• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
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    • 专利摘要:
    The invention relates to a power combiner (20A) and a generator which has a power combiner (20A). The power combiner (20A) has a multiplicity of inputs (38a to 38n), each input (38a to 38n) being connectable to a respective power amplifier (16a to 16n) for receiving a respective power signal. A plurality of impedance matching circuit branches (30a to 30n) are connected to a respective one of the plurality of inputs (38a to 38n). Each impedance matching circuit branch (30a to 30n) has at least one high-pass filter section (34a to 34n) and at least one low-pass filter section (36a to 36n) through which the respective power signal passes. The impedance matching circuit branches (30a to 30n) are connected to combine the power signals from each power amplifier (16a to 16n). An output (40) is provided for outputting the combined power signal. The invention further relates to a system which has a plasma chamber and to a printed circuit board.
    公开号:CH715600A2
    申请号:CH01462/19
    申请日:2019-11-19
    公开日:2020-05-29
    发明作者:Daniel Gruner Dr;Anton Labanc Dr;Guinnard Cyril
    申请人:Comet Ag;
    IPC主号:
    专利说明:

    TECHNICAL AREA
    [0001] The present disclosure generally relates to a power combiner and a generator. The present disclosure particularly relates to an impedance matching circuit for use in combining power signals from respective power amplifiers.
    BACKGROUND
    A block diagram of an exemplary known radio frequency, RF, generator 10 is shown in FIG. 1. The RF generator 10 includes an AC, AC, input 12, and an AC to DC, DC, converter 14 that is used to supply DC power to a plurality of RF power amplifiers 16a through 16n of a power amplification module 18 is connected. A control device 22 is connected for supplying high-frequency signals to the power amplifiers 16a to 16n. The high frequency power supplied from each power amplifier 16a to 16n is input to an n-to-1 power combiner 20, which performs power combining functions and is configured to output a combined power signal. In some RF generators, when implementing a control circuit to control a combined output, a sensing circuit 24 is connected to sense one or more characteristics of the combined output from the power combiner 20 for use by the controller 22. The combined output power is used by a radio frequency tool.
    Some such RF generators 10 are designed to provide targeted RF output power at a nominal RF center frequency, fc, e.g. 1 kW at fc = 13.56 MHz. In some applications, such as in plasma applications, a relative bandwidth of 10% (fc ± 5%) is required to enable adaptation processes by adaptively changing the RF operating frequency (frequency tuning). The adaptive change of the RF operating frequency is useful for customer-specific adaptation and optimization processes. Furthermore, a large relative bandwidth is useful in multi-frequency systems where more than one RF generator 10 is used and where it is desired that interaction between the generators 10 due to harmonic disturbance be avoided.
    Accordingly, increased bandwidth for an RF generator 10 is desirable in some applications and can offer significant advantages.
    In some generators 10, a power combiner 20 is used to combine power signals from n power amplifiers 16a to 16n by connecting the power amplifiers 16a to 16n in parallel. In order to maintain a desired characteristic system impedance Z0 (e.g. 50 ohms), an impedance matching circuit can be provided at the output of the power amplification module 18, which transforms Z0in n * Z0. Branches extending from each power amplifier 16a to 16n are connected behind the impedance matching circuit. Another methodology is the direct parallel connection of the power amplifiers at their outputs, followed by a single impedance matching network transformation Z0 / n to Z0. Known impedance matching circuits for combining multiple inputs from respective power amplifiers have limitations. In general, it has been found that the greater the number of power amplifiers 16a to 16n that are combined by the power combiner 20, the provision of an impedance matching circuit tends to reduce bandwidth or increase the quality Q, factor of the matching circuit. [0007] Accordingly, it is desirable to provide an impedance matching circuit, a power amplifier, and a generator that enable a power output with a relatively wide bandwidth. Furthermore, it is desirable to keep the number of circuit components used low in order to reduce costs and losses. Furthermore, further desirable features and characteristics of the present invention will become apparent from the following detailed description of the invention and the appended claims, taken in conjunction with the accompanying drawings and the background of the invention. ; OVERVIEW; A power combiner is provided in one aspect. The power combiner has a multiplicity of inputs, wherein each input can be connected to a respective power amplifier for receiving a respective power signal. A plurality of impedance matching circuit branches are connected to a respective one of the plurality of inputs. Each impedance matching circuit branch has at least one high-pass filter section and at least one low-pass filter section through which the respective power signal passes. The impedance matching branches are connected to combine the power signals from each power amplifier. An output is provided for outputting the combined power signal. [0009] In embodiments, the at least