JPH0738538A - Data transmission method - Google Patents

Abstract

PURPOSE:To provide a data transmitting system which can confirm whether transmission is normal or not on the transmission side, can decrease the number of transmission lines, can shorten transmission time as well and further can protect a circuit by detecting the short-circuiting of transmission lines without providing any dedicated short-circuiting detection circuit. CONSTITUTION:Series of transmitting signals TS containing a start synchronizing signal for providing synchronism and data following that signal are cyclically transmitted from the transmission side in a voltage mode, and a reply signal RS expressing that the reception of data in a preceding communication cycle is normal is returned from the reception side to the transmission side in a current mode while the start synchronizing signal is transmitted. Further, it is decided on the transmission side during any term excepting for the transmission term of the start synchronizing signal whether any signal in the current mode is returned or not and when that signal is returned, the transmission of the transmitting signals TS is stopped.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data transmission method used in a data transmission system such as a multiple transmission system for wiring reduction in factories, plants, etc.
More specifically, the present invention relates to an improvement in the method of confirming whether or not the transmission was normal, and the method of detecting the short circuit of the transmission line.

[0002]

2. Description of the Related Art In a data transmission system, there is a case where a method of confirming whether or not the transmission is normal is adopted on the transmission side for the purpose of improving the reliability of the transmission.

In that case, conventionally, for example, as shown in FIG. 6, a transmission line other than the ground reference line 8 is transmitted between the transmission device 2 and the reception device 4 for transmission of a transmission signal including data. Two lines 6 and a transmission line 7 for transmitting a reply signal are used, and the latter transmission line 7 is used to return a reply signal indicating that the reception is normal from the receiving device 4 to the transmitting device 2. I am trying. This is a conventional transmission signal and a reply signal, both of which are produced by changing the voltage. When two such signals are put on one transmission line, the two signals affect each other and the waveform is distorted. This makes it impossible to distinguish between the two signals.

As a conventional communication frame structure, for example, as shown in FIG. 7, a reply confirmation period for confirming return of a reply signal is provided in addition to the synchronization period and the data transmission / input / output period. There is.

[0005]

However, in the conventional data transmission method as described above, there is a problem that the transmission time becomes longer and the transmission speed decreases because the reply confirmation period has to be provided.

Further, since the transmission line 7 for the reply signal has to be provided, the number of transmission lines increases, and there is a problem that the material, wiring man-hour and cost increase.

Further, in the case of the method of transmitting a signal by changing the voltage as described above, if the transmission line, particularly the transmission line 6 for transmitting the transmission signal and the reference line 8 are short-circuited due to an accident or miswiring, the transmission is performed. Overcurrent flows in the line 6, which causes the transmission line 6
The circuit that sends the signal to is destroyed.

To prevent this, there is a method of inserting a current limiting resistor or the like in the transmission line 6 in series. However, if this is done, the voltage drop in the transmission line will be large even during normal operation. Therefore, another problem occurs such that the communicable distance is shortened.

There is also a method of providing a short circuit detecting circuit for detecting a short circuit of the transmission line 6 and performing a protection operation in response to the short circuit detection by the short circuit detecting circuit. In this method, a short circuit detecting circuit is provided. There is a problem in that the circuit becomes complicated and the cost increases due to the necessity.

Therefore, according to the present invention, whether or not the transmission is normal can be confirmed on the transmitting side, the number of transmission lines and the transmission time can be shortened, and a dedicated short-circuit detection circuit is provided. A main object of the present invention is to provide a data transmission method capable of detecting a short circuit of a transmission line and protecting a circuit without the need.

[0011]

In order to achieve the above object, the data transmission method of the present invention is such that the transmission side transmits a series of transmission signals including a start synchronization signal for synchronization and the following data in a voltage mode. Then, the receiver side returns a reply signal in current mode to the transmitter side, which indicates that the data reception in the previous communication cycle was normal during the transmission period of the start synchronization signal. Further, on the transmitting side, it is judged whether or not the current mode signal is returned during the period other than the transmission period of the start synchronization signal, and if it is returned, the transmission of the transmission signal is interrupted. Characterize.

[0012]

According to the above method, the transmitting side can confirm whether or not the transmission is normal by the presence or absence of the reply signal.

Moreover, the transmission signal is transmitted in the voltage mode,
Since the reply signal is returned in the current mode, both signals can be discriminated even if both signals are put on one transmission line, and therefore one transmission line can be shared for transmission of both signals. As a result, the number of transmission lines can be reduced.

