JP4131793B2 - High frequency power supply and control method thereof, and plasma processing apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a high frequency power supply and a control method thereof. And plasma processing apparatus In particular, the present invention relates to a high-frequency power source of a plasma processing apparatus that performs plasma processing on a semiconductor wafer and a control method thereof.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in a semiconductor device manufacturing process, a plasma processing apparatus that generates high-density plasma in a relatively low-pressure atmosphere and performs etching on a semiconductor wafer (hereinafter simply referred to as “wafer”) is used. For example, in a parallel plate plasma processing apparatus, a pair of parallel plate electrodes (upper and lower electrodes) are arranged in a plasma chamber, a processing gas is introduced into the chamber, and a high frequency is applied to one of the electrodes to provide a gap between the electrodes. A high-frequency electric field is generated at this time, and plasma of a processing gas is generated by this high-frequency electric field to etch the wafer.
[0003]
In such a plasma processing apparatus, in order to perform etching efficiently, a high frequency for plasma generation and a high frequency for bias for drawing ions in the plasma are superimposed and simultaneously applied to the lower electrode. Specifically, a high frequency power source for plasma generation is connected to the lower electrode via a matching circuit (hereinafter referred to as “matching box”), and a high frequency power source for bias is connected to the lower electrode via a matching box. Two high frequencies are superimposed. The high frequency for plasma generation is set to a frequency of 100 MHz in consideration of plasma generation efficiency, while the high frequency for bias is set to a frequency of 3.2 MHz.
[0004]
In the plasma processing apparatus, during the plasma processing, harmonics and modulation waves corresponding to the main frequencies of 100 MHz and 3.2 MHz are generated, and these harmonics and modulation waves are in the vicinity of the main frequency of the incident wave (Pf). (FIG. 4 (a)) and also appears in the vicinity of the main frequency of the reflected wave (Pr) (FIG. 4 (b)), causing a malfunction or the like in the matching box or the high-frequency power source. Therefore, the high-frequency power source includes a power monitor that detects incident waves and reflected waves and controls high-frequency output, and the power monitor uses a detection circuit (FIG. 5) including a band-pass filter composed of an LC circuit to generate harmonics. And modulation waves are removed.
[0005]
[Problems to be solved by the invention]
However, in the high-frequency power supply including the conventional bandpass filter, when the frequency difference between the plasma generation high frequency and the bias high frequency, which is an incident wave, increases, the main frequency included in the reflected wave and the frequency of the modulation wave, etc. The difference is reduced, and the band-pass filter composed of the LC circuit cannot sufficiently attenuate the modulated wave, and as a result, the modulated wave is regarded as a reflected wave, which may cause the high-frequency power supply to malfunction. .
[0006]
Further, if the modulation wave or the like cannot be sufficiently attenuated, it is difficult to apply an appropriate high frequency during plasma processing.
[0007]
The present invention has been made in view of the above-described problems, and removes harmonics and modulated waves generated during plasma generation with high accuracy to prevent malfunctions and to achieve appropriate high frequency. Mark High frequency power supply that can be applied and control method thereof And plasma processing apparatus The purpose is to provide.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, the high frequency power supply according to claim 1 is a high frequency power supply for a plasma processing apparatus in which a lower electrode is disposed in a plasma processing container, and the first high frequency power supply connected to the lower electrode. And a second high-frequency power source The first high-frequency power source includes a high-frequency generation source that generates a first high-frequency for generating plasma in the plasma processing vessel, a high-frequency extraction unit that extracts the first high-frequency, and the first Oscillation means for oscillating a second high frequency having a frequency different from the high frequency of the first frequency, multiplication means for multiplying the first high frequency extracted by the high frequency extraction means and the second high frequency oscillated by the oscillation means, and the multiplication From the result multiplied by means Includes harmonic and modulated wave components Attenuates high frequency components ·Removal High frequency attenuating means, and a detecting means for detecting a frequency in the range of 10 Hz to 500 kHz outputted from the high frequency attenuating means And a control means for comparing the detection output from the detection means with a reference voltage for setting the output of the high-frequency generation source and controlling the output of the high-frequency generation source based on the comparison result It is characterized by that.