one high-pass filter section and the at least one low-pass filter section each have a passive filter. [0010] In embodiments, the at least one high-pass filter section has at least one inductance and at least one capacitor. In embodiments, the at least one inductance of the at least one high-pass filter section is connected to ground. In embodiments, the at least one inductance of the high-pass filter section is formed by a concentrated inductance or a short-circuited transmission stub. In embodiments, the at least one capacitor is formed by a concentrated capacitor. [0011] In embodiments, the at least one low-pass filter section has at least one inductance and at least one capacitor. In embodiments, the at least one capacitor of the at least one low-pass filter section is connected to ground. In embodiments, the at least one capacitor of the at least one low-pass filter section is formed by a concentrated capacitor or a transmission line. In embodiments, the at least one inductance of the at least one low-pass filter section is formed by a concentrated capacitor or by an open transmission stub. [0012] In embodiments, the power combiner has an equalization circuit that connects each of the impedance matching circuit branches. In embodiments, the equalization circuit forms isolation between the plurality of inputs of the power combiner. In embodiments, the equalization circuit has a plurality of equalization circuit branches which are connected to each of the impedance matching circuit branches at tapping points. In embodiments, the tapping points are each located between the at least one high-pass filter section and the at least one low-pass filter section of the respective impedance matching circuit branch. In embodiments, each equalization circuit branch has at least one resistor and at least one capacitor. In embodiments, each equalization circuit branch has a resistor and a first capacitor that are connected in series and a second capacitor that is connected in parallel with the resistor and the first capacitor. In embodiments, all equalization circuit branches are connected to one another at a common equalization point. [0013] In embodiments, the at least one high-pass filter section and the at least one low-pass filter section each have at least one planar inductor and at least one capacitor. [0014] In embodiments, the power combiner has a heat dissipation substrate and at least one printed circuit board disposed thereon. Each of the plurality of impedance matching circuit branches is provided on the at least one printed circuit board. Each impedance matching circuit branch is provided by the at least one printed circuit board which has an input terminal, a first planar inductor, a first capacitor, a second planar inductor and a second capacitor and an output terminal. The input terminal corresponds to one of the plurality of inputs, the output terminal corresponds to the output, the first capacitor and the first inductance are accommodated in the at least one high-pass filter section, and the second capacitor and the second planar inductance are accommodated in the at least one low-pass filter, whereby one of the Variety of impedance matching circuit branches is formed. Each of the plurality of impedance matching circuit branches is formed correspondingly, the output terminals being connected to one another to provide the combined power signal. In embodiments, the at least one printed circuit board has an equalization circuit branch for each of the impedance matching circuit branches, which are connected between the high and low pass filters and have a capacitor and a resistor. The equalization circuit branches are interconnected to form an equalization circuit that isolates between the plurality of inputs of the power combiner. [0016] In embodiments, the power combiner is provided for frequencies of the combined power signal in the range from 1 to 100 MHz. In embodiments, the power combiner is provided for an output power level of at least 100 W for the combined power signal. [0017] In embodiments, the power combiner has n inputs for n power amplifiers and n impedance matching circuit branches. In embodiments, each input of the impedance matching circuit branch has a characteristic impedance Z0 and the output has a characteristic impedance n * Z0.
    In embodiments, each impedance matching circuit branch has a plurality of high-pass filter sections and a plurality of low-pass filter sections, which are arranged alternately.
    In embodiments, the characteristic impedance is Z050 ohms.
    The above embodiments can be combined multiple and independently in any way.
    In another aspect, a generator is provided. The generator has a plurality of power amplifiers and a power combiner. The power combiner has a large number of inputs, each input for receiving a respective power signal therefrom being connectable to a respective power amplifier of the large number of power amplifiers. A plurality of impedance matching circuit branches are connected to a respective one of the plurality of inputs. Each impedance matching circuit branch has at least one high-pass filter section and at least one low-pass filter section through which the respective power signal passes. The impedance matching circuit branches are connected to combine the power signals from each power amplifier. The power amplifier has an output for outputting the combined power signal.
    [0022] The features of the power combiner described in the above aspects and embodiments are also applicable to the generator aspect.