Further, since the reply signal is returned at the same timing as the start synchronization signal, a special period for returning the reply signal becomes unnecessary. As a result, the transmission time can be shortened.

Further, when the transmission line is normal, the current mode signal does not return to the transmission side except during the transmission period of the start synchronizing signal, and when the transmission line is short-circuited, it is always during the transmission period of the transmission signal. The current mode signal is returned. By utilizing this property, the transmitting side determines whether or not the current mode signal is returned during the period other than the transmission period of the start synchronization signal, and thus the circuit for reply signal detection is also used, that is, It is possible to detect a short circuit in the transmission line without providing a dedicated short circuit detection circuit. When a short circuit is detected, the transmission of the transmission signal is interrupted to protect the circuit.

[0016]

1 is a diagram showing an example of a transmission signal waveform, a reply signal waveform, and a return signal waveform when a transmission line is short-circuited, which is used in the data transmission method according to the present invention.

In this embodiment, as shown in FIG. 1A, a start sync signal for synchronization and a data 0 following it.
A series of transmission signals TS including .about.n are cyclically transmitted from the transmitting side in the voltage mode. After the last data n, an I / O service period is provided for processing the next input on the transmission side and processing the output on the reception side. T is a period for one unit, and is 120 μs, for example.

Then, as shown in FIG. 1B, the receiving side sends a reply signal RS indicating that the data reception in the immediately preceding communication cycle was normal during the transmission period of the start synchronizing signal in the current mode. I will send it back to the sender. The pulse width of this reply signal RS is, for example, T described above. Based on the presence or absence of this reply signal, the transmitting side can confirm whether or not the transmission was normal.

The return of the reply signal RS in the current mode from the receiving side is simple, for example, by consuming more current than usual in the transmission line at the receiving side during the transmission period of the start synchronization signal. Can be done.
An example of the specific method will be described in detail later with reference to FIG.

Further, in this embodiment, it is judged whether or not the current mode signal is returned during the period other than the transmission period of the start synchronizing signal, and if it is returned, the transmission signal TS is transmitted. I am trying to suspend it.

According to the above data transmission method, the transmission signal TS is transmitted in the voltage mode and the reply signal RS is returned in the current mode. Therefore, even if both signals are put on one transmission line, the two signals can be identified. Therefore, one transmission line can be shared for transmitting both signals. As a result, the number of transmission lines can be reduced.

FIG. 2 shows a schematic example of a data transmission system using the above data transmission method.
Between the two and the receiving device 14, only one transmission line 16 other than the ground reference line 18 is required.

Thus, according to the above data transmission method,
Whether or not the transmission was normal can be confirmed by the presence / absence of the reply signal RS, so that the reliability of the transmission is improved and a dedicated transmission line for the reply signal is not required. Wiring man-hours and cost savings can be realized.

Moreover, in the above data transmission method, since the reply signal RS is returned at the same timing as the start synchronization signal, a special period for returning the reply signal becomes unnecessary. As a result, the transmission time can be shortened and the transmission speed can be improved.

Further, when the transmission line is normal, the current mode signal is not returned to the transmission side except during the transmission period of the start synchronization signal, and when the transmission line is short-circuited, more specifically, FIG. In the case of the above example, when the transmission line 16 and the reference line 18 are short-circuited, for example, as shown in FIG. 1C, the transmission signal TS
A current mode signal is always returned during the transmission period of (However, this FIG. 1C is an example of the case where the transmission is not interrupted,
If the transmission of the transmission signal TS is interrupted according to the invention, then this current mode signal disappears. ). By utilizing this property, the transmitting side determines whether or not the current mode signal is returned during the period other than the transmission period of the start synchronization signal, thereby also serving as the circuit for detecting the reply signal RS. That is, it is possible to detect a short circuit in the transmission line without providing a dedicated short circuit detection circuit. As a result, the size of the device can be reduced and the cost can be reduced by simplifying the circuit. When a short circuit is detected, the transmission of the transmission signal TS is interrupted to protect the circuit for transmitting the transmission signal TS.

A method of expressing data in the transmission signal TS of FIG. 1 will be described for reference. In this example, whether the data is "0" or "1" depends on the length of the pulse width (that is, pulse width modulation). I am trying to express. More specifically, “0” is represented by a combination of “L” level of 30 μs and subsequent “H” level of 90 μs, and “1” is represented by a combination of “L” level of 60 μs and subsequent “H” level of 60 μs. Is represented. One cycle is T described above, which is 120 μs. When such pulse width modulation is used, it is less susceptible to disturbances due to noise, power supply voltage fluctuations, etc., as compared to the method of simply expressing “0” or “1” depending on the presence or absence of a pulse, and therefore the transmission reliability is improved. Is further improved.