The high-frequency power source according to claim 2 is the high-frequency power source according to claim 1, wherein the frequency of the first high-frequency generated by the high-frequency generation source is higher than the frequency of the output from the second high-frequency power source. It is characterized by.
The high-frequency power source according to claim 3 is the high-frequency power source according to claim 1 or 2, wherein the frequency of the output from the high-frequency attenuation means is lower than the frequency of the output from the second high-frequency power source. And
The high-frequency power source according to claim 4 is the high-frequency power source according to any one of claims 1 to 3, wherein the second high-frequency power source includes another high-frequency generation source that generates a third high frequency, and the lower portion A matching device is disposed between the electrode and the other high-frequency generation source, and a low-pass filter is disposed between the lower electrode and the matching device.
In order to achieve the above object, the high frequency power supply according to claim 5 is a high frequency power supply for a plasma processing apparatus in which a lower electrode is disposed in a plasma processing container, and the first high frequency power supply connected to the lower electrode. And a second high-frequency power source connected to the lower electrode and outputting a high frequency having a frequency lower than the first high-frequency frequency output by the first high-frequency power source. The first high-frequency power source includes a high-frequency generation source that generates a first high-frequency for generating plasma in the plasma processing vessel, a high-frequency extraction unit that extracts the first high-frequency, and the first Oscillation means for oscillating a second high frequency having a frequency different from the high frequency of the first frequency, multiplication means for multiplying the first high frequency extracted by the high frequency extraction means and the second high frequency oscillated by the oscillation means, and the multiplication From the result multiplied by means Includes harmonic and modulated wave components From a low-pass filter that attenuates high-frequency components and the low-pass filter The output frequency is lower than the frequency of the output from the second high frequency power supply Detection means to detect the output of And a control means for comparing the detection output from the detection means with a reference voltage for setting the output of the high-frequency generation source and controlling the output of the high-frequency generation source based on the comparison result It is characterized by that.
6. The high frequency power supply according to claim 6, wherein the second high frequency power supply includes another high frequency generation source for generating a third high frequency, and the lower electrode and the other high frequency generation source. A matching device is disposed between the lower electrode and the matching device, and another low-pass filter is disposed between the lower electrode and the matching device.
The high frequency power supply according to claim 7 is the high frequency power supply according to claim 5 or 6, wherein the detection means detects a frequency in a range of 10 Hz to 500 kHz output from the low pass filter.
The high-frequency power supply according to claim 8 is the high-frequency power supply according to any one of claims 5 to 7, wherein the detection means has an ideal detector, and an output from the low-pass filter by the ideal detector. Is a direct current.
[0012]
In order to achieve the above object, a high frequency power supply control method according to claim 9 is a high frequency power supply control method for a plasma processing apparatus in which a lower electrode is disposed in a plasma processing container, wherein the high frequency power supply includes First high-frequency power source connected to the lower electrode And a second high-frequency power source The first high-frequency power source includes a high-frequency generation source that generates a first high-frequency for generating plasma in the plasma processing container, and a high-frequency extraction step for extracting the first high-frequency, and the first An oscillation step of oscillating a second high frequency different from the first high frequency, a multiplication step of multiplying the first high frequency extracted in the high frequency extraction step and the second high frequency oscillated in the oscillation step, From the result of multiplication in the multiplication step Includes harmonic and modulated wave components Attenuates high frequency components ·Removal And a detection step of detecting a frequency in the range of 10 Hz to 500 kHz output after the high frequency attenuation step And a control step of comparing the detection output after the detection step with a reference voltage for setting the output of the high-frequency generation source and controlling the output of the high-frequency generation source based on the comparison result It is characterized by that.
