to this connection method, when a communication protocol having a delivery confirmation function is used,
By holding the transmission data group passed from the upper layer 3 while waiting for the acknowledgment, and connecting and transmitting the acknowledgment when the acknowledgment is received, the protocol of the transmission data in the situation where the data transfer is delayed There is an effect that the delay time in the processing unit can be minimized.

In the second embodiment, as described above,
Although the data linking function in the protocol processing unit 2 for limiting the number of linked data and the size of the linked data of the transmission data has been described, the transmission data group having a close occurrence time is linked to the contents of the second embodiment. Of course, the data link function of the first embodiment may be arbitrarily combined. That is, [Example using timer], [Example using information indicating presence / absence of subsequent data] in Embodiment 1,
[Example of Recognizing the Presence or Absence of Subsequent Transmission Data from the Contents of Transmission Data] and the Linking Method of Transmission Data Groups with Short Generation Times and [When the Data Size of Linked Data Exceeds a Large Size] Linked data size of transmission data by [Example of linking], [Example of linking so that the data size of linked data does not exceed a certain size], [Example of linking by limiting the number of data to be linked] May be arbitrarily combined with the connection method based on.

For example, the linking method for limiting the linking size of transmission data shown in FIGS. 5 and 6 and the like in the second embodiment and the linking method for linking transmission data whose generation time is short by the timer shown in the first embodiment. May be combined. By doing so, in the case of FIG. 5, for example,
If the time from transmission data 5A (a) to transmission data 5A (d) is short and the timer does not time out,
As in the case of the second embodiment, under the control of the data connection unit 7, the protocol processing unit 2 transfers the transmission data 5A (a to d) connected at that time to the lower layer 4. However, for example, when the transmission data 5A (c) and the transmission data 5A (d) are passed from the upper layer 3 after a considerable time, the data size becomes the predetermined size in the case of the second embodiment. Up to next transmission data 5A (d)
The transmission data 5A (a to d) connected after the waiting is transmitted to the lower layer 4, and a large data delay may occur. As a result, if an allowable data delay time is set, a time-out occurs before the data size becomes a predetermined size. Therefore, the transmission data 5A (a to c) connected at that time is transmitted to the lower layer 4. Can be passed. As a result, by combining Embodiment 1 and Embodiment 2, it becomes possible to execute concatenation of transmission data in consideration of not only the data size and the like but also the transmission delay. The same applies to other connection methods other than the timer according to the first embodiment [Example of using information indicating presence / absence of subsequent data] or [Example of recognizing presence / absence of subsequent transmission data from contents of transmission data] And [Example of linking when data size of linked data exceeds a certain size] and [Example of linking so that data size of linked data does not exceed a certain size] in Embodiment 2. ] And [Example in which the number of data to be linked is limited and the number of data is linked] can be described.

In particular, when an appropriate combination of Embodiments 1 and 2 is used for control data exchanged with a partner terminal for negotiation processing before starting communication, transmission delay of control data is suppressed. In addition, concatenation of data is performed while limiting the concatenated data size of the control data to a certain extent, enabling negotiations with reduced transmission delay and transmission errors of control data during negotiations, and greatly shortening the time until communication starts. It can be shortened.

Embodiment 3 Next, a description will be given of a third embodiment in which data is connected not only in a protocol processing unit of a transport layer having a data connection / separation function but also in a layer below the transport layer.

FIG. 8 is a configuration diagram showing a configuration of the communication device according to the third embodiment of the present invention. In the figure, reference numeral 8 denotes a protocol processing unit which realizes a protocol processing having a general-purpose data connection / separation function and other functions, and 9 denotes a data connection control unit 7 described in the first and second embodiments. This is a data link control unit having the same data link control function and the same data link function as the data link function of the protocol processing unit 8. Other parts are the same as those in FIG. 1, and thus the same reference numerals are given and their explanation is omitted.

That is, the communication apparatus according to the third embodiment
A general-purpose upper layer 3, a protocol processing unit 8, and a lower layer 4 are provided, and a data link control unit 9 is added to the general-purpose configuration.

Next, the operation will be described. Communication terminal 1
Is another equivalent communication terminal via a network etc.
(Not shown). The upper layer 3 passes the transmission data 5A to the protocol processing unit 8. The protocol processing unit 8 concatenates data, if possible, performs general protocol processing, and passes the transmission data to the data connection control unit 9.