Further, in this example, when one "0" or "1" data is transmitted, the data and complementary data of which the value is inverted are paired and continuously transmitted. . By doing this, on the receiving side,
Each time one "0" or "1" data and the complementary data following it are received, the complementarity between both data (that is, if one is "0", the other is "1") is checked. By doing so, a transmission error can be detected reliably and quickly, and in this sense, the reliability of transmission is further improved.

Needless to say, it is not essential to the present invention to use the above data representation method.

FIG. 3 is a diagram showing a more specific configuration example of the data transmission system of FIG.

In the present example, the transmitter 12 has the input circuit 2
0, output circuit 30, transmission control circuit 2 connected to them
2, a changeover switch 24 controlled by the transmission control circuit 22, a power supply terminal 32, a resistor 26 connected between the changeover switch 24, and an amplifier 28 having an input portion connected to both ends of the resistor 26. Changeover switch 24
The above-mentioned reference line 18 is connected to one terminal b, and the above-mentioned transmission line 16 is connected to the common terminal c.

In this example, the receiver 14 is connected to the amplifier 44 whose input section is connected to the transmission line 16 and the reference line 18, the reception control circuit 42 connected to the amplifier 44, and the reception control circuit 42. The output circuit 40 is provided.
A resistor 46 and a transistor 48, which are connected in series with each other, are connected in parallel between the transmission line 16 and the reference line 18. 52 is a power supply terminal. This power supply terminal 52
Another power supply may be connected to the power supply terminal 32, or one common power supply may be connected.

The input circuit 20 in the transmitter 12 is a circuit for an input interface, and in this example, the ON / OFF signal at the (n + 1) point is input. The output circuit 30 is a circuit for an output interface for outputting an alarm described later.

The transmission control circuit 22 has the following three main functions in this example.

Data supplied in parallel from the input circuit 20 is converted into serial data, and the above-mentioned complementary data, start sync signal and I / O service period are added to the data, and the transmission signal as shown in FIG. A signal S ₁ which is a source of TS is created.

The resistor 26 input through the amplifier 28
Across monitors the voltage V ₁ of the, if the start synchronization signal the rise voltage V ₁ is more usual during the transmission period, it is determined that transmission in the previous communication cycle is normal,
If the voltage V ₁ does not rise, it is determined to be abnormal and an alarm is output via the output circuit 30.

If the voltage V ₁ rises above the normal level during the period other than the transmission period of the start synchronizing signal, the transmission line 16
Is judged to be short-circuited to the reference line 18, and the changeover switch 2
4 is fixed to the terminal b side, the transmission of the transmission signal TS is immediately interrupted, and an alarm is output via the output circuit 30.

The change-over switch 24 is the transmission control circuit 2
In response to the signal S ₁ from 2, the common terminal c is switched between the terminal a side and the terminal b side. When switched to the terminal a side, a voltage is applied from the power supply terminal 32 through the resistor 26, so that the voltage of the common terminal c becomes "H" level, and when switched to the terminal b side, it is connected to the ground, and thus the common terminal c. Voltage becomes "L" level. In this way, the changeover switch 24 controls the transmission line 16 under the control of the transmission control circuit 22.
Then, the transmission signal TS as shown in FIG. 1 is output in the voltage mode. The changeover switch 24 is composed of, for example, a combination of a plurality of transistors.

The amplifier 44 in the receiver 14 is connected to the transmission line 1
The transmission signal TS sent via 6 is amplified and given to the reception control circuit 42.

The reception control circuit 42 has the following two main functions in this example.

The serial data in the transmission signal supplied from the amplifier 44 is converted into parallel data to create output data, which is supplied to the output circuit 40. The output circuit 40 outputs outputs 0 to n based on this output data.

It is judged whether or not the reception of data in one communication cycle is normal, and if it is normal, during the reception period of the start synchronization signal in the next communication cycle,
A signal S ₂ for turning on the transistor 48 is output. If not normal, an alarm is output via the output circuit 40.

Here, the normal reception of data in one communication cycle means that, for example, the transmission signal TS is not disturbed and the basic frame as shown in FIG. 1 is established, and the respective data therein. It means that the complementarity with the complementary data is all established.

