JP2008181846A - High frequency device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve a problem of a conventional high frequency device varying an output frequency of a high frequency electric power to control lowering of the reflection coefficient absolute value Γ, capable of adjusting a reactance component X of a load-side impedance ZL, while incapable of adjusting resistance component R, sometimes thereby incapable of lowering the reflection coefficient absolute value Γ. <P>SOLUTION: The high frequency device supplies an electric power to a plasma processing apparatus, for example. In the high frequency device, a frequency control circuit 11 varies the output frequency of the high frequency electric power to control lowering of the reflection coefficient absolute value Γ. When the control cannot lower the reflection coefficient absolute value Γ than a reference value, a reactance element control circuit 19 varies a variable capacitor VC1 in an impedance regulator 3 to control lowering of the reflection coefficient absolute value Γ. This lowers the reflection coefficient absolute value Γ than ever before. Moreover, use of a variable capacitor VC2 provides the further adjustment. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a high-frequency apparatus that supplies power to a load such as a plasma processing apparatus used for applications such as plasma etching and plasma CVD.

  In a load such as a plasma processing apparatus used for applications such as plasma etching and plasma CVD, the impedance changes from moment to moment as the manufacturing process proceeds. In order to efficiently supply an electrode to such a load, an impedance viewed from the output end of the high-frequency power supply device (hereinafter referred to as load-side impedance ZL) in accordance with a change in load impedance Z1 (impedance of only the load) Need to be adjusted. Therefore, not only a high-frequency power supply device that supplies high-frequency power but also an impedance adjuster for adjusting the load-side impedance ZL is usually used in combination.

  If the impedance when the power supply side is viewed from the output terminal of the high-frequency power supply device is the power supply impedance Z0, the reflected wave power is minimized when the power supply impedance Z0 and the load impedance ZL are matched. Also, the reflection coefficient absolute value Γ is minimized. That is, the reflected wave power can be reduced by adjusting the load side impedance ZL.

  Although there is one that adjusts the impedance only by this impedance adjuster, a variable frequency method that can adjust the load side impedance ZL by varying the output frequency of the high frequency power supply device as in Patent Document 1 and Patent Document 2. In some cases, a high frequency power supply device is used. A device configured by combining a high-frequency power supply device and an impedance adjuster is referred to as a high-frequency device.

FIG. 7 is a diagram illustrating a configuration example of a conventional high-frequency device and a connection relationship between the high-frequency device and the load 5.
The high frequency power supply device 50 supplies high frequency power to the load 5 via the impedance adjuster 6 and has a function of changing the output frequency.

  More specifically, the high-frequency power supply device 50 outputs high-frequency power using the power amplifier 53, and the high-frequency power output value measured by the power measuring device 54 is a target set by the power setting device 56. The output is controlled to be a value. Further, the output frequency of the high frequency power supply device is determined by the oscillation frequency of the oscillation circuit 52 whose oscillation frequency is controlled by the frequency control circuit 51. The high frequency power output from the high frequency power supply device 50 is supplied to the load 5 via the transmission line 2 made of a coaxial cable, the impedance adjuster 6, and the load connection portion 4 made of a shielded copper plate. The ON / OFF control circuit 57 controls the output ON / OFF of the oscillation circuit 52. The oscillation circuit 52 outputs a high frequency signal when the ON signal is output from the ON / OFF control circuit 57. To do. The ON / OFF control circuit 57 is controlled by operating a power output switch (not shown) provided in the high frequency power supply device 50, or controlled by a control signal from an external device.

The impedance adjuster 6 has reactance elements such as capacitors and inductors inside, and compared with the case without this impedance adjuster, the load side impedance ZL can be changed and the reflected wave power can be adjusted by the high frequency power supply device. Thus, the load side impedance ZL is adjusted.
In the example shown in FIG. 7, two capacitors, a capacitor C1 and a capacitor C2, and an inductor L1 are provided in the impedance adjuster. The reactance value of the reactance element (capacitance in the case of a capacitor, inductance in the case of an inductor) is a fixed value obtained according to the characteristics of the load from data obtained by simulation or experiment.

  The load 5 is an apparatus for processing (etching, CVD, etc.) a workpiece such as a wafer and a liquid crystal substrate that is provided with a processing unit and is carried into the processing unit. In order to process the workpiece, the load 5 introduces a plasma discharge gas into the processing portion, and applies high frequency power (voltage) supplied from the high frequency power supply device 50 to the plasma discharge gas. The plasma discharge gas is discharged to change from a non-plasma state to a plasma state. Then, the workpiece is processed using plasma.

  Now, when the output frequency is changed in the high-frequency power supply device 50 described above, the load-side impedance ZL changes, so that the reflected wave power can be reduced by controlling the output frequency.

However, the reflected wave power may not be sufficiently reduced only by controlling the output frequency of the high frequency power supply device 50. This is because, when the load impedance Z1 is expressed by the equation (1), even if the output frequency is changed, it is mainly the reactance component X that changes in the load impedance Z1, and the resistance component R is not so much. This is because it does not change. As far as Expression (1) is viewed, it seems that only the reactance component X changes due to the change in the output frequency. However, although details are omitted, actually, the resistance component R also slightly changes. In Expression (1), “f” represents the output frequency of the high-frequency power supply device 50, “C” represents the capacitive component of the load, and “L” represents the inductive component of the load.
Z1 = R + jX = R + j (2πfL−1 / (2πfC)) (1)

  In addition, since there is a limit to the range of the reactance component X that is changed by changing the output frequency of the high-frequency power supply device 50, it is possible to deal with all the load impedances Z1 only by controlling the output frequency of the high-frequency power supply device 50. I can't.

