KR101399902B1 - Directional coupler sensor apparatus - Google Patents

Abstract

The directional coupler sensor device of the present invention includes a traveling wave input unit receiving a traveling wave detection signal detected by a directional coupler, a reflected wave input unit receiving a reflected wave detection signal detected by the directional coupler, A second differential amplifier for differentially amplifying the reflected wave detection signal inputted through the reflected wave input section and outputting the result as a corrected reflected wave detection signal; a second differential amplifier for outputting the output voltage of the first differential amplifier, And a second canceling feedback unit for dividing an output voltage of the second differential amplifier and providing the divided voltage as a negative feedback input of the first differential amplifier do. In the directional coupler sensor device of the present invention, in order to minimize the detection error due to mutual influence components of the traveling wave and the reflected wave in detecting the traveling wave and the reflected wave through the directional coupler, So that the detection error can be minimized.

Description

[0001] DIRECTIONAL COUPLER SENSOR APPARATUS [0002]

The present invention relates to a directional coupler sensor device, and more particularly, to a new directional coupler sensor device capable of minimizing a detection error caused by mutual influences between a traveling wave and a reflected wave in detecting a traveling wave and a reflected wave through a directional coupler.

Directional couplers are widely used in electric and electronic circuits. For example, in a power supply system in a plasma device for semiconductor fabrication. A directional coupler is used to detect the ratio of the traveling wave to the reflected wave when impedance matching is performed in order to change the input impedance of the processing chamber in the plasma apparatus. When the impedance matching is performed in the plasma apparatus, it is necessary to move the respective matching elements to the matching position by repeating the feedback control while controlling the positions of the matching elements and bringing the reflectance close to the reference value.

However, the detection of the traveling wave and the reflected wave detected by the directional coupler has difficulties in accurately measuring the real value due to the mutual influence components of the traveling wave and the reflected wave, which makes it difficult to accurately match the impedance. If the mutual influence components of the traveling wave detected by the directional coupler and the detection component of the reflected wave can be canceled out, accurate traveling wave detection without any error and reflection wave detection will be possible, thereby making it possible to perform impedance matching more accurately will be.

It is an object of the present invention to provide a directional coupler capable of minimizing a detection error by canceling mutual influence components in traveling wave and reflected wave detection so as to minimize a detection error caused by mutual influence components of a traveling wave and a reflected wave, And to provide a new directional coupler sensor device.

According to an aspect of the present invention, there is provided a directional coupler sensor device. The directional coupler sensor device of the present invention includes a traveling wave input unit receiving a traveling wave detection signal detected by a directional coupler; A reflected wave input unit receiving the reflected wave detection signal detected by the directional coupler; A first differential amplifier for differentially amplifying a progressive wave detection signal input through the progressive wave input unit and outputting the amplified progressive wave detection signal as a corrected progressive wave detection signal; A second differential amplifier that differentially amplifies the reflected wave detection signal input through the reflected wave input unit and outputs the differential wave as a corrected reflected wave detection signal; A first canceling feedback unit dividing an output voltage of the first differential amplifier and providing the divided voltage as a negative feedback input of the second differential amplifier; And a second canceling feedback unit for dividing the output voltage of the second differential amplifier and providing the divided voltage as a negative feedback input of the first differential amplifier.

In one embodiment, the first canceling feedback section includes two ratio division resistors connected in series between the output terminal of the first differential amplifier and the ground, and the second canceling feedback section is connected between the output terminal of the second differential amplifier and the output terminal of the second differential amplifier. And two ratio-dividing resistors connected in series between the ground.

In one embodiment, the ratio division resistors of the first and second cancellation feedback sections include variable resistors.

The directional coupler may include a first amplifier that amplifies the progressive wave detection signal input from the directional coupler and outputs the amplified progressive wave detection signal without offset correction, and a second amplifier that amplifies the progressive wave detection signal input from the directional coupler, And a second amplifier for amplifying the reflected wave detection signal inputted from the directional coupler and outputting the amplified reflected wave detection signal without offset correction, and a second amplifier for amplifying the progressive wave detection signal inputted from the directional coupler, As shown in FIG.