    In embodiments, the at least one high-pass filter section has at least one inductance and at least one capacitor, and the at least one low-pass filter section has at least one inductance and at least one capacitor.
    [0024] In embodiments, the power combiner has an equalization circuit that connects each of the impedance matching circuit branches. In embodiments, the equalization circuit forms isolation between the plurality of inputs. In embodiments, the equalization circuit has a plurality of equalization circuit branches which are connected to each of the impedance matching circuit branches at tapping points. In embodiments, the tapping points are each located between the at least one high-pass filter section and the at least one low-pass filter section of the respective impedance matching circuit branch. In embodiments, each equalization circuit branch has a resistor and a capacitor.
    [0025] In embodiments, the generator is used to deliver high frequency power as a combined power signal to a load.
    In embodiments, the generator has a DC, DC feeder configured to convert an input AC, AC, power signal into an output DC power signal for parallel feeding to each of the power amplifiers.
    In embodiments, the generator has a control device which is designed to output signals to each of the power amplifiers for controlling a waveform of the respective power signals from the power amplifiers.
    [0029] In embodiments, a sensing circuit is designed to sense a characteristic of the combined power signal. The sensing circuit is designed to deliver at least one sensed signal to the control device. The control device is designed to determine the control signals on the basis of the at least one sensed signal.
    In another aspect, a system is provided that has a tool connected to the generator. The tool is connected to receive the combined output power. In embodiments, the tool is a plasma tool.
    [0031] In embodiments, the system is a plasma processing system, the tool having a plasma chamber. In another aspect, a printed circuit board is provided. In embodiments, the printed circuit board includes a dielectric substrate, a plurality of input terminals disposed on the dielectric substrate, a plurality of impedance matching circuit branches disposed on the dielectric substrate, each of the impedance matching circuit branches having at least one high pass filter section and at least one low pass filter section are each configured to filter an input power signal received from one of the input ports, and an output port disposed on the dielectric substrate, the output port being configured to output the combined filtered power signal. In embodiments, the printed circuit board has an equalization circuit that connects each of the impedance matching circuit branches and isolates the input terminals from one another.
    BRIEF DESCRIPTION OF THE DRAWINGS
    The present invention is described below in connection with the following drawing figures, in which like reference numerals designate the same elements and in which
    Figure 1 is a block diagram of a prior art generator having a power combiner in accordance with various embodiments;
    2 is a circuit diagram of a power combiner in accordance with various embodiments;
    3 is a circuit diagram of another power combiner in accordance with various embodiments;
    4 is a circuit diagram of another power combiner in accordance with various embodiments;
    5 is an impedance matching circuit branch on a printed circuit board according to various embodiments;
    6 is a diagram illustrating a bandwidth of the reflection coefficient at an input of a power combiner according to an embodiment;
    [0039] FIGS. 7 (a) through 7 (c) show replacement for lumped circuit elements with transmission lines according to various embodiments.
    DETAILED DESCRIPTION
    [0040] The following detailed description is merely exemplary in nature and should not be taken as limiting the invention or the application and use of the invention. Furthermore, any theory presented in the prior art or the following detailed description should not be taken as a limitation.
    1 is a block diagram of a generator 10, in particular an RF generator 10, according to various embodiments. As described above, the generator 10 has an AC input 12, an AC-DC converter 14 for supplying DC power, and a power amplification module 18. A control device 22 is designed to deliver control signals to the power amplification module 18 and / or the AC-DC converter 14 to provide the desired RF power signal. The power amplification module 18 is designed to receive the supplied DC power from the AC-DC converter 14 and the control signals from the control device 22 and to generate a plurality of parallel output power signals. In embodiments, the power amplification module 18 is configured to split the DC power from the AC-DC converter 14 into respective DC power signals for each of the plurality of power amplifiers 16a to 16n of the power amplification module 18.
    [0042] According to various embodiments, the generator 10 has a power combiner 20 which is designed to combine the parallel power signals output from the power amplifiers 16a to 16n. In various embodiments, n corresponds to the power amplification module 18, which has at least 2, 3, 4, 5 etc. power amplifiers 16a to 16n. In embodiments, each power amplifier 16a to 16n has at least one transistor. Various topologies for the power amplifiers 16a through 16n are available for use in embodiments. Exemplary amplifier types include classic, state-of-the-art power amplifier classes - class A, class AB, class D, switching power amplifier classes - class D, class E, and harmoniously coordinated classes: class F and class F-inverse.
