KR100366018B1 - Data transmission system and method for transmitting data frames - Google Patents

Abstract

A data communication system and a communication method thereof are disclosed. The transmitter of the data communication system according to the present invention comprises a frame generation unit for generating an information frame having sequence designation information and an ordered information frame according to a set sequence designation interval with respect to original data to be transmitted according to its unique arrangement order; And a transmitter for transmitting the information frame generated by the generator to a receiver through a communication network. According to such a data communication system and a communication method thereof, the communication burden for checking transmission errors and correcting errors for data to be transmitted is reduced.

Description

Data communication system and method for transmitting the same {Data transmission system and method for transmitting data frames}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data communication system and a communication method thereof, and more particularly, to a data communication system and a communication method for selectively performing a transmission error check for transmitted information frames in order to reduce a communication traffic burden.

The data communication system includes a communication terminal connected through a communication network.

The bidirectional communication terminal handles both transmission and reception of data. Therefore, the communication terminal becomes a send station when transmitting data, and becomes a receiver station when receiving data.

In such a data communication system, a transmission error may occur while data transmitted from a transmitter is transmitted to a receiver through a communication network. In consideration of this, in order to receive the original data without error in the receiver, there is a method of requesting retransmission to the transmitter until the reception error data is normally received.

As a conventional method for recovering a reception error, the transmitter transmits a sequence number for inter-frame identification to each receiver to transmit information to the receiver.

In a wireless logical-link control (LLC) layer, a typical information frame format consisting of a plurality of fields is shown in FIG. In the drawing, F is a field (F; field) indicating the start and end of one frame, A is a field in which the address of a remote receiver is written, and C _N is a control field in which the purpose of the frame is recorded. , Info denotes an information feed containing information to be transmitted, and FCS denotes a frame check sequence feed for checking for transmission errors. The order information is recorded in the control feed C (N).

In addition, the receiver checks the transmission error for each received frame, and transmits a result signal of the reception state to the transmitter for each frame. That is, the receiver transmits an acknowledgment signal (ACK) with the sequence information on the normally received frame to the transmitter, and sends a negative acknowledgment signal (NAK) to the transmitter on the received frame with an error. send.

The transmitter retransmits a frame in which a disapproval signal is input from the receiver among the transmitted frames to the receiver.

This conventional communication method will be described in more detail with reference to FIG. 2.

First, the transmitter sequentially generates information frames in accordance with the data arrangement order from the transmission target information original data. In this case, the sequence information corresponding to the arrangement order of the original data is contained in the control feed of each sequentially generated information frame. The transmitter sequentially transmits the generated information frames to the receiver from the first frame F1 sequentially through the communication network. On the other hand, the receiver transmits a result signal (ACK or NAK) signal for the reception state for the received first frame with the sequence information indicating that the first frame to the transmitter. In this case, a time taken for the response signal from the receiver to the transmitter at the time when the transmitter transmits the first frame is referred to as a round-trip delay. In the case of real-time communication, the transmitter transmits subsequent frames sequentially according to the arrangement order of the data to be transmitted, even before the response signal from the receiver arrives for the transmitted frame to eliminate the communication gap during the round trip delay time. As one example of such a communication process, when the reception error signal NAK3 is input to the third frame F3 from the receiver, the transmitter waits for transmission of the next frame to be transmitted, and then transmits the third frame F3. Resend.

According to the data transmission method, when a transmission error of some frames occurs in the data communication process, the sequence numbers of frames normally received at the receiver are not sequentially arranged and mixed. Thus, the receiver requires a buffer of adequate capacity to reorder the frames in that order in order to restore the transmitted data to its original state. Similarly, the transmitter needs a buffer of a suitable capacity to temporarily store the transmitted frame in consideration of the possibility of retransmission until the ACK signal is input from the receiver.

