JP2000261523A - Method and system for data transmission in multi-link communication and medium recording program to execute this method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a data transmission method by which a plurality of real time data transmission and non-real-time data transmission with a multi-link on one communication link are realized in an asynchronous.half-duplex communication system. SOLUTION: A reference link is set to a client requesting a fastest data exchange timing among clients performing real time data transmission. Data transmission requests from clients to which no reference link is set (RdataReq, DataReq for a period A in Figure) are saved in a buffer. On the occurrence of a data transmission request from the client to which the reference link is set (RdataReq for a period B in Figure), the system informs a Link manager about a multi-link transmission request (Rbasedata Req for the period B in Figure). Then the transmission request data saved in the buffer are acquired (GetTxReq, GetTxRsp for a period C in Figure), the data are multiplexed in a communication frame and the resulting frame is transmitted to a communication Port (Port-DataReq for a period D in Figure).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data transmission method, a data transmission system, and a medium on which a program for executing the data transmission method is recorded.
Infrared data communication (hereinafter IrDA (Infrared Data Ass
In a non-synchronous / half-duplex communication system typified by the term “association (communication)”, a multilink in which real-time data transmission (synchronous communication) and non-real-time data transmission (asynchronous communication) are mixed on one communication link The present invention relates to a data transmission method and system to be realized, and a program recording medium.

[0002]

2. Description of the Related Art As one of data transmission systems used between communication apparatuses, there has been an asynchronous / half-duplex communication system represented by IrDA communication or the like. The asynchronous / half-duplex communication method is a method in which bidirectional data transmission between communication devices that occurs asynchronously is performed using a single communication link.
Therefore, in this asynchronous / half-duplex communication method, when one communication device is performing data transmission or the like (using a communication link), the other communication device cannot perform data transmission or the like. On the other hand, if both communication devices transmit data or the like at the same time, the data will collide with each other on the communication link, and a communication failure will occur.

For this reason, in the asynchronous / half-duplex communication system,
In general, a "transmission right" indicating which communication device is the execution subject of data transmission or the like is transmitted together with data (in some cases, only the transmission right), and only the communication device having this transmission right transmits data or the like. Is defined in advance so that the following can be performed. Conventionally, asynchronous / half-duplex communication has been realized without collision of data on a communication link.

In this asynchronous / half-duplex communication system, when transmitting data requiring real-time characteristics such as synchronous communication data such as ISDN and voice data, the conditions shown in FIG. 6 are essential. FIG. 6 is a diagram illustrating an example of a communication sequence when transmitting real-time data in the asynchronous / half-duplex communication method. In FIG. 6, the primary station and the secondary station are communication devices, respectively, and the primary station manages the transmission right. Each term in FIG. 6 represents the following content. Link0 RL: Link 0 established for real-time data Communication Port: Physical communication port RdataReq: Request for transmission of real-time data RdataInd: Instruction for receiving real-time data Port_DataReq: Transmission to physical port Port_DataInd: Reception from physical port

When transmitting real-time data, FIG.
As shown in (1), data is transmitted in real time in synchronization with the generation of real-time data by a data transmission request (RdataReq) from the client (data transmission request source) (R
It is an essential condition that dataInd) and the interval t between data exchange timings of transmission and reception be constant.

[0006]

However, in the asynchronous / half-duplex communication system as described above, data transmission from a plurality of clients including real-time data transmission is to be realized by a multi-link on one communication link. , There have been the following problems.

FIG. 7 is a diagram showing an example of a communication sequence for explaining a problem when real-time data transmission and non-real-time data transmission are to be realized by multilink in the asynchronous / half-duplex communication system. is there. In FIG. 7, the primary station and the secondary station are communication devices, respectively, and the primary station manages the transmission right. Each term in FIG. 7 represents the following content. Link0 RL: Link 0 established for real-time data Link1 NRL: Link 1 established for non-real-time data Communication Port: Physical communication port RdataReq: Real-time data transmission request DataReq: Non-real-time data transmission request RdataInd: Instruction for receiving real-time data DataInd: Instruction for receiving non-real-time data Port_DataReq: Transmission to physical port Port_DataInd: Reception from physical port

When real-time data transmission and non-real-time data transmission are to be realized by multilink,
As shown in FIG. 7, when a sudden transmission request (DataReq) of non-real-time data that does not require synchronization is generated (indicated by a broken line in FIG. 7), real-time data (RdataReq) is transmitted at a constant interval t. You will not be able to do it. this is,
The transmission right of the primary station is transferred to the secondary station due to the generation of a non-real-time data transmission request (DataReq), and transmission of real-time data to be performed thereafter can be performed immediately in synchronization with the transmission request (RdataReq) This is because there is no longer a delay corresponding to the time of the interval t ′.

When a plurality of real-time data transmissions are to be realized by multi-link, it is necessary to support a data transmission service synchronized with a data exchange timing requested by a client performing each real-time data transmission. However, in this case, it is practically impossible to support these data transmissions because data exchange timings required by each client are different from each other.

