JPH09130430A - Output impedance adjusting method of interface - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily adjust a matching state. SOLUTION: In the interface including a variable resistance 3, an amplifier 2 imparting an output to a load 5 via this variable resistance 3 and a terminal 4 for reflection wave monitor provided between the variable resistance 3 and the load 5, an adjustment is performed so that the signal level of the reflection wave monitor terminal 4 may be a specified value. When the load is changed to the other load having different impedance after this adjustment, the adjustment is performed so that the signal level of the reflection wave monitor terminal 4 may be the specified value. By this adjusting method, the adjustment to a matching state can be easily performed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an output impedance adjusting method, and more particularly to a method for adjusting the output impedance of an interface when the load impedance is changed.

[0002]

2. Description of the Related Art Generally, a CMI (Coded Mark) is used.
Inversion) encoded unipolar signal or AMI (Alternate Mark Invers)
Ion) When transmitting digital data such as encoded bipolar signals through a balanced pair cable or coaxial cable,
The cable appears as a load to the driver amplifier. In order to improve the transmission quality in data transmission using such a cable, it is necessary to adjust impedance so that reflection does not occur.

By the way, Japanese Patent Laid-Open No. 58-134521 discloses a gain variable circuit which realizes improved power transfer characteristics, widened variable range of gain and simplified circuit. This technique will be described with reference to FIGS. 5 and 6.

Referring to FIG. 5, the variable gain circuit includes an amplifier 2 having a low output impedance connected to an input terminal 1, a variable resistor 3 connected to the output of the amplifier 2, and a negative electrode having one end grounded. 8 has a resistor 9 connected thereto, and a load 5 connected between the other end of the variable resistor 3 and the other end of the resistor 9 and the negative electrode 6. Then, the gain is changed by changing the variable resistor 3.

Further, referring to FIG. 6, this variable gain circuit has a configuration in which a variable resistor 7 is provided instead of the resistor 9 of FIG. 6, the same parts as those in FIG. 5 are designated by the same reference numerals.

Here, when the output impedance of the amplifier 2 is 0 [Ω], the output impedance Zx of the load 5 connected to the output end is 75 [Ω], and the gain fluctuation is 0 [dB], the attenuation amount is It was set to 3 [dB]. When judging the quality of the power transfer characteristics, it is possible to judge by the value of the mismatch attenuation amount. Therefore, if the relationship between the output mismatch attenuation amount and the change in gain is expressed using the following formula (1), The amount is large, and ± 2 [dB] as the gain can be changed sufficiently. −20log | (X−X0) / (X + X0) | (1) In the equation (1), X is the impedance of the circuit,
X0 is the ideal impedance of the circuit.

The mismatch attenuation amount indicates the ratio of the reflected voltage and the ideal transmitted power due to the difference in impedance between the two circuits at the connection point of the circuits. The larger the value, the better the power transfer characteristic. Show.

Next, the operation of FIG. 6 will be described. The circuit constants in FIG. 6 are the same as those in FIG. In contrast to the configuration of FIG. 5, the variable resistor 7, one end of which is connected to the negative electrode 8, is prepared to match the output impedance of the circuit that changes with the change of the attenuation amount and the impedance Zx of the load 5. . The variable resistor 3 and the variable resistor 7 are used together to adjust the attenuation amount and the input / output impedance.

[0009]

In the conventional circuit described above, it is a necessary condition that the impedance Zx of the load 5 is fixed, and the range in which the circuit impedance can be changed is limited.

That is, since the above-mentioned conventional circuit aims at providing an attenuator capable of changing the gain with respect to a definite load, it is not necessary to set a wide variable range of the attenuation amount and the output impedance. .

When such a conventional circuit is applied to an uncertain load, even if the output waveform is reflected due to impedance mismatch and the transmission malfunction occurs, the variable resistor 3, when the mismatch state is wide, There is a drawback in that it is not easy to respond by changing 7 and 9. For example, when the load is a cable, if the cable is replaced or the number of cables is increased, a mismatched state occurs, but such a state cannot be dealt with by a conventional circuit. In such a case, there is a drawback in that only the system can be temporarily mitigated by a method of adjusting another load such as adjusting the distance of the load cable.

The present invention has been made to solve the above-mentioned drawbacks of the prior art, and its object is to provide an output impedance adjusting method which can be easily adjusted to a matched state.