In order to achieve the above object, a high frequency power supply control method according to claim 10 is a high frequency power supply control method for a plasma processing apparatus in which a lower electrode is disposed in a plasma processing vessel, wherein the high frequency power supply includes First high-frequency power source connected to the lower electrode And a second high-frequency power source connected to the lower electrode and outputting a high frequency having a frequency lower than the first high-frequency frequency output by the first high-frequency power source. The first high-frequency power source includes a high-frequency generation source that generates a first high-frequency for generating plasma in the plasma processing container, and a high-frequency extraction step for extracting the first high-frequency, and the first An oscillation step of oscillating a second high frequency different from the first high frequency, a multiplication step of multiplying the first high frequency extracted in the high frequency extraction step and the second high frequency oscillated in the oscillation step, From the result of multiplication in the multiplication step Includes harmonic and modulated wave components A high frequency attenuation process for attenuating a high frequency component with a low-pass filter and output in the high frequency attenuation process A frequency lower than the frequency of the output from the second high-frequency power source. Detection process for detecting output And a control step of comparing the detection output after the detection step with a reference voltage for setting the output of the high-frequency generation source and controlling the output of the high-frequency generation source based on the comparison result It is characterized by that.
In order to achieve the above object, a plasma processing apparatus according to claim 11 is a plasma processing apparatus in which a lower electrode is disposed in a plasma processing container, wherein a first high-frequency power source connected to the lower electrode, Two high-frequency power sources, wherein the first high-frequency power source includes a high-frequency generation source that generates a first high frequency for generating plasma in the plasma processing vessel, and a high-frequency extraction unit that extracts the first high frequency. Oscillating means for oscillating a second high frequency different from the first high frequency, and multiplying means for multiplying the first high frequency extracted by the high frequency extracting means and the second high frequency oscillated by the oscillating means. And from the result of multiplication by the multiplication means Includes harmonic and modulated wave components Attenuates high frequency components ·Removal High frequency attenuating means, and a detecting means for detecting a frequency in the range of 10 Hz to 500 kHz outputted from the high frequency attenuating means And a control means for comparing the detection output from the detection means with a reference voltage for setting the output of the high-frequency generation source and controlling the output of the high-frequency generation source based on the comparison result It is characterized by that.
The plasma processing apparatus according to claim 12 is the plasma processing apparatus according to claim 11, wherein the frequency of the first high frequency generated by the high frequency generation source is higher than the frequency of the output from the second high frequency power supply. It is characterized by being.
The plasma processing apparatus according to claim 13 is the plasma processing apparatus according to claim 11 or 12, wherein the frequency of the output from the high frequency attenuation means is lower than the frequency of the output from the second high frequency power supply. It is characterized by.
The plasma processing apparatus according to claim 14 is the plasma processing apparatus according to any one of claims 11 to 13, wherein the second high-frequency power source includes another high-frequency generation source that generates a third high-frequency, The apparatus further includes a matching unit disposed between the lower electrode and the other high-frequency generation source, and a low-pass filter disposed between the lower electrode and the matching unit.
In order to achieve the above object, the plasma processing apparatus according to claim 15 is a plasma processing apparatus in which a lower electrode is disposed in a plasma processing container, and the first high-frequency power source connected to the lower electrode And outputs a high frequency having a frequency lower than the first high frequency output from the first high frequency power source connected to the lower electrode. Second high frequency power supply When The first high-frequency power source is a high-frequency for generating plasma in the plasma processing vessel, and the first high-frequency power is higher than the frequency of the output from the second high-frequency power source. A high-frequency generation source for generating, a high-frequency extraction means for extracting the first high frequency, an oscillating means for oscillating a second high frequency different from the first high frequency, and a first extracted by the high-frequency extraction means Multiplying means for multiplying the high frequency and the second high frequency oscillated by the oscillating means, and the result multiplied by the multiplying means Includes harmonic and modulated wave components From a low-pass filter that attenuates high-frequency components and the low-pass filter The output frequency is lower than the frequency of the output from the second high frequency power supply Detection means to detect the output of And a control means for comparing the detection output from the detection means with a reference voltage for setting the output of the high-frequency generation source and controlling the output of the high-frequency generation source based on the comparison result It is characterized by that.
The plasma processing apparatus according to claim 16 is the plasma processing apparatus according to claim 15, wherein the second high-frequency power source includes another high-frequency generation source that generates a third high-frequency, and the lower electrode and the other high-frequency generation source. It further comprises a matching unit disposed between the generation sources, and another low-pass filter disposed between the lower electrode and the matching unit.