On the other hand, in case of real time communication, some data transmission error may be allowed, but data transmission delay over a certain time is difficult to allow. For example, in the case of real-time voice communication, voice data allows some noise and data loss, while excessive data transmission delay causes communication failure. However, the conventional communication method of designating and transmitting a sequence number for every frame to be transmitted and transmitting a response signal for a reception result for each frame received in case of real-time communication of voice data in which partial data loss is allowed, It takes a lot of load, and there is a disadvantage that a communication failure occurs when the transmission error rate is high.

The present invention has been made to solve the above problems, and a data communication system for selectively performing a reception error correction to reduce the communication load of the channel during the real-time communication of the specific data that is allowed to lose some data and its The purpose is to provide a communication method.

1 is a view showing the format of a general information frame,

2 is a timing diagram showing a data transmission process between a conventional transmitter and a receiver,

3 is a block diagram showing a data communication system to which the present invention is applied;

4 is a block diagram illustrating an example of the communication controller of FIG. 3 in more detail.

5 is a view showing the format of the specified information frame is applied to the present invention,

6 is a view showing the format of the non-ordering information frame applied to the present invention,

7 is a flowchart illustrating a process of transmitting data of a transmitter of a communication system according to the present invention;

8 is a flowchart illustrating a process of processing received data of a receiver of a communication system according to the present invention;

9 is a timing diagram illustrating a data transmission process between a transmitter and a receiver when the sequence numbering interval is 3 in the communication system according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: transmitter 11, 41: central processing unit

12, 42: storage device 13, 43: operating system

14, 44: communication interface 20, 50: communication controller

21: frame generation unit 22: transmission unit

23: sequence designation interval adjusting unit 24: receiving signal processing unit

26: Buffer

In order to achieve the above object, a data communication system according to the present invention includes a transmitter for transmitting data to be transmitted in units of frames and a receiver for receiving a signal transmitted from the transmitter through a communication network. The transmitter comprises: a frame generation unit for generating the information frame having the order designation information and the non order designation information frame according to the unique ordering interval for the transmission target document data; And a transmitter for transmitting the information frame generated by the frame generator to the receiver through the communication network.

In addition, the receiver transmits a response signal corresponding to a reception normal / error to the transmitter only for information frames having sequence designation information among the received information frames,

When the reception error signal is transmitted from the receiver, the transmitter retransmits the information frame in which the reception error occurred.

Preferably, the transmitter further adjusts the sequence designation interval according to a communication environment and further controls the sequence designation interval adjusting unit which controls the frame generation unit to generate the information frame and the ordered information frame which are sequentially designated by the adjusted sequence designation interval. Equipped.

The sequence designation interval adjusting unit may calculate a transmission error rate of the information frames transmitted by using the error / normal signal input from the receiver, and adjust the sequence designation interval according to the calculated transmission error rate.

In addition, the data communication system of the present invention includes a transmitter for transmitting data to be transmitted in units of frames and a receiver for receiving a signal transmitted from the transmitter through a communication network in order to achieve the above object. How is it going? Generating, by the transmitter, a frame having sequence designation information and a frame without sequence designation according to a unique sequence designation interval for original data to be transmitted; I. Transmitting the generated information frame to the receiver; All. And if it is determined that a reception error signal is input from the receiver with respect to the transmitted sequence number information frame, retransmitting the information frame in which the reception error occurred to the receiver.

Preferably, time counting is started for the sequence numbered frame transmitted in step b. If there is no response signal from the receiver until the counted time reaches a predetermined time, the receiver processes the received error and processes the error. Retransmitting the received information frame to the receiver.

The transmitter may further include calculating a transmission error rate for the information frames transmitted from the response signal provided for the reception result from the receiver; And adjusting the sequence designation interval according to the calculated transmission error rate.

Hereinafter, a data communication system and a communication method thereof according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram showing a data communication system to which the present invention is applied.

Referring to the drawings, a data communication system includes a transmitter 10 and a receiver 20 connected through a communication network 30.

The communication network 30 includes both a wired communication network and a wireless communication network.

The transmitter 10 includes a central processing unit (CPU) 11, a storage device 12, a communication controller 20, an operating system (OS) 13, and a communication interface 14.

