Patent Description:
Plasma processing is a very versatile and precise technique to modify the surfaces of materials, in particular in the manufacturing of semiconductor chips. In plasma processing systems, RF power signals are used to excite gaseous compounds such that free electrons and ions are formed. Depending on a variety of process parameters, the plasma composition, i. the amount of ions, electrons, neutrals, and various radicals can be controlled precisely. Such plasma processes are used multiple times in semiconductor production, preferably for the deposition of layers onto a semiconductor wafer or for etching the surface of a semiconductor wafer, both with high uniformity and very precisely over the entire surface.

Plasma process tools are typically operated with RF power signals at frequencies in the range from <NUM> to <NUM> and at power levels of <NUM> W and higher, preferably <NUM> W and higher.

The use of pulse-mode operation to modulate the envelope of the RF power signal has several advantages, in particular, the amount of power dissipated within the semiconductor wafer over a certain time period can be adjusted such that detrimental effects on the wafer or the involved materials are prevented. In addition, the ratio of the different active species can be varied by the power modulation such that, during the various pulsing stages, different reactive species are dominant. This allows to tailor the chemical processes which occur at the wafer surface.

For an RF generator, pulse-mode operation is challenging. Typical pulse rates are in the range of <NUM> to <NUM>, but also up to <NUM>. In consequence, the output of the RF generator has to be modulated accordingly, for example, a sequence of different power levels has to be adjusted in a repeating pattern. The rapid changes of output power can cause internal fluctuations which affect the stability of the DC power which is provided to all parts of the circuit.

Ideally, the DC supply in an RF generator provides a stable settable voltage for an RF power amplifier (PA) input. In fast pulse-mode operation, the DC power supply is operated at a constant set point and provides power to the PA which generates the carrier signal. The modulation of the output power can be done via the driver circuit as a modulation of the gate voltage of the PA.

The DC voltage (Vbusbar) is distributed via a rail ("busbar") and feeds the driver circuit and the PAs of the RF generator. Ideally, the output wave form of an RF generator in pulse-mode operation would be an amplified copy of the PA input, i. rectangular edges when the power level is changed with very fast rise and fall times.

In reality, a stray impedance is present between the DC power supply and the PAs. When the required output current suddenly changes by the modulation, e. during RF turn-on and turn-off, when changing the power level, or periodically in pulse-mode operation, transient voltage excursions and oscillations occur on the DC voltage Vbusbar at the inputs of driver and PA, generating undesired additional signal modulation, for example reduced rise and fall times, over- and undershoots.

The acceptable tolerances for over- and undershoots and the required rise and fall times for power level changes are typically given by the user of the RF generator. Additional boundary conditions and limits on components may be required to ensure reliable, stable, and safe operation of DC supply and PA.

Therefore, an optimization of the components for stabilizing the RF generator's output to several boundary conditions is required to fulfill the output signal specifications.

The standard solution to avoid Vbusbar transients on the busbar is the use of banks of electrolyte capacitors with large capacitance such that all voltage fluctuations are completely suppressed. Therein, a total capacitance of more than <NUM>µP or even <NUM>µP and higher is implemented usually by electrolyte capacitors. Therein, electrolyte capacitors are an easy way to provide such a high capacitance in a relatively compact way.

However, electrolyte capacitors are very sensitive in terms of reliability. To operate them for several years without failure (as is required in semiconductor production) requires that their operating temperature be kept below specified limits which means that cooling is required. Due to the geometrical shape of such capacitors, they cannot be appropriately mounted on a cooling plate, and only air cooling via fans is possible.

Power RF generators above <NUM> kW are typically water-cooled, and all circuit parts which require cooling are arranged on a cooling plate through which water circulates. For such power generators, the use of electrolyte capacitors would require additional air cooling which comes at additional cost and space consumption. Also, for power levels above <NUM> kW the required number of electrolyte capacitors can typically only be fit into a full <NUM>-inch (<NUM>-mm) wide housing, but not into a <NUM>/<NUM>-inch (<NUM>-mm) wide housing, since efficient air cooling requires a certain spacing of the capacitors.

