JPH07336410A - Data transmitting device - Google Patents

Abstract

PURPOSE:To reduce the processing load on a terminal equipment and a modem which are contained in a data transmitting device. CONSTITUTION:A data transmitting device contains a terminal equipment 1 and a modem 2. The modem 2 includes a transmission data buffer 3 which temporarily stores the transmission data that are not followed by the transmission request signal sent form the equipment 1, a data detecting part 4 which detects the transmission data sent from the equipment 1, and a control part 6 which starts the transmission of the carrier sent from a modulating part 5 based on the detection signal of the transmission data acquired from the part 4 and then modulates and transmits the transmission data stored in the buffer 3 through the part 5.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data transmission device equipped with a terminal device and a modem for modulating and transmitting data. A data transmission device that transmits and receives data via a dedicated line or public line is a personal computer (personal computer).
Etc., and a modem for modulating and transmitting data and demodulating the received modulated signal into data. In that case, various standardized systems are known for the interface between the terminal device and the modem, and it is desired to reduce the processing load of the terminal device.

[0002]

2. Description of the Related Art FIG. 3 is an explanatory view of a conventional data transmission apparatus. The data transmission apparatus comprises a terminal device 31 such as a personal computer (personal computer) and a modem 32 including a modulation section and a demodulation section. The interface between the terminal device 31 and the modem 32 is, for example, RS-232.
C and the like have standardized mechanical characteristics and electrical characteristics.

In FIG. 3, the terminal device 31 and the modem 3 are shown.
2 shows a signal line in the case of being connected to the No. 2 by an RS-232C interface. The terminal device 31 sends to the modem 32 the transmission data SD and the transmission request signal R.
S and the terminal device ready signal ER are transferred. Modem 3
The reception data RD, the transmission enable signal CS, the data set ready signal DR, the carrier detection signal CD, the transmission data timing signal ST2, the reception data timing signal RT, and the ring detection signal CI are transferred from 2 to the terminal device 31. Note that SG indicates a signal ground line.

FIG. 4 is a time chart of a conventional example, showing a case of transmitting data by a dedicated line in a half-duplex communication system, ER is a terminal device ready signal, DR is a data set ready signal, and CD is a carrier. A detection signal, RS is a transmission request signal, CS is a transmission enable signal, TC is transmission data on the line, and RC is reception data on the line. First, the terminal device ready signal ER is sent from the terminal device 31 to the modem 32.
Is turned on (from low level to high level). As a result, the modem 32 turns on the data set ready signal DR after a time t ₁ (from low level to high level). The terminal device 31 turns on the transmission request signal RS by turning on the data set ready signal DR. When the transmission request signal RS is turned on, the modem 32 sends a training signal Z having a repeating pattern of "1", "0" or the like to the line as shown by TC.

After transmitting the training signal Z to the line, the modem 32 turns on the transmission request signal RS and, after a lapse of a certain time, the transmission enable signal CS turns on t ₄ and then the terminal device 3
The transmission enable signal CS for 1 is turned on. Terminal device 31
Transmits the transmission data SD when the transmission enable signal CS is turned on, the modem 32 modulates the transmission data SD and
After the training signal Z, the data D
It is sent to the line as ATA. After sending the transmission data SD to the modem 32, the terminal device 31 turns off the transmission request signal RS (from high level to low bell). Modem 32
Turns off the transmission enable signal CS after a predetermined time due to the transmission request signal RS turning off, and stops carrier transmission.

Further, as indicated by RC, when receiving the training signal Z from the partner data transmission device, the modem 32 turns on the carrier detection signal CD after the carrier detection response time t ₃ . Thereby, the terminal device 31 prepares to receive the data DATA when the carrier detection signal CD is turned on, and performs the reception process of the reception data RD demodulated by the modem 32.

Further, the modem 32 receives the carrier detection signal C after the carrier detection response time due to the end of the reception of the data DATA.
When turning off D and ending the communication, the terminal device 31 turns off the terminal device ready signal ER. The modem 32 turns off the data set ready signal DR after a time t ₂ after turning off the terminal device ready signal ER. When the terminal device 31 turns off the terminal device ready signal ER after transmitting / receiving data to / from the partner data transmission device in this way, the modem 32 causes the data set ready signal DR to the terminal device 31 after time t _2. To turn off.

[0008]

As described above, when transmitting data, the terminal device 31 transmits the transmission request signal RS.
After turning on, it is necessary to monitor whether or not the transmission enable signal CS from the modem 32 is on, and confirm that the transmission enable signal CS is turned on before sending the transmission data SD to the modem 32. is there. That is, there is a problem that the processing load on the terminal device 31 is large due to the complicated transmission procedure.