  Therefore, the load side impedance ZL is changed using the impedance adjuster 6 so that the reflected wave power can be reduced only by controlling the output frequency of the high frequency power supply device 50.

JP 2006-310245 A JP 2006-286254 A

  Although the reflected wave power can be controlled to be small by the high frequency device in which the high frequency power supply device 50 and the impedance adjuster 6 are combined, as described above, it changes by changing the output frequency of the high frequency power supply device. This is mainly the reactance component X, and the resistance component R does not change much. Accordingly, the reactance value of the reactance element in the impedance adjuster 6 is set in advance so that the resistance component R is close to a specified value (for example, 50Ω).

However, since the load impedance Z1 changes from moment to moment, the optimum setting cannot be made at all points in the manufacturing process. For this purpose, for example, the reactance value of the reactance element is set in advance so that the reflected wave power is equal to or lower than the reference value in the entire manufacturing process.
That is, the reactance element of the impedance adjuster 6 has a fixed reactance value. It is desirable to set the fixed reactance value in this way from the viewpoint of downsizing and cost of the apparatus. Therefore, the fixed reactance value is adopted as much as possible.

  However, when such a high-frequency device is used in the case of a load having a characteristic in which the load impedance Z1 largely fluctuates throughout the manufacturing process, the reflected wave power cannot be sufficiently reduced and may exceed the reference value.

  In order to improve this problem, a variable reactance element such as a variable capacitor and a variable inductor is used, and an automatic impedance matching unit that performs impedance matching by automatically controlling the variable reactance element is used instead of the impedance adjuster. It is possible to use it. In other words, this is a case where a high frequency device is obtained by combining the variable frequency type high frequency power supply device 50 and the automatic impedance matching device.

  However, since the automatic impedance matching unit performs control for simultaneously adjusting both the resistance component R and the reactance component X, the control is complicated. In addition, when the automatic impedance matching unit is used, the size of the apparatus increases and the price becomes expensive. In addition, when the automatic impedance matching device is used, the matching operation by the automatic impedance matching device and the adjustment operation of the output frequency by the high frequency power supply device 50 proceed at the same time.

  There is also a method of reducing the reflected wave power by using only an automatic impedance matching device that automatically performs impedance matching using a high frequency power supply device with a fixed output frequency instead of a variable frequency type high frequency power supply device. It is faster to use a variable frequency high frequency power supply device in terms of adjustment speed to be reduced. Therefore, a high-frequency device using a variable-frequency high-frequency power supply device is desired in applications that require an adjustment speed for reducing the reflected wave power.

  The present invention has been conceived under the above circumstances, using a variable frequency method high frequency power supply device, and regardless of the configuration without using an automatic impedance matching device, throughout the manufacturing process, An object of the present invention is to provide a high-frequency device capable of reducing the reflected wave power even when the load impedance Z1 is a load having a characteristic that fluctuates greatly.

The high-frequency device provided by the first invention is
A high frequency device for supplying high frequency power to a load,
An oscillation means capable of varying the oscillation frequency;
A high frequency power supply means for amplifying an oscillation signal output from the oscillation means to be a power generation source and supplying high frequency power to the load;
Reflected wave information calculation means for calculating reflected wave information related to the reflected wave power and outputting the calculated reflected wave information;
Frequency control means for controlling the oscillation frequency of the oscillating means so that the reflected wave information becomes small;
Impedance adjusting means provided between the high-frequency power supply means and the load and having at least one variable reactance element, wherein one of the variable reactance elements is controllable;
Element control means for controlling a variable reactance element that can be controlled by the impedance adjustment means so that the reflected wave information becomes smaller;
It is equipped with.

  A high-frequency device provided by a second invention relates to the element control means, wherein the element control means oscillates the oscillation means so that the reflected wave information becomes small in the frequency control means. The control of the controllable variable reactance element is started when the reflected wave information does not become smaller than a reference value in spite of controlling the frequency.

  A high-frequency device provided by a third invention relates to the frequency control means, and the frequency control means controls the oscillation while the variable reactance element that can be controlled by the element control means is being controlled. The oscillation frequency of the means is not controlled.

  A high-frequency device provided by a fourth invention relates to the frequency control means, wherein the frequency control means controls the impedance adjustment means so that the reflected wave information becomes small in the element control means. A possible variable reactance element is controlled, and after the reflected wave information becomes smaller than a reference value, the control is resumed when the reflected wave information becomes larger than the reference value again. .

  A high-frequency device provided by a fifth invention relates to the frequency control means, wherein the frequency control means controls the impedance adjustment means so that the reflected wave information becomes small in the element control means. Control is resumed when the reflected wave information does not become smaller than a reference value in spite of controlling a possible variable reactance element.

  A high-frequency device provided by a sixth invention relates to a variable reactance element that can be controlled by the impedance adjusting means, and the variable reactance element changes a resistance component of impedance on a load side relative to the high-frequency power supply means. It is characterized by having a function to make it.

The high-frequency device provided by the seventh invention is
A high frequency device for supplying high frequency power to a load,
An oscillation means capable of varying the oscillation frequency;
A high frequency power supply means for amplifying an oscillation signal output from the oscillation means to be a power generation source and supplying high frequency power to the load;
Reflected wave information calculation means for calculating reflected wave information related to the reflected wave power and outputting the calculated reflected wave information;
Frequency control means for controlling the oscillation frequency of the oscillating means so that the reflected wave information becomes small;
Impedance adjusting means that is provided between the high-frequency power supply means and the load and has a plurality of variable reactance elements, and two of the plurality of variable reactance elements can be controlled;
Element control means for controlling any one of the variable reactance elements that can be controlled by the impedance adjustment means so that the reflected wave information becomes small;
It is equipped with.

