JP2001331884A - Signal transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a signal transmission system capable of transmitting a signal at high speed even when a signal line for network control and a power supply line are wired through the same cable. SOLUTION: A power unit/communication power conveying circuit 11 alternately switches signal transmission and power supply in time-division manner. An I/O device 13 changes over a switcher 21 to the side of a communication circuit 23 at the time of signal transmission and changes over the switcher to the side of a power source part 24 at the time of power supply by operating a control circuit 22 synchronously with the switching operation of the power unit/communication power conveying circuit 11. At the time of signal transmission, a variable impedance element 25 of the communication circuit 23 is set to an optimal value corresponding to the impedance of a cable 12. When the power unit/communication power conveying circuit 11 is switched to power supply, the I/O device 13 stores power to be supplied to the power source part 24 in a capacitor 26 and supplies the power to respective circuits and afterwards, when the circuit 11 is switched to signal transmission, operating power is supplied to the respective circuits by the power stored in the capacitor 26.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention
The present invention relates to a signal transmission system for performing power supply and signal transmission to an I / O device using the same transmission cable.

[0002]

2. Description of the Related Art Generally, process control I / O devices are distributed and arranged around devices for controlling and monitoring. Conventionally, connecting these I / O devices via a network to streamline cables has been performed.

In the prior art, when a high-speed network is required, a network control signal line 2 and a power supply line 3 are separately wired to a plurality of I / O devices 1 as shown in FIG. I have.

In the case of a low-speed network, a network control signal line and a power supply line are wired with the same cable 4 as shown in FIG. The I / O device 1 transmits a signal to the I / O device 1 and supplies power.

[0005]

However, in the above conventional system, in the case of the high-speed network shown in FIG. 3, the network control signal line 2 and the power supply line 3 are different.
The effect of cable rationalization is not very large.

When the network control signal line and the power supply line are wired with the same cable 4 as shown in FIG. 4, the cable can be streamlined, but the signal transmission speed is limited. . Therefore, when a high transmission speed is required, the distance cannot be increased, and the number of nodes that can be connected to the same network as the distance decreases,
There is a problem that the effect of rationalization is reduced and the applicable range is limited.

[0007] When the network control signal line and the power supply line are wired with the same cable 4 as described above, signals cannot be transmitted at high speed due to the following points. That is, as shown in FIGS. 4 and 5, when signals and power are supplied from the power supply device / communication power transfer circuit 5 to the I / O device 1 via the cable 4, the I / O device 1
Since the internal impedance of the power supply section is low, the input / output impedance 6 is low. As a result, it is necessary to lower the impedance of the cable 4 as the transmission path. However, if the transmission characteristics of the signal do not match as a result of lowering the impedance of the transmission line, the reflection of the signal occurs at the branch point or the terminal end, and high-speed communication cannot be performed. As described above, in the related art, when the network control signal line and the power supply line are wired with the same cable, there is a problem that high-speed signal transmission cannot be performed.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems. A signal transmission system capable of transmitting signals at high speed even when a network control signal line and a power supply line are wired with the same cable. The purpose is to provide.

[0009]

According to a first aspect of the present invention, there is provided a signal transmission system for transmitting a signal having a different signal form via a transmission path between devices having a signal transmission function. The transmission is sequentially switched by division control, and the input / output impedance is set to an optimum value according to each signal form.

According to a second aspect of the present invention, in a signal transmission system for performing signal transmission and power supply between devices having a signal transmission function using the same transmission line, the signal transmission and power supply are sequentially switched by time division control. A first device for transmitting
A switching unit that switches between a power supply unit having a storage element and a communication circuit to connect to the transmission line, and switches the switching unit to the communication circuit and the power supply unit in response to signal transmission and power supply of the first device. And a second device comprising control means.

According to a third aspect, in the signal transmission system according to the second aspect, the first device and the second device include:
Control means for setting an input / output impedance to an optimum value in accordance with signal transmission and power supply is provided.

According to a fourth aspect, in the signal transmission system according to the second aspect, the second device includes control means for setting an input / output impedance to an optimum value in accordance with the characteristics of the transmission path. Features.