The receiver includes a central processing unit (CPU) 41, a storage unit 42, a communication controller 50, an operating system (OS) 53, and a communication interface 54.

For bidirectional communication, each element of the transmitter and receiver performs the same function.

The communication controller 20 of the transmitter 10 is responsible for data communication with an external device, that is, the receiver 10. The communication controller 20 may be configured in hardware as is known, or may be configured in software to be in charge of communication using some or these of the central processing unit 11 and / or the operating system 13. have.

Referring to FIG. 4, which shows an example of the communication controller 20 of the transmitter 10 according to the present invention, the communication controller 20 includes a frame generation unit 21, a transmission unit 22, and a sequence designation interval adjusting unit. 23, a reception signal processing section 24 is provided.

The frame generation unit 21 generates a frame having sequence designation information and a frame having no sequence designation in accordance with the sequence numbering interval between the set information frames for the transmission target document data stored in the storage device 12 in its unique arrangement order. Here, the transmission target document data stored in the storage device 12 includes voice data input through an input device (not shown) of the transmitter in real time. In addition, the original data is data to be restored in the receiver 40 and is distinguished from state information for checking a communication state between the transmitter 10 and the receiver 40.

The ordered frame format generated by the frame generation unit 21 is divided into an ordered information frame and an ordered information frame. The ordered information frame is applied in the same manner as the conventional ordered frame format (see FIG. 1) as shown in FIG. Sequence number in the given frame control blood Ile (C _N) of 60 is the order information has been recorded is specified in order.

On the other hand, an example of the format of the non-ordering designated frame generated by the frame generation unit 21 is shown in FIG. In the drawing, the control number C of the non-ordering frame 70 is not recorded with the sequence number information for identifying the frame.

The sequence numbering interval adjusting unit 23 divides the original document information data to be transmitted by the amount of data to be recorded in the information feed (Info) according to the arrangement order, that is, the data arrangement order of the original, and the frame generation unit 21 makes a frame. In order to generate sequentially, generation intervals between the sequentially designated frames 60 are determined, and the determined sequence designation interval information is provided to the frame generation unit 21. Here, the sequence numbering interval refers to the interval between frames 60 sequentially designated among frame sequences to be sequentially generated from the original data according to the data arrangement order. For example, when the sequence numbering interval is 2, one non-order number is specified between the frame 60 numbered in any order (n times) and the frame 60 numbered next (n + 1). Refers to a structure in which the frame 70 is arranged.

The sequence designation interval adjusting unit 23 preferably varies the sequence designation interval according to the environment of the communication system.

Preferably, the order designation interval is determined in consideration of the relationship as shown in Equation 1 below.

N ∝ (MTD * JIT * ER) / (ADV * BW)

In Equation 1, N is a sequential interval, ADV is an allowed delay value, MTD is an average time delay on a channel, JIT is a jitter of a channel, and BW is allocated. The bandwidth, ER, indicates the transmission error rate of the data frame, respectively.

The reception signal processor 24 processes a response signal transmitted from the receiver 40 through the communication interface 14.

The reception signal processing unit 24 inputs a non-acknowledgement signal NAK indicating that the reception is abnormally processed from the receiver 40 with respect to the sequentially designated frame 60 transmitted from the transmission unit 22 of the transmitter 10. In this case, the sequence number information of the disapproved frame is registered in the retransmission list 25. In addition, the reception signal processing unit 24 calculates a transmission error rate from the response signal (acknowledgment signal ACK or non-acknowledgement signal) for the reception result of the sequentially designated frames 60, and converts the calculated error rate into the sequence designation interval adjusting unit 23. It is preferable to output to. In this case, the sequence designation interval adjusting unit 23 adjusts the sequence designation interval according to the input transmission error rate.

The transmitter 22 transmits the information frame generated by the frame generator 21 to the receiver 40 through the communication interface 14. In this case, the same frame data is recorded in the buffer 26 together with the transmission in consideration of the retransmission possibility for the sequentially designated frame 60.