Therefore, an object of the present invention is to provide a data transmission method and a data transmission method for realizing a plurality of real-time data transmissions and non-real-time data transmissions on a single communication link by a multi-link in an asynchronous / half-duplex communication system. An object of the present invention is to provide a transmission system and a medium recording a program for executing the method.

[0011]

According to a first aspect of the present invention, a communication device having a plurality of clients for real-time data transmission or non-real-time data transmission is connected to another communication device by an asynchronous / half-duplex communication method. A method for performing data transmission, wherein a step of setting a client performing real-time data transmission to a reference link and, when receiving a data transmission request from a client not set to the reference link, setting the data transmission request in advance Temporarily storing each in the buffer, and receiving a data transmission request (hereinafter, referred to as a reference data transmission request) from a client set in the reference link, obtaining each data transmission request stored in the buffer, The reference data transmission request and each data transmission request are simultaneously transmitted to another communication device. And transmitting to.

As described above, according to the first aspect, a reference link is set for a client requesting the fastest data exchange timing among clients performing real-time data transmission, and a data transmission request relating to the reference link is set. And simultaneously execute data transmission of other clients. As a result, the data exchange timing required by each client performing real-time data transmission can be secured. In the asynchronous / half-duplex communication method, a plurality of real-time data transmissions and non-real-time data transmissions can be performed by one communication link. Above can be realized by multilink.

[0013] A second invention is a method in which a communication device having a plurality of clients for real-time data transmission or non-real-time data transmission performs data transmission with another communication device by an asynchronous / half-duplex communication method. Data exchange timing requested by the client performing data transmission, the step of giving a timer timing, and the step of temporarily storing the data transmission request received from the client in a predetermined buffer, respectively,
In synchronization with the timing given by the timer timing,
Get each data transmission request stored in the buffer,
Transmitting to another communication device.

As described above, according to the second aspect, the greatest common divisor of the data exchange timing of a plurality of clients performing real-time data transmission is obtained, and the data exchange timing of this greatest common divisor is given by timer counting. As a result, the data exchange timing required by each client performing more real-time data transmission can be secured, and in the asynchronous / half-duplex communication method,
Multiple real-time data transmissions and non-real-time data transmissions can be realized by multiple links on one communication link. Further, communication failure due to link disconnection during communication does not occur.

[0015] A third invention is the invention according to the first invention, wherein a step of providing a data exchange timing requested by a client performing real-time data transmission by a timer is provided, and a data transmission request received from the client is provided by: Temporarily storing each in a predetermined buffer, and acquiring each data transmission request stored in the buffer in synchronization with the timing given by the timer timing, and transmitting the data transmission request to the other communication device. Prepare.

As described above, according to the third aspect, the first aspect
In the invention of the present invention, further, a method of determining the greatest common divisor of the data exchange timing of a plurality of clients performing real-time data transmission, giving the data exchange timing of this greatest common divisor by timer timing, and setting a client of a reference link, and a timer timing And the method of giving timing can be selectively used according to the communication situation. As a result, it is possible to secure the data exchange timing required by each client that performs more real-time data transmission, and to perform multiple real-time data transmissions and non-real-time data transmissions in the asynchronous / half-duplex communication system. Can be realized by a multilink on the communication link. Further, communication failure due to link disconnection during communication does not occur.

A fourth invention is an invention according to the first and third inventions, wherein there are two or more clients performing real-time data transmission, and each of the data exchange timings requested by the clients is different. If all have a multiple relationship, the setting step is characterized in that the client requesting the fastest data exchange timing is set as the reference link.

A fifth invention is an invention according to the second and third inventions, wherein there are two or more clients that perform real-time data transmission, and the data exchange timings requested by the clients are different. When there is a common divisor, the providing step is characterized in that the largest common divisor among the common divisors is given as a data exchange timing of data transmission by a timer.

As described above, according to the fourth and fifth aspects, in each of the first to third aspects, even if there are two or more clients performing real-time data transmission,
Useful effects in the first to third inventions can be obtained.

According to a sixth aspect of the present invention, there is provided a data transmission system for performing data transmission between communication apparatuses having a plurality of clients for performing real-time data transmission or non-real-time data transmission by an asynchronous / half-duplex communication method. A control means for setting a client for real-time data transmission to a reference link, and a data transmission request received from a client which exists individually for each client and is not set for the reference link. In response to a plurality of buffers to be transmitted and a data transmission request received from a client set on the reference link (hereinafter referred to as a reference data transmission request), each data transmission request stored in the buffer is acquired, and the reference data transmission request And each data transmission request is multiplexed to another communication device. And a multiplexing means for signal.

As described above, according to the sixth aspect, a reference link is set for a client that requests the fastest data exchange timing among clients that perform real-time data transmission, and a data transmission request for the reference link is set. And simultaneously execute data transmission of other clients. As a result, the data exchange timing required by each client performing real-time data transmission can be secured. In the asynchronous / half-duplex communication method, a plurality of real-time data transmissions and non-real-time data transmissions can be performed by one communication link Above can be realized by multilink.

