Patent application number | Description | Published |
20130213573 | STATE-BASED ADJUSTMENT OF POWER AND FREQUENCY - Systems and methods for state-based adjustment of power and frequency are described. A primary generator of a system includes a primary power supply for supplying a primary radio frequency (RF) signal to an electrode. The primary generator further includes an automatic frequency control (AFC) to provide a first frequency input to the primary power supply when a pulsed signal is in a first state. A secondary generator of the system includes a secondary power supply for supplying a secondary RF signal to the electrode. The secondary generator also includes an AFC to provide a second frequency input to the secondary power supply when the pulsed signal is in the first state. The secondary generator includes an AFC to provide a third frequency input to the secondary power supply when the pulsed signal is in a second state. The system includes a digital pulsing source for generating the pulsed signal. | 08-22-2013 |
20130214683 | Impedance-Based Adjustment of Power and Frequency - Systems and methods for impedance-based adjustment of power and frequency are described. A system includes a plasma chamber for containing plasma. The plasma chamber includes an electrode. The system includes a driver and amplifier coupled to the plasma chamber for providing a radio frequency (RF) signal to the electrode. The driver and amplifier is coupled to the plasma chamber via a transmission line. The system further includes a selector coupled to the driver and amplifier, a first auto frequency control (AFC) coupled to the selector, and a second AFC coupled to the selector. The selector is configured to select the first AFC or the second AFC based on values of current and voltage sensed on the transmission line. | 08-22-2013 |
20140009073 | Adjustment of Power and Frequency Based on Three or More States - Systems and methods for adjusting power and frequency based on three or more states are described. One of the methods includes receiving a pulsed signal having multiple states. The pulsed signal is received by multiple radio frequency (RF) generators. When the pulsed signal having a first state is received, an RF signal having a pre-set power level is generated by a first RF generator and an RF signal having a pre-set power level is generated by a second RF generator. Moreover, when the pulsed signal having a second state is received, RF signals having pre-set power levels are generated by the first and second RF generators. Furthermore, when the pulsed signal having a third state is received, RF signals having pre-set power levels are generated by the first and second RF generators. | 01-09-2014 |
20140076713 | Edge Ramping - Systems and methods for performing edge ramping are described. A system includes a base RF generator for generating a first RF signal. The first RF signal transitions from one state to another. The transition from one state to another of the first RF signal results in a change in plasma impedance. The system further includes a secondary RF generator for generating a second RF signal. The second RF signal transitions from one state to another to stabilize the change in the plasma impedance. The system includes a controller coupled to the secondary RF generator. The controller is used for providing parameter values to the secondary RF generator to perform edge ramping of the second RF signal when the second RF signal transitions from one state to another. | 03-20-2014 |
20140172335 | DETERMINING A VALUE OF A VARIABLE ON AN RF TRANSMISSION MODEL - Systems and methods for determining a value of a variable on a radio frequency (RF) transmission model are described. One of the methods includes identifying a complex voltage and current measured at an output of an RF generator and generating an impedance matching model based on electrical components defined in an impedance matching circuit coupled to the RF generator. The method further includes propagating the complex voltage and current through the one or more elements from the input of the impedance matching model and through one or more elements of an RF transmission model portion that is coupled to the impedance matching model to determine a complex voltage and current at the output of the RF transmission model portion. | 06-19-2014 |
20140195033 | Control of Etch Rate Using Modeling, Feedback and Impedance Match - A method for achieving an etch rate is described. The method includes receiving a calculated variable associated with processing a work piece in a plasma chamber. The method further includes propagating the calculated variable through a model to generate a value of the calculated variable at an output of the model, identifying a calculated processing rate associated with the value, and identifying based on the calculated processing rate a pre-determined processing rate. The method also includes identifying a pre-determined variable to be achieved at the output based on the pre-determined processing rate and identifying a characteristics associated with a real and imaginary portions of the pre-determined variable. The method includes controlling variable circuit components to achieve the characteristics to further achieve the pre-determined variable. | 07-10-2014 |
20140197731 | Tuning A Parameter Associated With Plasma Impedance - Systems and methods for tuning a parameter associated with plasma impedance are described. One of the methods includes receiving information to determine a variable. The information is measured at a transmission line and is measured when the parameter has a first value. The transmission line is used to provide power to a plasma chamber. The method further includes determining whether the variable is at a local minima and providing the first value to tune the impedance matching circuit upon determining that the variable is at the local minima. The method includes changing the first value to a second value of the parameter upon determining that the variable is not at the local minima and determining whether the variable is at a local minima when the parameter has the second value. | 07-17-2014 |