According to a fifth aspect of the present invention, in the signal transmission system according to the second aspect, the second device includes control means for setting an input / output impedance to a high value when the operation is stopped. And

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a configuration diagram of a signal transmission system according to an embodiment of the present invention. As shown in FIG. 1, a plurality of I / Os are connected to a power supply / communication power transfer circuit 11 via a network transmission line, that is, a cable 12.
The device 13 is connected. The power supply / communication power carrier circuit 11 separates signal transmission and power supply by time, that is, time-division, and alternately switches between signal transmission and power supply. The impedance of the cable 12 is set corresponding to the signal transmission.

On the other hand, on the I / O device 13 side, a switch 21 is provided at an input portion connected to the cable 12, and the switch 21 is controlled by a control circuit 22. The power supply unit 24 is switched. The communication circuit 23 includes a variable impedance element 25 such as a variable resistor in an input unit, and the impedance thereof is adjusted by the control circuit 22 to an optimum value corresponding to signal transmission. The value of the variable impedance element 25 adjusted by the control circuit 22 can be specified by a user. In addition, the power supply unit 24 includes a power storage element 26 such as a rechargeable battery and a capacitor. When power is transmitted from the power supply device / communication power transfer circuit 11, the power is stored in the power storage element 26. Communication circuit 23
And an operating power supply to the other circuits. The internal impedance of the power supply unit 24 is set according to the output impedance of the power supply device / communication power transfer circuit 11 when power is supplied.

The power supply / communication power transfer circuit 11 also includes a switch and a control circuit, like the I / O device 13, and controls the switch by this control circuit.
As shown in the figure, the signal transmission time and the power supply time are alternately switched by time division. In this case, the power supply device / communication power carrier circuit 11 outputs a start flag when starting signal transmission, and outputs an end flag when ending the signal transmission. I
On the I / O device 13 side, the power supply device / communication power transfer circuit 11
The control circuit 22 detects a start flag, an end flag, and the like sent from the controller 21 to control the switching of the switch 21. That is, the control circuit 22 switches the switch 21 to the communication circuit 23 when detecting the start flag, and switches to the power supply unit 24 when detecting the end flag. The switching control of the switch 21 by the control circuit 22 may be performed by outputting a synchronization signal or a switching signal from the power supply / communication power carrier circuit 11.

In the above configuration, the power supply / communication power transfer circuit 11 alternately switches between signal transmission and power supply by time division as shown in FIG. In this case, the impedance at the time of signal transmission is set to an optimal value within a range of, for example, 100 to 150Ω, and the impedance at the time of power supply is set to, for example, 10Ω or less.

The I / O device 13 detects a start flag, an end flag, and the like sent from the power supply / communication power transfer circuit 11 by the control circuit 22, and switches the switch 21 to the communication circuit 23 during signal transmission. When the power is supplied, the switch 21 is switched to the power supply unit 24 side. During signal transmission,
Signals are transmitted and received between the power supply / communication power carrier circuit 11 and the communication circuit 23. At this time, the input / output impedance (internal impedance) of the communication circuit 23, that is, the value of the variable impedance element 25 is set to an optimum value in accordance with the impedance of the power supply device / communication power transfer circuit 11 and the cable 12, so that the power supply device / High-speed transmission can be realized between the communication power carrier circuit 11 and the I / O device 13.

When the power supply / communication power transfer circuit 11 switches from signal transmission to power supply, the I / O device 13 switches the power supplied from the power supply / communication power transfer circuit 11 to the power supply unit 24 to a power storage element. 26 and the communication circuit 2
3 and so on. When the operation of the power supply device / communication power carrier circuit 11 is switched to signal transmission, the power supply unit 2
Numeral 4 supplies operating power to each circuit by using the power stored in the storage element 26.

As described above, the I / O device 13 supplies the power supply unit 2 at a predetermined time interval from the power supply device / communication power transfer circuit 11.
4 is stored in the storage element 26 and supplied to each circuit. Therefore, even if the signal transmission and the power supply are alternately switched in the power supply / communication power transfer circuit 11, the power supply unit 24 can continuously supply power to each circuit.

According to the above embodiment, the input / output impedance can be optimized during signal transmission and power supply, and signal transmission can be performed at high speed. Further, even when the characteristics of the network are changed by adding a node such as the I / O device 13, the variable impedance element 25
By adjusting the setting, the optimum input / output impedance can be set.
A high-speed signal transmission state can be maintained.