The plasma processing apparatus according to claim 17 is the plasma processing apparatus according to claim 15 or 16, wherein the detection means detects a frequency in a range of 10 Hz to 500 kHz output from the low-pass filter.
The plasma processing apparatus according to claim 18 is the plasma processing apparatus according to any one of claims 15 to 17, wherein the detection means includes an ideal detector, and the ideal detector detects the low-pass filter. Is characterized in that the output is DC.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0014]
FIG. 1 is a block diagram showing an overall configuration of a plasma processing apparatus including a high frequency power source according to an embodiment of the present invention.
[0015]
In FIG. 1, a plasma processing apparatus 1 is connected to a plasma chamber 2 that is a plasma processing container, a first matching box 3 connected to a lower electrode (not shown) in the plasma chamber 2, and a first matching box 3. First high-frequency power source 4, a second matching box 5 connected to the electrode in the plasma chamber 2 via a low-pass filter 7, and a second high-frequency power source connected to the second matching box 5 6.
[0016]
The plasma processing apparatus 1 arranges a pair of parallel plate electrodes (not shown) (upper electrode and lower electrode) in the plasma chamber 2 to introduce a processing gas, and applies a high frequency to one of the electrodes to apply a gap between the electrodes. A high frequency electric field is formed, plasma is generated by the high frequency electric field, and a semiconductor wafer (hereinafter referred to as “wafer”) is subjected to plasma treatment.
[0017]
The first high-frequency power source 4 detects an incident wave (incident power: Pf) traveling to the plasma chamber 2 and a reflected wave (reflected power: Pr) returning from the plasma chamber 2 when plasma is generated to control the high-frequency output. A power monitor 8 and a high frequency generation source 10 that generates a high frequency of 100 MHz are provided, and a high frequency power for plasma generation of 100 MHz is output. Further, the first high frequency power source 4 controls the high frequency generated from the high frequency generation source 10 by the power monitor 8 and outputs it to the first matching box 3.
[0018]
The first matching box 3 includes an RF sensor (not shown) that detects a high frequency of 100 MHz and a circuit (not shown) that includes a variable capacitor, a coil, and the like, and has a plasma chamber 2 side that minimizes reflected waves. Is a matching circuit for matching the load impedance to the power impedance on the first high-frequency power source 4 side. In particular, the load impedance viewed from the input side of the first matching box 3 and the impedance viewed from the output side of the first high-frequency power supply 4 are set to be the same (50Ω).
[0019]
The second high-frequency power source 6 includes a power monitor 9 that detects incident waves and reflected waves and controls high-frequency output, and a high-frequency generation source 11 that generates a high frequency of 3.2 MHz different from the frequency generated by the high-frequency generation source 10. And outputs a bias high frequency power of 3.2 MHz.
[0020]
The second matching box 5 includes an RF sensor (not shown) for detecting a high frequency of 3.2 MHz and a circuit (not shown) made up of a variable capacitor, a coil and the like, and a plasma chamber so as to minimize reflected waves. This is a matching circuit for matching the load impedance on the second side with the power source impedance on the second high-frequency power source 6 side. The low-pass filter 7 protects the second matching box 5 and the second high-frequency power source 6 from a high frequency of 100 MHz from the first high-frequency power source 4 and attenuates reflected waves.
[0021]
At the time of plasma processing, a plasma generation high frequency output from the first high frequency power supply 4 and a bias high frequency output from the second high frequency power supply 6 for drawing ions in the plasma discharge are superimposed. The voltage is applied to a lower electrode (not shown) in the plasma chamber 2.
[0022]
FIG. 2 is a schematic diagram showing the internal configuration of the power monitor 8 in FIG.
[0023]
In FIG. 2, the power monitor 8 includes a directional coupler 21, a mixer 22 that is a 2-input 1-output multiplier (DBM: double balanced mixer), a 100 kHz low-pass filter 23, and a low-frequency detector 24. The control device includes an oscillator 25 that oscillates at a predetermined frequency, and performs detection by removing harmonics and modulation waves generated during plasma generation, and applies a predetermined high frequency to the plasma chamber 2 during plasma generation.
