JPH0936920A - Impedance mismatch detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect impedance mismatching between a transmission system and a terminating resistor by monitoring the pulse width of a signal on a transmission line, detecting and displaying that the pulse width is out of specification. SOLUTION: A pulse width verifying circuit 1 measures the pulse width of a signal to be inputted and when the pulse width is within a specified value higher than a prescribed value, normality is judged. Then, an indicator 4 of a display circuit 3 is turned on and an indicator 6 is turned off. When the measured pulse width is out of the specified value, on the other hand, abnormality is judged, an indicator 5 is turned on and an indicator 7 is turned off. Besides, when a measured voltage level is out of a specified value, the generation of overshoot or undershoot is judged, the indicator 7 is turned on and the indicator 5 is turned off. Therefore, when the indicators 4 and 5 are turned on, impedance matching is judged but when the indicator 6 or 7 is turned on, mismatching is judged.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an impedance mismatch detection device used in a device for connecting a computer or the like and its peripheral equipment.

[0002]

2. Description of the Related Art Generally, various peripheral devices are connected to a computer. As an interface specification for connecting the computer and peripheral devices, SCSI (Small Co
mputerStandard Interface) is often used. With SCSI, a plurality of peripheral devices can be connected in series. A cable is used to connect the computer to peripheral devices or peripheral devices. A termination resistance is provided on the SCSI transmission line of the device connected to the termination. This terminating resistor is provided to prevent the transmission wave generated on the transmission line from being reflected at the end of the transmission line.

[0003]

In order to prevent the reflected wave from being generated by the terminating resistor, the value of the terminating resistor and the value of the impedance of the transmission system viewed from the terminating side are matched (the two values are substantially equal). Need to). The impedance of the transmission system largely depends on the impedance of the cable. By the way, there are various types of cables, and each has different impedance. Therefore, depending on the cable used, it may not be possible to match the termination resistance. In this case, the transmission in SCSI may fail.

The present invention has been made in view of the above problems, and an object of the present invention is to provide an impedance mismatch detection device capable of detecting the impedance mismatch between the transmission system and the terminating resistor. To do.

[0005]

[Means for Solving the Problems] In order to solve the above problems,
The impedance mismatch detection device of the present invention comprises a detection circuit for inputting a signal from a transmission line, monitoring a pulse width of the signal, and detecting that the pulse width is out of a specified range, and the detection circuit. The display means for displaying the detection result is provided.

Further, the impedance mismatch detection device of the present invention inputs a signal from a transmission line, detects overshoot or undershoot of the level of the signal, and detects undershoot or overshoot of a certain value or more. The detection circuit and the display means for displaying the detection result of the detection circuit are provided.

Further, the impedance mismatch detection device of the present invention receives the signal from the transmission line, monitors the pulse width of the signal, and detects that the pulse width is out of the specified range. A configuration is provided that includes a detection circuit and a display unit that displays the detection results of the first detection circuit and the second detection circuit.

[0008]

In the present invention, the impedance mismatch is detected by monitoring the pulse width of the signal generated on the transmission line. Further, by detecting the overshoot or undershoot of the level of the signal generated on the transmission line, the impedance mismatch is detected.

[0009]

1 is a block diagram showing the configuration of an impedance mismatch detection apparatus according to an embodiment of the present invention. The device of this embodiment is used when the computer main body and peripheral devices are connected by the interface specifications of the SCSI standard. The apparatus of the present embodiment matches the impedance of the cable used for connecting the computer main body and the peripheral device with the termination resistance of the peripheral device (peripheral device connected to the end when a plurality of devices are connected). It is detected whether or not it is removed. Therefore, the data is input to this device in parallel from the SCSI transmission line. Of course, a terminating resistor is provided at the end of the transmission line.

In FIG. 1, the pulse width verification circuit 1 and the overshoot / undershoot detection circuit 2 have SC
A signal from the SI transmission line is input. In this embodiment, among the plurality of SCSI transmission lines, REQ (Requ
est) signal transmission line or ACK (Acknowlege)
The signal from the signal transmission line is input to the pulse width verification circuit 1 and the overshoot / undershoot detection circuit 2. The reason for using the REQ signal or the ACK signal is that these signals have the highest frequency. Higher frequency signals are more susceptible to impedance mismatch.