In one embodiment, the progressive wave input unit further includes a first band pass filter and a first multiplier connected in series to a progressive wave detection signal output terminal of the directional coupler, and the reflected wave input unit is connected to a reflected wave detection signal output terminal of the directional coupler And a second multiplier connected in series with the second band-pass filter.

In the directional coupler sensor device of the present invention, in order to minimize the detection error due to mutual influence components of the traveling wave and the reflected wave in detecting the traveling wave and the reflected wave through the directional coupler, So that the detection error can be minimized.

1 is a circuit diagram of a directional coupler sensor device according to a preferred embodiment of the present invention.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. It should be noted that the same components are denoted by the same reference numerals in the drawings. Detailed descriptions of well-known functions and constructions which may be unnecessarily obscured by the gist of the present invention are omitted.

1 is a circuit diagram of a directional coupler sensor device according to a preferred embodiment of the present invention.

1, a directional coupler sensor device 20 according to the present invention includes a directional coupler 10 and a directional coupler 10. The directional coupler sensor device 20 includes a directional coupler 10 and a directional coupler 10, An offset correction circuit 50 is provided to cancel the offset correction. The directional coupler sensor device 20 can minimize the detection error due to mutual influence components of the traveling wave and the reflected wave through the offset correction circuit 50. [

The directional coupler sensor device 20 includes a traveling wave input unit 30, a reflected wave input unit 40, and an offset correction circuit 50. The traveling wave input unit 30 receives the traveling wave detection signal FWD detected by the directional coupler 10 and the reflected wave input unit 40 receives the reflected wave detection signal RFL detected by the directional coupler 10. The progressive wave detection signal FWD input through the progressive wave input unit 30 and the reflected wave detection signal RFL input through the reflected wave input unit 40 are input to the cancel correction circuit 50. [

The canceling correction circuit 50 includes a first differential amplifier 51 and a first canceling feedback section 52 for canceling out the progressive wave detection signal FWD and a second differential amplifier 52 for canceling out the reflected wave detection signal REL. And includes an amplifier 55 and a second canceling feedback section 56. [ The first canceling feedback section 52 includes two ratio division resistors 53 and 54 connected in series between the output terminal of the first differential amplifier 51 and the ground and the second canceling feedback section 56 includes And two ratio division resistors 57 and 58 connected in series between the output terminal of the two-differential amplifier 55 and the ground. Each of the ratio division resistors 53, 54 (57, 58) constituting the first and second canceling feedback sections 52, 56 may include a variable resistor.

The first differential amplifier 51 receives the progressive wave detection signal FWD input through the progressive wave input unit 30 and the divided voltage of the second canceling feedback unit 56 as negative feedback signals, (FWD_A). In addition, the second differential amplifier 55 also receives the divided voltage of the reflected wave detection signal FWD input through the reflected wave input unit 40 and the divided voltage of the second canceling feedback unit 56 as a negative feedback input, And outputs it as a detection signal RFL_A.

The progressive wave detection signal FWD is X, the reflected wave detection signal RFL is X ', the progressive wave detection signal outputted without correction is Y, the reflected wave detection signal outputted without correction is Y' If the wave reflection wave cancellation ratio is b, then the relationship as shown in Equation 1 can be defined.

The following equation (2) can be obtained in the same manner as in equation (1).

Thus, when X '/ X = a, Y' / Y = b, Y becomes the maximum and Y 'becomes the minimum. In other words, the offset correction becomes the maximum.