[0024]
The directional coupler 21 takes out a high frequency of 100 MHz generated from the high frequency generation source 10 and inputs it to the mixer 22. The oscillator 25 includes an amplifier (not shown), a double frequency multiplier (not shown), a 49.95 MHz crystal oscillator (not shown), and the like, and inputs a high frequency of 99.9 MHz to the mixer 22. The mixer 22 multiplies the high frequency extracted by the directional coupler 21 and the high frequency input by the oscillator 25 to perform frequency mixing. The low pass filter 23 attenuates the high frequency component of the output from the mixer 22. The low-frequency detector 24 includes an amplifier (not shown), an ideal detector (not shown) of 100 kHz, and the like, and detects a low frequency of 100 kHz among outputs from the low-pass filter 23 to obtain a DC output (detection output). . FIG. 3 shows frequency characteristics of detection (beat down type) in the power monitor 8 of FIG. 2 and conventional detection (filter type) in FIG.
[0025]
Next, the operation of the power monitor 8 will be described.
[0026]
For example, a high frequency with a main frequency of 100 MHz including a side band component of ± 3.2 MHz generated by modulation of the plasma load in the plasma chamber 2 is taken out by the directional coupler 21 and input to the mixer 22. On the other hand, a high frequency of 99.9 MHz from the oscillator 25 is input to the mixer 22. The mixer 22 multiplies these input high frequencies, and as a result, a signal of 199.9 MHz ± 3.2 MHz, 100 MHz + 3.2 MHz, or the like is output to the low-pass filter 23.
[0027]
Among the outputs from the mixer 22, those having a frequency of 199.9 ± 3.2 MHz or 3.2 MHz are attenuated and removed by the low-pass filter 23 and output to the low-frequency detector 24. The low frequency detector 24 outputs a low frequency of 100 kHz, which is an output from the low pass filter 23, as a DC output to an error amplifier circuit (not shown). In this error amplification circuit, a direct current voltage (DC) from a low frequency detector is compared with a reference voltage for setting an output, and a comparison voltage is applied to a high frequency amplifier (not shown) according to the comparison result. Control the output. Thereby, harmonics and modulation waves generated during plasma generation can be accurately removed to prevent malfunction of the first high-frequency power supply 4 and an appropriate high frequency can be applied to the plasma processing apparatus 1.
[0028]
By selecting the frequency from the oscillator 25 to 99.9 MHz with respect to the main frequency of 100 MHz, the sideband component becomes a frequency sufficiently separated from the cutoff frequency of the low-pass filter 23, so the low-pass filter 23 has a simple configuration. However, the sideband component can be sufficiently removed. Even if the modulation wave is close to the main frequency, the modulation wave component can be removed by selecting the cutoff frequency of the low-pass filter 23 to a value sufficiently lower than the modulation frequency.
[0029]
According to the above embodiment, the mixer 22 adds the high frequency of the main frequency 100 MHz including the modulated wave extracted by the directional coupler 21 and the high frequency of the frequency 99.9 MHz oscillated by the oscillator 25, and outputs the result. Is converted to 100 kHz by the low-pass filter 23 and the low-frequency detector 24 to perform detection, so that harmonics and modulation waves generated at the time of plasma generation can be accurately removed to prevent malfunction of the first high-frequency power source 4. An appropriate high frequency can be applied to the plasma chamber 2.
[0030]
Although the parallel plate plasma processing apparatus 1 has been described in the above embodiment, it can be applied to plasma processing apparatuses having various plasma sources such as a microwave plasma processing apparatus and an ECR (electron coupling resonance) plasma processing apparatus. Is possible.
[0031]
Further, the power monitor 8 in the above embodiment converts the main frequency of 100 MHz to 100 kHz and performs detection. However, the present invention is not limited to this, and other than 100 MHz, for example, the main frequency of 70 MHz or more is converted to 100 kHz and detected. You may make it perform. Furthermore, the frequency for detection may be set to a frequency other than 100 kHz, for example, a frequency in the range of 10 Hz to 500 kHz. If a sufficiently fast response speed as a control loop is desired, the value is set to a value of about 15 Hz to 500 kHz. It is desirable to set.