[0013]

An interface output impedance adjusting method according to the present invention comprises a variable impedance element, an amplifier for providing an output to a load via the variable impedance element, and a variable impedance element between the variable impedance element and the load. A method for adjusting an output impedance of an interface including a reflected wave monitor terminal provided in, wherein the step of adjusting the signal level of the reflected wave monitor terminal to a specific value and the load have different impedances Adjusting the signal level at the reflected wave monitor terminal to the specific value when the load is changed to another load.

Another interface output impedance adjusting method according to the present invention comprises a variable impedance element,
An amplifier for providing an output to a load via the variable impedance element, a first reflected wave monitor terminal provided between the variable impedance element and the load, and between the amplifier and the variable impedance element. A method for adjusting an output impedance of an interface including a second reflected wave monitor terminal provided, wherein the signal of the first reflected wave monitor terminal when the load is changed to another load having a different impedance It is characterized by including the step of adjusting the level to approximately ½ of the signal level of the second reflected wave monitor terminal.

In still another interface output impedance adjusting method according to the present invention, a first variable impedance element, an amplifier for providing an output to a load via the first variable impedance element, and the first variable impedance element. A first reflected wave monitor terminal provided between the amplifier and the load, a second reflected wave monitor terminal provided between the amplifier and the first variable impedance element, and the second reflected wave monitor terminal. Second and third variable impedance elements provided between the reflected wave monitor terminal and the ground,
A method for adjusting an output impedance of an interface including a third reflected wave monitor terminal provided between these second and third variable impedance elements, wherein the load is changed to another load having different impedances. Then, the step of adjusting the signal level of the third reflected wave monitor terminal to approximately 1/2 of the signal level of the second reflected wave monitor terminal, and thereafter, the step of adjusting the signal level of the first reflected wave monitor terminal Adjusting the signal level to approximately ½ of the signal level of the second reflected wave monitor terminal.

In still another interface output impedance adjusting method according to the present invention, there is provided a first variable impedance element, an amplifier for providing an output to a load via the first variable impedance element, and the first variable impedance element. A first reflected wave monitor terminal provided between the amplifier and the load, a second reflected wave monitor terminal provided between the amplifier and the first variable impedance element, and the second reflected wave monitor terminal. Second and third variable impedance elements provided between the reflected wave monitor terminal and the ground,
The difference between the signal levels of the third reflected wave monitor terminal provided between the second and third variable impedance elements and the first reflected wave monitor terminal and the third reflected wave monitor terminal. And an output impedance adjusting method for an interface including a comparator circuit for outputting the signal level of the third reflected wave monitor terminal when the load is changed to another load having a different impedance. The step of adjusting the signal level of the reflected wave monitor terminal to about ½, and thereafter the signal level of the first reflected wave monitor terminal is set to about ½ of the signal level of the second reflected wave monitor terminal. It is characterized by including the step of adjusting to 2 and the step of adjusting the output of the comparison circuit to substantially zero after that.

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The operation of the present invention is as follows.

A variable impedance element, and an amplifier for providing an output to a load via the variable impedance element,
In the interface including the reflected wave monitor terminal provided between the variable impedance element and the load, first, the signal level of the reflected wave monitor terminal is adjusted to a specific value. After this adjustment, when the load is changed to another load having a different impedance, the signal level of the reflected wave monitor terminal is adjusted to the specific value. According to this adjusting method, it is possible to easily adjust to the matching state.

Next, an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a circuit diagram showing the structure of an interface to which the first embodiment of the interface output impedance adjusting method according to the present invention is applied, and the same parts as those in FIGS. 5 and 6 are designated by the same reference numerals. ing. The interface shown in the figure includes an input terminal 1, a variable resistor 3, an amplifier 2 for providing an output to a load 5 via the variable resistor 3, and a reflection resistor provided between the variable resistor 3 and the load 5. The wave monitoring terminal 4 is included.

The output impedance of the interface having such a configuration is adjusted by the following procedure.

First, assume that a digital signal is input to the input terminal 1. Further, the variable resistor 3 is set so that the output waveform amplitude of the circuit becomes a specific value with respect to the constant output of the amplifier 2 in a state where the impedance of the output load 5 and the impedance of the circuit that are determined match. To do. In this example, the output waveform amplitude of the circuit is 1/2 VP-P
The variable resistor 3 is set so as to be (1/2 of the maximum amplitude).