  A high-frequency device provided by an eighth invention relates to the element control means, wherein the element control means oscillates the oscillation means so that the reflected wave information becomes small in the frequency control means. When the reflected wave information does not become smaller than a reference value in spite of controlling the frequency, control of one of the two variable reactance elements that can be controlled is started.

  A high-frequency device provided by a ninth invention relates to the element control means, wherein the element control means can control the variable of the impedance adjustment means so as to reduce the reflected wave information. When one of the reactance elements is controlled and the reflected wave information is not smaller than a reference value, control of the other of the two controllable variable reactance elements is started. It is a feature.

  A high-frequency device provided by a tenth aspect of the invention relates to the frequency control means, and the frequency control means performs the oscillation while controlling the variable reactance element that can be controlled by the element control means. The oscillation frequency of the means is not controlled.

  A high-frequency device provided by an eleventh aspect of the invention relates to the frequency control means, and the frequency control means controls the impedance adjustment means so that the reflected wave information becomes small in the element control means. A possible variable reactance element is controlled, and after the reflected wave information becomes smaller than a reference value, the control is resumed when the reflected wave information becomes larger than the reference value again. .

  A high-frequency device provided by a twelfth aspect of the invention relates to the frequency control means, and the frequency control means controls the impedance adjustment means so that the reflected wave information becomes small in the element control means. Control is resumed when the reflected wave information does not become smaller than a reference value in spite of controlling a possible variable reactance element.

  A high frequency device provided by a thirteenth aspect of the invention relates to a variable reactance element that can be controlled by the impedance adjusting means, and one of the two variable reactance elements that can be controlled by the impedance adjusting means is a high frequency power supply means. The other of the two variable reactance elements that can be controlled has the function of changing the reactance component of the load side impedance rather than the high-frequency power supply means. It is characterized by that.

  According to the present invention, it is possible to perform control for adjusting both the resistance component R and the reactance component X of the load side impedance regardless of the configuration using the variable frequency type high frequency power supply device and not using the automatic impedance matching device. Therefore, the reflected wave power can be reduced. Moreover, the resistance component R can be adjusted by simple control. As a result, for example, even in the case of a load having a characteristic in which the load impedance Z1 varies greatly throughout the manufacturing process, the reflected wave power can be reduced. Of course, the absolute value of the reflection coefficient may be controlled to be small.

  Even when two controllable variable reactance elements are used, there is only one variable reactance element that is simultaneously controlled by the reactance element control circuit 19 while high-frequency power is supplied to the load. Therefore, the variable reactance element can be controlled relatively easily.

  Hereinafter, details of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a diagram illustrating a configuration example of a high-frequency device according to the first embodiment of the present invention and a connection relationship between the high-frequency device and a load 5. In addition, let the apparatus comprised combining the high frequency power supply device 1 and the impedance regulator 3 be a high frequency apparatus.

  The high frequency power supply device 1 is a device for amplifying a high frequency signal output from the oscillation circuit 12 using a power amplifier 13 and supplying the generated high frequency power to a load 5. The high frequency power output from the high frequency power supply device 1 is supplied to the load 5 via the transmission line 2 made of a coaxial cable, the impedance adjuster 3, and the load connecting part 4 made of a shielded copper plate. In general, this type of high-frequency power supply 1 outputs high-frequency power having a frequency of several hundred kHz or more. The power amplifier 13 is an example of a high-frequency power supply unit according to the present invention.

  The ON / OFF control circuit 17 controls the output ON / OFF of the oscillation circuit 12, and the oscillation circuit 12 outputs a high frequency signal when the ON signal is output from the ON / OFF control circuit 17. The ON / OFF control circuit 17 is controlled by operating a power output switch (not shown) provided in the high frequency power supply device 1 or controlled by a control signal from an external device. The oscillation circuit 12 is an example of an oscillation unit according to the present invention.

  The power control of the high frequency power supply device 1 is performed by converting a high frequency output from the power amplifier 13 into a power value by a power measuring device 14 provided at a subsequent stage of the power amplifier 13 and measuring the measured power value as a power setting device. The output is controlled to be equal to the power target value set at 16. More specifically, the power measurement value and the power target value are input to the power control circuit 15 and a control signal is output to the power amplifier 13 so that the deviation of the power measurement value from the power target value is eliminated.

  The power measuring instrument 14 not only outputs a high frequency output from the power amplifier 13, that is, a traveling wave power measurement value obtained by converting a traveling wave into a power value, but is also reflected from the load side to the power amplifier 13. It has a function of outputting a reflected wave power measurement value obtained by converting a reflected wave to be converted into a power value. What is necessary is just to comprise the electric power measuring device 14 with the conversion circuit for converting the output of a directional coupler and a directional coupler into an electric power value, for example.

  In FIG. 1, the object controlled by the power control circuit 15 may be a traveling wave power measurement value or a load side power measurement value obtained by subtracting the reflected wave power measurement value from the traveling wave power measurement value. In FIG. 1, even if the load-side power measurement value is a control target, a single connection line from the power measuring instrument 14 to the power control circuit 15 is drawn in order to simplify the drawing. . In addition, a traveling wave power measurement value and a reflected wave power measurement value output from the power measuring device 14 are input to the reflection coefficient calculating circuit 18 to be described later, and the connection from the power measuring device 14 toward the reflection coefficient calculating circuit 18 is performed. I draw a single line.