A seventh invention is a data transmission method for performing data transmission between communication devices having a plurality of clients for real-time data transmission or non-real-time data transmission by an asynchronous / half-duplex communication method. A timer means for timing the data exchange timing requested by the client performing the real-time data transmission; and a plurality of timer means for individually storing the data transmission request received from the client and temporarily storing the data transmission request received from the client. A buffer, and multiplexing means for acquiring each data transmission request stored in the buffer in synchronization with the timing given by the timer means, multiplexing each data transmission request, and transmitting the multiplexed data transmission request to another communication device. .

As described above, according to the seventh aspect, the greatest common divisor of the data exchange timing of a plurality of clients performing real-time data transmission is determined, and the data exchange timing of this greatest common divisor is given by the timer means. As a result, it is possible to secure the data exchange timing required by each client that performs more real-time data transmission, and to perform multiple real-time data transmissions and non-real-time data transmissions in the asynchronous / half-duplex communication system. Can be realized by a multilink on the communication link. Further, communication failure due to link disconnection during communication does not occur.

An eighth invention is a invention according to the sixth invention, further comprising timer means for giving a data exchange timing requested by a client for real-time data transmission by measuring time, wherein the multiplexing means comprises a timer. In addition to the function of acquiring each data transmission request stored in the buffer in synchronization with the timing given by the means, multiplexing each data transmission request and transmitting the multiplexed request to another communication device.

As described above, according to the eighth aspect, the sixth aspect
A method of determining the greatest common divisor of the data exchange timing of a plurality of clients performing real-time data transmission, giving the data exchange timing of the greatest common divisor by a timer means, and setting a client of a reference link; And the method of giving timing can be selectively used in accordance with the communication situation. As a result, it is possible to secure the data exchange timing required by each client that performs more real-time data transmission, and to perform multiple real-time data transmissions and non-real-time data transmissions in the asynchronous / half-duplex communication system. Can be realized by a multilink on the communication link. Further, communication failure due to link disconnection during communication does not occur.

A ninth invention is an invention according to the sixth and eighth inventions, wherein there are two or more clients for performing real-time data transmission, and each of the data exchange timings requested by the clients is In a case where all of them are in a multiple relationship, the control means sets a client requesting the fastest data exchange timing as a reference link.

A tenth invention is an invention according to the seventh and eighth inventions, wherein there are two or more clients performing real-time data transmission, and at the data exchange timing requested by the clients. When there is a common divisor, the timer means gives the largest common divisor among the common divisors as the data exchange timing of data transmission by timing.

As described above, according to the ninth and tenth aspects, in the sixth to eighth aspects, even if there are two or more clients for performing real-time data transmission, the sixth to eighth aspects are described. Can provide a useful effect.

[0029] An eleventh invention records a computer program for executing data transmission requested by a plurality of clients performing real-time data transmission or non-real-time data transmission in a communication device which performs the transmission in an asynchronous / half-duplex communication system. Setting a client that performs real-time data transmission to a reference link, and, when receiving a data transmission request from a client that is not set to the reference link, stores the data transmission request in a predetermined buffer. Temporarily storing, and a data transmission request from a client set on the reference link (hereinafter referred to as a reference data transmission request)
Receiving the respective data transmission requests stored in the buffer, and simultaneously transmitting the reference data transmission request and the respective data transmission requests to the other communication device. It records a computer program to be implemented on the device.

A twelfth invention records a computer program for executing data transmission requested by a plurality of clients performing real-time data transmission or non-real-time data transmission in a communication device which performs the transmission in an asynchronous / half-duplex communication system. Providing a data exchange timing requested by a client performing real-time data transmission by a timer,
Temporarily storing each data transmission request received from the client in a predetermined buffer, and acquiring each data transmission request stored in the buffer in synchronization with the timing given by the timer, and And a computer program for realizing, on a communication device, an operating environment including a step of transmitting to the device.

A thirteenth invention is the invention according to the eleventh invention, wherein the step of giving the data exchange timing requested by the client performing the real-time data transmission by the timer measurement, and the step of giving the data transmission request received from the client, Temporarily storing each in a predetermined buffer, and acquiring each data transmission request stored in the buffer in synchronization with the timing given by the timer timing, and transmitting the data transmission request to the other communication device. Prepare.

A fourteenth invention is an invention according to the eleventh and thirteenth inventions, wherein there are two or more clients that perform real-time data transmission, and each client requests a data exchange timing. If all are multiples, the setting step is to identify the client requesting the fastest data exchange timing,
It is set as a reference link.

A fifteenth invention is an invention according to the twelfth and thirteenth inventions, wherein there are two or more clients that perform real-time data transmission, and the data exchange timings requested by the clients are different. When there is a common divisor, the providing step is characterized in that the largest common divisor among the common divisors is given as a data exchange timing of data transmission by a timer.