Due to their particularly large capacitance values, electrolyte capacitors can only be replaced by a much larger number of alternative capacitors. Such alternatives have smaller capacitances. However, due to the required large number, they need much more space than electrolyte capacitors of a similar capacitance.

There is therefore a need to avoid the use of electrolyte capacitors banks in RF generators, but at the same time to fit the power RF generator with high output powers into a <NUM>/<NUM>-inch (<NUM>-mm) wide housing.

<CIT> describes a combiner for an RF amplifier comprising wiring and a transmission line transformer.

<CIT> describes a generator that includes a housing, a high-power circuit including a power amplifier, and a low-power circuit. An air flow guidance plate divides the housing into at least two compartments including a high-power compartment and a low-power compartment. The high-power circuit is disposed within the high-power compartment and the low-power circuit is disposed within the low-power compartment.

<CIT> describes a multi-stage system of a radio frequency (RF) power amplifier. Fluid cooling is incorporated directly into the power amplifier (PA) module design. Therein, a PA module includes a circuit board, RF circuit components, a ground plane, and a cooling plate having one or more cooling channels to receive a cooling fluid. The cooling channels are positioned to dissipate heat from the RF circuit components through the ground plane. The PA module may also include RF bias and power electronics within a housing for the PA module without requiring an external control board or power conversion electronics.

<CIT> describes a compact RF generator system. <CIT> discloses the use of a a damping circuit, comprising a damping resistor and a damping capacitor, to reduce or eliminate the oscillatory ringing and overshoot that may develop in an output voltage.

Thus, it is an objective of the present invention to provide an RF generator, which overcomes the drawbacks of the prior art.

The problem is solved by a radio frequency (RF) generator according to claim <NUM>.

The present invention provides an RF generator, in particular for plasma applications. The RF generator generates an RF output and comprises at least one cooling element having an upper surface and a lower surface. Therein, the cooling element may be built as cold plate including one or more channels or pipes through which a coolant can flow in order to cool the cold plate. Alternatively, the cooling element may be built as heat sink, which may be cooled by an airstream. Further, the RF generator comprises at least one DC power supply. Preferably the RF generator comprises two or more DC power supplies. Therein, the one or more DC power supplies can be connected to the cooling element and cooled via the cooling element. Alternatively, the DC power supplies may be separated from the cooling element and may be cooled by an independent cooling element, e.g. cooled by an airstream generated by an independent fan.

The RF generator comprises at least one power stage to amplify an RF signal, wherein the power stage is connected to an upper surface of the at least one cooling element. The power stage comprises one or more power amplifiers (PAs). If there is more than one power stage, the RF generator may comprise a power combiner in order to combine the amplified RF signal of the more than one power stages. In addition, or alternatively, each power stage may comprise more than one PA, wherein the amplified RF signal of each PA is combined by a combiner, which may be part of the power stage or an individual component. Therein, due to connecting the at least one power stage to the cooling element the at least one power stage is efficiently cooled by the cooling element.

The RF generator further comprises a driver to supply the PA of the at least one power stage, wherein the driver is connected to the upper surface of the at least one cooling element for cooling the driver.

Therein, the at least one DC power supply is connected by a busbar with the PA and the driver, wherein a DC voltage Vbusbar is supplied to the PA and the driver via the busbar. The busbar comprises a damping network comprising a plurality of capacitors connected between ground and the busbar and configured to shape transients on Vbusbar. Thus, by the damping network, transient voltage excursions and oscillations on Vbusbar can be reduced in order to provide a reliable, stable and safe operation of the DC power supply, PA, and any other component. At the same time, it is possible to meet the requirements with respect to acceptable tolerances for the required rise and fall times for power level changes Preferably, the busbar is at least partially built as PCB connecting the DC power supply with the PA and the driver. More preferably, the busbar is completely provided by a PCB.