  Further, the output frequency of the high frequency power supply device 1 is determined by the oscillation frequency of the oscillation circuit 12. For example, when it is desired to vary the output frequency of the high frequency power supply device 1 in the range of 13.56 MHz ± α, the oscillation frequency of the oscillation circuit 12 may be varied in the range of 13.56 MHz ± α. The oscillation frequency of the oscillation circuit 12 is controlled by the frequency control circuit 11 so that the reflected wave power is reduced. As the control method, for example, the methods disclosed in Patent Document 1 and Patent Document 2 can be used.

  Further, as described later, when the reflection coefficient absolute value Γ is not smaller than the reference value in spite of controlling the output frequency of the high frequency power supply device 1 (in the above case), the reactance control circuit 19 Adjustment of the variable capacitor VC1 of the impedance adjuster 3 is necessary. For this purpose, the frequency control circuit 11 outputs a control start signal to the reactance control circuit 19. The frequency control circuit 11 is an example of a frequency control unit according to the present invention.

The reflection coefficient calculation circuit 18 calculates and calculates the absolute value of the reflection coefficient (hereinafter referred to as the reflection coefficient absolute value Γ) from the traveling wave power measurement value and the reflected wave power measurement value output from the power meter 14. A reflection coefficient absolute value Γ is output. When the traveling wave power measurement value is represented by Pf and the reflected wave power measurement value is represented by Pr, the reflection coefficient absolute value Γ is represented by the following equation (2). The reflection coefficient absolute value Γ may be obtained by a method different from the method shown here. The reflection coefficient calculation circuit 18 is an example of the reflected wave information calculation means according to the present invention.
Reflection coefficient absolute value Γ = √Pr / √Pf (2)

  The reactance element control circuit 19 controls a variable reactance element in the impedance adjuster 3 to be described later based on the reflection coefficient absolute value Γ output from the reflection coefficient calculation unit 18. This control will be described later with reference to FIG. As will be described later, when the absolute value of the reflection coefficient Γ is smaller than the reference value by controlling the variable reactance element in the impedance adjuster 3, the purpose is to reduce the absolute value of the reflection coefficient Γ. Since it has been achieved, control returns to the frequency control circuit 11. For this purpose, the reactance control circuit 19 outputs a control start signal to the frequency control circuit 11. The reactance element control circuit 19 is an example of an element control unit according to the present invention.

  1 shows an example in which the output frequency of the high frequency power supply device 1 and the reactance of the variable reactance element of the impedance adjuster 3 are controlled based on the reflection coefficient absolute value Γ. Control may be performed using information related to reflected wave power, such as reflected wave power measurement value Pr, instead of the coefficient absolute value. Information related to the reflected wave power such as the reflection coefficient absolute value and the reflected wave power measurement value Pr is referred to as reflected wave information in this specification. Moreover, you may comprise a reflected wave information calculating means so that the information relevant to these reflected wave electric power may be calculated | required.

  The impedance adjuster 3 includes a reactance element such as a capacitor and an inductor. The impedance adjuster 3 changes the load-side impedance ZL and adjusts the reflected wave power by the high frequency power supply device 1 as compared with the case without the impedance adjuster. The load side impedance ZL is adjusted so that it can be performed. The impedance adjuster 3 is an example of impedance adjusting means according to the present invention.

  In the example shown in FIG. 1, the impedance adjuster 3 includes two capacitors, a variable capacitor VC1 and a fixed capacitor C2, and an inductor L1. The load side impedance ZL is adjusted by these reactance elements. Among these, the variable capacitor VC <b> 1 is controlled by the reactance element control circuit 19. The reactance values of the reactance elements, such as the variable capacitance range of the variable capacitor VC1 and the capacitance of the fixed capacitor C2, may be selected from data obtained by simulation or experiment according to the characteristics of the load.

  The capacitance of the variable capacitor VC1 can be changed by a motor (for example, a stepping motor). That is, the reactance element control circuit 19 actually changes the capacitance of the variable capacitor VC1 by controlling the motor.

  More specifically, the variable capacitor VC1 has a movable part for changing the capacitance, and the capacitance can be changed by displacing the position of the movable part. Therefore, the capacitance of the variable capacitor VC1 can be changed by displacing the movable part by the motor. That is, the impedance of the variable impedance element can be changed.

  For example, the capacitance may be increased when the motor is rotated clockwise, and the capacitance may be decreased when the motor is rotated counterclockwise. That is, the capacitance of the variable capacitor VC1 can be changed by controlling the operation direction (rotation direction) and the operation amount (rotation amount) of the motor.

  Note that the variable capacitor VC1 is of a variable type because the resistance component can be changed more greatly by changing the capacitance of the capacitor arranged at this position than at the position of the capacitor C2. It is. That is, the variable capacitor VC1 has a function of changing the resistance component of the load side impedance. Furthermore, when the capacitance of the variable capacitor VC1 is changed, the resistance component changes more greatly than the reactance component.

  Incidentally, the reactance component can be greatly changed by changing the capacitance by changing the capacitor C2 to the variable capacitor VC2. That is, when the capacitor C2 is changed to the variable capacitor VC2, the variable capacitor VC2 has a function of changing the reactance component of the load side impedance. Furthermore, when the capacitor C2 is changed to the variable capacitor VC2, if the capacitance of the variable capacitor VC2 is changed, the reactance component changes more greatly than the resistance component.