Further, among the SCSI transmission lines, TERM PWR and SGND which are power source lines are inputted. FIG. 2 is a diagram showing the configuration of the power input unit of the apparatus of this embodiment. The input power supply voltage is supplied to each circuit in FIG. 1 (pulse width verification circuit 1, overshoot / undershoot detection circuit 2, display circuit 3). The SCSI transmission standard defines the effective duration of various signals generated on a transmission line. Therefore, the pulse width should normally be longer than a predetermined time. However, a signal having a width shorter than a predetermined time may be generated due to the influence of the reflected wave due to the impedance mismatch.

Further, the SCSI transmission standard defines the level of a signal generated on a transmission line. Therefore, the voltage level of the signal is usually a value between the predetermined upper limit level (high level) and the 0 volt level. However, due to the influence of the reflected wave due to the impedance mismatch, the voltage exceeding the high level (overshoot)
Alternatively, a voltage lower than 0 volt (undershoot) may be detected.

The pulse width verification circuit 1 measures the pulse width of the input signal. When the measured pulse width is equal to or longer than the predetermined time (that is, within the specified value), a signal indicating that the display circuit 3 is normal is output. And
The display circuit 3 is a display device (including a light emitting diode) 4
Is turned on and the display 6 is turned off. Then, when the measured pulse width is out of the specified value, a signal indicating that the display circuit 3 is abnormal is output. Then, the display circuit 3 turns on the indicator 6 (made of a light emitting diode or the like) and turns off the indicator 4.

The overshoot / undershoot detection circuit 2 measures the voltage level of the input signal. When the measured voltage level is a value between a predetermined high level and 0 volt level (that is, within a specified value), a signal indicating that the display circuit 3 is normal is output. Then, the display circuit 3 turns on the indicator 5 (made of a light emitting diode or the like) 5 and turns off the indicator 7.

When the measured voltage level is out of the specified value (that is, when overshoot or undershoot occurs), a signal indicating that the display circuit 3 is abnormal is output. Then, the display circuit 3 turns on the indicator 7 (made of a light emitting diode or the like) and turns off the indicator 5. The operator operates the indicators 4 and 5
When is lit, it is determined that the impedance is matched. When the display 6 or 7 is lit, it is determined that the impedance is not matched.

As described above, the present device detects impedance matching / mismatching by monitoring whether a signal that does not satisfy the SCSI transmission standard is generated. The pulse width verification circuit 1 and the overshoot /
The undershoot detection circuit 2 may output a signal indicating an abnormality depending on the frequency of occurrence of the non-specified signal (for example, how many times the non-specified signal occurs within a predetermined time).

It is also possible to mount a terminating resistance circuit on the device of this embodiment. With the device of this embodiment, it is possible to detect whether or not impedance matching is achieved, so that an appropriate cable can be selected.
This can improve impedance matching.
Therefore, the reflected wave in the transmission line can be reduced. Further, since the reflected wave is reduced, unnecessary radiation is reduced. Also, since the transmission waveform is clean, transmission errors are less likely to occur. Also, the transfer speed can be increased.

[0018]

As described above, according to the present invention, it is possible to detect whether or not the impedance of the transmission system viewed from the terminal side and the impedance of the terminal resistance are matched. Then, based on the detection result, it is possible to take measures such as using an appropriate transmission cable.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of an impedance mismatch detection device according to an embodiment of the present invention.

FIG. 2 is a diagram showing a configuration of a power supply input section of an impedance mismatch detection device according to an embodiment of the present invention.

[Explanation of symbols]

 1 ... Pulse width verification circuit, 2 ... Overshoot / undershoot detection circuit, 3 ... Display circuit, 4, 5, 6, 7 ... Display unit

Claims (3)

[Claims] 1. A detection circuit for inputting a signal from a transmission line, monitoring a pulse width of the signal, and detecting that the pulse width is out of a specified range, and displaying a detection result by the detection circuit. An impedance mismatch detection device comprising a display means. 2. A detection circuit for inputting a signal from a transmission line, detecting an overshoot or undershoot of the level of the signal, and detecting an undershoot or overshoot of a certain value or more, and a detection result of the detection circuit. An impedance mismatch detection device, comprising: a display unit for displaying. 3. A first detection circuit for inputting a signal from a transmission line, monitoring the pulse width of the signal, and detecting that the pulse width is out of regulation, and a signal from the transmission line. Input, detect overshoot or undershoot of the level of the signal,
An impedance, comprising: a second detection circuit for detecting undershoot or overshoot of a certain value or more; and display means for displaying the detection results of the first detection circuit and the second detection circuit. Inconsistency detector.