    In some embodiments, the generator has a sensing circuit 24 that is configured to sense at least one electrical characteristic (e.g., voltage and current) of the combined power output from the power combiner 20. The sensing circuit is designed to output sensing signals to the control device. The control device 22 is designed to generate control signals on the basis of the sensed signals. The control device 22 is designed to execute regulation and control schemes for generating the regulation / control signals which are used by the power amplifiers 16a to 16n and / or the AC-DC converter 14 to provide the desired output control signals. Controller 22, in some embodiments, includes a processor and programming instructions stored in memory to instruct the generation of control signals. Those skilled in the art will recognize that the processor of controller 22 can be replaced by using any logical processor (eg, control circuitry) that is designed to perform the calculations and / or set of instructions described herein, and one Field programmable gate array, a digital signal processor, and combinations thereof may include, but is not limited to.
    In embodiments, the generator 10 outputs a combined control signal with operating frequencies in the high frequency range, in particular in the range of 1-100 MHz, and an output power of at least 100 W.
    In various embodiments, generator 10 has an output connector, such as e.g. a coaxial connector, which is designed to be connected to a tool. In some embodiments, the tool is a plasma tool. Generator 10 is used in a variety of applications including semiconductor manufacturing (e.g., coating, etching, and modifying thin films), medical devices (e.g., electrosurgical devices and medical imaging devices such as magnetic resonance imaging, MRI, devices), food packaging, commercial surface modification, and coatings, radio, etc., are useful for providing output power signals.
    2 is a circuit diagram of a first power combiner 20A in accordance with various embodiments. The here with reference to FIGS. Power combiners 2 to 4 disclosed are useful as power combiner 20 in generator 10 of FIG. 1. The power combiner 20A has a plurality of impedance matching circuit branches 30a to 30n, each of which has an input 38a to 38n, which is connected to receive a power signal from one of the power amplifiers 16a to 16n. There are n impedance matching circuit branches 30a to 30n, one for each power amplifier 16a to 16n. Thus, the impedance matching circuit branches 30a to 30n receive power signals that are output in parallel from the power amplifiers 16a to 16n.
    [0047] In various embodiments, each impedance matching circuit branch 30a to 30n has a high-pass filter 34a to 34n (or high-pass filter section) and a low-pass filter 36a to 36n (or low-pass filter section). 2, the high-pass filter 34a to 34n is closer to the input 38a to 38n than the low-pass filter 36a to 36n. In other embodiments, the low pass filter 36a to 36n is closer to the input 38a to 38n than the high pass filter 34a to 34n. In the embodiment of FIG. 2, a set of high and low pass filters 34a to 34n, 36a to 36n is provided in each impedance matching circuit branch 30a to 30n. It is contemplated that there are a plurality m of such sets in each impedance matching circuit branch 30a to 30n. The greater m is, the greater the number of circuit components and the greater the potential losses, but further bandwidth increases are also possible.
    In the embodiment of FIG. 2, each high-pass filter 34a to 34n has at least one capacitor and at least one inductor. In the embodiment there is a capacitor and an inductor and the inductor is connected to ground. Each low-pass filter 36a to 36n has at least one capacitor and at least one inductance. In the embodiment there is an inductor and a capacitor and the capacitor is connected to ground. The high-pass filters 34a to 34n and the low-pass filters 36a to 36n are shown in the exemplary circuit diagram of FIG. 2 as being connected in series. However, Pi and T connections are also possible. The high pass filters 34a through 34n can be described as CL networks and the low pass filters can be described as LC networks. A variety of other high pass filter configurations are possible. A variety of other low pass filter configurations are possible in essentially the same way. A variety of capacitor and inductance components are available, such as concentrated components.