  In the present embodiment, the variable capacitor VC1 is described as an example of the variable impedance element. However, even when a variable inductor is used as the variable impedance element, the inductance can be similarly changed using a motor.

  Although omitted in FIG. 1, a discharge detector 17 that detects the presence or absence of discharge in the load 5 is provided as in Patent Document 1, and the frequency control of the high-frequency power supply device is changed depending on the presence or absence of discharge. May be.

  FIG. 2 is an example of a flowchart showing a control method for reducing the reflection coefficient absolute value Γ by the high-frequency device according to the first embodiment of the present invention. A control for reducing the reflection coefficient absolute value Γ will be described with reference to this flowchart. As described above, control may be performed using reflected wave information such as the reflected wave power measurement value Pr instead of the reflection coefficient absolute value.

  Step 1: Supply of high frequency power from the high frequency power supply device 1 to the load 5 is started. High frequency power is output from the high frequency power supply device 1 and supplied to the load 5. When a voltage equal to or higher than the discharge start voltage is applied to the gas in the plasma processing apparatus serving as the load 5, the discharge occurs.

Step 2: After discharging, the frequency control circuit 11 controls the output frequency of the high-frequency power supply device 1 so that the reflection coefficient absolute value Γ is reduced.
Here, the output frequency that minimizes the reflection coefficient absolute value Γ in the variable range of the output frequency of the high-frequency power supply device 1 may be set. Of course, the output frequency may be determined according to other criteria. For example, even if the reflection coefficient absolute value Γ is not the smallest but the second smallest, the reflection coefficient absolute value Γ is more stable in consideration of the reflection coefficient absolute value Γ at the surrounding output frequency. is there. In that case, an output frequency having the second smallest reflection coefficient absolute value Γ may be selected.

Step 3: It is determined whether or not the reflection coefficient absolute value Γ has become smaller than the reference value as a result of controlling the output frequency of the high frequency power supply device 1 in Step 2.
When it is smaller than the reference value (Yes), it is only necessary to control the output frequency of the high-frequency power supply device 1, and the process proceeds to Step 4. If it is not smaller than the reference value (No), the adjustment by the impedance adjuster 3 is necessary, and the process proceeds to Step 5.

Step 4: Transition to the standby mode and monitor the reflection coefficient absolute value Γ. Then, it is determined whether or not the reflection coefficient absolute value Γ is larger than the reference value.
If it is larger than the reference value (Yes), it is necessary to control the output frequency of the high-frequency power supply device 1 again in order to decrease the reflection coefficient absolute value Γ, so the process proceeds to Step 2. When it is not larger than the reference value (No), Step 4 is repeated again.

Step 5: If the reflection coefficient absolute value Γ is not less than or equal to the reference value simply by controlling the output frequency of the high-frequency power supply device 1, it is necessary to adjust the load side impedance ZL by the impedance adjuster 3. 5 to Step 8 are executed.
In step 5, the variable capacitor VC1 is operated by a predetermined amount in the determined operation direction. Note that the initial value is a direction in which the capacitance decreases. Of course, the initial value may be a direction in which the capacitance increases.
When the reactance element control circuit 19 controls the variable reactance element inside the impedance adjuster 3, the frequency control circuit 11 does not control the oscillation frequency of the oscillation circuit 12. That is, the oscillation frequency of the oscillation circuit 12 is held at the previous oscillation frequency.

Step 6: In Step 5, it is determined whether or not the reflection coefficient absolute value Γ has become smaller than the reference value as a result of operating the variable capacitor VC1.
If the value is smaller than the reference value (Yes), the objective of reducing the reflection coefficient absolute value Γ is achieved, and the process proceeds to Step 4. When it is not smaller than the reference value (No), the process proceeds to Step 7 in order to determine whether or not the operation amount of the variable capacitor VC1 is small.

  In step 6, when the value is not smaller than the reference value (No) continues for a predetermined number of times, it may be better to once control the output frequency of the high-frequency power supply device 1. . Therefore, the process may proceed to step 4. As a standard for such processing, not only when it has continued for a predetermined number of times, but also when it does not become smaller than the standard value within a predetermined time, for example. In this case, a timer may be provided inside. That is, even when the value is not smaller than the reference value (No), the process may proceed to Step 4 when a predetermined condition is satisfied. Note that this case corresponds to the case where the reflection coefficient absolute value Γ is larger than the reference value in Step 4 (Yes), and thus the process proceeds to Step 2. Therefore, the process may proceed from step 6 to step 2.

  Further, in step 6 described above, when the reflection coefficient absolute value Γ is not smaller than the reference value (No), when a predetermined condition is satisfied (for example, when it continues continuously for a predetermined number of times), it is Since there is a possibility that an abnormality has occurred, an abnormality signal may be output. The output of the high frequency power of the high frequency power supply device 1 may be stopped by this abnormal signal.

Step 7: It is determined whether or not the reflection coefficient absolute value Γ has decreased as a result of operating the variable capacitor VC1.
When the reflection coefficient absolute value Γ decreases (Yes), the operation amount of the variable capacitor VC1 may be small, and the process proceeds to Step 5. When the reflection coefficient absolute value Γ has not decreased (No), the operation direction of the variable capacitor VC1 may be incorrect, and the process proceeds to Step 8.

Step 8: If the reflection coefficient absolute value Γ has not decreased in Step 7 (No), the operation direction of the variable capacitor VC1 may be incorrect. Go to 5. The reversed operation direction becomes the operation direction from the next time.
Since the reflection coefficient absolute value Γ changes from moment to moment, if the processing in step 8 is performed strictly, the operation direction becomes forward rotation → reverse → normal rotation → reverse... It may not be stable. Therefore, in order to stabilize the control, for example, the operation may be performed in the same operation direction until No continues for a predetermined number of times.

