JPH0548013B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an error control method for eliminating data errors caused by transmission errors by retransmission correction in digital facsimile communication using a telephone network.

Conventionally, when a transmission error occurs in facsimile communication using a telephone network, the receiver processes the error in the facsimile data and cannot reproduce the received image correctly. The method of pre-line replacement is used. This method guarantees against data errors, but does not faithfully reproduce transmitted data.

On the other hand, automatic repeat correction (ARQ) is an error control method that removes errors in received data.
As a typical example, the high-level data link control (HDLC) procedure is in practical use. When HDLC is applied to telephone networks, half-duplex communication methods must generally be used because the two-wire subscriber telephone network occupies the main part of the telephone network. Therefore, additional time is required to obtain a response from the receiver indicating the presence or absence of data errors, and switching time is also required to switch the signal transmission direction, resulting in an extremely inefficient method.

Therefore, a method can be considered in which a two-wire line is divided into weekly steps, and a forward direction transmission path for transmission from a transmitter and a reverse direction transmission path for transmission from a receiver are constructed, and error control is performed using a full-duplex system. Since this method is full-duplex, a response in the reverse direction can be immediately returned for data in the forward direction, making it extremely efficient. However, the telephone network has a limited frequency band, and dividing the frequency band reduces the forward band, increasing the forward data error rate and reducing transmission efficiency. It has a bottleneck.

The present invention has been made in view of the above-mentioned conventional circumstances, and therefore, an object of the present invention is to use a tone signal as a backword (reverse direction) signal for requesting retransmission of erroneous data. The object of the present invention is to provide a new error control method capable of efficiently performing error control in a telephone network, while eliminating the above-mentioned drawbacks.

In order to achieve the above object, the error control method according to the present invention is such that, in the error control method based on the ARQ method in the telephone network, a transmitting device that transmits digital data divides the transmitted data into blocks, and arranges the transmission order for each block. The receiving device includes an error code detector and a data generating unit including means for adding a sequence number according to the sequence number and a code for error detection, and a tone signal detector indicating a request for error retransmission. a detector, a timer that monitors the reception interval of data blocks and checks after a certain period of time whether or not the data blocks that should be received within the interval have been received; and the data blocks that were not received and the received data. and a tone signal generating section that transmits a tone signal for instructing a retransmission request only for a received data block that is determined to be erroneous by the error code detector and the sequence number abnormality detector among the blocks, the transmitting device Further, between the transmitting and receiving devices, at the beginning of the error control communication control procedure, the own device transmits a command signal, the receiving device receives the command signal, and then receives a response signal from the receiving device corresponding to the command signal. The data block is configured to include a timer for counting the time required until detecting that a tone signal has been detected, and means for determining a sequence number of a data block to start retransmission when a tone signal is detected based on the counting result.

That is, in the present invention, a device that transmits data using a telephone network can execute an error control method based on the ARQ method, and the receiving device can reproduce error-free data. That is, the transmitting device divides the transmitted data into pieces with a specified data block length or less, and
A sequence number addition mechanism provided for each block adds a sequence number according to the transmission order. Furthermore, an error detection code is added by an error detection code generator, and the data is sent to the line.
In this process, a unique synchronization code or delimiter is generally inserted at the boundary between block divisions, and a cyclic redundancy check (CRC) code is used as an example of an error detection code. A modulated signal is sent to the modem.

The receiving device uses each detector to check the sequence number and error detection code added to each block of the demodulated data to check its validity. As a result, if a data block determined to be erroneous appears, the tone signal generator transmits a tone signal to the transmitter to request retransmission of the data block in which the error was detected.

When the tone detector detects this tone, the transmitter determines that a retransmission request has been made and retransmits the data block. In the HDLC procedure, the sequence number information of the data block to be retransmitted is included in the response signal for requesting retransmission, so that the retransmission data block is uniquely determined.

However, when a tone signal is used as a response signal, it is difficult to transmit such detailed information. To this end, the present invention includes means for counting the time required for a response signal to be returned from a receiving device in response to a command signal transmitted by a transmitting device, and a sequence number for a data block that starts retransmission based on the counting result. and the means to decide;
The turnaround time, which consists of the round-trip transmission and reception time including the propagation delay on the transmission path, and the processing time required for transmission and reception in the receiving device, is counted, and when a tone signal is detected, the latest sequence number of the data blocks that have been transmitted before this turnaround time is calculated. Retransmission starts from the data block with .