[0032]
Note that the matching circuit in the first matching box 3 and the second matching box 5 in the above embodiment is configured with a variable capacitor and a coil. However, for example, when a high frequency of 70 MHz or more is applied, a special circuit is used. You may comprise using the matching device disclosed by the open 2001-118700 gazette.
[0033]
Further, although the power monitor 8 is built in the first high frequency power supply 4, it may be built in the first matching box 5 instead of the first high frequency power supply 4. Instead of the circuit, a phase detection circuit or an arithmetic circuit may be used and used as an RF sensor.
[0034]
【The invention's effect】
As described above in detail, according to the high frequency power source of claim 1 and the plasma processing apparatus of claim 11, the first high frequency extracted by the high frequency extraction means and the second high frequency oscillated by the oscillation means. And from the multiplied result Includes harmonic and modulated wave components High frequency component attenuated ·Removal Since a frequency in the range of 10 Hz to 500 kHz is detected, harmonics and modulation waves generated during plasma generation can be accurately removed to prevent malfunction, and an appropriate high frequency can be applied. Harmonics and modulated waves can be removed with a simple filter.
According to the high frequency power source of claim 5 and the plasma processing apparatus of claim 15, the first high frequency extracted by the high frequency extraction means and the second high frequency oscillated by the oscillation means are multiplied and multiplied. From the result of the low pass filter Includes harmonic and modulated wave components Since the high frequency component is attenuated and detected, harmonics and modulated waves generated during plasma generation can be accurately removed to prevent malfunction and an appropriate high frequency can be applied.
[0037]
According to the method for controlling a high frequency power supply according to claim 9, the first high frequency extracted in the high frequency extraction step and the second high frequency oscillated in the oscillation step are multiplied and the result of multiplication is used. Includes harmonic and modulated wave components High frequency component attenuated ·Removal Since a frequency in the range of 10 Hz to 500 kHz is detected, harmonics and modulation waves generated during plasma generation can be accurately removed to prevent malfunction, and an appropriate high frequency can be applied. Harmonics and modulated waves can be removed with a simple filter.
According to the method for controlling a high frequency power supply according to claim 10, the first high frequency extracted in the high frequency extraction step and the second high frequency oscillated in the oscillation step are multiplied, and a low pass is determined from the multiplication result. By filter Includes harmonic and modulated wave components Since the high frequency component is attenuated and detected, harmonics and modulated waves generated during plasma generation can be accurately removed to prevent malfunction and an appropriate high frequency can be applied.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an overall configuration of a plasma processing apparatus including a high frequency power supply according to an embodiment of the present invention.
2 is a schematic diagram showing an internal configuration of a power monitor 8 in FIG.
3 is a diagram showing frequency characteristics of detection (beat-down type) in the power monitor 8 of FIG. 2 and conventional detection (filter type) in FIG. 5;
FIGS. 4A and 4B are diagrams showing input / output modulated wave spectra in a conventional plasma processing apparatus, where FIG. 4A shows an incident wave and FIG. 4B shows a reflected wave;
FIG. 5 is a schematic diagram showing an internal configuration of a power monitor in a conventional plasma processing apparatus.