    It is also possible to construct inductive and capacitive elements using transmission line elements as series transmission lines, open and short-circuited stub lines to provide the high-pass filters 34a to 34n and the low-pass filters 36a to 36n. Such a replacement is for the concentrated capacitive and / or inductive elements that are shown here in each of the circuit diagrams of FIGS. 2 to 5 are applicable. Fig. 7 shows an embodiment of how concentrated capacitive and inductive elements can be replaced by transmission lines with design-characteristic impedance and electrical length. FIG. 7 (a) illustrates an impedance matching circuit branch 30a, which has a high-pass filter 34 and a low-pass filter 36 with concentrated elements according to FIG. 2. In the embodiment of Fig. 7 (b), the high pass filter 34 is replaced by a high pass filter 34a 'with a concentrated capacitor and a shorted transmission stub which provides an inductance. Furthermore, the low-pass filter 36 is replaced by a low-pass filter 36a 'with a transmission line for providing the inductance and a concentrated parallel capacitor. In another variation shown in Fig. 7 (c), the low pass filter 36a "has an open transmission stub to provide a capacitor and a transmission line to provide an inductance. The transmission lines in Figs. 7 (b) and 7 (c) have a characteristic Impedance and electrical length to provide a desired capacitance or inductance equivalent to the lumped elements shown in Fig. 7 (a) In each impedance matching circuit branch 30a to 30n, one or more of the lumped capacitors or inductors can be replaced by a corresponding transmission line implementation, such as shown in Figures 7 (b) and 7 (c).
    The capacitance and inductance values for the high pass filters 34a to 34n and the low pass filters 36a to 36n can be derived, for example, using Smith Chart input parameters to achieve the desired impedance matching. In a specific example, the input parameters include the load impedance of the common load (e.g. 50 ohms, mostly equal to Z0), Z0 for the amplifiers (mostly equal to Z050 ohms), the number of amplifiers n, impedance transformation can be calculated (e.g. 50 ohms to 100 ohms) , Frequency (e.g. 13.56 MHz), number of sections (high pass, low pass), e.g. m = 2 (a low pass filter and a high pass filter), network topology CLLC or LCCL or use of transmission (microstrip) lines.
    In embodiments, the first impedance matching circuit 20A has a first equalizing circuit 28A for providing isolation between the inputs 38a to 38n of the first impedance matching circuit 20A. The first equalization circuit 20A has a plurality of equalization circuit branches 32a to 32n. The equalization circuit branches 32a to 32n are connected to the impedance matching circuit branches 30a to 30n at tapping points 41a to 41n. In various embodiments, there are n tapping points 41a to 41n for each impedance matching circuit branch 30a to 30n. In the disclosed embodiment, there are n equalizer branches 32a to 32n, one for each impedance matching circuit branch 30a to 30n. In embodiments, all equalization branches 32a to 32n are connected to one another. In the exemplary embodiment of FIG. 2, the equalization circuit 28A has a common equalization point 44, at which all equalization circuit branches 32a to 32n are connected to one another. Such a connection of branches with different phases can be described as a Y or star connection. The equalization circuit 28A is designed such that a parasitic differential mode between the inputs of the power combiner 26A is adapted by providing the tapping points 41a to 41n between the high-pass filters 34a to 34n and the low-pass filters 36a to 36n.
    In various embodiments, each equalization circuit branch 32a to 32n has at least one resistor and at least one capacitor, which are connected in series. In the embodiment of FIG. 2, a further capacitor is connected in parallel with the capacitor and resistor connected in series. Various other configurations are possible for the impedance matching circuit branches 32a to 32n. For example, the second capacitor connected in parallel need not necessarily be provided, as described below with reference to FIG. 5. The capacitors and resistors can be known (such as concentrated components). Other forms of providing resistive and capacitive elements to form isolating equalizer branches 32a through 32n, including corresponding transmission lines (microstrip technology), as with reference to FIGS. 7 (a) to 7 (c), but may also be provided.
    Fig. 3 is a circuit diagram of a second power combiner 20B having a second type of impedance matching branches and a second equalization circuit 28B, according to another embodiment. The second power combiner 20B is in many ways the same as the first power combiner 20A of FIG. 2, except that a specific configuration of n (number of power amplifiers 16a, 16b and corresponding number of impedance matching circuit branches 30a, 30b) is 2. 3, the electrical component 42 of the high or low pass filter that is closest to the output 40 of the second impedance matching circuit 20B is a component shared by all impedance matching circuit branches 30a, 30b. The shared electrical component 42 in the present configuration is a capacitor C7, although it could be a shared inductance if the high pass filters 34a, 34b and the low pass filters 36a, 36b were arranged in a different order.