  Control that adjusts both the resistance component R and the reactance component X of the load-side impedance, regardless of the configuration using the variable frequency type high frequency power supply device and not using the automatic impedance matching device, by controlling in this way. Therefore, the reflected wave power can be reduced. Moreover, the resistance component R can be adjusted by simple control. As a result, the reflected wave power can be reduced throughout the manufacturing process even in the case of a load having a characteristic in which the load impedance Z1 varies greatly. Of course, the absolute value of the reflection coefficient may be controlled to be small.

  This state will be further described with reference to FIG. Heretofore, an example in which the reflection coefficient absolute value Γ is controlled to be small has been shown, but in FIG. 3, description will be made using reflected wave power.

  FIG. 3 is a diagram three-dimensionally showing a change example of the reflected wave power. In the figure, “R” represents a resistance component, “X” represents a reactance component, and the vertical axis represents reflected wave power. Therefore, a recessed portion near the center of the figure indicates a portion having the smallest reflected wave power.

  As described above, by controlling the output frequency of the high frequency power supply device, the load side impedance ZL changes. At this time, as described above, the reactance component X mainly changes. An example of a change locus of the load side impedance ZL is assumed as a locus 100.

  As in the example shown by the locus 100, in the process in which the reactance component X is changed, the reflected wave power is somewhat reduced, but the reflected wave power may not be minimized. As described above, this is because the resistance component R cannot be adjusted so much only by controlling the output frequency of the high-frequency power supply device.

  For this purpose, the high frequency device of the present invention supplies high frequency power at an output frequency at which reflected wave power in the middle of the trajectory 100 is minimized, for example. Thereafter, the resistance component R is adjusted by controlling the variable reactance element (the variable capacitor VC1 in this example) of the impedance adjuster, and the reflection coefficient absolute value Γ is controlled to be small. An example of a change locus of the load side impedance ZL at this time is defined as a locus 200. As a result, the reflected wave power can be reduced as compared with the case where only the output frequency of the high frequency power supply device is controlled.

(Second Embodiment)
FIG. 4 is a diagram illustrating a configuration example of the high-frequency device according to the second embodiment of the present invention and a connection relationship between the high-frequency device and the load 5. In addition, let the apparatus comprised combining the high frequency power supply device 1a and the impedance adjuster 3a be a high frequency apparatus.

The impedance adjuster 3a shown in FIG. 4 is obtained by changing the fixed capacitor C2 of the impedance adjuster 3 shown in FIG. 1 to a variable capacitor VC2. Similar to the variable capacitor VC1, the variable capacitor VC2 is configured such that its capacitance can be changed by a motor. The motor is configured to be controlled by a reactance element control circuit 19 in the same manner as the variable capacitor VC1.

  The high frequency power supply device 1a is similar to the high frequency power supply device 1 shown in FIG. 1, but is configured to change the capacitance of the variable capacitor VC2 by controlling the motor for the variable capacitor VC2, as described above. ing. In addition, since it is the same as that of the high frequency power supply device 1 shown in FIG. 1 about others, description is abbreviate | omitted. For the sake of convenience, the reactance element control circuit 19 has the same symbol as in FIG.

  In the first embodiment described above, the reflected wave information is obtained using one variable capacitor (the variable capacitor VC1 in the example shown in FIG. 1) provided in the variable frequency type high frequency power supply device and the impedance adjuster. Was trying to be smaller. In most cases, the reflected wave information can be set to a predetermined value or less as in the first embodiment described above. However, there are rare cases where the reflected wave information cannot be reduced. This phenomenon will be described with reference to FIG.

  FIG. 5 is a diagram three-dimensionally showing another variation example of the reflected wave power. The coordinates and the like are the same as in FIG.

  As shown in FIG. 5, an example of a change locus of the load side impedance ZL when the output frequency of the high frequency power supply device is changed is taken as a locus 101, and the load side impedance ZL when the variable capacitor VC1 of the impedance adjuster is controlled. An example of a change locus is a locus 201.

  As shown in FIG. 5, even when the output frequency of the high-frequency power supply device 1 is set to the output frequency that minimizes the reflected wave power, and then the capacitance is changed by controlling the variable capacitor VC1. There is a case where it does not reach the recessed part near the center of. In FIG. 5, the locus 101 and the locus 201 are drawn with a large shift for easy explanation.

The reason for the above is that the output frequency at which the reflected wave power is minimum within the variable range of the output frequency of the high-frequency power supply device 1 is not optimal for the subsequent operation of the variable capacitor VC1. For example, in the case of FIG. 5, the reflected wave power is reduced by moving the start point of the trajectory 201 to a position slightly shifted in the arrow selection direction of the trajectory 101 from the start point of the trajectory 201 shown in the figure. Can do.
That is, when considering the combination of the control of the output frequency of the high-frequency power supply device 1 and the control of the variable capacitor VC1, there is a case where the reflected wave power cannot be minimized even if the two are combined.