The effect of using a tone signal as a response signal in the reverse direction is that the tone signal can be transmitted in an extremely narrow band, and when full-duplex communication is performed by band division on a two-wire transmission line, the reduction in the forward direction band is minimized. Therefore, it becomes possible to transmit a response signal for a retransmission request without substantially degrading forward data transmission characteristics.

Next, a preferred embodiment of the present invention will be specifically explained with reference to the drawings.

FIGS. 1a and 1b are block diagrams showing one embodiment of the present invention.

Referring to FIGS. 1a and 1b, a is a transmitting device, b
indicate receiving devices, respectively. The transmitting device in figure a is
A data generator 1 generates original data to be transmitted, a block length counter 2 counts the data length, and a block division circuit 3 divides the data so that the data length of the block is less than or equal to a predetermined length. divided into two parts. A sequence number corresponding to the transmission order is added to the divided data block 20 by a sequence number adding circuit 4, and a sequence number corresponding to the transmission order is added to the divided data block 20 by an error detection encoder 5. An error detection code is added. A data generating section 6 is constituted by including these components, and a data block 20 is output. This output is stored in a buffer memory 7 for error control and transmitted to the line through a modulator 8 and a hybrid circuit 9 in sequence number order.

In the receiving device, as shown in Figure b, a carrier detector 14 detects the presence or absence of a signal through a hybrid circuit 9' and a demodulator 13, and an error code detector 15 detects data errors in blocks with respect to the demodulated data. Check. Furthermore, the sequence number abnormality detector 16 detects data whose sequence number does not match the order of the received data among the data blocks that have passed the error check in the error code detector 15 and are determined to have no errors. Treat the block as having an abnormal sequence number and make it the target of a playback request. When the control unit 18 receives notification of a data error from the error code detector 15 and the sequence number abnormality detector 16, it immediately activates the tone generator 17 for a certain period of time and sends a tone signal to the line via the hybrid circuit 9'. Send.

The transmitting device detects this tone signal via the hybrid 9 with the tone detector 10, and then detects the tone signal with the control section 11.
Notify. When the control unit 11 learns that a retransmission request has been made, it instructs the buffer memory 7 to start retransmission from the data block whose sequence number goes back by the lowest value. In this way, the retransmission of the erroneous data is executed, and the receiving device discards the block of erroneous data and accepts only the correct data, so that the data error is corrected at the receiving device when the retransmission is executed.

An example of a data block is shown in FIG. In this embodiment, a block of data in the HDLC procedure is called a frame. data block 2
0 is composed of a synchronization code 21 indicating a block boundary, a control code 22 including a sequence number, data 23 which is transmission information, and an error detection code 24.

FIG. 3 shows the power spectra of forward and reverse signals resulting from band division. A modulated wave by a high-speed data modem is transmitted in the forward direction, and a tone signal is transmitted in the reverse direction. As an example, in a modem compliant with CCITT Recommendation V ₁ 27, the power spectrum 31 is very small in the low range of 300 to 500 Hz of the signal pass band of the telephone network. If the power spectrum 32 of the tone signal is placed in the center of this band, it is easy to separate the two signals by band division, and a band rejection filter for frequency division,
It becomes economically possible to implement a band extraction filter.

On the other hand, Recommendation V ₁ is used as a response signal in the opposite direction.
Considering the case where a signal from a 75 baud modem is used for a backward channel of 27, the power spectrum 33 and the forward spectrum 31 become close to each other, making frequency separation difficult. Filters for this purpose require steep characteristics and are extremely expensive.

A backward modem allows a receiving device to send an acknowledgment (ACK) for a correctly received and a negative acknowledgment (NAK) for an error, and to include in the NAK signal the sequence number of the data block to be retransmitted. be able to.

On the other hand, since it is difficult to insert a sequence number as a NAK signal in response to a tone signal, the sequence number of the retransmitted data block can be determined by the method shown in FIG.