Preferably, the busbar is at least partially built as metal bar or stripe. Thus, the busbar may be built as a combination of a PCB and the metal bar or stripe. Therein, the metal bar or stripe may have a width larger than the height of the stripe, preferably by a factor of <NUM> and more preferably by a factor of <NUM>. In particular, the metal stripe may have a height or thickness of between <NUM> and <NUM> and a width of between <NUM> and <NUM>.

Preferably, the busbar comprises an inductance of 50nH or less and, preferably, <NUM> nH or less. By these values, the effect of transient voltage excursions and oscillations occurring on the DC voltage Vbusbar at the inputs of driver and PA can be reduced.

Preferably, the damping network capacitors are built as ceramic capacitors. Ceramic capacitors have the advantage of an increased lifetime compared to electrolyte capacitors or metal film capacitors, thereby also increasing the lifetime of the RF generator and the reliability of operation. In addition, less cooling or no additional cooling may be required for ceramic capacitors due to their thermal endurance.

Preferably, the ceramic capacitors are connected to the cooling element for cooling. Thus, efficient cooling is possible due to use of the ceramic capacitors. Alternatively, if the ceramic capacitors cannot be connected directly to the cooling element, an indirect connection to the cooling element can be implemented. This indirect connection may include an array of vias connecting the solder pads of the ceramic resistors to similar areas on the bottom side of the PCB to which the ceramic capacitors are attached. Thus, thermal losses are spread over a larger area of the PCB. In addition, thermally conductive metal standoffs, spacers, or bolts to which the PCB is screwed may thermally connect specific areas for cooling on the bottom side of the PCB to the cooling element. Alternatively or additionally, convection air cooling might be used to provide cooling.

Preferably, the sum or total capacitance of all capacitors in the damping network is less than <NUM>µF, preferably less than <NUM>µF, more preferably less than <NUM>µF, even more preferably less than <NUM>µF and most preferably less than <NUM>µF. In order to provide a compact size of the RF generator and, in particular, to fit the RF generator in a <NUM>/<NUM>-inch (<NUM>-mm) sized housing, it is desirable to reduce the space required by the capacitors of the damping network. At the same time, by reducing the capacitance of the damping network, the current provided by the DC supply can be limited when loading the capacitors of the damping network.

Due to the reduced capacitance of the damping network, the time constant of the LC network of busbar inductance and capacitance of the damping network may be below <NUM>.

Thus, the resonance is shifted to above the pulsing frequency of the RF generator, wherein in the prior art when using capacitors with a total capacitance of <NUM>µF or more, the resonance frequency was within the range of the pulsing frequency of the RF generator. For example, for a busbar inductance in the range of <NUM> nH to <NUM> nH, and a state-of-the-art damping network with electrolyte capacitors of a total capacitance of <NUM> to <NUM> mF, the resonance frequency would be in the range of <NUM> to <NUM>, which is within the range of typically used pulse rates of <NUM> to <NUM>. In contrast, for the much smaller capacitances in the damping network according to this invention, e. <NUM> to <NUM>µF, the resonance frequency would be between <NUM> and <NUM>, which is much higher than the usual pulse rates.

When the RF power is suddenly changed from one level to another in pulse-mode operation, the time constant for over- and undershoots is derived from the resonance frequency of the busbar inductance and the damping network capacitance. In consequence, for the example above, the state-of-the-art damping network with electrolyte capacitors would have a time constant in the range of <NUM> to <NUM> microseconds, whereas the solution according to this invention would have a time constant of <NUM> to <NUM> microseconds.

For the electrolyte capacitor solution, such over- and undershoots with long time constant can be compensated by the regulation loop which controls the RF output power. However, this is not possible in all cases depending on the required speed of the regulation. In addition, if the electrolyte capacitors are operated with pulse frequencies in the range of the resonances described above, an increased ripple current results which causes thermal losses and severely impacts the lifetime of the electrolyte capacitors. This is a particular disadvantage of the state-of-the-art solution in an RF generator which is operated in pulse mode compared to the damping network with much smaller capacitances according to this invention.