In addition, the transmission unit 22 first checks the retransmission list 25 for each frame transmission period, and if there is a frame registered in the retransmission list 25, the transmission unit 22 receives the corresponding frame number from the buffer 26 and retransmits it. In other words, the transmission unit 22 processes the frame generation unit 21 to transmit the frames of the sequence registered in the retransmission list 25 preferentially rather than the frames waiting to be transmitted.

The transmission unit 22 starts the time counting by resetting the timer 27 at the same time as the frame transmission for the sequentially designated frame 60.

If the acknowledgment signal is not input from the reception signal processing unit 24 until the set time, for example, the round trip delay time, is reached after the sequentially designated frame is transmitted, the transmitter 22 processes the transmission frame and processes the corresponding frame. Resend.

On the other hand, the transmitter 22 deletes the frame in which the acknowledgment signal is input from the reception signal processor 24 in the buffer 26.

In connection with the data transmission process of the transmitter 10, the receiver 40 analyzes a frame received through the communication interface 44, and in particular, receives a result signal for normal reception or reception error with respect to the sequentially designated frame 60. Transmit to transmitter 10.

Hereinafter, the communication process of the communication system according to the present invention will be described in more detail with reference to FIGS. 7 to 8.

First, an information frame generation and transmission process in the transmitter 10 will be described with reference to FIG. 7.

The frame generation unit 21 sequentially generates information frames according to the sequence designation interval set by the sequence designation interval section 23 according to the data arrangement order from the transmission target document data (step 100).

The transmitter 22 determines whether there is content registered in the retransmission list 25 (step 110).

If there is content registered in the retransmission list 25 in step 110, the frame is retransmitted in the registered frame number (step 160). A time count is started for the retransmitted frame (step 140).

If there is no content registered in the retransmission list 25, the transmission unit 22 determines whether the information frame generated by the frame generation unit 21 and waiting to be transmitted is designated sequentially (step 120).

If it is determined that the sequence number is designated in step 120, the same information as the frame to be transmitted is stored in the buffer 26, and the frame is transmitted through the communication interface 14 (step 130). In addition, a time count is started (step 140).

If the sequence number is not determined in step 120, the frame is transmitted (step 150).

On the other hand, if it is determined that the acknowledgment signal (ACK) is input from the receiver 40 to the frame 60 designated in step 170, the frame is removed from the buffer (step 210), and the process returns to step 100. Alternatively, if it is determined in step 180 that the non-approval signal NAK is input from the receiver 40, the sequence number of the corresponding frame is registered in the retransmission list 25 (step 220).

In addition, in step 200, if it is determined that the counted time after the transmission has timed out without receiving any response signal from the receiver 40 for the frame 60 that has been sequentially assigned and previously transmitted, the corresponding timed out. Register the frame in the retransmission list. In step 200, the timeout time is set to a normal response delay time.

Frames exceeding the retransmission allowance range among the transmission target frames registered in the retransmission list are deleted from the list and removed from the buffer (step 230). Here, the factor for determining the retransmission allowance may be a set retransmission limit number of times and / or a retransmission limit time set based on the initial transmission. The retransmission timeout is preferably set to several times the timeout time.

As an example, if the retransmission limit is set to 3 times and / or the retransmission timeout is set to t, the same frame retransmitted up to 3 times before reaching t time after being stored in the buffer at the initial transmission time is no longer retransmitted. So that it is deleted from the buffer. Alternatively, frames that are stored in the buffer at the time of initial transmission and then reach time t are also deleted from the buffer so that they are not retransmitted.

Meanwhile, the data processing of the receiver 40 will be described with reference to FIG. 8.

First, it is determined whether an information frame has been received (step 300).

If it is determined in step 300 that the information frame has been received, the content of the received information frame is analyzed (step 310).

If it is determined in step 320 that the frames received are sequentially designated, it is subsequently determined whether there is an error (step 330). In the case of the sequentially designated error frame, a non-approved signal (NAK signal) is transmitted to the transmitter 10 (step 340).

