This disclosure describes systems, methods, and apparatus for waveform control, comprising: a power supply having an input terminal, and at least one output terminal for coupling to a load; a controller; a variable inductor coupled to at least one of the output terminals, the variable inductor comprising a first magnetic core having a plurality of arms, including at least a first inductor arm and a first control arm, wherein an inductance winding having one or more turns is wound around the first inductor arm, and wherein a first control winding comprising one or more turns is wound around the first control arm; and a DC current source coupled to the first control arm and the controller, the controller configured to adjust a DC bias applied by the DC current source to the first control arm to control an output waveform at the at least one output terminal.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a chamber having a space for treating a substrate therein; a support unit for supporting the substrate within the chamber; and an insulation member having a space of a predetermined volume therein.

Disclosed are an apparatus for monitoring pulsed high-frequency power and a substrate processing apparatus including the same. The apparatus includes an attenuation module configured to attenuate a pulsed high-frequency power signal; a rectifier module configured to convert the pulsed high-frequency power signal into a direct current signal; and a detection module configured to detect a pulse parameter based on the direct current signal.

A substrate support including a body, a heating element, a first radio frequency filter, and a second radio frequency filter. The body is configured to support a substrate. The heating element is at least partially implemented in a first portion of the body. The first radio frequency filter is connected to an input of the heating element and at least partially implemented in a second portion of the body and connected to the heating element by a first via. The second radio frequency filter is connected to an output of the heating element and at least partially implemented in the second portion or a third portion of the body.

An apparatus for providing signals to a device may include one or more radiofrequency signal generators, and electrically-small transmission line, which couples signals from the one or more RF signal generators to the fabrication chamber. The apparatus may additionally include a reactive circuit to transform impedance of the electrically-small transmission line from a region of relatively high impedance-sensitivity to region of relatively low impedance-sensitivity.

Embodiments provided herein generally include apparatus, plasma processing systems and methods for boosting a voltage of an electrode in a processing chamber. An example plasma processing system includes a processing chamber, a plurality of switches, an electrode disposed in the processing chamber, a voltage source, and a capacitive element. The voltage source is selectively coupled to the electrode via one of the plurality of switches. The capacitive element is selectively coupled to the electrode via one of the plurality of switches. The capacitive element and the voltage source are coupled to the electrode in parallel. The plurality of switches are configured to couple the capacitive element and the voltage source to the electrode during a first phase, couple the capacitive element and the electrode to a ground node during a second phase, and couple the capacitive element to the electrode during a third phase.

An apparatus includes an electrostatic chuck and located within a vacuum enclosure. A plurality of conductive plates can be embedded in the electrostatic chuck, and a plurality of plate bias circuits can be configured to independently electrically bias a respective one of the plurality of conductive plates. Alternatively or additionally, a plurality of spot lamp zones including a respective set of spot lamps can be provided between a bottom portion of the vacuum enclosure and a backside surface of the electrostatic chuck. The plurality of conductive plates and/or the plurality of spot lamp zones can be employed to locally modify chucking force and to provide local temperature control.

A clamp configured to be coupled to a printed circuit board to cool and compress one or more electrical connections subject to repeated power and thermal cycling. A first conductive column of the clamp is configured to compress a first electrical connection between a first power device lead and a first printed circuit board trace of the printed circuit board, and draw thermal energy away from the first power device lead. The first conductive column extends from a load spreading plate. The load spreading plate is an insulator that electrically isolates a fastener extending therefrom from the first conductive column. The fastener is configured to cooperate with the circuit board to connect the clamp to the circuit board, compress the load spreading plate against the first conductive column to compress the first electrical connection, and connect the clamp to ground.

An atmospheric pressure linear RF plasma source having an enclosure enclosing a chamber in the form of an extended slot having a width W, a length L, and a thickness T, with W≥20T, the enclosure having a top opening for receiving a flow of a working gas in the direction of the length L and a bottom opening for delivering a flow of plasma, with the bottom opening being open to atmospheric pressure. Then walls of the enclosure comprise a dielectric material. Two mutually opposing pancake coils are positioned on opposite sides of the enclosure and are capable of being driven by an RF power source in an opposing phase relationship. Alternatively, an elongated solenoid coil may surround the enclosure.

A power supply control system includes a power generator for providing a signal to a load. The power generator includes a power controller controlling a power amplifier. The power generator includes an adaptive controller for varying the output signal controlling the power amplifier. The adaptive controller compares an error between a measured output and a predicted output to determine adaptive values applied to the power controller. The power generator also includes a sensor that generates an output signal that is digitized and processed. The sensor signal is mixed with a constant K. The constant K is varied to vary the processing of the sensor output signal. The value K may be commutated based on the phase, frequency, or both phase and frequency, and the bandwidth of K is determined by coupled power in the sensor output signal.