Abstract: In one embodiment, the present disclosure may be directed to a method for impedance matching. A matching network is positioned between a radio frequency (RF) source and a plasma chamber. The RF source is configured to provide at least two non-zero pulse levels, and the matching network includes at least one electronically variable capacitor (EVC) configured to alter its capacitance to provide a match configuration. For each of the pulse levels, at a regular time interval, the method determines a first parameter value for a first parameter related to the plasma chamber or matching network. For each of the pulse levels, the method carries out a separate matching process based on the determined parameter values for the pulse level.

Abstract: In one embodiment, the present disclosure is directed to a method for performing diagnostics on a matching network that utilizes an electronically variable capacitor (EVC). According to the method, all the discrete capacitors of the EVC are switched out. At a first node, a parameter associated with a current flowing between a power supply and one or more of the switches of the discrete capacitors is measured. The method then switches in, one at a time, each discrete capacitor of the EVC. Upon the switching in of each discrete capacitor, the method remeasures the parameter at the first node and determines whether a change to the parameter at the first node is within a predetermined range to determine whether the corresponding switch, driver circuit, or filter of the discrete capacitor most recently switch in has failed.

Abstract: In one embodiment, the present disclosure may be directed to an impedance matching network that includes an electronically variable capacitor (EVC). The EVC includes discrete capacitors and corresponding switches, each switch configured to switch in and out one of the discrete capacitors to alter a capacitance of the EVC. The switches are operably coupled to a power supply providing a blocking voltage to the switches. A control circuit determines a blocking voltage value of the power supply. Upon determining the blocking voltage value is at or below a predetermined first level, the control circuit causes a limited altering of the capacitance of the EVC, the limited altering limiting the number or type of discrete capacitors to switch in or out based on the extent to which the blocking voltage value is at or below the first level.

Abstract: In one embodiment, the present disclosure may be directed to an impedance matching network that includes an electronically variable capacitor (EVC). The EVC includes discrete capacitors and corresponding switches, each switch configured to switch in and out one of the discrete capacitors to alter a capacitance of the EVC. The switches are operably coupled to a power supply providing a blocking voltage to the switches. A control circuit determines a blocking voltage value of the power supply. Upon determining the blocking voltage value is at or below a predetermined first level, the control circuit causes a limited altering of the capacitance of the EVC, the limited altering limiting the number or type of discrete capacitors to switch in or out based on the extent to which the blocking voltage value is at or below the first level.

Abstract: In one embodiment, the present disclosure may be directed to a method for impedance matching. A matching network is positioned between a radio frequency (RF) source and a plasma chamber. The RF source is configured to provide at least two non-zero pulse levels, and the matching network includes at least one electronically variable capacitor (EVC) configured to alter its capacitance to provide a match configuration. For each of the pulse levels, at a regular time interval, the method determines a first parameter value for a first parameter related to the plasma chamber or matching network. For each of the pulse levels, the method carries out a separate matching process based on the determined parameter values for the pulse level.

Abstract: In one embodiment, the present disclosure may be directed to a matching network coupled to an RF source and a plasma chamber and including an electronically variable capacitor (EVC) and a control circuit. The control circuit receives parameter signals and determines corresponding parameter values. For each parameter value, the control circuit determines whether the parameter value is relevant to the matching activity and whether the parameter value is relevant to a second activity of the matching network. The matching network carries out the matching activity based on the parameter values determined to be relevant to the matching activity, and carries out the second activity based on the parameter values determined to be relevant to the second activity.

Abstract: In one embodiment, the present disclosure is directed to a method for impedance matching. The RF source provides at least two repeating, non-zero pulse levels, including a high-priority pulse level and a low-priority pulse level. The matching network comprises at least one EVC, which comprises discrete capacitors configured to switch in and out to provide a plurality of match configurations. Each EVC has a switching limit comprising a predetermined number of switches in or out of the EVC's discrete capacitors in a prior time interval. Upon determining that switching to a new match configuration would cause an EVC to reach the switching limit, the method determines whether the new match configuration is for the low- or high-priority pulse level. If for the low-priority pulse level, the method prevents the switching of the EVC. If for the high-priority pulse level, the method switches the EVC to the new match configuration.

Abstract: In one embodiment, the present disclosure may be directed to a matching network coupled to an RF source and a plasma chamber and including an electronically variable capacitor (EVC) and a control circuit. The control circuit receives parameter signals and determines corresponding parameter values. For each parameter value, the control circuit determines whether the parameter value is relevant to the matching activity and whether the parameter value is relevant to a second activity of the matching network. The matching network carries out the matching activity based on the parameter values determined to be relevant to the matching activity, and carries out the second activity based on the parameter values determined to be relevant to the second activity.

Abstract: In one embodiment, the present disclosure is directed to a method for impedance matching. The RF source provides at least two repeating, non-zero pulse levels, including a high-priority pulse level and a low-priority pulse level. The matching network comprises at least one EVC, which comprises discrete capacitors configured to switch in and out to provide a plurality of match configurations. Each EVC has a switching limit comprising a predetermined number of switches in or out of the EVC's discrete capacitors in a prior time interval. Upon determining that switching to a new match configuration would cause an EVC to reach the switching limit, the method determines whether the new match configuration is for the low- or high-priority pulse level. If for the low-priority pulse level, the method prevents the switching of the EVC. If for the high-priority pulse level, the method switches the EVC to the new match configuration.

Abstract: In one embodiment, the present disclosure is directed to a method for impedance matching including a) positioning a matching network between a radio frequency (RF) source and a plasma chamber; b) determining, from among the plurality of match configurations, a new match configuration to be used when there is an expected pulse level change from a first of the pulse levels to a second of the pulse levels; and c) sending a control signal to alter the at least one EVC to provide the new match configuration. The control signal is sent a predetermined time period before a time for the expected pulse level change, the predetermined time period being substantially similar to a time period for the EVC to switch between two match configurations of the plurality of match configurations.

Abstract: In one embodiment, the present disclosure is directed to a method for impedance matching including a) positioning a matching network between a radio frequency (RF) source and a plasma chamber; b) determining, from among the plurality of match configurations, a new match configuration to be used when there is an expected pulse level change from a first of the pulse levels to a second of the pulse levels; and c) sending a control signal to alter the at least one EVC to provide the new match configuration. The control signal is sent a predetermined time period before a time for the expected pulse level change, the predetermined time period being substantially similar to a time period for the EVC to switch between two match configurations of the plurality of match configurations.

Abstract: In one embodiment, the present disclosure is directed to a method for performing diagnostics on a matching network that utilizes an electronically variable capacitor (EVC). According to the method, all the discrete capacitors of the EVC are switched out. At a first node, a parameter associated with a current flowing between a power supply and one or more of the switches of the discrete capacitors is measured. The method then switches in, one at a time, each discrete capacitor of the EVC. Upon the switching in of each discrete capacitor, the method re-measures the parameter at the first node and determines whether a change to the parameter at the first node is within a predetermined range to determine whether the corresponding switch, driver circuit, or filter of the discrete capacitor most recently switch in has failed.