The reason why the maximum amplitude is set to ½ is to be able to cope with both cases where the amplitude is increased and decreased due to an uncertain load. However, when the change in the amplitude is small, it may not be 1/2.

Assuming that an uncertain output load is connected to the output, the state of the reflected wave is monitored using the reflected wave monitor terminal 4, and the output waveform amplitude is adjusted by adjusting the variable resistor 3. Is set to 1/2 VP-P in the matched state. When performing this monitoring, a probe with high input impedance is applied to the terminal 4 and observed with an oscilloscope so that the waveform is not deteriorated. For example, a probe having an input impedance of several M [Ω] and several [pF] may be applied for observation. Further, it may be observed by an oscilloscope type waveform observing measuring instrument or a level meter.

FIG. 2 is a circuit diagram showing a structure of an interface which is a target for carrying out the second embodiment of the interface output impedance adjusting method according to the present invention. The same parts as those in FIGS. Indicated by.
This interface includes a second reflected wave monitor terminal 10 between the amplifier 2 and the variable resistor 3 of the interface shown in FIG.
Is added.

The output impedance of the interface having such a configuration is adjusted as follows. That is, the variable resistor 3 is adjusted so that the output amplitude level of the terminal 4 becomes 1/2 VP-P of the output amplitude level of the terminal 10. That is, when the variable resistor 3 and the load 5 are in a matched state, the amplitude at the terminal 10 is ½ due to the variable resistor 3 and the load 5 connected between the negative electrode 6 and the terminal 10.
It should be. Therefore, if the output amplitude level of the terminal 4 becomes 1 / 2VP-P of the output amplitude level of the terminal 10,
It becomes a consistent state. Therefore, terminals 4 and 10
It can be easily adjusted by monitoring the output amplitude level of.

FIG. 3 is a circuit diagram showing the structure of an interface to which the third embodiment of the interface output impedance adjusting method according to the present invention is applied, which is equivalent to FIGS. 1, 2, 5, and 6. Are denoted by the same reference numerals. This interface is provided with a second variable resistor 13 and a third variable resistor 14 between the second reflected wave monitor terminal 10 and the negative electrode 12 of the interface shown in FIG. 2, and further between these variable resistors. Third reflected wave monitor terminal 1
1 is provided.

The output impedance of the interface having such a configuration is adjusted as follows. That is, the output amplitude of the terminal 11 is equal to 1 of the output amplitude of the terminal 10.
The variable resistors 13 and 14 are set so as to be / 2VP-P. Here, when the resistance value of the variable resistor 14 is ZY and the internal output resistance of the amplifier 2 is R0, the resistance value of the variable resistor 13 is set to ZY-R0. This setting is
This is to adjust the internal output resistance of the amplifier 2 to a matching state.

Further, if the variable resistor 3 is adjusted while monitoring the terminal 4 so that the same waveform can be obtained at the terminal 4 and the terminal 11, the matching state can be easily adjusted. For this monitor, an oscilloscope type waveform measuring instrument or a level meter may be used.

FIG. 4 is a circuit diagram showing the structure of an interface to which the fourth embodiment of the interface output impedance adjusting method according to the present invention is applied, which is equivalent to FIGS. 1 to 3, 5 and 6. Are denoted by the same reference numerals. This interface is provided with a comparator 15 that outputs the level difference between the two outputs by using the output of the terminal 11 as a positive input and the output of the terminal 4 as a negative input in the interface of FIG. 3, and the output level of the comparator 15 at the terminal 16. The configuration is such that it is monitored.

The method of adjusting the output impedance of the interface configured as described above is partially the same as the case of FIG. 3 described above. That is, the output amplitude of the terminal 11 is
The variable resistors 13 and 14 are set so that the output amplitude of the terminal 10 is 1/2 VP-P. Then, the terminal 4 and the terminal 11
When the variable resistor 3 is adjusted so that the same waveforms are obtained, the output level of the comparator 15 is monitored at the terminal 16 and the variable resistor 3 is adjusted so that the level becomes substantially zero. This adjustment eliminates the need for an oscilloscope-based waveform observation measuring instrument and level meter.

By adjusting the output impedance of the interface as described above, even if the output impedance of the load is changed, it is possible to easily adjust to the matching state. Especially, when the load is a cable, even if the cable is replaced or the number of cables is increased, the above-mentioned adjustment methods can alleviate the reflection state from the load and easily adjust to a matching state. Can be done.

