Provided is a generator including a power amplifier, at least one sampler, an RF output, a signal generator, a controller including a digital control portion and an analogue control portion, an analogue feedback path between the at least one sampler and the controller enabling an analogue signal representation of a signal to be provided to the controller, and a digital feedback path between the at least one sampler and the controller enabling a digital signal representation of the signal to be provided to the controller. The controller is configured to adjust the RF signal at the RF output from a first state into a second state based on the analogue signal representation and/or the digital signal representation.

A system for plasma ignition and maintenance of an atmospheric pressure plasma. The system has a variable frequency alternating current (AC) power source, a transformer, a cable connected to a secondary winding of the transformer, a programmed microprocessor for control of power to the atmospheric pressure plasma. The microprocessor is configured to a) at pre-ignition, power the AC power source at an operational frequency f.sub.op higher than the resonant frequency f.sub.r, b) decrease the operational frequency f.sub.op of the AC power source until there is plasma ignition, and c) after the plasma ignition, further decrease the operational frequency f.sub.op of the AC power source to a frequency lower than the resonant frequency f.sub.r.

Methods for detecting arcs in power delivery systems for plasma process chambers leverage visible arc detection sensors to facilitate in locating the arc and shutting down a power source associated with arc location. In some embodiments, the method includes receiving an arc indication from an arc detection sensor operating in a visible light spectrum where the at least one arc detection sensor is positioned in an assembly of a power delivery system for a plasma process chamber, determining a location of the arc indication by an arc detection controller of the plasma process chamber, and activating a safety interlock signal to the power source of the power delivery system of the plasma process chamber when the at least one arc indication exceeds a threshold value. The safety interlock signal controls a power status of the power source and activating the safety interlock signal removes power source power.

A plasma processing apparatus, for releasing plasma-converted gas from plasma head for performing process, detects the pressures of a gas prior to application of a voltage to electrodes of the plasma head, the gas being supplied from gas supply section to a plasma head, and allow initiation of process by the plasma processing apparatus based on the detected pressures.

A plasma discharge detection system detects undesirable plasma discharge events within a semiconductor process chamber. The plasma discharge detection system includes one or more cameras positioned around the semiconductor process chamber. The cameras capture images from within the semiconductor process chamber. The plasma discharge detection system includes a control system that receives the images from the cameras. The control system analyzes the images and detects plasma discharge within the semiconductor process chamber based on the images. The control system can adjust a semiconductor process in real time responsive to detecting the plasma discharge.

The present disclosure relates to plasma generation systems particularly applicable to systems which utilize plasma for semiconductor processing. A plasma generation system consistent with the present disclosure includes an arc suppression device coupled to the RF generator. The arc device includes switches that engage upon a triggering signal. In addition, the arc device includes a power dissipater to be engaged by the set of switches to dissipate both stored and delivered energy when the set of switches engage. The arc suppression device also includes an impedance transformer coupled to the power dissipater to perform an impedance transformation that, when the switches are engaged in conjunction with the power dissipater, reduces the reflection coefficient at the input of the device. The plasma generation system further includes a matching network coupled to the radio frequency generator and a plasma chamber coupled to the matching network.

Connection includes transistor, transistor exciter controlled by the frequency generator and/or programmable unit, the power source of voltage, the unit with capacitors. The voltage power source is connected to the transistor through the unit with capacitors. The stabilizing non-inductive resistor is connected to the power supply branch for the magnetron with transistor. The power stabilizing non-inductive resistor is a resistor with the wire wound by Ayrton-Perry-type winding and/or the resistor with low value of the parasitic inductance on the basis of thin layers. The electronic control circuits of the gate of the transistor include a frequency generator with the cut-off switch and with support elements and also include an exciter with support elements. The connection with the stabilizing non-inductive resistor is used in case of the bipolar and/or multi-circuit pulse plasma generator. The depolarization voltage is led from the outside source through the capacitor to the depolarization block.

A thin-film deposition system includes a top plate positioned above a wafer and configured to generate a plasma during a thin-film deposition process. The system includes a gap sensor configured to generate sensor signals indicative of a gap between the wafer and the top plate. The system includes a control system configured to adjust the gap during the thin-film deposition process responsive to the sensor signals.

A fabrication system for fabricating an IC is provided which includes a processing tool, a computation device and a FDC system. The processing tool includes an electrode and an RF sensor to execute a semiconductor manufacturing process to fabricate the IC. The RF sensor wirelessly detects the intensity of the RF signal. The computation device extracts statistical characteristics based on the detection of the intensity of the RF signal. The FDC system determines whether or not the intensity of the RF signal meets a threshold value or a threshold range according to the extracted statistical characteristics. When the detected intensity of the RF signal exceeds the threshold value or the threshold range, the FDC system notifies the processing tool to adjust the RF signal or stop tool to check parts damage.

A method and system for plasma arc suppression includes a RF generator supplying power to a plasma chamber coupled to an impedance matching network reacting to impedance changes to match an impedance of the plasma chamber with an impedance of the radio frequency generator. An arc suppression device coupled to the RF generator and the plasma chamber detects plasma arcing causing a sharp impedance change increasing reflection of the power by the plasma chamber and switches a power dissipator reducing the power delivered to the plasma chamber extinguishing or mitigating the plasma arcing. The power dissipator is switched more quickly than the impedance matching network reacts to the sharp impedance change. For example, the impedance matching network may react to the impedance change on an order of hundredths of milliseconds or more, while the arc suppression device switches the power dissipator on an order of microseconds or less.