  In such a case, as in the special example shown in “Step 6” in the flowchart of FIG. 2 described above (even if “No”, the condition is satisfied, the process proceeds to Step 4 or Step 2). Returning to the control of the output frequency by the power supply device 1a is one method, but the situation may still not be improved. Therefore, in such a case, as shown in FIG. 4, the fixed capacitor C2 may be changed to the variable capacitor VC2, and the capacitance of the variable capacitor VC2 may be changed. If this is done, the situation changes from before, so it may be possible to improve the problem that could not be improved only by changing the output frequency of the high-frequency power supply device 1a and changing the capacitance of the variable capacitor VC1. For example, when the capacitance of the variable capacitor VC2 is changed, the load side impedance ZL can be changed as shown by the locus 301. Therefore, it may be possible to reach a recessed portion (a portion where the reflected wave power is small) near the center of the figure.

FIG. 6 is an example of a flowchart illustrating a control method for reducing the reflection coefficient absolute value Γ by the high-frequency device according to the second embodiment of the present invention.
A control for reducing the reflection coefficient absolute value Γ will be described with reference to this flowchart. This flowchart mainly describes control in which the capacitance of the variable capacitor VC2 is changed. In addition, this control is inserted in the flow chart of FIG. 2 while proceeding to step 4 from the special example of step 6 (the process proceeds to step 4 or step 2 when the condition is satisfied even if “No”). Therefore, this part is extracted and illustrated.

Step 9: If the condition of the special example shown in Step 6 of FIG. 2 (if the condition is satisfied even if “No” is satisfied, the process proceeds to Step 4 or Step 2), then from Step 6 to Step of FIG. Proceeding to Step 9, Steps 9 to 12 are executed to adjust the capacitance of the variable capacitor VC2.
In step 9, the variable capacitor VC2 is operated by a predetermined amount in the determined operation direction. Note that the initial value is a direction in which the capacitance decreases. Of course, the initial value may be a direction in which the capacitance increases.

Step 10: In Step 9, it is determined whether or not the reflection coefficient absolute value Γ has become smaller than the reference value as a result of operating the variable capacitor VC2.
When the value is smaller than the reference value (Yes), the objective of reducing the reflection coefficient absolute value Γ is achieved, and the process proceeds to Step 4 in FIG. When it is not smaller than the reference value (No), the process proceeds to step 11 in order to determine whether or not the operation amount of the variable capacitor VC1 is small.

  In Step 10, when the value is not smaller than the reference value (No) continues for a predetermined number of times, it may be better to once control the output frequency of the high-frequency power supply device 1. . Therefore, the process may proceed to step 4. As a standard for such processing, not only when it has continued for a predetermined number of times, but also when it does not become smaller than the standard value within a predetermined time, for example. In this case, a timer may be provided inside. That is, even when the value is not smaller than the reference value (No), the process may proceed to Step 4 when a predetermined condition is satisfied. Note that this case corresponds to the case where the reflection coefficient absolute value Γ is larger than the reference value in Step 4 (Yes), and thus the process proceeds to Step 2. Therefore, the process may proceed from step 10 to step 2.

  Further, in the above-described step 10, when the reflection coefficient absolute value Γ is not smaller than the reference value (No), when a predetermined condition is satisfied (for example, when it continues continuously for a predetermined number of times), Since there is a possibility that an abnormality has occurred, an abnormality signal may be output. The output of the high frequency power of the high frequency power supply device 1 may be stopped by this abnormal signal.

Step 11: It is determined whether or not the reflection coefficient absolute value Γ has decreased as a result of operating the variable capacitor VC2.
If the reflection coefficient absolute value Γ has decreased (Yes), the amount of operation of the variable capacitor VC2 may be small, and the process proceeds to step 9. When the reflection coefficient absolute value Γ has not decreased (No), the operation direction of the variable capacitor VC1 may not be correct, and the process proceeds to step 12.

Step 12: If the reflection coefficient absolute value Γ has not decreased in Step 7 (No), the operation direction of the variable capacitor VC1 may be incorrect. Proceed to step 9. The reversed operation direction becomes the operation direction from the next time.
Since the reflection coefficient absolute value Γ changes from moment to moment, if the processing in step 12 is performed strictly, the operation direction becomes forward rotation → reverse → normal rotation → reverse... It may not be stable. Therefore, in order to stabilize the control, for example, the operation may be performed in the same operation direction until No continues for a predetermined number of times.

  Control that adjusts both the resistance component R and the reactance component X of the load-side impedance, regardless of the configuration using the variable frequency type high frequency power supply device and not using the automatic impedance matching device, by controlling in this way. Therefore, the reflected wave power can be reduced.

  In the second embodiment as well, there is one variable reactance element that is simultaneously controlled by the reactance element control circuit 19 while high-frequency power is supplied to the load. Therefore, the variable reactance element can be controlled relatively easily. Moreover, the resistance component R can be adjusted by simple control. As a result, the reflected wave power can be reduced throughout the manufacturing process even in the case of a load having a characteristic in which the load impedance Z1 varies greatly. Of course, the absolute value of the reflection coefficient may be controlled to be small.

  In addition, this invention is not limited to the structure of the reactance element of the impedance regulator 3 as shown in FIG. 1, The impedance regulator 3 of another structure can be used.

  In the impedance adjuster 3 shown in FIG. 1, the reactances of the capacitor C2 and the inductor L1 are fixed values, but the reactance may be variable. However, in any case, there is one reactance element that is simultaneously controlled by the reactance element control circuit 19 while high-frequency power is supplied to the load. Therefore, the variable reactance element can be controlled relatively easily.

  A case where two or more variable reactance elements are driven by one motor is conceivable. For example, instead of the variable capacitor C2, two variable capacitors can be connected in parallel and driven by a motor. In this case, if two variable capacitors connected in parallel are regarded as one variable impedance element, control can be performed in the same manner as described above.