In the modem 32, carrier transmission (training signal Z transmission) is started when the transmission request signal RS is turned on from the terminal device 31, and after the time when the modem of the partner data transmission device can receive data, Terminal device 31
It is necessary to turn on the transmission enable signal CS for. Further, it is necessary to stop the carrier transmission by turning off the transmission request signal RS from the terminal device 31. Therefore, there is a problem that the modem 32 needs to perform processing such as time monitoring. An object of the present invention is to reduce the processing load on the terminal device and the modem.

[0010]

The data transmission apparatus of the present invention will be described with reference to FIG. 1. The transmission data from the terminal apparatus 1 is temporarily stored in the modem transmission section 7 of the modem 2. The buffer 3, the data detection unit 4 that detects the transmission data from the terminal device 1, and the modulation unit 5 starts carrier transmission based on the detection signal of the transmission data by the data detection unit 4, and transmits after a predetermined time elapses. A control unit 6 is provided for modulating the transmission data accumulated in the data buffer 3 in the modulation unit 5 and transmitting the modulated transmission data. Further, 8 is a modem receiving unit, 9 is an interface unit, and 10 is a line.

[0011]

The transmission data is transmitted to the modem 2 via the interface unit 9 without transmitting the transmission request signal RS from the terminal device 1 to the modem 2. The modem 2 stores the transmission data in the transmission data buffer 3. When the data detection unit 4 detects the transmission data from the terminal device 1, the detection signal is added to the control unit 6. The control unit 6 controls the modulation unit 5 with this detection signal to start the carrier transmission on the line 10 by the training signal or the like. Then, when the carrier detectable time in the partner data transmission device elapses, the transmission data accumulated in the transmission data buffer 3 is added to the modulator 5 and modulated, and is transmitted to the partner data transmission device via the line 10. Send out. Further, the data detection unit 4 can detect whether or not the transmission is completed depending on the presence or absence of the transmission data in the transmission data buffer 3. Therefore, when the transmission completion of the transmission data is detected, the control unit 6 is notified, and the control unit 6 causes the modulation unit 5 to perform the notification. To stop carrier transmission from.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is an explanatory view of an embodiment of the present invention, in which a data transmission device is constituted by a terminal device 1 and a modem 2, and the modem 2 comprises a modem transmitting section 7, a modem receiving section 8 and an interface section 9. It has and. The modem reception unit 8 includes a demodulation unit (not shown) that receives and demodulates data transmitted from the partner data transmission device via the line 10.
The modem transmission unit 7 also includes a transmission data buffer 3, a data detection unit 4, a modulation unit 5, and a control unit 6.

The transmission data buffer 3 has a capacity equal to or less than the amount of transmission data for one transmission, and is sufficient to store the transmission data SD from the terminal device 1. The data detection unit 4 detects the transmission data SD from the terminal device 1, and detects, for example, the head of the transmission data SD added to the interface unit 9 or the head of the transmission data SD added to the transmission data buffer 3. In order to detect and identify the end of transmission, the transmission data SD from the terminal device 1 disappears and the transmission data SD is stored in the transmission data buffer 3.
Is equipped with a function of detecting that no longer exists. In this case, for example, it is turned on (“1”) by detecting the beginning of the transmission data SD, and turned off (“0”) when there is no transmission data SD from the terminal device 1 and there is no transmission data SD in the transmission data buffer 3. ) And a detection signal. The detection signal from the data detector 4 is applied to the controller 6. The controller 6 controls the transmission data buffer 3 and the modulator 5 based on the detection signal from the data detector 4.
And control.

The transmission request signal RS from the terminal device 1 to the modem 2 and the transmission enable signal CS from the modem 2 to the terminal device 1 corresponding thereto are omitted. Therefore, the terminal device 1 transmits the transmission request signal RS. The transmission data SD is transferred to the modem 2 without transmitting and without identifying the transmission enable signal CS. The modem 2 stores the transmission data SD in the transmission data buffer 3 via the interface unit 9. When the data detection unit 4 detects the head of the transmission data SD added to the interface unit 9 or the head of the transmission data SD stored in the transmission data buffer 3 as described above, the detection signal is added to the control unit 6. .

The control unit 6 controls the modulation unit 5 by the detection signal which detects the head of the transmission data SD from the data detection unit 4 to control the repeat pattern of "1" and "0" for the partner data transmission device. A training signal such as is transmitted via the line 10. The transmission data SD from the terminal device 1 is accumulated in the transmission data buffer 3 even during the transmission of the training signal. Then, after a time corresponding to the carrier detection response time of the partner data transmission apparatus from the start of the training signal transmission, the transmission data S from the transmission data buffer 3
D is modulated by the modulator 5 and sent to the line 10. Further, the transmission data SD from the terminal device 1 during the transmission of the data to the line 10 is also added to the transmission data buffer 3 and is transmitted via this transmission data buffer 3. Various known means can be applied to such address control of writing and reading of data in the transmission data buffer 3.