FIG. 4 is a diagram showing the sequence of signal exchange between the transmitting device and the receiving device. At the beginning of communication, the transmitting device transmits a command signal 41 and a response signal 4.
The turnaround time T until receiving 2 is measured by the timer 12 in FIG. 1a. The transmission data blocks 43 are transmitted with sequence numbers D ₀ , D ₁ , D ₂ . . . . Now data block D ₂
If an error is detected, a negative acknowledgment tone signal 44 requesting retransmission is transmitted. When the transmitter detects this response signal, it retransmits data block _D2 , which has a sequence number that is a certain value back from the data block currently being transmitted. If the data block length is L and the forward data transmission rate is S, a sequence number that goes back a certain value can be defined as a sequence number older than (S/L) x T.
This is efficient because it prevents unnecessary retransmission of data blocks. There is a large difference in the value of T between terrestrial lines and satellite lines.

Furthermore, when a data block that cannot be detected by the receiving device occurs, such as data blocks _D5 and _D6 , a sequence abnormality is detected only when data block _D7 is received, so if a response signal is returned at this point, In retransmission control using the above formula,
Errors become irrecoverable. Therefore, with the help of _the timer ₁₉ shown in FIG. If the value is returned, the validity of the playback control based on the above calculation formula can be guaranteed.

As explained above, the present invention includes a data generator 6 having a sequence number and an error detection code for each block, an error code detector 15, a sequence number abnormality detector 16, a tone signal generator 17, and a tone detector 10. By configuring a system based on this, we have made it possible to inexpensively and efficiently realize error control in full-duplex data transmission using frequency division in a telephone network.

Although the present invention has been described above with reference to one preferred embodiment thereof, this is merely an illustrative example, and the present invention is not limited only to the embodiment described here, but can be applied to all aspects within its scope. Of course, it includes modifications and changes.

[Brief explanation of the drawing]

FIGS. 1a and 1b show an embodiment of the present invention as a transmitting device,
A block configuration diagram showing the main parts of the receiver, Figure 2 shows the configuration of the data block to be transmitted, and Figure 3 shows the power spectrum and occupied frequency band of the signals transmitted in the forward and reverse directions. A diagram showing
FIG. 4 is a diagram showing a sequence of signal exchange between transmitting and receiving devices that performs error control. DESCRIPTION OF SYMBOLS 1... Data generation section, 2... Block length counter, 3... Block division circuit, 4... Sequence number addition circuit, 5... Error detection encoder, 6... Data generation section, 7... Buffer memory, 8...Modulator, 9,9'...hybrid circuit, 10...Tone detector, 11...Control unit, 12...Timer,
13... Demodulator, 14... Carrier detector, 15
...Error code detector, 16...Sequence number abnormality detector, 17...Tone generator, 18...Control unit, 19...Timer, 20...Data block,
21... Synchronization signal indicating the block boundary, 22...
...Control code including sequence number, 23...Data, 24...Error detection code, 31-33...Power spectrum, 41...Command signal, 42...Response signal, 43...Transmission data block, 4
4...Tone signal, 45...Response signal.

Claims (1)

[Claims] 1. In an error control system based on the ARQ system in a telephone network, a transmitting device that transmits digital data divides the transmitted data into blocks, adds a sequence number according to the transmission order to each block, and detects errors. The receiving device is equipped with a data generator including a means for adding a detection code and a tone signal detector indicating a request for error retransmission, and the receiving device includes an error code detector, a sequence number abnormality detector, and a data block receiving interval. a timer that monitors and checks after a certain period of time whether or not a data block to be received within the interval has elapsed; and an error code detector and sequence for the unreceived data block and the received data block. and a tone signal generating unit that transmits a tone signal for instructing a retransmission request only for the received data blocks determined to be errors by the number abnormality detector, and the transmitting device further includes:
At the beginning of a communication control procedure for error control, a command signal is transmitted from the own device, the command signal is received by the receiving device, and the process is performed until detecting that a response signal from the receiving device corresponding to the command signal has been received. A data transmission device using a telephone network, comprising: a timer for counting the required time; and means for determining a sequence number of a data block to start retransmission when a tone signal is detected based on the counting result. error control scheme.