Alternatively, in the case of normal numbered normal frames, an acknowledgment signal (ACK signal) is transmitted to the transmitter 10 (step 350), and the received frame is stored in a serial number adjustment buffer (not shown) (step 360).

On the other hand, if it is determined in step 320 that the received frame is a non-ordering designated frame, the received data is deleted if it is a frame having an error through step 370 (step 380).

Alternatively, if it is determined that the received non-ordered frame is normally received without error, the received frame is stored in the sequence adjustment buffer (step 360).

In this case, the receiver 40 does not transmit a separate response signal to the transmitter 10 regardless of the presence or absence of an error for a frame received in a non-ordering manner.

An embodiment of a data transmission process between the transmitter 10 and the receiver 40 for the communication process described above is shown in FIG. 9. In the illustrated example, the frame sequence transmitted by the transmitter 10 and the frame sequence received by the receiver 40 are shown for the case where the sequence numbering interval is set to 3. FIG.

In the figure, a block denoted by F denotes an ordered frame 60, and a subscript appended to F denotes a sequence number. In addition, a block denoted by NF indicates a non-ordering frame 70, and the first subscript of the subscripts attached to the NF indicates the previous sequence information in the data arrangement relationship, and the second subscript indicates the sequence of order between the non-ordering frames. . In the figure, the shaded one of the frames received by the receiver 40 indicates that a reception error has occurred. The response signal is not transmitted to the non-orderly designated frame NF ₂₁ among the error frames received by the receiver 40.

In this communication method, the receiver 40 transmits a response signal only for frames sequentially designated, thereby reducing a response burden, and retransmitting only frames designated among frames in which the transmitter or a reception error has occurred, thereby reducing the communication traffic. Can be reduced.

This communication method is more efficient when real-time communication is performed on specific data that allows some loss of data, such as voice data.

As described so far, according to the data communication system and the communication method thereof, the communication burden for the transmission error check and error correction for the data to be transmitted is reduced.

Claims (7)

A data communication system comprising a transmitter for transmitting data to be transmitted in units of frames and a receiver for receiving a signal transmitted from the transmitter through a communication network, The transmitter is A frame generation unit for generating the information frame having the order designation information and the non-order designation information frame according to the unique ordering interval with respect to the original data to be transmitted; And a transmitter for transmitting the information frame generated by the frame generator to the receiver through the communication network. The method of claim 1, The receiver is Transmitting a response signal corresponding to a reception normal / error only to an information frame having sequence designation information among the received information frames, The transmitter retransmits an information frame in which a reception error occurs when a reception error signal is transmitted from the receiver. The method of claim 2, The transmitter further includes a sequence designation interval adjusting unit for adjusting the sequence designation interval according to a communication environment, and controlling the frame generation unit to generate an ordered information frame and an ordered information frame by the adjusted sequence designation interval. Data communication system characterized by. The method of claim 3, The sequence designation interval adjusting unit calculates a transmission error rate of the information frames transmitted by using the error / normal signal input from the receiver, and adjusts the sequence designation interval according to the calculated transmission error rate. In a data communication method of a data communication system comprising a transmitter for transmitting data to be transmitted in units of frames and a receiver for receiving a signal transmitted from the transmitter through a communication network, end. Generating, by the transmitter, a frame having sequence designation information and a frame without sequence designation according to a unique sequence designation interval for original data to be transmitted; I. Transmitting the generated information frame to the receiver; All. If it is determined that a reception error signal is input from the receiver for the transmitted sequence number information frame, retransmitting the information frame in which the reception error occurred to the receiver; data communication method of a data communication system, comprising: . The method of claim 5, Time counting is started for the sequence numbered frame transmitted in step b. If there is no response signal from the receiver until the counted time reaches the set time, it is treated as a reception error. And retransmitting the data to the receiver. The method of claim 5, The transmitter calculating a transmission error rate for the information frames transmitted from the response signal provided for the reception result from the receiver; And adjusting the sequence designation interval according to the calculated transmission error rate.