    Exemplary values for the different resistances, capacitances and inductances of the circuit components of FIG. 3 are only in the following table for illustrative purposes for a combined output power with a frequency of 13.56 MHz and a characteristic impedance Z0 of 50 ohms at input connections T1, T2 for parallel power signals and at an output terminal T3 for a combined power signal. These values can be determined as inputs using available circuit design software tools using the circuit structure shown, the characteristic impedance, the desired center frequency and a desired design bandwidth (> ± 5%).<tb> C5 <SEP> 355 <SEP> R1 <SEP> 50 <SEP> L5 <SEP> 1293<tb> C7 <SEP> 147 <SEP> R2 <SEP> 50 <SEP> L6 <SEP> 535<tb>C8<SEP>355<SEP><SEP> <SEP> L7 <SEP> 535<tb>C9<SEP>148<SEP><SEP> <SEP> L8 <SEP> 1293<tb>C10<SEP>148<SEP><SEP><SEP> <SEP><tb>C11<SEP>355<SEP><SEP><SEP> <SEP><tb>C12<SEP>355<SEP><SEP><SEP> <SEP>
    Fig. 4 is a circuit diagram of a third power combiner 20C having a third balancing circuit 28C according to yet another embodiment. The third power combiner 20C is in many ways the same as the first power combiner 20A of FIG. 2, except that a specific configuration of n (number of power amplifiers 16a, 16b, 16c and corresponding number of impedance matching circuit branches 30a, 30b, 30c) 3 is. The third equalizer 28C also differs from the first equalizer 28A in that it is provided in a delta configuration. This means that a first equalization circuit branch 32a is connected via respective tapping points 41a, 41b between the first and the second impedance matching circuit branches 30a, 30b. A second equalization circuit branch 32b is connected via respective tapping points 41b, 41c between the second and the third impedance matching circuit branches 30b, 30c. A third equalization circuit branch 32c is connected via respective tapping points 41c, 41d between the first and the third impedance matching circuit branches 30a, 30c. Each different pair of impedance matching circuit branches 30a, 30b, 30c thus has an equalization circuit branch 32a, 32b, 32c, which are connected between them via respective tapping points 41a, 41b, 41c, 41d. The equalization circuit branches 32a, 32b, 32c are formed with capacitors and a resistor, as described above with reference to the first equalization circuit 28A.
    An n = 3 power combiner, as shown in FIG. 4, operates with a star-type equalization circuit 28A, as shown in FIG. 2. In much the same way, the equalization circuit 28C of the delta configuration of Fig. 4 operates with n> 3 power combiners.
    5 is a printed circuit board 74 having a third type of impedance matching circuit branches, according to another embodiment. The impedance matching circuit branch 30 is the impedance matching circuit branches of FIG. 2 and 3 essentially the same. In fact, the topology of FIG. 5 for constructing impedance matching circuit branches 30a, 30b of FIGS. 2 and 3 are provided. 5, the impedance matching circuit branch 30 comprises, in this order, an input terminal 38, which corresponds to one of the aforementioned inputs 38a to 38n, a first capacitor 48, a first inductor 50, a second inductor 52, a second capacitor 54 and an output terminal 58 , which corresponds to the aforementioned output 40. The first capacitor 48 and the first inductor 50 provide one of the aforementioned high-pass filters 34a to 34n. The second inductance 52 and the second capacitor 54 correspond to one of the aforementioned low-pass filters 36a to 36n.
    In different embodiments, the first inductor 50 and the second inductor 52 are provided as planar inductors. In some examples, the first capacitor 48 and the second capacitor 54 are provided as concentrated capacitors. In embodiments, the first capacitor 48 and the second capacitor 54 are multilayer ceramic capacitors. In embodiments, the first inductor 50 has a larger inductance (eg, greater number of windings) than the second inductor 52, so that the high-pass filter 34 has a larger inductance than the low-pass filter 36. In embodiments, the first capacitor 48 has a larger capacitance than the second Capacitor 54 so that the low pass filter 36 has a lower capacitance than the high pass filter 34.
    The printed circuit 74 has a second equalization circuit 28B in some embodiments. The second equalizer 28B is substantially the same (and could be replaced in some embodiments) by the first equalizer 28A described above, except that an additional parallel capacitor is not provided. The second compensation circuit 28B has a third capacitor 62 and a first resistor 64, which are connected in series. The second compensation circuit 28B is connected to the impedance matching circuit branch 30 at a tapping point 41. The tapping point 41 is located at the connection between the first capacitor and the first inductor 50, as a result of which the tapping point 41 is arranged electrically between the high-pass filter 34 and the low-pass filter 36. The second equalization circuit 28B has a common equalization terminal 46 which is connected in series with the third capacitor 62 and the first resistor 64.