In the solution according to this invention with strongly reduced capacitance which can be realized by ceramic capacitors, the lifetime issue of electrolyte capacitors is avoided. Due to the short time constant of over- and undershoots, they are always much shorter than the pulse length and in the vicinity of the rising and falling edges of the pulse pattern. The combination of resistances and capacitances of the RC damping network is specifically designed to keep the excursions of over- and undershoots within the specified deviations from the power set value.

Due to the reduced total capacitance of the damping network, the damping network can be realized solely by ceramic capacitors increasing the reliability and lifetime of the RF generator.

Preferably, the one or more capacitors in the damping network comprise a damping resistor or are connected to a damping resistor in series to create an RC combination. Thus, by the damping resistor, damping of transients on Vbusbar is achieved.

Preferably, two or more damping resistors have different resistance values. Preferably, all damping resistors have different resistance values. Alternatively, all damping resistors have the same resistance value.

Preferably, the capacitors of the damping network comprise different capacitances. Therein, at least two capacitors of the damping network may have a different capacitance or each of the capacitors of the damping network has a different capacitance. Thus, transients on different time scales can be efficiently damped.

Preferably, the damping network comprises RC combinations with different time constants. Thus, the time constants by the combination of the capacitor and the damping resistor are different for at least two RC combinations or are different for each of the RC combination of the damping network. Therein, the RC combinations with decreased capacitance comprise a decreased resistance. In other words, the smaller the capacitance of the capacitor of the RC combination the smaller the resistance of the resistor of the RC combination.

Preferably, the damping network is arranged on a separate PCB, wherein preferably the damping network comprises one PCB for each power stage. Therein, the PCB may be separate from the driver PCB and/or the power stage. Thus, by use of a separate PCB, arrangement of the damping network within the housing of the RF generator is facilitated in order to provide a compact RF generator. In particular, stacking of two or more PCBs in a three-dimensional arrangement, may be used to achieve a compact arrangement which is compatible with a <NUM>/<NUM>-inch (<NUM>-mm) wide housing of the RF generator.

Preferably, the PCB of the damping network is arranged above the power stage. The PCB is thus placed relative to the power stage opposite to the cooling element. In particular, the PCB is placed in a distance from the power stage and connected to the power stage by one or more connectors such as metallic bolts, spacers, or standoffs. Thereby, a compact arrangement of the damping network is achieved and connection with the power stage is facilitated.

Preferably, the DC power supply is connected to the same cooling element as the power stage and/or the driver. Thus, a compact RF generator is built, and the required number of cooling elements may be reduced. Alternatively, the DC power supply is arranged on a separate cooling element. Alternatively, the DC power supply is not connected to any cooling element of the RF generator and may be cooled by an air stream generated by a fan of the DC power supply. Preferably, the DC power supply is arranged at the lower surface of the at least one cooling element.

Preferably, the at least one cooling element comprises an opening to feed the busbar from the lower surface to the upper surface of the cooling element. Preferably, the busbar is connected to the lower surface of the cooling element, wherein an insulating layer is arranged between the busbar and the at least one cooling element. By using an electrically insulating, but thermally conducting layer between the busbar and the at least one cooling element, cooling of the busbar is facilitated.

Preferably, the RF generator comprises more than one DC power supply, wherein all DC power supplies are connected to the same busbar. Thus, by using more than one DC power supply the available output power of the RF generator can be increased.

Preferably, the RF generator generates more than <NUM> kW RF output and preferably more than <NUM> kW.

Preferably, the RF generator is arranged inside a housing, wherein the housing has preferably a standardized <NUM>/<NUM>-inch (<NUM>-mm) size or a <NUM>-inch (<NUM>-mm) size. Thus, a compact built RF generator is provided.

Preferably, the busbar comprises an RF decoupling network, wherein the RF decoupling network comprises one or more capacitors. Therein, the decoupling network acts as a low pass filter. In particular, the capacitors are connected to ground. Preferably, the capacitors have a total, i e. combined, capacitance of less than <NUM> nF, preferably less than <NUM> nF and more preferably less than <NUM> nF.