As described above, the eleventh to fifteenth aspects of the invention
It is a recording medium on which a computer program for executing the data transmission method of the first to fifth inventions is recorded. This corresponds to supplying the data transmission method of the first to fifth inventions to an existing device in the form of software.

[0035]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, an embodiment of the present invention will be described by using Ir
An example in which data transmission between communication devices is performed by the asynchronous / half-duplex communication method in DA communication, in which two clients perform real-time data transmission and one client performs non-real-time data transmission. A description is given below.

(First Embodiment) FIG. 1 shows a first embodiment of the present invention.
1 is a diagram illustrating an example of a configuration of a data transmission system using a data transmission method according to an embodiment. In FIG. 1, the data transmission system according to the first embodiment includes a primary station 1 that is a communication device that manages a transmission right, and a secondary station 2 that is another communication device. The secondary station 2 is connected by an IrDA communication link of an asynchronous / half-duplex communication system.

The primary station 1 performs clients 11 and 12 for real-time data transmission (in the example of FIG. 1, ISDN communication and ADPCM voice transmission) and non-real-time data transmission (file transmission in the example of FIG. 1). The communication management unit 14 includes a client 13 that performs the communication. The secondary station 2 corresponds to each of the clients 11 and 12 of the primary station 1 and performs a real-time data transmission.
1 and 22, a client 23 corresponding to the client 13 of the primary station 1 and performing non-real-time data transmission, and a communication management unit 24. The communication management unit 14
Are buffers 141 to 143 and a control / multiplexing unit 144
And The communication management unit 24 includes buffers 241 to 24
3 and a control / multiplexing unit 244. It should be noted that the primary station 1 and the secondary station 2 basically differ only in whether or not the transmission right is managed. Therefore, in the following description, each configuration of the primary station 1 and the operation of the primary station 1 are performed. The processing will be mainly described.

The clients 11 to 13 correspond to a communication application, and perform a data transmission request, a data reception process, and the like to the communication management unit 14. The communication management unit 14 is a part corresponding to a communication protocol, and controls predetermined data transmission and reception in response to requests from the clients 11 to 13. The buffers 141 to 143 correspond to the clients 11 to 13, respectively, and temporarily store data requested by the clients 11 to 13, respectively. The control / multiplexing unit 144 first determines a link (hereinafter, referred to as a reference link) serving as a reference for IrDA communication data exchange timing by a method described later. Thereafter, the control / multiplexing unit 144 determines whether each buffer 14
The transmission data temporarily stored in 1 to 143 is acquired, a communication frame required for transmission is generated by multiplexing, and the communication frame is transmitted to the secondary station 2 together with the transmission right.

Hereinafter, a data transmission method according to the first embodiment of the present invention, which is performed by the data transmission system having the above configuration, will be described with reference to FIGS. FIG. 2 is a flowchart illustrating an example of a processing procedure performed by the communication management units 14 and 24 in the data transmission method according to the first embodiment of the present invention. In FIG. 1, it is assumed that the client 11 requests the data exchange timing of 10 msec and the client 12 requests the data exchange timing of 20 msec.

First, the control / multiplexing section 144 sets a reference link prior to communication (step S201). This reference link is set for a client that requests the fastest data exchange timing among clients that perform real-time data transmission. Therefore, in FIG. 1, a reference link is set for the client 11 requesting the data exchange timing of 10 msec.
The data exchange timing T _N (N = 1, 2, 2, 3) required by a plurality of clients performing real-time data transmission
, N) do not satisfy a multiple relationship with respect to the fastest data exchange timing T ₁ , that is, T ₂ = K
₁ * T ₁ , T ₃ = K ₂ * T ₁ ,..., T _n = K _m * T
_{If 1} (K ₁ , K ₂ ,..., K _m are positive integers) are not satisfied, all of these clients cannot be simultaneously realized by multilink (the correspondence for this is the second Described in the embodiment). When one client performs real-time data transmission, a reference link is inevitably set for this client.

Then, the primary station 1 starts actual communication after setting the reference link. When communication starts,
The control / multiplexing unit 144 controls any one of the clients 11
It is determined whether a data transmission request has been received from か ら 13 (step S202). If it is determined in step S202 that a data transmission request has been received from any of the clients 11 to 13, the control / multiplexing unit 144
It is further determined whether the data transmission request is from the client 11 of the set reference link (step S).
203). If it is determined in step S203 that the request is not a data transmission request from the client 11 of the reference link, the control / multiplexing unit 144 stores the transmission data in the buffer 142 or 143 corresponding to the client (step S204). Step S20
2 and waits for a data transmission request from the clients 11 to 13 again.