[Explanation of symbols]
1 Plasma processing equipment
2 Plasma chamber
3 First matching box
4 First high frequency power supply
5 Second matching box
6 Second high-frequency power supply
7 Low-pass filter
8,9 Power monitor
10, 11 High frequency source
21 Directional coupler
22 Mixer
23 Low-pass filter
24 Low frequency detector
25 Oscillator

Claims (18)

A high-frequency power supply for a plasma processing apparatus in which a lower electrode is disposed in a plasma processing container,
A first high-frequency power source and a second high-frequency power source connected to the lower electrode;
The first high frequency power source is:
A high frequency generation source for generating a first high frequency for generating plasma in the plasma processing vessel;
A high frequency extraction means for extracting the first high frequency;
Oscillating means for oscillating a second high frequency different from the first high frequency;
Multiplying means for multiplying the first high frequency extracted by the high frequency extracting means and the second high frequency oscillated by the oscillating means;
High-frequency attenuation means for attenuating and removing high-frequency components including harmonic and modulated wave components from the result of multiplication by the multiplication means;
Detection means for detecting a frequency in the range of 10 Hz to 500 kHz output from the high-frequency attenuation means ;
Control means for comparing the detection output from the detection means with a reference voltage for setting the output of the high-frequency generation source, and controlling the output of the high-frequency generation source based on the comparison result. And high frequency power supply.   2. The high frequency power supply according to claim 1, wherein a frequency of the first high frequency generated by the high frequency generation source is higher than a frequency of an output from the second high frequency power supply.   The high frequency power supply according to claim 1 or 2, wherein the frequency of the output from the high frequency attenuating means is lower than the frequency of the output from the second high frequency power supply.   The second high-frequency power source includes another high-frequency generation source that generates a third high-frequency, a matching unit is disposed between the lower electrode and the other high-frequency generation source, and the lower electrode and the matching unit The high frequency power supply according to any one of claims 1 to 3, wherein a low-pass filter is disposed therebetween. A high-frequency power supply for a plasma processing apparatus in which a lower electrode is disposed in a plasma processing container,
A first high-frequency power source connected to the lower electrode ;
A second high frequency power source connected to the lower electrode and outputting a high frequency of a frequency lower than the first high frequency frequency output by the first high frequency power source ,
The first high frequency power source is:
A high frequency generation source for generating a first high frequency for generating plasma in the plasma processing vessel;
A high frequency extraction means for extracting the first high frequency;
Oscillating means for oscillating a second high frequency different from the first high frequency;
Multiplying means for multiplying the first high frequency extracted by the high frequency extracting means and the second high frequency oscillated by the oscillating means;
A low-pass filter for attenuating high-frequency components including harmonic and modulated wave components from the result of multiplication by the multiplication means;
Detection means for detecting an output having a frequency lower than that of the output from the second high-frequency power source, which is output from the low-pass filter ;
Control means for comparing the detection output from the detection means with a reference voltage for setting the output of the high-frequency generation source, and controlling the output of the high-frequency generation source based on the comparison result. And high frequency power supply.   The second high-frequency power source includes another high-frequency generation source that generates a third high-frequency, a matching unit is disposed between the lower electrode and the other high-frequency generation source, and the lower electrode and the matching unit 6. The high-frequency power source according to claim 5, wherein another low-pass filter is disposed between them.   7. The high frequency power supply according to claim 5, wherein the detection means detects a frequency in a range of 10 Hz to 500 kHz output from the low pass filter.   The high-frequency power supply according to any one of claims 5 to 7, wherein the detection means includes an ideal detector, and the output from the low-pass filter is converted into a direct current by the ideal detector. A method for controlling a high frequency power source of a plasma processing apparatus in which a lower electrode is disposed in a plasma processing container,
The high frequency power source includes a first high frequency power source and a second high frequency power source connected to the lower electrode,
The first high frequency power source includes a high frequency generation source that generates a first high frequency for generating plasma in the plasma processing vessel,
A high frequency extraction step of extracting the first high frequency;
An oscillation step of oscillating a second high frequency having a frequency different from the first high frequency;
A multiplication step of multiplying the first high frequency extracted in the high frequency extraction step and the second high frequency oscillated in the oscillation step;
A high-frequency attenuation step for attenuating and removing high-frequency components including harmonic and modulated wave components from the result of multiplication in the multiplication step;
A detection step of detecting a frequency in the range of 10 Hz to 500 kHz output after the high-frequency attenuation step ;
A control step of comparing the detection output after the detection step with a reference voltage for setting the output of the high-frequency generation source, and controlling the output of the high-frequency generation source based on the comparison result. A method for controlling a high-frequency power source. A method for controlling a high frequency power source of a plasma processing apparatus in which a lower electrode is disposed in a plasma processing container,