Preferably, the driver comprises a MOSFET having a drain-gate-feedback connection, wherein the drain-gate-feedback connection comprises a capacitor in order to suppress or reduce transients of Vbusbar to the gate. Preferably, the capacitor comprises a capacitance of less than <NUM> pF, preferably less than <NUM> pF and more preferably less than <NUM> pF.

Preferably, the PA comprises a MOSFET, in particular built as LDMOS (laterally diffused metal oxide semiconductor) having a drain-gate-feedback connection, wherein the drain-gate-feedback connection comprises a capacitor to reduce transients of Vbusbar to the gate. In particular, the capacitor has a capacitance of less than <NUM> nF, preferably less than <NUM> nF and more preferably equal to or less than <NUM> nF.

Preferably, the driver comprises an output network comprising a DC blocking capacitor having a capacitance of preferably less than <NUM> nF, preferably less than <NUM> nF and more preferably less than <NUM> nF.

Therein, the output network may be arranged between the driver and the PA, in particular the gate of the PA MOSFET.

Preferably, the output network of the driver comprises a series RC circuit parallel to the DC blocking capacitor. Therein, the series RC circuit comprises a resistor and a capacitor connected in series. Preferably, the resistor has a resistance between <NUM> kOhm and <NUM> kOhm and the capacitor of the RC circuit has a capacitance between <NUM> nF and <NUM> nF.

Preferably, the RF output comprises a rise- and fall-time of less than <NUM> and preferably less than <NUM>.

Therein, the rise and fall times are defined by a <NUM>% to <NUM>% change of full power up or a <NUM>% to <NUM>% change of full power down, e. for a <NUM> W to <NUM> W power change, the time period for going from <NUM> W to <NUM> W is below <NUM> and preferably below <NUM>.

Preferably, the output RF power deviates from a setpoint within +/- <NUM>%. This means that transient output power over- and undershoots stay within +/- <NUM>% of the set power.

Thus, by the RF generator of the present invention a damping network is used in order to reduce transients on the Vbusbar voltage provided by the DC power supply due to a stray impedance of the busbar. Therein, the damping network only comprises ceramic capacitors increasing the lifetime of the RF generator.

However, in order to further compensate for the reduced capacitance of the ceramic capacitors, compared for example to electrolyte capacitors, additional measures may be implemented in the RF generator to avoid/reduce transients and their effects on the amplified RF output. Such measures may include one or more of an optimized RF decoupling network, optimized drain-gate-feedback connections in the driver and/or the PA, or an optimized DC blocking capacitor between the driver and the PA. Thus, acceptable tolerances for over- and undershoots and the required rise and fall times for power level changes of the RF generator can be met. Additional boundary conditions and limits on components may be fulfillable to ensure reliable, stable, and safe operation of DC supply and PA.

In the following the present invention is described in more detail with reference to the accompanying figures.

Referring to <FIG> showing a schematic RF generator <NUM>. The RF generator <NUM> comprises at least one power amplifier (PA) <NUM> amplifying an RF signal provided by a driver <NUM> to generate an amplified version of the RF signal at the output <NUM> as RF output. The connection <NUM> may be used to provide an RF modulated input signal to the driver <NUM>. Therein, the driver <NUM> and the power amplifier <NUM> are supplied by a DC power supply <NUM>, which is connected to the PA <NUM> and the driver <NUM> via a busbar <NUM>. By the busbar <NUM> a DC voltage Vbusbar is applied to the PA <NUM> and the driver <NUM>. Therein, the RF generator <NUM> according to the present invention is able to provide an amplified RF signal at output <NUM> with an output power of <NUM> kW or more, preferably <NUM> kW or more. The RF signal has a frequency of <NUM> - <NUM> and in particular <NUM>, <NUM>, <NUM> or <NUM>. Therein, in pulse-mode operation of the RF generator <NUM>, the envelope of the RF output signal is shaped by changes of the driver output power. Therein, typical pulse rates are in the range of <NUM> to <NUM> and might be up to <NUM>. By this pulse-mode operation, internal fluctuations may occur, which affect the stability of the DC power supply and/or other components of the RF generator. In particular, transients might occur on Vbusbar, which need to be suppressed.