On the other hand, if it is determined in step S203 that the request is a data transmission request from the client 11 of the reference link, the control / multiplexing unit 144 transmits the data to the buffers 142 and 143 together with the transmission data of the data transmission request.
(Ie, transmission data for which transmission has been requested up to this point) (step S205). Then, the control / multiplexing unit 144 multiplexes all the acquired transmission data to generate a necessary communication frame (Step S206), and transmits the communication frame to the secondary station 2 (Step S207). As described above, when one data transmission is completed at the data exchange timing of the reference link, the control / multiplexing unit 144 proceeds to step S20.
2 and the above process is repeated again.

Incidentally, the primary station 1 may receive a connection request for real-time data transmission from a new client after setting the reference link and starting communication as described above. At this time, the primary station 1 determines whether or not a request for a new client can be received while keeping the current reference link, and in some cases, it is necessary to reset the reference link. Hereinafter, a method of determining and resetting (reviewing) the reference link will be described with reference to FIG.
FIG. 3 is a flowchart illustrating an example of a reference link review processing procedure performed by the communication management units 14 and 24 in the data transmission method according to the first embodiment of the present invention.

First, the communication manager 14 checks whether a connection request for real-time data transmission has been received from a new client (step S301). If a connection request has been received in the confirmation in step S301, the communication management unit 14 compares the current data exchange timing RT of the reference link with the data exchange timing rt requested by a new client that has issued the connection request. (Step S302).

As a result of the comparison in step S302, if the data exchange timing RT and the data exchange timing rt are the same (RT = rt), the communication management unit 1
No. 4 executes connection of a new client while keeping the reference link as it is (step S306).

As a result of the comparison in step S302, when the data exchange timing RT is earlier than the data exchange timing rt (RT <rt), the communication management unit 14
Further, it is determined whether the data exchange timing rt is a multiple of the data exchange timing RT (step S30).
3). When it is determined in step S303 that the number is a multiple, the communication management unit 14 executes connection of a new client while keeping the reference link as it is (step S306). For example, RT = 10 msec, rt = 30 msec
Is the case. On the other hand, if it is determined in step S303 that the number is not a multiple, the communication management unit 14 determines that connection of the new client is impossible (step S307). For example, RT = 10 msec, rt = 25
In the case of msec.

As a result of the comparison in step S302, when the data exchange timing RT is later than the data exchange timing rt (RT> rt), the communication management unit 14
Further, it is determined whether the data exchange timing rt is a divisor of the data exchange timing RT (step S30).
4). If it is determined in step S304 that the number is a divisor, the communication management unit 14 resets the reference link for the new client (step S305), and executes connection of the new client (step S30).
6). For example, a case where RT = 10 msec and rt = 5 msec. On the other hand, if it is determined in step S304 that it is not a divisor, the communication management unit 14 determines that connection of the new client is impossible (step S3).
07). For example, a case where RT = 10 msec and rt = 7 msec.

In this way, the primary station 1 realizes an appropriate multilink by successively revising the reference link every time a connection request is received from a new client.
The response to the case where it is determined in step S307 that a new client cannot be connected will be described in a second embodiment described later.

Next, an example of communication performed based on the above-described data transmission method will be described with reference to FIG. FIG.
Is a data transmission method according to the first embodiment of the present invention,
FIG. 2 is a diagram illustrating an example of a communication sequence when used in the data transmission system of FIG. 1. In addition, each term in FIG. 4 represents the following contents, respectively. Further, a period indicated by a bold line represents a state in which data is stored and held in a buffer or the like. Link0 RL: Link 0 established for real-time data (between client 11 and client 21) Link1 RL: Link 1 established for real-time data (between client 12 and client 22) Link2 NRL: Non Link 2 established between real-time data (between client 13 and client 23) Link management: Multi-link management performed by communication management units 14 and 24 Communication Port: Physical communication port RdataReq: Real-time data transmission request DataReq: Non-real-time data transmission request RBasedataReq: Multi-link transmission request performed in response to real-time data transmission request as a reference link GetTxReq: Acquisition of transmission request GetTxRsp: Response to acquisition of transmission request (GetTxReq) RdataInd: Real-time data transmission Receive instruction DataInd: For non-real-time data Receive instruction Port_DataReq: Transmission to physical port Port_DataInd: Reception from physical port

The primary station (1) further receives a data transmission request (period A in FIG. 4, RdataReq, DataReq) received from a client (12, 13) for which a reference link is not set.
The link management (control / multiplexing unit 144) is made to wait without making a data transmission request (that is, temporarily stored in each of the buffers 141 to 143). The primary station performs this data transmission request standby process until a data transmission request (period B in FIG. 4, RdataReq) from the client (11) to which the reference link is set.
Thereafter, when a data transmission request (period B in FIG. 4, RdataReq) is generated from the client to which the reference link is set, the primary station firstly requests the Link management for a multi-link transmission request (period B, FIG. 4). RBasedataReq).
Then, in the link management, the primary station acquires the waiting data transmission requests (period C, GetTxReq, Ge in FIG. 4).
tTxRsp). Then, the primary station multiplexes the plurality of acquired transmission data in a communication frame and simultaneously
(Period D in FIG. 4, Port_DataReq). In FIG. 4, the acquisition (GetTxReq) of each data transmission request in the period C is described so as to have a time lag. However, this is done for the sake of convenience in describing the communication sequence, and in the actual processing, when a multilink transmission request (RBasedataReq) is notified, a data transmission request is obtained (GetTxReq) at once.
Processing is in progress.

