JPS6113251B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an automatic power-on method in a data transmission system configured to turn on power to a terminal device only when necessary.

In a banking system, a center sends data such as the day's trading volume to each branch at night. In order to receive data, each terminal device must be powered on, but it would be wasteful to leave the power on all day, so conventionally, a timer operates at a certain time and the terminal device A method of turning on power to a terminal device, or a method of detecting a carrier on a line sent from a center and turning on power to a terminal device, etc. have been adopted. Although the former method allows the power to be turned on almost at the same time as the data is transmitted, it has the disadvantage that some power is wasted. The latter method of turning on the power by carrier detection has the disadvantage of causing malfunctions due to noise. Furthermore, in the latter method, if a repeater is provided in the middle of the line, there is a risk that a malfunction of the repeater may cause a terminal device other than the designated one to be powered on.

The present invention is based on the above consideration, and provides an automatic power-on method in a data transmission system that ensures that the power of the corresponding terminal device is turned on when data is transmitted from the center. It is intended to. And for that reason,
The automatic power-on method in the data transmission system of the present invention includes a control device, a terminal device connected via a communication line, and a power-on device, and includes address data and command data specifying predetermined processing. , data, and data is transmitted between the control device and the terminal device. In the power-on method, the control device transmits address data pointing to the terminal device to be powered on and command data instructing power-on to the communication line as address data and command data of the data group of the unit, and , the power-on device includes a circuit that outputs a permission signal indicating power-on permission based on the address data and command data of the data group transmitted to the communication line, and a circuit that outputs a permission signal indicating power-on permission, and a circuit that outputs a permission signal indicating that the terminal device is already in a power-on state. The present invention is characterized in that it is provided with means for prohibiting power-on of the terminal device based on the permission signal. The present invention will be explained below with reference to the drawings.

FIG. 1 is a block diagram of one embodiment of the present invention, and FIG.
The figure shows an example of the format of the control signal.
FIG. 3 is a block diagram of one embodiment of the power-up device.

In FIG. 1, M ₁₁ to Mn ₁ and M ₁₂ to Mn ₂ are modems, T ₁ to Tn are terminal devices, D ₁ to Dn are power-on devices, and H is a data processing device on the center side. The data transmission system of FIG. 1 is, for example, a banking system, and the terminals _T1 to Tn are bank terminals. During the day, the terminal devices _T1 to Tn are always powered on. Center side data processing device H, modem M ₁₁ to Mn ₂ , power supply device D ₁ to Dn
The power is turned on day and night. As mentioned earlier, in the banking system, the data processing system at the center sends processed data to the terminal devices _T1 to Tn at each branch even at night. Since the terminal devices _T1 to Tn are not powered on at night, in order to receive processing data from the data processing device H on the center side, the corresponding terminal device, for example, terminal device _T1 , must first be powered on. Must-have.

Figure 2 shows data processing from the data processing device H on the center side to the terminal devices _T1 to Tn, or from the data processing device H on the center side to the terminal devices _T1 to Tn.
This shows the format of the control signal transmitted from _T2 to the data processing device. In Figure 2, F
is the flag part, A is the address part, C is the instruction part, and the FCS part is the CRC (cyclic check).
code) section. The above control signal is
SDLC procedures are followed. The format of the message is flag-address-instruction-data-
It is called FCS. The instruction part consists of 8 bits and can express a total of 256 types of instructions. One of the codes can be selected as the power-on command. Further, the power-on command can also be used as another control command, and can be different for each terminal device.

FIG. 3 shows one embodiment of the power-on device, in which 1 is a code detection section, 2 is a register, and 3 is a
FCS calculation unit, 4 is a counter, 5 is a comparison circuit, 6
is a setting board, 7 is an AND circuit, 8 is a clock generator, RD is reception data, and RT is reception timing.

The code detection unit 1 detects a flag part of received data. When the flag section is detected, the data following it is stored in register 2. According to the SDLC transmission procedure, if there are five consecutive ``1''s, a ``0'' is added after them, and the ``0'' suppress signal is for suppressing these ``0''s.
The address and command stored in register 2 are compared with the address and command set by setting board 6. In this case, the address set by the setting board 6 is the address of the own terminal device,
Needless to say, the command is a power-on command. The FCS calculation unit 3 performs a CRC (cyclic check) from the address part and instruction part of the received data.
code) and use this code and the received data as
It is compared with the FCS section by a comparator circuit 5. The counter 4 counts the number of characters. When all comparison results match, the comparison circuit 5
Generates an OK signal. The OK signal is applied to the input terminal of the AND circuit 7. The REM signal and *RLI signal are applied to other input terminals of the AND circuit 7.
The REM signal is a signal indicating whether or not the terminal device is in remote control mode, and is logic "1" when in remote control mode. The RLI signal is a signal indicating whether or not the terminal device is powered on, and is logic "1" when the terminal device is powered on. AND circuit 7 receives an OK signal,
“1” when REM signal and *RLI signal are “1”
Output. As a result, the terminal device is powered on. As the power-on section in the terminal device, either a locking type or a non-locking type can be used.

As is clear from the above description, according to the present invention, (a) an operator on the terminal device side is not required, and (b) the power of the terminal device is turned on when receiving data, resulting in power savings. Therefore, an automatic power-on method in a data transmission system can be obtained which has excellent effects such as:

[Brief explanation of the drawing]

FIG. 1 is a block diagram of one embodiment of the present invention, and FIG.
The figure shows one example of the format of the control signal used in the present invention, and FIG. 3 shows a block diagram of one embodiment of the power-on device. H...Data processing device on the center side, _M11 or
Mn ₂ ...Modem, _D1 or Dn...Power supply device, 1...Sign detection unit, 2...Register, 3...
FCS calculation section, 4...Counter, 5...Comparison circuit, 6...Setting board, 7...AND circuit, 8...Clock generator.

Claims (1)

[Claims] 1. It has a control device, a terminal device connected via a communication line, and a power-on device, and includes address data, command data specifying predetermined processing,
Data is transmitted between the control device and the terminal device, and the terminal device is an automatic power supply of the data transmission system that is powered on according to instructions from the power supply device. In the power-on method, the control device transmits address data pointing to the terminal device to be powered on and command data instructing power-on to the communication line as address data and command data of the data group of the unit, and , the power-on device includes a circuit that outputs a permission signal indicating power-on permission based on the address data and command data of the data group transmitted to the communication line, and a circuit that outputs a permission signal indicating power-on permission, and a circuit that outputs a permission signal indicating that the terminal device is already in a power-on state. 1. An automatic power-on method for a data transmission system, comprising means for prohibiting power-on of said terminal device by said permission signal when said signal is supplied thereto.