Referring to <FIG> and <FIG> showing an RF generator <NUM> in top view and side view, respectively. In <FIG>, modules and components with solid-line boundaries are located on or above the upper side of the cooling element <NUM>, whereas modules and components with dashed-line boundaries are located on or below the lower side of the cooling element <NUM>. In the example of <FIG> the RF generator <NUM> comprises a cooling element <NUM> built as cold plate, which might be water cooled or cooled by another coolant flowing through channels within the cooling element <NUM>. As indicated in <FIG> and <FIG>, the cooling element <NUM> comprises an upper surface <NUM> and a lower surface <NUM>. On the upper surface <NUM> of the cooling element <NUM> a driver <NUM> is arranged. In addition, in the example of <FIG> and <FIG>, two power stages <NUM> are arranged to amplify the RF signal from the driver <NUM>. Therein, each power stage <NUM> may comprise one or more PAs <NUM>, wherein the signals of each PA <NUM> of one power stage <NUM> may be combined by a combiner (not shown). The output <NUM> of each power stage <NUM> is combined in a power combiner <NUM> and provided to the output coupler <NUM>.

In the example of <FIG> and <FIG>, two DC power supplies <NUM> are arranged at the lower surface <NUM> of the cooling element <NUM>. The two DC power supplies <NUM> are connected via a bracket <NUM> to the busbar <NUM>. Alternatively, in another embodiment there might be more or less DC power supplies and/or the one or more DC power supplies may be at least partially arranged at the upper surface <NUM> of the cooling element <NUM>. Thus, in the example of <FIG> and <FIG>, the DC power supplies <NUM>, the power stages <NUM>, the power combiner <NUM>, and the driver <NUM> share a common cooling element <NUM>. Alternatively, there might be more than one cooling element <NUM>, wherein for example the DC power supplies <NUM> may be arranged on a separate cooling element. Alternatively, the one or more DC power supplies may not be cooled by a cooling element and may, instead, be cooled by an airstream generated by a fan.

The DC power supplies <NUM> are connected to the power stages <NUM> by a busbar <NUM>. In the example of <FIG> and <FIG>, the busbar <NUM> is at least partially built as metal stripe or ribbon. The busbar <NUM> is arranged partially at the lower surface <NUM> of the cooling element <NUM> and partially above the upper surface <NUM> of the cooling element <NUM> wherein the busbar <NUM> is routed through an opening <NUM> in the cooling element from the lower to the upper side of the cooling element. In particular, the busbar <NUM> is partially arranged between the DC power supply <NUM> and the lower surface <NUM> of the cooling element <NUM>. In order to avoid short circuits between the busbar <NUM> and the cooling element <NUM>, an insulating layer <NUM> may be arranged between the busbar <NUM> and the lower surface <NUM> of the cooling element <NUM>. In order to route the busbar <NUM> from the lower surface <NUM> to the upper surface <NUM> of the cooling element <NUM>, the cooling element <NUM> may comprise an opening <NUM> through which the busbar extends towards the upper surface <NUM> of the cooling element <NUM>. Therein, a substantially vertical section <NUM> of the busbar <NUM> extends through the opening <NUM> and above the power stages <NUM>.

Preferably, the busbar <NUM> is connected to the individual power stages <NUM> by a connecting PCB <NUM>. Therein, the connecting PCB <NUM> is above the power stages <NUM> and separate therefrom. The connecting PCB <NUM> is connected to the power stages <NUM> by connectors <NUM>, e. metallic bolts, spacers, or standoffs, to supply the Vbusbar voltage to the power stages <NUM>, i. e the PAs <NUM>. Therein, in particular for each power stage <NUM> an individual connecting PCB <NUM> is implemented.