As can be seen from FIG. 4, the secondary station (2) performs the same processing. Here, since the primary station performs transmission data in synchronization with the data transmission request generated by the client of the reference link at regular intervals, the transmission right transmitted along with the transmission data is ultimately at the secondary station. It will be obtained at regular intervals. Therefore, even at the secondary station, real-time data transmission at a constant interval becomes possible.

As described above, according to the data transmission method and the data transmission system according to the first embodiment of the present invention, of the clients that perform real-time data transmission,
A reference link is set for a client requesting the fastest data exchange timing, and data transmission of another client is simultaneously executed in synchronization with a data transmission request related to the reference link. As a result, the data exchange timing required by each client performing real-time data transmission can be secured. In the asynchronous / half-duplex communication method, a plurality of real-time data transmissions and non-real-time data transmissions can be performed by one communication link Above can be realized by multilink.

(Second Embodiment) As described above, the first embodiment
In the data transmission method and the data transmission system according to the embodiment, the multilink cannot be realized for a client whose data exchange timing is not a multiple relation with respect to the client of the reference link. Also, even when the data exchange timings are in a multiple relationship, if the client of the reference link disconnects the link during communication, a situation occurs in which the remaining clients cannot continue the multilink. Therefore, a second embodiment of the present invention is a data transmission method and a data transmission system for solving the above problem.

FIG. 5 is a diagram showing an example of the configuration of a data transmission system using the data transmission method according to the second embodiment of the present invention. As shown in FIG. 5, the data transmission system of the second embodiment differs from the data transmission system of the first embodiment in that
45 and 245 are further provided. The other configuration of the data transmission system according to the second embodiment is the same as the configuration of the data transmission system according to the first embodiment, and the other configurations are denoted by the same reference numerals. Description is omitted.

As described above, in the first embodiment, the client of the reference link is set, and the client is synchronized with the data transfer request periodically issued by the client, so that data transmission (exchange) at a constant interval is performed. Has been realized. On the other hand, in the second embodiment, the timer unit 14
By giving data exchange timing at regular intervals (hereinafter, referred to as reference exchange timing) by 5,245,
Data transmission at regular intervals is realized.

The reference exchange timing provided by the timer units 145 and 245 is determined by calculating the greatest common divisor of each data exchange timing requested by a plurality of clients performing real-time data transmission. For example, the data exchange timings required by a plurality of clients performing real-time data transmission are 10 msec and 15 mse, respectively.
c, 20 msec, the timer units 145, 245
5 msec, which is the greatest common divisor of each data exchange timing, is set as a reference exchange timing (in the case of the first embodiment, a connection of 15 msec becomes impossible).

Also, as described above, the timer units 145 and 245
By giving the reference exchange timing according to this, it is possible to cope with the following cases. For example, consider a case where a new connection request with a data exchange timing of 15 msec occurs when the data exchange timings requested by a plurality of clients performing real-time data transmission are 10 msec and 20 msec. In this case, in the first embodiment, the newly connected 15 msec is requested.
Is not a multiple of 10 msec, which is the reference link, so it is determined that connection is impossible. On the other hand, in the second embodiment, the timer units 145 and 245 change the current reference exchange timing of 10 msec to 10 msec, 15 msec, and 20 ms.
15ms because it is reset to 5msec which is the greatest common divisor of ec
ec connection is possible.

Further, for example, when the data exchange timing requested by a plurality of clients performing real-time data transmission is 5 msec, 10 msec, and 15 msec, 5 ms
Consider the case where the client of ec requests a link disconnection. In this case, in the first embodiment, 5 msec, which is the reference link, disappears, and as a result, the remaining 10 msec and 15 msec cannot be multi-linked (10 msec and 15 msec are not in a multiple relation). . On the other hand, in the second embodiment, since there is no concept of the reference link, the multilink can be continuously performed in 5 msec. If the greatest common denominator can be newly calculated with the remaining data exchange timing, the current reference exchange timing setting may be changed to a new greatest common divisor (for example, when the values are 2 msec, 12 msec, and 30 msec). 2msec
When the link is disconnected, a new greatest common divisor of 6 msec can be calculated from 12 msec and 30 msec.)

As described above, according to the data transmission method and the data transmission system according to the second embodiment of the present invention, the greatest common divisor of the data exchange timing of a plurality of clients performing real-time data transmission is obtained, Gives the greatest common divisor of the data exchange timing (reference exchange timing). As a result, it is possible to secure the data exchange timing required by each client that performs more real-time data transmission, and to perform multiple real-time data transmissions and non-real-time data transmissions in the asynchronous / half-duplex communication system. Can be realized by a multilink on the communication link. Further, communication failure due to link disconnection during communication does not occur.