    The printed circuit board 74 has a ground connection 56, to which the first inductor 50 and the second capacitor 54 are connected. The input port 38, the output port 58, the ground port 56, and the common equalization port 46 are provided in various embodiments as pins, plates, and in other forms.
    In the embodiment of FIG. 5, the printed circuit board 74 has a dielectric substrate 66 on which the impedance matching circuit branch 30 is arranged. In some embodiments, dielectric substrate 66 is disposed on a ground / heat sink (not shown) and is configured to transfer dissipated energy to the heat sink.
    In exemplary embodiments, the input connection 38 can be connected to a power amplifier 16a and the output connection 58 is connected to an output port of a generator 10. For combining parallel power signals from a plurality of n power amplifiers 16a to 16n, a power combiner is designed to have n impedance matching circuit branches 30a to 30n according to the construction shown in FIG. 5. The impedance matching circuit branches 30a to 30n are arranged on a common dielectric substrate 66 in some embodiments and on respective dielectric substrates 66 in other embodiments. The impedance matching circuit branches 30a to 30n are arranged alongside one another along a plane of the dielectric substrate 66 in some embodiments and are stacked relative to one another in other embodiments. The power amplifiers 16a to 16n are connected to respective input connections 38a, and the common compensation connections 46 are each connected to a further common compensation connection 46 in order to provide the common compensation point 44. The output terminals 58 are connected to each other and to a common output, to thereby provide the combined output power signal to the output connector 40. One skilled in the art will recognize that the disclosed printed circuit board can have any of the aforementioned circuits.
    Fig. 6 (a) is a diagram illustrating an input-to-output transmission of the power combiner of Fig. 3, and Fig. 6 (b) shows a reflection coefficient at one of the inputs 38a, 38b of the power combiner of Fig 3. The diagrams of FIGS. 6 (a) and 6 (b) were generated based on a power combiner S parameter of ~ 13.56 MHz. In the illustrated embodiment, a bandwidth of + - 5% of the power combiner 20B is achieved, the bandwidth being defined as having a reflection coefficient of <-30 dB and a transmission error of <0.05 dB. Although at least one exemplary aspect has been set forth in the foregoing detailed description, it should be appreciated that there is a wide variety of variations. It should also be noted that the exemplary aspect or aspects are only examples and should not be construed to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing detailed description provides those skilled in the art with a good guide to implementing an exemplary aspect of the invention. It is understood that various changes in the function and arrangement of elements described in an exemplary aspect can be made without departing from the scope of the invention as set forth in the appended claims.
    权利要求:
    Claims (22)
    [1]
    1. power combiner, comprising:a plurality of inputs, each input being connectable to a respective power amplifier for receiving a respective power signal,a plurality of impedance matching circuit branches connected to a respective one of the plurality of inputs,wherein each impedance matching circuit branch has at least one high-pass filter section and at least one low-pass filter section through which the respective power signal passes,wherein the impedance matching circuit branches are connected to combine the power signals from each power amplifier, andan output for outputting the combined power signal.
    [2]
    2. Power combiner according to claim 1, wherein the at least one high-pass filter section and the at least one low-pass filter section each have a passive filter.
    [3]
    3. Power combiner according to claim 1, wherein the at least one high-pass filter section has at least one inductor and at least one capacitor.
    [4]
    4. Power combiner according to claim 3, wherein the at least one inductance of the at least one high-pass filter section is connected to ground.
    [5]
    5. Power combiner according to claim 1, wherein the at least one low-pass filter has at least one inductance and at least one capacitor.
    [6]
    6. Power combiner according to claim 5, wherein the at least one capacitor of the at least one low-pass filter is connected to ground.
    [7]
    7. A power combiner according to claim 1, comprising an equalization circuit connecting each of the impedance matching circuit branches and isolating the inputs from each other.
    [8]
    8. The power combiner of claim 7, wherein the equalization circuit comprises:a plurality of equalizer branches connected to each of the impedance matching circuit branches at tap points.
    [9]
    9. Power combiner according to claim 8, wherein each equalization circuit branch has at least one resistor and at least one capacitor.