20140210508 | Determining A Malfunctioning Device in A Plasma System - Systems and methods for determining a malfunctioning device in a plasma system, are described. One of the methods includes receiving an indication whether plasma is generated within a plasma chamber of the plasma system. The plasma system includes a processing portion and a power delivery portion. The method further includes determining whether the plasma system operates within constraints in response to receiving the indication that the plasma is generated, determining a value of a variable at an output of the power delivery portion when the processing portion is decoupled from the power delivery portion, and comparing the determined value with a pre-recorded value of the variable. The method includes determining whether the determined value is outside a range of the pre-recorded value and determining that the malfunctioning device within the power delivery portion upon determining that the determined value is outside the range of the pre-recorded value. | 07-31-2014 |
20140214350 | Using Modeling to Determine Wafer Bias Associated With A Plasma System - Systems and methods for determining wafer bias are described. One of the methods includes detecting output of a generator to identify a generator output complex voltage and current (V&I). The generator is coupled to an impedance matching circuit and the impedance matching circuit is coupled to an electrostatic chuck (ESC). The method further includes determining from the generator output complex V&I a projected complex V&I at a point along a path between an output of a model of the impedance matching circuit and a model of the ESC. The operation of determining of the projected complex V&I is performed using a model for at least part of the path. The method includes applying the projected complex V&I as an input to a function to map the projected complex V&I to a wafer bias value at the ESC model. | 07-31-2014 |
20140214351 | Using Modeling to Determine Ion Energy Associated with A Plasma System - Systems and methods for determining ion energy are described. One of the methods includes detecting output of a generator to identify a generator output complex voltage and current (V&I). The generator is coupled to an impedance matching circuit and the impedance matching circuit is coupled to an electrostatic chuck (ESC). The method further includes determining from the generator output complex V&I a projected complex V&I at a point along a path between an output of a model of the impedance matching circuit and a model of the ESC. The operation of determining of the projected complex V&I is performed using a model for at least part of the path. The method includes applying the projected complex V&I as an input to a function to map the projected complex V&I to a wafer bias value at the ESC model and determining an ion energy from the wafer bias value. | 07-31-2014 |
20150048740 | SUB-PULSING DURING A STATE - A method for achieving sub-pulsing during a state is described. The method includes receiving a clock signal from a clock source, the clock signal having two states and generating a pulsed signal from the clock signal. The pulsed signal has sub-states within one of the states. The sub-states alternate with respect to each other at a frequency greater than a frequency of the states. The method includes providing the pulsed signal to control power of a radio frequency (RF) signal that is generated by an RF generator. The power is controlled to be synchronous with the pulsed signal. | 02-19-2015 |
Patent application number | Description | Published |
20130213934 | METHODS AND APPARATUS FOR CONTROLLING PLASMA IN A PLASMA PROCESSING SYSTEM - Methods and apparatus for processing a substrate in a multi-frequency plasma processing chamber are disclosed. The base RF signal pulses between a high power level and a low power level. Each of the non-base RF generators, responsive to a control signal, proactively switches between a first predefined power level and a second predefined power level as the base RF signal pulses. Alternatively or additionally, each of the non-base RF generators, responsive to a control signal, proactively switches between a first predefined RF frequency and a second predefined RF frequency as the base RF signal pulses. Techniques are disclosed for ascertaining in advance of production time the first and second predefined power levels and/or the first and second predefined RF frequencies for the non-base RF signals. | 08-22-2013 |
20130214682 | FREQUENCY ENHANCED IMPEDANCE DEPENDENT POWER CONTROL FOR MULTI-FREQUENCY RF PULSING - Methods for processing a substrate in a plasma processing, chamber employing a plurality of RF power supplies. The method includes pulsing at a first pulsing frequency a first RF power supply to deliver a first RF signal between a high power state and a low power state. The method further includes switching the RF frequency of a second RF signal output by a second RF power supply between a first predefined RF frequency and a second RF frequency responsive to values of a measurable chamber parameter. The first RF frequency and the second RF frequencies and the thresholds for switching were learned in advance during a learning phase while the first RF signal pulses between the high power state and low power state at a second RF frequency lower than the first RF frequency and while the second RF power supply operates in different modes. | 08-22-2013 |
20130214828 | METHODS AND APPARATUS FOR SYNCHRONIZING RF PULSES IN A PLASMA PROCESSING SYSTEM - A synchronized pulsing arrangement for providing at least two synchronized pulsing RF signals to a plasma processing chamber of a plasma processing system is provided. The arrangement includes a first RF generator for providing a first RF signal. The first RF signal is provided to the plasma processing chamber to energize a plasma therein, the first RF signal representing a pulsing RF signal. The arrangement also includes a second RF generator for providing a second RF signal to the plasma processing chamber. The second RF generator has a sensor subsystem for detecting values of at least one parameter associated with the plasma processing chamber that reflects whether the first RF signal is pulsed high or pulsed low and a pulse controlling subsystem for pulsing the second RF signal responsive to the detecting the values of at least one parameter. | 08-22-2013 |