FIG. 1 is a diagram illustrating a configuration example of a high-frequency device according to the first embodiment of the present invention and a connection relationship between the high-frequency device and a load 5. FIG. 2 is an example of a flowchart showing a control method for reducing the reflection coefficient absolute value Γ by the high-frequency device according to the first embodiment of the present invention. FIG. 3 is a diagram three-dimensionally showing a change example of the reflected wave power. FIG. 4 is a diagram illustrating a configuration example of the high-frequency device according to the second embodiment of the present invention and a connection relationship between the high-frequency device and the load 5. FIG. 5 is a diagram three-dimensionally showing another variation example of the reflected wave power. FIG. 6 is an example of a flowchart illustrating a control method for reducing the reflection coefficient absolute value Γ by the high-frequency device according to the second embodiment of the present invention. FIG. 7 is a diagram illustrating a configuration example of a conventional high-frequency device and a connection relationship between the high-frequency device and the load 5.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 High frequency power supply device 1a High frequency power supply device 2 Transmission line 3 Impedance adjuster 3a Impedance adjuster 4 Load connection part 5 Load 11 Frequency control circuit 12 Oscillation circuit 13 Power amplifier 14 Power measuring device 15 Power control circuit 16 Power setting device 17 ON / OFF control circuit 18 Reflection coefficient calculation circuit 19 Reactance element control circuit Z0 Power supply side impedance Z1 Load impedance ZL Load side impedance

Claims (13)

A high frequency device for supplying high frequency power to a load,
An oscillation means capable of varying the oscillation frequency;
A high frequency power supply means for amplifying an oscillation signal output from the oscillation means to be a power generation source and supplying high frequency power to the load;
Reflected wave information calculation means for calculating reflected wave information related to the reflected wave power and outputting the calculated reflected wave information;
Frequency control means for controlling the oscillation frequency of the oscillating means so that the reflected wave information becomes small;
Impedance adjusting means provided between the high-frequency power supply means and the load and having at least one variable reactance element, wherein one of the variable reactance elements is controllable;
Element control means for controlling a variable reactance element that can be controlled by the impedance adjustment means so that the reflected wave information becomes smaller;
High frequency device with   When the reflected wave information is not smaller than a reference value even though the element control means controls the oscillation frequency of the oscillation means so that the reflected wave information becomes smaller in the frequency control means. The high-frequency device according to claim 1, wherein control of the controllable variable reactance element is started.   The high frequency apparatus according to claim 2, wherein the frequency control means does not control the oscillation frequency of the oscillation means while the variable reactance element that can be controlled by the element control means is being controlled. .   The frequency control means controls the variable reactance element that can be controlled by the impedance adjustment means so that the reflected wave information becomes smaller in the element control means, and the reflected wave information becomes smaller than a reference value. 4. The high-frequency device according to claim 3, wherein the control is resumed later when the reflected wave information becomes larger than a reference value again.   The frequency control means controls the variable reactance element that can be controlled by the impedance adjustment means so that the reflected wave information becomes smaller in the element control means, but the reflected wave information is lower than a reference value. 4. The high frequency device according to claim 3, wherein the control is resumed when it is not reduced.   6. The variable reactance element controllable by the impedance adjusting means has a function of changing a resistance component of impedance on the load side relative to the high-frequency power supply means. High frequency equipment. A high frequency device for supplying high frequency power to a load,
An oscillation means capable of varying the oscillation frequency;
A high frequency power supply means for amplifying an oscillation signal output from the oscillation means to be a power generation source and supplying high frequency power to the load;
Reflected wave information calculation means for calculating reflected wave information related to the reflected wave power and outputting the calculated reflected wave information;
Frequency control means for controlling the oscillation frequency of the oscillating means so that the reflected wave information becomes small;
Impedance adjusting means that is provided between the high-frequency power supply means and the load and has a plurality of variable reactance elements, and two of the plurality of variable reactance elements can be controlled;
Element control means for controlling any one of the variable reactance elements that can be controlled by the impedance adjustment means so that the reflected wave information becomes small;
High frequency device with   When the reflected wave information is not smaller than a reference value even though the element control means controls the oscillation frequency of the oscillation means so that the reflected wave information becomes smaller in the frequency control means. The high-frequency device according to claim 7, wherein control of one of the two controllable variable reactance elements is started.   Although the element control means controls one of the two variable reactance elements that can be controlled by the impedance adjustment means so that the reflected wave information becomes small, the reflected wave information is less than a reference value. 9. The high-frequency device according to claim 8, wherein when it does not become smaller, control of the other of the two controllable variable reactance elements is started.   The said frequency control means does not control the oscillation frequency of the said oscillation means, while controlling the variable reactance element which the said element control means can control. High frequency device.   The frequency control means controls the variable reactance element that can be controlled by the impedance adjustment means so that the reflected wave information becomes smaller in the element control means, and the reflected wave information becomes smaller than a reference value. The high-frequency device according to any one of claims 8 to 10, wherein the control is resumed later when the reflected wave information becomes larger than a reference value later.   The frequency control means controls the variable reactance element that can be controlled by the impedance adjusting means so that the reflected wave information becomes smaller in the element control means, but the reflected wave information is lower than a reference value. The high-frequency device according to claim 8, wherein the control is resumed when it does not become smaller.   One of the two variable reactance elements that can be controlled by the impedance adjusting means has a function of changing the resistance component of the impedance on the load side of the high frequency power supply means, and the other of the two variable reactance elements that can be controlled. The high-frequency device according to claim 8, having a function of changing a reactance component of impedance on the load side of the high-frequency power supply means.

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