[0033]

As described above, according to the present invention, the variable resistor and the monitor terminal are provided, and when the impedance of the load is changed, the variable resistor is adjusted while monitoring the waveform at the monitor terminal. In addition, the matching state can be easily adjusted, the reflection state can be relaxed, and the malfunction due to the reflection can be suppressed.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing a configuration of an interface to which a first embodiment of an interface output impedance adjusting method according to the present invention is applied.

FIG. 2 is a circuit diagram showing a configuration of an interface to which a second embodiment of an interface output impedance adjusting method according to the present invention is applied.

FIG. 3 is a circuit diagram showing a configuration of an interface to which a second embodiment of the interface output impedance adjusting method according to the present invention is applied.

FIG. 4 is a circuit diagram showing a configuration of an interface to which a second embodiment of an interface output impedance adjusting method according to the present invention is applied.

FIG. 5 is a circuit diagram showing a configuration of an interface to which a conventional interface output impedance adjusting method is applied.

FIG. 6 is a circuit diagram showing a configuration of an interface which is a target for performing another conventional output impedance adjusting method of the interface.

[Explanation of symbols]

 1 Input Terminal 2 Amplifying Circuit 3, 13, 14 Variable Resistance 4, 10, 11 Reflected Wave Monitor Terminal 5 Load 15 Comparison Circuit

Claims (6)

[Claims] 1. An output of an interface including a variable impedance element, an amplifier for providing an output to a load via the variable impedance element, and a reflected wave monitoring terminal provided between the variable impedance element and the load. An impedance adjusting method, the step of adjusting the signal level of the reflected wave monitor terminal to a specific value, and the signal of the reflected wave monitor terminal when the load is changed to another load having a different impedance. Adjusting the level so that the level becomes the specific value. 2. The output impedance adjusting method according to claim 1, wherein the specific value is a value that is approximately ½ of an output level of the amplifier. 3. A variable impedance element, an amplifier for providing an output to a load via the variable impedance element, a first reflected wave monitoring terminal provided between the variable impedance element and the load, A method for adjusting an output impedance of an interface including a second reflected wave monitoring terminal provided between an amplifier and the variable impedance element, wherein the load is changed to another load having a different impedance, An output impedance adjusting method comprising the step of adjusting the signal level of the first reflected wave monitoring terminal to approximately ½ of the signal level of the second reflected wave monitoring terminal. 4. A first variable impedance element, an amplifier for providing an output to a load via the first variable impedance element, and a first variable impedance element provided between the first variable impedance element and the load. Between the reflected wave monitor terminal, the second reflected wave monitor terminal provided between the amplifier and the first variable impedance element, and the second reflected wave monitor terminal and the ground. Second provided
And a third variable impedance element and a third reflected wave monitor terminal provided between the second and third variable impedance elements, wherein the load is different. Adjusting the signal level of the third reflected wave monitor terminal to approximately ½ of the signal level of the second reflected wave monitor terminal when the load is changed to another load having impedance; The signal level of the first reflected wave monitor terminal is approximately 1 of the signal level of the second reflected wave monitor terminal.
And a step of adjusting to / 2. 5. A first variable impedance element, an amplifier for providing an output to a load via the first variable impedance element, and a first variable impedance element provided between the first variable impedance element and the load. Between the reflected wave monitor terminal, the second reflected wave monitor terminal provided between the amplifier and the first variable impedance element, and the second reflected wave monitor terminal and the ground. Second provided
And a third variable impedance element, a third reflected wave monitor terminal provided between the second and third variable impedance elements, the first reflected wave monitor terminal and the third reflected wave. A method for adjusting an output impedance of an interface including a comparison circuit for outputting a difference between signal levels of monitor terminals, wherein the third reflected wave monitor is used when the load is changed to another load having a different impedance. Adjusting the signal level of the terminal to about 1/2 of the signal level of the second reflected wave monitor terminal, and thereafter adjusting the signal level of the first reflected wave monitor terminal to the second reflected wave monitor Approximately 1 of the signal level of the terminal for
A method of adjusting output impedance, comprising the step of adjusting to / 2 and the step of adjusting the output of the comparison circuit to substantially zero thereafter. 6. The output impedance adjusting method according to claim 1, wherein the load is a cable.