There is no transmission data SD from the terminal device 1,
When the transmission data SD in the transmission data buffer 3 also disappears, the data detection signal from the data detection unit 4 is turned off (“0”). Therefore, the control unit 6 determines that the transmission is completed, controls the modulation unit 5, and stops the carrier transmission after a predetermined time.

FIG. 2 is a time chart of an embodiment of the present invention. ER is a terminal device ready signal, DR is a data set ready signal, SD is transmission data, DET is a data detection signal, and TC is data on the line 10. Indicates. First, when the terminal device ready signal ER from the terminal device 1 to the modem 2 is turned on, the data set ready signal DR from the modem 2 to the terminal device 1 is turned on. When the data set ready signal DR is turned on, the terminal device 1 immediately transfers the transmission data SD to the modem 2 without sending the transmission request signal RS.

The modem 2 adds the transmission data SD from the terminal device 1 to the transmission data buffer 3 via the interface section 9 and accumulates it. The detection signal DET obtained by detecting the head of the transmission data SD by the data detection unit 4 is added to the control unit 6. The control unit 6 controls the modulation unit 5 by the detection signal ON (“1”) to start transmitting the training signal Z as indicated by TC. The transmission data SD from the terminal device 1 during transmission of the training signal Z is also transmitted to the transmission data buffer 3
Accumulated in.

The control unit 6 continuously transmits the training signal Z from the modulation unit 5 for a time corresponding to the carrier detection response time of the partner data transmission device, and then the transmission data SD stored in the transmission data buffer 3. Is modulated in the modulator 5 and sent to the line 10 as data DATA.

When the transmission data SD from the terminal device 1 disappears and the transmission data SD in the transmission data buffer 3 also disappears, the detection signal of the data detector 4 is also turned off ("0").
Therefore, the control unit 6 determines that the transmission has ended, and stops the carrier transmission from the modulation unit 5 after a predetermined time.

The present invention is not limited to the above-mentioned embodiment but can be variously modified and added, and can be applied not only to the half-duplex communication system but also to the full-duplex communication system. is there. Further, the data detection unit 4 applies a detection signal when the head of the transmission data SD from the terminal device 1 is detected to the control unit 6, and the transmission data SD from the terminal device 1 disappears and the transmission data buffer 3 It is also possible to adopt a configuration in which a detection signal when it is detected that the transmission data SD is gone is added to the control unit 6.

[0022]

As described above, according to the present invention, since the modem 2 is provided with the transmission data buffer 3, the data detection unit 4, and the control unit 6, the transmission request signal RS is transmitted from the terminal device 1. The transmission data SD is transferred to the modem 2 without being transmitted, and the modem 2 temporarily stores the transmission data SD in the transmission data buffer 3 and after transmitting the training signal from the modulation unit 5 under the control of the control unit 6, the transmission data SD is transmitted. The transmission data SD in 3 can be modulated by the modulation unit 5 and transmitted, and the transmission request signal RS from the terminal device 1 can be transmitted.
Is unnecessary, and the modem 2 does not need to transmit the corresponding transmission enable signal CS, which has the advantage of simplifying the procedure at the time of data transmission between the terminal device 1 and the modem 2. Since the processing load on the terminal device 1 is reduced, it is possible to direct the data to other data processing.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of an embodiment of the present invention.

FIG. 2 is a time chart of an example of the present invention.

FIG. 3 is an explanatory diagram of a conventional example.

FIG. 4 is a time chart of a conventional example.

[Explanation of symbols]

 1 Terminal Device 2 Modem 3 Transmission Data Buffer 4 Data Detection Section 5 Modulation Section 6 Control Section 7 Modem Transmission Section 8 Modem Reception Section 9 Interface Section 10 Lines

Continuation of front page (51) Int.Cl. ⁶ Identification number Office reference number FI technical display location 9297-5K H04L 27/00 Z

Claims (1)

[Claims] 1. A data transmission device comprising a terminal device (1) and a modem (2), wherein transmission data from the terminal device (1) is temporarily stored in the modem (2). A data buffer (3),
A data detection section (4) for detecting transmission data from the terminal device (1), and a modulation section (5) to start carrier transmission based on a detection signal of the transmission data by the data detection section (4), A data transmission device, comprising: a control unit (6) that modulates the transmission data accumulated in the transmission data buffer (3) after a lapse of a predetermined time in the modulation unit (5) and transmits the modulated transmission data.