The traveling wave input unit 30 includes a first amplifier 34 for amplifying the traveling wave detection signal FWD input from the directional coupler 10 and outputting the traveling wave detection signal FWD without offset compensation and a second amplifier 34 for amplifying the traveling wave detection signal input from the directional coupler, And a second amplifier 35 for inputting the reflected wave detection signal RFL to the differential amplifier 51. The reflected wave input unit 40 includes a third amplifier for amplifying the reflected wave detection signal RFL input from the directional coupler 10, And a fourth amplifier 45 for amplifying the traveling wave detection signal input from the directional coupler 10 and inputting the amplified traveling wave detection signal to the second differential amplifier 55. The traveling wave input unit 30 and the reflected wave input unit 40 may each include amplifiers 33 and 43 for preliminary amplification. The bandpass filters 31 and 41 and the multipliers 32 and 42 are added to the progressive wave input unit 30 and the reflection wave input unit 40 for signal processing of the progressive wave detection signal FWD and the reflected wave detection signal RFL, As shown in FIG.

The progressive wave detection signal and the reflected wave detection signal that are output without correction through the progressive wave input unit 30 and the reflected wave input unit 40 are input to the microcontroller 70 through the analogue digital converter 60, Analog converter 80 to the amplifiers 90 and 91 and output as the progressive wave detection signal FWD_D and the reflected wave detection signal RFL_D, which have undergone the primary digital conversion processing.

The embodiments of the directional coupler sensor device of the present invention described above are merely exemplary and those skilled in the art will appreciate that various modifications and equivalent arrangements may be made therein without departing from the scope of the present invention. You will know. Accordingly, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

10: directional coupler 20: directional coupler sensor device
30: traveling wave input unit 31: bandpass filter
32: multiplier 33: input stage amplifier
34: first output stage amplifier 35: second output stage amplifier
40: Reflected wave input unit 41: Bandpass filter
42: multiplier 43: input stage amplifier
44: first output stage amplifier 45: second output stage amplifier
50: offset correction circuit 51: first differential amplifier
52: first canceling feedback section 53, 54:
55: second differential amplifier 56: second canceling feedback section
57, 58: ratio division resistor 60: analog-to-digital converter
70: Microcontroller 80: Digital to analog converter
90, 91: Amplifier

Claims (5)

A traveling wave input unit for receiving the traveling wave detection signal detected by the directional coupler;
A reflected wave input unit receiving the reflected wave detection signal detected by the directional coupler;
A first differential amplifier for differentially amplifying a progressive wave detection signal input through the progressive wave input unit and outputting the amplified progressive wave detection signal as a corrected progressive wave detection signal;
A second differential amplifier that differentially amplifies the reflected wave detection signal input through the reflected wave input unit and outputs the differential wave as a corrected reflected wave detection signal;
A first canceling feedback unit dividing an output voltage of the first differential amplifier and providing the divided voltage as a negative feedback input of the second differential amplifier; And
And a second canceling feedback unit for dividing an output voltage of the second differential amplifier and providing the output voltage as a negative feedback input of the first differential amplifier. The method according to claim 1,
Wherein the first canceling feedback section includes two ratio division resistors connected in series between an output terminal of the first differential amplifier and the ground,
Wherein the second canceling feedback section includes two ratio division resistors connected in series between an output terminal of the second differential amplifier and the ground. 3. The method of claim 2,
And the ratio division resistors of the first and second cancellation feedback portions include variable resistors. The method according to claim 1,
The traveling wave input unit
A first amplifier for amplifying the progressive wave detection signal input from the directional coupler and outputting the amplified progressive wave without offset compensation;
And a second amplifier for amplifying the traveling wave detection signal input from the directional coupler and inputting the amplified traveling wave detection signal to the first differential amplifier,
The reflected wave input unit
A third amplifier for amplifying the reflected wave detection signal input from the directional coupler and outputting the amplified detection signal without canceling correction;
And a fourth amplifier for amplifying the traveling wave detection signal input from the directional coupler and inputting the amplified traveling wave detection signal to the second differential amplifier. 5. The method of claim 4,
The traveling wave input unit
Further comprising a first band pass filter and a first multiplier connected in series to a progressive wave detection signal output terminal of the directional coupler,
The reflected wave input unit
Wherein the directional coupler further comprises a second bandpass filter and a second multiplier connected in series to a reflected wave detection signal output terminal of the directional coupler.

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