The data linking control unit 9 performs data linking control in the same manner as in the first and second embodiments, and based on the control, the data linking control unit 9 itself has the data linking function of the protocol processing unit 8. Even if the same linking function is provided and the optimum data linking cannot be performed by the protocol processing unit 8, the optimum data linking is performed and the data is transferred to the lower layer 4 as transmission data 5 </ b> B.

Then, the lower layer 4 adds a header to the transmission data 5B and transmits it as transmission data 5C to the other communication terminal (not shown) via the network. Here, the transmission data format generated by the data concatenation performed by the data concatenation control unit 9 is the same as the transmission data format generated by the data concatenation performed by the protocol processing unit 8. Even if the transmission data 5B thus received is received by the other communication terminal (not shown), it can be received and processed by the protocol processing unit 8 as the reception data 6B on the other communication terminal (not shown) side.

FIG. 9 is a diagram showing a connection transmission sequence of transmission data 5A according to the third embodiment. First,
When the transmission data 5A (a) and 5A (b) are sent from the upper layer 3 to the general-purpose protocol processing unit 8, they are connected by the general-purpose protocol processing unit 8 and passed to the data connection control unit 9 as transmission data (a + b). Further, the protocol processing unit 8 transfers the transmission data 5A (c) passed from the upper layer 3 to the data connection control unit 9 as transmission data (c) without linking it to other data. Since the general-purpose protocol processing unit 8 does not connect the transmission data 5A (a) and 5A (b) when the connection algorithm is not set, the transmission data 5A (a), 5A ( b) and 5A (c) are passed to the data link control unit 9 as they are.

In both cases, the data link control unit 9
In the same manner as in the first embodiment, the transmission data (a + b) and the transmission data (c) that are close in time are linked to each other and passed to the lower layer 4 as transmission data 5B (ac).
Similarly to the case of the second embodiment, the transmission data to be connected is limited to the data size, the number of data, and the like and is passed to the lower layer 4, thereby performing the optimum connection while suppressing the delay of the transmission data.

For this reason, when the general-purpose protocol processing unit 8 having the data connection / separation function cannot achieve the optimum data connection, the data connection control unit 7 of the first and second embodiments is added to the lower layer. By providing a data link control unit 9 having the same data link control function and the same data link function as that of the protocol processing unit 8, the general-purpose protocol processing unit 8 does not have a link algorithm that can perform the optimum link. However, an optimal transmission data linking function can be realized.

The general-purpose protocol processing unit 8 having the data linking / separating function may have various functions in addition to the data linking / separating function. In the lower layer,
An optimum data linking function can be easily achieved simply by adding the data linking control unit 9.

As described above, according to the third embodiment,
Below the layer of the protocol processing unit 8, a data connection control unit 9 having the same data connection function as the data connection control unit 7 of the first and second embodiments and the same data connection function as the protocol processing unit 8 is provided. Therefore, even when the protocol processing unit 8 cannot be modified or the like, the data connection control unit 9 has an effect that an optimum data connection function can be easily added.

In the description of the third embodiment, the data connection control unit 9 is provided separately from the general-purpose protocol processing unit 8, and the data connection control unit 9 is provided with the data connection control unit of the first and second embodiments. In addition to the data link control function similar to that of the protocol processing unit 7, the data link function of the protocol processing unit 8 is described as having the same data link function.
Not limited to this, the data link control unit 9 has only the same data link control function as in the first and second embodiments,
If it is determined that the transmission data is to be connected, a command may be issued to the protocol processing unit 8 to perform the data connection control and pass the data to the lower layer 4.

In the description of the first to third embodiments,
The above-described data connection control has been described as being performed when the communication terminal 1 transmits control data for negotiation performed before starting communication with another communication terminal. However, the present invention is not limited to this. After the negotiation process,
It may be applied to transmission data at the time of normal data transmission after the start of normal communication.

[0088]

As described above, according to the present invention,
In the communication device for linking the transmission data generated from the upper layer 3 and passing the transmission data to the lower layer, control is performed such that the transmission data having a shorter generation time is linked and passed to the lower layer. In the data group, we will concatenate data that will be delivered soon,
There is an effect that data connection can be performed without increasing the delay of transmission data.

In particular, when such data link control is used for control data exchanged with a partner terminal for negotiation processing before the start of communication, the number of transmissions of transmission data from the calling terminal during negotiation is reduced. So
The number of times of acknowledgment data from the called terminal of the other party is also reduced, and the time until the start of communication can be greatly reduced.

[0090]

[Brief description of the drawings]

FIG. 1 is a configuration diagram illustrating a communication device according to a first embodiment of the present invention.