The high frequency power source outputs a first high frequency power source connected to the lower electrode and a high frequency having a frequency lower than a first high frequency frequency output from the first high frequency power source connected to the lower electrode. And a second high frequency power source
The first high frequency power source includes a high frequency generation source that generates a first high frequency for generating plasma in the plasma processing vessel,
A high frequency extraction step of extracting the first high frequency;
An oscillation step of oscillating a second high frequency having a frequency different from the first high frequency;
A multiplication step of multiplying the first high frequency extracted in the high frequency extraction step and the second high frequency oscillated in the oscillation step;
A high-frequency attenuation step of attenuating a high-frequency component including harmonic and modulated wave components from the result multiplied in the multiplication step by a low-pass filter;
A detection step of detecting an output having a frequency lower than the frequency of the output from the second high-frequency power source, which is output in the high-frequency attenuation step ;
A control step of comparing the detection output after the detection step with a reference voltage for setting the output of the high-frequency generation source, and controlling the output of the high-frequency generation source based on the comparison result. A method for controlling a high-frequency power source. A plasma processing apparatus in which a lower electrode is disposed in a plasma processing container,
A first high-frequency power source and a second high-frequency power source connected to the lower electrode;
The first high frequency power source is:
A high frequency generation source for generating a first high frequency for generating plasma in the plasma processing vessel;
A high frequency extraction means for extracting the first high frequency;
Oscillating means for oscillating a second high frequency different from the first high frequency;
Multiplying means for multiplying the first high frequency extracted by the high frequency extracting means and the second high frequency oscillated by the oscillating means;
High-frequency attenuation means for attenuating and removing high-frequency components including harmonic and modulated wave components from the result of multiplication by the multiplication means;
Detection means for detecting a frequency in the range of 10 Hz to 500 kHz output from the high-frequency attenuation means ;
Control means for comparing the detection output from the detection means with a reference voltage for setting the output of the high-frequency generation source, and controlling the output of the high-frequency generation source based on the comparison result. A plasma processing apparatus.   12. The plasma processing apparatus according to claim 11, wherein the frequency of the first high frequency generated by the high frequency generation source is higher than the frequency of the output from the second high frequency power source.   13. The plasma processing apparatus according to claim 11, wherein the frequency of the output from the high frequency attenuation means is lower than the frequency of the output from the second high frequency power source.   The second high-frequency power source includes another high-frequency generation source that generates a third high-frequency power source, and includes a matching unit disposed between the lower electrode and the other high-frequency generation source, and the lower electrode and the matching unit. The plasma processing apparatus according to claim 11, further comprising a low-pass filter disposed therebetween. A plasma processing apparatus in which a lower electrode is disposed in a plasma processing container,
A first high-frequency power source connected to the lower electrode ;
Connected to said lower electrode, and a second RF power supply that outputs a high frequency of the first first frequency lower than the frequency of the high frequency RF power is output,
The first high frequency power source is:
A high frequency generating source that generates a first high frequency that is a high frequency for generating plasma in the plasma processing vessel and that is higher than a frequency of an output from the second high frequency power supply;
A high frequency extraction means for extracting the first high frequency;
Oscillating means for oscillating a second high frequency different from the first high frequency;
Multiplying means for multiplying the first high frequency extracted by the high frequency extracting means and the second high frequency oscillated by the oscillating means;
A low-pass filter for attenuating high-frequency components including harmonic and modulated wave components from the result of multiplication by the multiplication means;
Detection means for detecting an output having a frequency lower than that of the output from the second high-frequency power source, which is output from the low-pass filter ;
Control means for comparing the detection output from the detection means with a reference voltage for setting the output of the high-frequency generation source, and controlling the output of the high-frequency generation source based on the comparison result. A plasma processing apparatus.   The second high-frequency power source includes another high-frequency generation source that generates a third high-frequency power source, and includes a matching unit disposed between the lower electrode and the other high-frequency generation source, and the lower electrode and the matching unit. The plasma processing apparatus according to claim 15, further comprising another low-pass filter disposed therebetween.   The plasma processing apparatus according to claim 15 or 16, wherein the detection means detects a frequency in a range of 10 Hz to 500 kHz output from the low-pass filter.   The plasma processing apparatus according to any one of claims 15 to 17, wherein the detection means includes an ideal detector, and the output from the low-pass filter is converted into a direct current by the ideal detector.

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