    [10]
    10. The power combiner of claim 8, wherein each equalization circuit branch comprises a resistor and a first capacitor connected in series and a second capacitor connected in parallel with the resistor and the first capacitor.
    [11]
    11. The power combiner according to claim 8, wherein the tapping points are each located between the at least one high-pass filter section and the at least one low-pass filter section of the respective impedance matching circuit branch.
    [12]
    12. A power combiner according to claim 8, wherein all of the equalization circuit branches are connected to one another at a common equalization point.
    [13]
    13. The power combiner according to claim 1, wherein the at least one high-pass filter section and the at least one low-pass filter section each have at least one planar inductor and at least one capacitor.
    [14]
    14. The power combiner according to claim 1, wherein the at least one high-pass filter section or the at least one low-pass filter section has at least one transmission line and at least one capacitor.
    [15]
    15. Generator, which has:a variety of power amplifiers; anda power combiner, the power combiner comprising:a plurality of inputs, each input being connectable to a respective power amplifier of the plurality of power amplifiers for receiving a respective power signal from it,a plurality of impedance matching circuit branches connected to a respective input of the plurality of inputs,wherein each impedance matching circuit branch has at least one high-pass filter section and at least one low-pass filter section through which the respective power signal passes,wherein the impedance matching circuit branches are connected to combine the power signals from each power amplifier, andan output for outputting the combined power signal.
    [16]
    16. The generator of claim 15, wherein the at least one high-pass filter section has at least one inductor and at least one capacitor and the at least one low-pass filter has at least one inductor and at least one capacitor.
    [17]
    17. The generator of claim 15, comprising an equalizer circuit connecting each of the impedance matching circuit branches and isolating the inputs from each other, the equalizer circuit comprising:a plurality of equalization circuit branches which are connected to each of the impedance matching circuit branches at tapping points, the tapping points each being located between the at least one high-pass filter section and the at least one low-pass filter section of the respective impedance matching circuit branches, and each equalizing circuit branch having a resistor and a capacitor.
    [18]
    18. The generator of claim 15, wherein the at least one high-pass filter section has at least one inductor and at least one capacitor, the at least one inductor of the at least one high-pass filter section being connected to ground, and wherein the at least one low-pass filter has at least one inductor and at least one capacitor and wherein the at least one capacitor of the at least one low-pass filter is connected to ground.
    [19]
    19. The generator of claim 18, wherein the at least one inductance of the at least one high-pass filter section and / or the at least one inductance of the at least one low-pass filter section is provided by a transmission line or by a concentrated component.
    [20]
    20. The system of claim 15, in combination with a plasma tool having a plasma chamber.
    [21]
    21. Printed circuit board, which has:a dielectric substrate,a plurality of input terminals arranged on the dielectric substratea plurality of impedance matching circuit branches disposed on the dielectric substrate, each of the impedance matching circuit branches having at least one high pass filter section and at least one low pass filter section, each configured to filter an input power signal received from one of the input terminals, andan output terminal arranged on the dielectric substrate, the output terminal being designed for outputting the combined filtered power signal.
    [22]
    22. The printed circuit board of claim 21, further comprising an equalizer circuit connected to each of the impedance matching circuit branches and isolating the input terminals from each other.
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    同族专利:
    公开号 | 公开日
    US11146224B2|2021-10-12|
    JP2020099043A|2020-06-25|
    KR20200062047A|2020-06-03|
    CN111224626A|2020-06-02|
    GB201819140D0|2019-01-09|
    US20200169230A1|2020-05-28|
    DE102019008123A1|2020-05-28|
    KR102354140B1|2022-01-20|
    GB2579215A|2020-06-17|
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    US9986646B2|2014-11-21|2018-05-29|Nxp Usa, Inc.|Packaged electronic devices with top terminations, and methods of manufacture thereof|
    US9871501B2|2015-06-22|2018-01-16|Nxp Usa, Inc.|RF circuit with multiple-definition RF substrate and conductive material void under a bias line|
    KR20170066915A|2015-12-07|2017-06-15|삼성전자주식회사|Power combinder/divider using mutual inductance|EP3934095A1|2020-07-03|2022-01-05|Nxp B.V.|Wilkinson power combiner, communication unit and method therefor|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    GB1819140.3A|GB2579215A|2018-11-23|2018-11-23|Broadband power combining arrangement|
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