In the above embodiment, the switching circuit 21 switches between the communication circuit 23 and the power supply section 24 to obtain the optimum impedance. However, the input section of the I / O device 13 is provided with a variable impedance element. The value of the variable impedance element may be variably controlled by a control circuit in accordance with time-division timing. That is, the variable impedance element is variably controlled to a large value during signal transmission, and to a small value during power supply. Even with such a configuration, the same effect as in the above embodiment can be obtained.

In the above embodiment, when signal transmission is performed between the power supply / communication power carrier circuit 11 and the plurality of I / O devices 13, the signal transmission and the power supply are alternately switched by time division. Although the input / output impedance is optimized by using the above method, the signal transmission may be performed at an optimum input / output impedance by time division control, for example, between arbitrary nodes. In this case, the time-division control is not limited to signal transmission and power supply, but can be performed when switching between transmission modes having different impedances to obtain a great effect.

Further, in the above embodiment, the case where a variable resistor is used as the variable impedance element 25 has been described, but the phase of the voltage and current of the signal to be transmitted is further taken into consideration.
With the configuration in which the adjustment is performed using the variable reactance and the variable capacitance, the impedance can be adjusted with higher accuracy.

When an abnormality occurs in the control circuit 22 or the storage element 26 in the I / O device 13, the impedance which reduces the influence on the network is provided by:
That is, the switch 21 is switched to the communication circuit 23 side, and the circuit conditions are set such that the I / O device 13 is stopped while the high impedance is connected to the cable 12. With such a configuration, a certain I / O
Even if the device 13 stops operating due to a failure, the characteristics of the network can be maintained at a normal value, and the other I / O devices 13
Adverse effects can be prevented.

[0026]

As described above, according to the present invention, when the same transmission line is used for signal transmission and power supply between a power supply / communication power carrier circuit and an I / O device, the power supply The communication power carrier circuit alternately switches between signal transmission and power supply in a time-division manner, and the I / O device transmits the communication circuit and the power supply according to the switching operation of the power supply device / communication power carrier circuit. When switching to signal transmission, power is supplied to each circuit by using the power stored in the storage element when switching to signal transmission. Therefore, even if time division control is performed, power can be supplied continuously, and input / output impedance can be optimized during both signal transmission and power supply, so that signal transmission can be performed at high speed. . Further, since the I / O device has a variable impedance element as an input / output impedance, even when the characteristics of the network are changed by adding a node, the optimum impedance can be set by adjusting the variable impedance element, and the high-speed operation can be performed. The signal transmission state can be maintained. Also, when the I / O device stops operating due to a failure or the like, the input / output impedance is set to a high value. Therefore, even if a certain I / O device stops operating, the network characteristic is set to a normal value. Can be kept in
An adverse effect on other I / O devices can be prevented.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a signal transmission system according to an embodiment of the present invention.

FIG. 2 is an exemplary view for explaining a time division control operation in the embodiment.

FIG. 3 is a configuration diagram showing a signal transmission system when configuring a conventional high-speed network.

FIG. 4 is a configuration diagram of a conventional signal transmission system for a low-speed network in which signal transmission and power supply are performed by the same transmission line.

FIG. 5 is a diagram for explaining the operation of a conventional low-speed network signal transmission system.

[Explanation of symbols]

 Reference Signs List 11 power supply device / communication power transfer circuit 12 cable 13 I / O device 21 switch 22 control circuit 23 communication circuit 24 power supply unit 25 variable impedance element 26 power storage element

Claims (5)

[Claims] In a signal transmission system for transmitting signals having different signal forms between devices having a signal transmission function via a transmission path, signals having different signal forms are sequentially switched by time division control and transmitted. A signal transmission system, wherein input / output impedance is set to an optimum value according to each signal form. 2. In a signal transmission system in which signal transmission and power supply are performed using the same transmission path between devices having a signal transmission function, the signal transmission and power supply are sequentially switched by time division control and transmitted. Switching means for switching between a device, a power supply unit having a power storage element, and a communication circuit to connect to the transmission line, and the switching device corresponding to the signal transmission and power supply of the first device. And a second device comprising a control unit for switching to a power supply unit. 3. The signal according to claim 2, wherein the first device and the second device include control means for setting an input / output impedance to an optimum value in accordance with signal transmission and power supply. Transmission system. 4. The signal transmission system according to claim 2, wherein the second device includes a control unit that sets an input / output impedance to an optimum value according to characteristics of a transmission path. 5. When the second device stops operating,
3. The signal transmission system according to claim 2, further comprising control means for setting the input / output impedance to a high value.