In the first and second embodiments, the case of IrDA communication has been described as an example. However, if data transmission between communication devices is performed by an asynchronous / half-duplex communication method. The present invention can also provide useful effects in other communications. In the first and second embodiments, the case where two clients perform real-time data transmission and one client performs non-real-time data transmission is described as an example. It goes without saying that the present invention can be similarly applied to a client.

Further, the method of setting the reference link in the first embodiment has been described separately for the method of using the timer unit in the second embodiment. However, a method and a system having both of them are described. Can also. In other words, when the data exchange timings of the plurality of clients performing the real-time data transmission have a multiple relation, a reference link is set to perform data transmission (effective use of timer resources can be achieved). For example, data may be transmitted using a timer unit, and may be selectively used in accordance with communication conditions.

In a typical hardware environment, the client 11 in the first and second embodiments is used.
, 13, 21 to 23 and the communication management units 14, 24 are storage devices (ROM, ROM, etc.) storing predetermined program data.
RAM, hard disk, etc.) and CPU (Central Processing Unit). In this case, the functions executed by the communication management units 14 and 24 are provided in the form of independent program data. This program data may be introduced via a recording medium such as a CD-ROM or a floppy disk, or may be introduced by communication.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating an example of a configuration of a data transmission system using a data transmission method according to a first embodiment of the present invention.

FIG. 2 is a flowchart illustrating an example of a processing procedure performed by communication management units 14 and 24 in the data transmission method according to the first embodiment of the present invention.

FIG. 3 is a flowchart illustrating an example of a reference link review processing procedure performed by the communication management units 14 and 24 in the data transmission method according to the first embodiment of the present invention.

FIG. 4 is a diagram showing an example of a communication sequence when the data transmission method according to the first embodiment of the present invention is used in the data transmission system of FIG.

FIG. 5 is a diagram illustrating an example of a configuration of a data transmission system using a data transmission method according to a second embodiment of the present invention.

FIG. 6 is a diagram showing an example of a communication sequence when transmitting real-time data in the asynchronous / half-duplex communication method.

FIG. 7 is a diagram showing an example of a communication sequence for explaining a problem when real-time data transmission and non-real-time data transmission are to be realized by multilink in the asynchronous / half-duplex communication method.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Primary station 2 ... Secondary station 11-13, 21-23 ... Client 14, 24 ... Communication management parts 141-143, 241-243 ... Buffer 144, 244 ... Control / multiplexing part 145, 245 ... Timer part

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Kuniaki Sugimoto 3-10-18 Kagamiyama, Higashihiroshima-shi, Hiroshima Pref. Matsushita Electric Information Systems Hiroshima Research Laboratories Co., Ltd. (72) Noriyuki Ogawa 3-chome Kagamiyama, Higashihiroshima-shi, Hiroshima No. 10-18 Inside Matsushita Electric Information System Hiroshima Research Institute (72) Inventor Masatomo Morioka 3-10-18 Kagamiyama, Higashihiroshima City, Hiroshima Prefecture Inside Matsushita Electric Information System Hiroshima Research Center (72) Inventor Kazuya Yasawa Tokyo Inside NTT Mobile Communication Network Co., Ltd., 2-1-1 Toranomon, Minato-ku (72) Inventor Yusuke Kusuda Inside NTT Mobile Communication Network, 2-1-1 Toranomon, Minato-ku, Tokyo F term (reference) 5K018 AA01 DA02 DA06 DA11 FA02 5K028 AA11 CC02 KK01 KK03 KK32 RR03 5K034 AA14 CC01 DD05 DD06 EE01 EE13 HH01 HH02 HH17 HH27 HH32 HH42 HH65 KK05 LL01 NN13 PP01 PP03 PP04

Claims (15)