FIG. 2 is a diagram showing a connection transmission sequence of transmission data 5A.

FIG. 3 is a diagram showing a connection transmission sequence of transmission data 5A when a timer is used.

FIG. 4 is a diagram showing a connection transmission sequence of transmission data 5A when information on the presence or absence of subsequent transmission data is used.

FIG. 5 is a diagram showing a connection transmission sequence of transmission data 5A while limiting data to be connected.

FIG. 6 is a diagram showing a connection transmission sequence of transmission data 5A while limiting data to be connected.

FIG. 7 is a diagram showing a connection transmission sequence of transmission data 5A in a protocol having a delivery confirmation function.

FIG. 8 is a configuration diagram illustrating a configuration of a communication device according to a third embodiment of the present invention.

FIG. 9 is a diagram showing a connection transmission sequence of transmission data 5A.

[Explanation of symbols]

1 communication terminal (communication device), 2,8 protocol processing unit,
7, 9 Data link control unit, 3 upper layers, 4 lower layers.

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5B089 GA04 GB01 HB18 5K034 AA03 BB06 FF02 HH01 HH02 HH06

Claims (13)

[Claims] 1. A communication apparatus for connecting transmission data generated from an upper layer and passing the transmission data to a lower layer and transmitting the transmission data to a partner terminal. A communication device comprising a unit. 2. The communication device according to claim 1, wherein the data connection control unit is provided in a protocol processing unit of a layer having a data connection function. 3. The communication device according to claim 1, wherein the data connection control unit is provided separately from a protocol processing unit of a layer having a data connection function. 4. When the transmission data is received from the upper layer when the transmission data from the upper layer is not held, the data connection control unit activates a timer and waits until a predetermined timer value is reached. The communication device according to any one of claims 1 to 3, wherein control is performed so as to link the received transmission data. 5. The communication device according to claim 4, wherein the predetermined timer value is set in accordance with a response time until transmission acknowledgment data from a partner terminal for transmission data is received. 6. The data link control unit, when receiving transmission data from an upper layer, receives information indicating the presence or absence of subsequent transmission data, and the information indicates that there is subsequent data. The communication device according to any one of claims 1 to 3, wherein received communication data is held, and control is performed so that connection is performed when subsequent transmission data is received. 7. The data link control unit determines the presence or absence of subsequent transmission data from the content of the transmission data received from the upper layer, and if it determines that there is subsequent transmission data, the received data is transmitted. The communication device according to claim 1, wherein the communication device is held and controlled so as to be connected when subsequent transmission data is received. 8. The data link control unit, when receiving transmission data from an upper layer, retains the transmission data, determines whether the total size of the transmission data retained each time exceeds a predetermined size, and retains the transmission data. The communication apparatus according to claim 1, wherein when the total size of the transmitted data exceeds a predetermined size, control is performed to link the currently held transmission data. 9. The data link control unit, when receiving transmission data from an upper layer, retains the transmission data, determines whether the total size of the transmission data retained each time exceeds a predetermined size, and retains the transmission data. 8. The communication apparatus according to claim 1, wherein connection of currently held transmission data is controlled so that the total size of the transmission data does not exceed a predetermined size. 10. The data link control unit, when receiving transmission data from an upper layer, holds the transmission data and counts the number of transmission data held each time, so that the counted number does not exceed a predetermined number. 8. The communication apparatus according to claim 1, wherein the connection of the transmission data currently held is controlled. 11. The data connection control unit, when receiving transmission data from an upper layer when transmission data from an upper layer is not held, connects the received transmission data having a similar occurrence time to the lower layer. To send to another communication device and hold transmission data from the upper layer until receiving acknowledgment data from the other communication device,
If there is transmission data received from the upper layer before receiving the acknowledgment data from the other communication device, when the acknowledgment is received from the other communication device, it is connected and passed to the lower layer, while the other communication device If there is no transmission data received from the upper layer until a delivery confirmation is received from the device, then when transmission data is received from the upper layer,
8. A control system according to claim 1, wherein said transmission data is received so as to be transmitted with a short generation time and transferred to a lower layer.
The communication device according to any one of the above. 12. The communication device according to claim 1, wherein the transmission data is control data transmitted at the time of negotiation before starting communication. 13. A communication method for connecting control data generated from an upper layer at the time of negotiation before starting communication and transferring the control data to a lower layer, wherein the control data having a nearer occurrence time is connected and transferred to a lower layer. Communication method.