In an embodiment where the DC power supply <NUM> is arranged on the upper side <NUM> of the cooling element <NUM> or laterally side by side to the upper side <NUM> of the cooling element <NUM> (i. with the DC output at the same side as the power stages <NUM>, but may be arranged on different cooling elements or without cooling element), the busbar may be implemented without metallic stripe and only by the connecting PCB <NUM>.

Referring to <FIG> showing a simplified representation of the circuit of the RF generator <NUM>. Therein, the connection <NUM> is connected to the one or more DC power supplies <NUM>. The connection <NUM> may be connected to an RF signal source to provide an RF modulated signal to the driver <NUM>. Connected to the busbar <NUM> is a damping network <NUM>. The damping network <NUM> may be arranged on the individual connecting PCBs <NUM>. The damping network <NUM> is described in more detail with reference to <FIG>. The damping network <NUM> may be integrated into the busbar <NUM> by connectors <NUM> and <NUM>. The damping network <NUM> comprises a plurality of capacitors <NUM> having the capacitance C<NUM>, C<NUM>,. Therein, the sum of the capacitance of all capacitors in the damping network <NUM>, Σi Ci, is less than <NUM>µF, preferably less than <NUM>µF and more preferably less than <NUM>µF.

In particular, all capacitors <NUM> are built as ceramic capacitors. Therein, ceramic capacitors are more reliable and have an increased lifetime compared to electrolyte capacitors. Usually, it would be intended to increase the capacitance of the damping network <NUM> in order to suppress transients on the Vbusbar voltage. With higher capacitance, the required loss to suppress resonances can be decreased. Therefore, the maximum possible capacitance within the available space would be used to keep the heat generated as low as possible. However, such high capacitance could only be achieved with electrolyte capacitors or metal film capacitors, which suffer thermal stress and a reduced lifetime. Thus, by the present invention, it is suggested to implement a reduced capacitance of the damping network <NUM> and thereby enabling the use of more reliable ceramic capacitors without increase of the space of the RF generator <NUM>. By the reduced capacitance of the capacitors <NUM> of the damping network <NUM>, the time constant is reduced such that the resonances of the damping network <NUM> are above the operating frequencies of the RF generator <NUM>. In order to damp transients on the Vbusbar voltage and suppress over- and undershoots, one or more of the capacitors <NUM>, preferably all of the capacitors <NUM>, are connected in series with damping resistors <NUM> as depicted in <FIG>. Therein, the damping resistors <NUM> have the resistance R<NUM>, R<NUM>,. , Rn, respectively.

Therein, for example all capacitances C<NUM>,. , Cn might be the same or different. Similar, all resistances R<NUM>,. , Rn might be the same or different.

In a first example the resistances of the resistors <NUM> and the capacitances of the capacitors <NUM> are selected with identical values as follows:.

In another example, the capacitances and the resistances of the capacitors <NUM> and the resistors <NUM>, respectively, have two different values each. In one example, the resistances and the capacitances are selected as follows:.

Thereby, by the different RC combinations, transients on different time scales can be efficiently damped. Therein, in particular the smaller the capacitance of the capacitor <NUM> of an RC combination, the smaller the resistance of the damping resistor <NUM> can be selected. In another example, every capacitor and every resistor may have a different value and may be selected as follows:.

Although <FIG> and <FIG> show only one capacitor <NUM> and only one resistor <NUM> for each RC combination, however, the capacitance as well as the resistance of one RC combination can be composed by a combination of more than one capacitor and/or more than one resistor, respectively. Further, although the tables above indicate a specific number of resistors and their resistances as well as a specific number of capacitors and their capacitances, these are only examples and should not be construed in any limiting way.

Due to implementing the damping network <NUM> according to <FIG>, efficient damping of transients of the Vbusbar voltage is feasible with one or more time constants.

By reducing the capacitance of the damping network <NUM>, the required space for the ceramic capacitors is maintained or even reduced in comparison to the use of electrolyte capacitors. Thus, the RF generator can fit into a standardized <NUM>/<NUM>-inch (<NUM>-mm) sized housing or into a <NUM>-inch (<NUM>-mm) sized housing.