[Claims] 1. A method in which a communication device having a plurality of clients performing real-time data transmission or non-real-time data transmission performs data transmission with another communication device by an asynchronous / half-duplex communication method, Setting a client to be performed as a reference link; and, when receiving a data transmission request from a client that is not set to the reference link, temporarily storing the data transmission request in a predetermined buffer. When a data transmission request (hereinafter, referred to as a reference data transmission request) is received from a client set on the reference link, each data transmission request stored in the buffer is acquired, and the reference data transmission request and the respective data transmission requests are acquired. Transmitting the request to the other communication device at the same time. A data transmission method. 2. A method in which a communication device having a plurality of clients for performing real-time data transmission or non-real-time data transmission performs data transmission with another communication device by an asynchronous / half-duplex communication method, Performing a data exchange timing requested by the client, by a timer timing, temporarily storing a data transmission request received from the client in a predetermined buffer, and synchronizing with the timing provided by the timer timing. Acquiring each data transmission request stored in the buffer and transmitting the data transmission request to the other communication device. 3. A step of providing, by a timer, a data exchange timing requested by a client performing the real-time data transmission, and temporarily storing a data transmission request received from the client in a predetermined buffer, respectively. 2. The data transmission method according to claim 1, further comprising: acquiring each data transmission request stored in the buffer in synchronization with a timing given by the timer timing, and transmitting the data transmission request to the other communication device. . 4. When there are two or more clients performing the real-time data transmission, and all the data exchange timings requested by the clients are in a multiple relationship, the setting step is performed by the fastest data exchange timing. 4. The data transmission method according to claim 1, wherein a client requesting the request is set as a reference link. 5. When there are two or more clients performing the real-time data transmission, and there is a common divisor in each data exchange timing requested by the client, the providing step includes: 4. The data transmission method according to claim 2, wherein the common divisor is given as a data exchange timing of the data transmission by timer counting. 6. A data transmission system for performing data transmission between communication devices having a plurality of clients performing real-time data transmission or non-real-time data transmission by an asynchronous / half-duplex communication method, wherein each of the communication devices comprises: Control means for setting a client performing the real-time data transmission to a reference link; and temporarily storing a data transmission request which is individually provided for each of the clients and received from a client not set to the reference link. A plurality of buffers to be transmitted, and in response to a data transmission request received from a client set on the reference link (hereinafter referred to as a reference data transmission request), obtain each data transmission request stored in the buffer, and Multiplexing the transmission request and each data transmission request, Wherein and a multiplexing means for transmitting to the communication device, the data transmission system. 7. A data transmission method for performing data transmission between communication devices having a plurality of clients performing real-time data transmission or non-real-time data transmission by an asynchronous / half-duplex communication method, wherein each of the communication devices comprises: Timer means for providing a data exchange timing requested by a client performing the real-time data transmission by timing, and a plurality of timers which individually exist for each of the clients and temporarily store a data transmission request received from the client. Multiplexing means for acquiring each data transmission request stored in the buffer in synchronism with a buffer and a timing given by the timer means, multiplexing the data transmission requests, and transmitting the multiplexed data transmission request to another communication device A data transmission system comprising: 8. The data processing apparatus according to claim 1, further comprising timer means for providing a data exchange timing requested by the client performing the real-time data transmission by timing, wherein the multiplexing means stores the data in the buffer in synchronization with the timing given by the timer means. The data transmission system according to claim 6, further comprising a function of acquiring each stored data transmission request, multiplexing each data transmission request, and transmitting the multiplexed data transmission request to another communication device. 9. When there are two or more clients performing the real-time data transmission, and all data exchange timings requested by the clients are in a multiple relation, the control means determines the fastest data exchange timing. 9. The data transmission system according to claim 6, wherein the requesting client is set as a reference link. 10. When there are two or more clients performing the real-time data transmission and a common divisor exists in each data exchange timing requested by the client, the timer means sets a maximum of the common divisors. The data transmission system according to claim 7, wherein the common divisor is given as a data exchange timing of data transmission by clocking. 11. A medium on which a computer program is recorded for executing data transmission requested by a plurality of clients performing real-time data transmission or non-real-time data transmission in a communication device that performs an asynchronous / half-duplex communication method. Setting a client that performs the real-time data transmission to a reference link; and, when receiving a data transmission request from a client that is not set to the reference link, temporarily storing the data transmission request in a predetermined buffer. And when a data transmission request (hereinafter, referred to as a reference data transmission request) is received from a client set on the reference link, each data transmission request stored in the buffer is obtained. Transmission request and each data transmission request concerned At the same time, a recording medium in which a computer program for realizing an operating environment including the step of transmitting to the other communication device on the communication device is recorded. 12. A medium in which a computer program is recorded for executing data transmission requested by a plurality of clients performing real-time data transmission or non-real-time data transmission in a communication device that performs an asynchronous / half-duplex communication method. Providing a data exchange timing requested by a client performing the real-time data transmission by a timer timing; temporarily storing a data transmission request received from the client in a predetermined buffer, respectively; Acquiring each data transmission request stored in the buffer in synchronization with the timing given by the buffer, and transmitting the data transmission request to the other communication device. Program Recorded recording medium. 13. A step of providing, by a timer, a data exchange timing requested by a client performing the real-time data transmission, and temporarily storing a data transmission request received from the client in a predetermined buffer, respectively. 12. The recording medium according to claim 11, further comprising: acquiring each data transmission request stored in the buffer in synchronization with a timing given by the timer timing, and transmitting the data transmission request to the other communication device. 14. When there are two or more clients performing the real-time data transmission, and all the data exchange timings requested by the clients are in a multiple relation, the setting step includes the fastest data exchange timing. 14. The recording medium according to claim 11, wherein the client requesting the request is set as a reference link. 15. When there are two or more clients performing the real-time data transmission, and there is a common divisor in each data exchange timing requested by the client, the providing step includes: The common factor is given as a data exchange timing of data transmission by a timer clock.
4. The recording medium according to 3.