When the transistor 48 is turned on during the reception period of the start synchronization signal (from the transmission side, the changeover switch 24 is switched to the terminal a side and during the transmission period of the start synchronization signal), the transmission line 16 and the reference line 18 are connected to each other. Since the resistor 46 is connected to the power source terminal 32 on the receiving side,
6, a current larger than usual (for example, about 10 times the usual current) flows through the path of the changeover switch 24, the transmission line 16 and the resistor 46. This current is the above-mentioned current mode reply signal RS, and in this way, the receiving device 1
4, the reply signal RS can be returned to the transmitter 12 in the current mode.

In the transmitter 12, as described above, the voltage V ₁ across the resistor 26 is monitored by the transmission control circuit 22 via the amplifier 28, and when the reply signal RS is returned, this resistor Since a large amount of current flows through 26 and the voltage V ₁ across it rises above normal, the transmission control circuit 22 monitors whether or not this rise in voltage V ₁ is during the transmission period of the start synchronization signal. This makes it possible to determine whether or not the transmission in the immediately preceding communication cycle was normal.

Also, when the transmission line 16 is short-circuited to the reference line 18, a large amount of current flows through the resistor 26 and the voltage V ₁ across the resistor 26 rises higher than usual, so the reply signal RS
Is also used as a circuit for confirming the return of the signal (more specifically, the resistor 26, the amplifier 28, and a part of the transmission control circuit 22), and the transmission control circuit 22 determines the voltage V _{1 at} the determination time of the start synchronization signal. Only by switching during the transmission period, that is, during the period other than the transmission period of the start synchronization signal, the voltage V
By determining whether there is a rise of ₁ , a short circuit in the transmission line can be detected. Therefore, it is not necessary to provide a dedicated short circuit detection circuit.

An example of a more specific processing flow in the transmission device 12 and the reception device 14 is shown in FIGS. 4 and 5.
Are shown respectively. As can be seen from FIG. 5, in this example,
The alarm is not output immediately after one reception abnormality, but the alarm is output only when the reception is abnormal three or more times consecutively. In this way, an alarm is not issued in the case of a momentary communication error, so it is easy to use in an actual field.

[0047]

As described above, according to the present invention, it is possible to confirm whether or not the transmission was normal by the presence or absence of the reply signal, so that the reliability of the transmission is improved and the reply signal is exclusively used. Since the transmission line is unnecessary, it is possible to realize wiring saving, man-hour saving, and cost saving.

Moreover, in the data transmission method of the present invention, the reply signal is returned at the same timing as the start synchronization signal, so that a special period for returning the reply signal becomes unnecessary. As a result, the transmission time can be shortened and the transmission speed can be improved.

Further, by determining whether or not the current mode signal is returned during the period other than the transmission period of the start synchronizing signal, the transmitting side also serves as a circuit for detecting the reply signal, that is, a dedicated circuit. It is possible to detect a short circuit in the transmission line without providing a short circuit detection circuit. As a result, the size of the device can be reduced and the cost can be reduced by simplifying the circuit. Further, since it is not necessary to insert a current limiting resistor or the like in series with the transmission line for short-circuit protection, the communicable distance does not become short.

[Brief description of drawings]

FIG. 1 is a diagram showing an example of a transmission signal waveform, a reply signal waveform, and a return signal waveform when a transmission line is short-circuited, which is used in the data transmission method according to the present invention.

FIG. 2 is a schematic diagram showing an example of a data transmission system using the data transmission method according to the present invention.

FIG. 3 is a diagram showing a more specific configuration example of the data transmission system of FIG.

FIG. 4 is a diagram showing an example of a processing flow on the transmission device side.

FIG. 5 is a diagram illustrating an example of a processing flow on the receiving device side.

FIG. 6 is a schematic diagram showing an example of a conventional data transmission system.

FIG. 7 is a schematic diagram showing an example of a frame structure in a conventional data transmission method.

[Explanation of symbols]

 12 transmitter 14 receiver 16 transmission line 18 reference line

Claims (1)

[Claims] 1. In a data transmission system, a series of transmission signals including a start synchronization signal for synchronization and data following the same are cyclically transmitted in a voltage mode from a transmission side, and the start synchronization is performed from a reception side. During the signal transmission period, a reply signal indicating that the data reception in the immediately previous communication cycle was normal is returned to the transmission side in the current mode, and the transmission side other than the transmission period of the start synchronization signal. During the period, it is determined whether or not a current mode signal is returned, and if it is returned, the transmission of the transmission signal is interrupted.