In order to be able to further reduce the effects of transients onto the RF output, the busbar <NUM> may be connected to an RF decoupling network <NUM> which is built as low pass filter which has at least one capacitor <NUM> connected to ground and which, additionally, may comprise a resistor. Therein, the capacitance of the capacitor <NUM> may be less than <NUM> nF, preferably less than <NUM> nF and more preferably less than <NUM> nF.

The driver <NUM> may comprise a MOSFET <NUM> comprising a drain-gate-feedback connection <NUM>, where the drain-gate-feedback connection <NUM> comprises at least one capacitor <NUM>. Therein, the capacitor <NUM> of the drain-gate-feedback connection <NUM> may have a capacitance of less than <NUM> pF, preferably less than <NUM> pF and more preferably less than <NUM> pF.

The capacitor <NUM> may be combined with a resistor <NUM>. The resistance of the resistor <NUM> may be less than <NUM> kOhm preferably less than <NUM> kOhm and more preferably <NUM> kOhm or less.

The driver <NUM> is connected to a PA <NUM> of the power stage <NUM>, wherein in the connection a DC blocking capacitor <NUM> is arranged. Therein, the DC blocking capacitor <NUM> may have a capacitance of less than <NUM> nF, preferably less than <NUM> nF, and more preferably less than <NUM> nF.

The PA <NUM> comprises a MOSFET <NUM>, preferably built as LDMOS. The MOSFET <NUM> comprises a drain-gate-feedback connection <NUM>, wherein the drain gate feedback connection <NUM> may comprise a capacitor <NUM>. Therein, the capacitor <NUM> of the drain-gate-feedback connection <NUM> may have a capacitance of less than <NUM> nF, preferably less than <NUM> nF and more preferably equal to or less than <NUM> nF.

Further, the drain-gate-feedback connection <NUM> may comprise a resistor <NUM>, wherein the resistor <NUM> may have a resistance of less than <NUM> kOhm, II preferably less than <NUM> Ohm and more preferably less than <NUM> Ohm.

In the output of the power stage <NUM> as well as in the output of the driver <NUM> additional filters <NUM>, <NUM>' may be implemented in order to shape the RF signal. Thus, according to the present invention, in order to use ceramic capacitors <NUM> in the damping network <NUM> without increase of the required space, the total capacitance of the damping network <NUM> is reduced and still sufficiently suppressing transients on the busbar <NUM> and their effects on the RF output. Additional measures can be implemented to provide an undisturbed RF signal at the output of the RF generator. Therein, a deviation between the generated RF output signal and a set point corresponding to the intended RF signal power of less than +/- <NUM>% can be achieved.

Claim 1:
Radiofrequency, RF, generator (<NUM>), arranged to generate an RF output in particular for a plasma application, comprising:
at least one cooling element (<NUM>) having an upper surface (<NUM>) and a lower surface (<NUM>);
at least one DC power supply (<NUM>);
at least one power stage (<NUM>) arranged to amplify an RF signal and connected to the upper surface (<NUM>) of the at least one cooling element (<NUM>), wherein the power stage (<NUM>) comprises one or more power amplifiers (<NUM>);
a driver (<NUM>) arranged to supply the power amplifier (<NUM>) of the at least one power stage (<NUM>), wherein the driver (<NUM>) is connected to the upper surface (<NUM>) of the at least one cooling element (<NUM>); and
wherein the at least one DC power supply (<NUM>) is connected by a busbar (<NUM>) with the power amplifier (<NUM>) and the driver (<NUM>), wherein the at least one DC power supply (<NUM>) is arranged to supply a DC voltage Vbusbar to the power amplifier (<NUM>) and the driver (<NUM>) via the busbar (<NUM>);
characterized in that
the busbar (<NUM>) comprises a damping network (<NUM>) comprising a plurality of capacitors (<NUM>) connected between ground and the busbar (<NUM>) and configured to shape transients on Vbusbar.