A system for controlling the non-product wafer includes the following: a monitoring module, configured to monitor the state of the non-product wafer; a statistics module, configured to obtain usage information of the non-product wafer; and a control module, configured to receive a production instruction and control the non-product wafer according to the state and the usage information of the non-product wafer. The disclosure implements the purpose of automatic control and management of the non-product wafer.

A system for controlling the non-product wafer includes the following: a monitoring module, configured to monitor the state of the non-product wafer; a statistics module, configured to obtain usage information of the non-product wafer; and a control module, configured to receive a production instruction and control the non-product wafer according to the state and the usage information of the non-product wafer. The disclosure implements the purpose of automatic control and management of the non-product wafer.

Disclosed are methods and devices, among which is a device that includes a finite state machine lattice. The lattice may includes a programmable Boolean logic cell that may be programmed to perform various logic functions on a data stream. The programmability includes an inversion of a first input to the Boolean logic cell, an inversion of a last output of the Boolean logic cell, and a selection of an AND gate or an OR gate as a final output of the Boolean logic cell. The Boolean logic cell also includes end of data circuitry configured to cause the Boolean logic cell to only output after an end of data signifying the end of a data stream is received at the Boolean logic cell.

Trigger event detection employs a finite state machine (FSM) and interpolation of time-sampled data. A trigger event detector includes an interpolator configured to interpolate time-sampled data and to provide an interpolated sequence of data. The trigger event detector further includes an FSM that has a plurality of predefined states including a trigger event state. The FSM is configured to transition among the predefined states according to an ordered sequence of symbols corresponding to the interpolated sequence of data. A transition of the FSM into the trigger event state represents detection of a trigger event. The trigger event detection provides one or both of a real-time trigger and a post-acquisition trigger.

Trigger event detection employs a finite state machine (FSM) and interpolation of time-sampled data. A trigger event detector includes an interpolator configured to interpolate time-sampled data and to provide an interpolated sequence of data. The trigger event detector further includes an FSM that has a plurality of predefined states including a trigger event state. The FSM is configured to transition among the predefined states according to an ordered sequence of symbols corresponding to the interpolated sequence of data. A transition of the FSM into the trigger event state represents detection of a trigger event. The trigger event detection provides one or both of a real-time trigger and a post-acquisition trigger.

A circuit includes a guard trigger circuit that includes a first input node adapted to be coupled to a first state signal, a second input node adapted to be coupled to a second state signal and an output node. The circuit also includes a reset synchronizer circuit that includes an input node coupled to the output node of the guard trigger circuit, a clock node adapted to be coupled to a clock signal and an output node. The circuit further includes a timeout circuit including an input node coupled to the output node of the reset synchronizer circuit, a clock node adapted to be coupled to the clock signal and an output node. The circuit still further includes a reset requestor circuit that includes a first input node coupled to the output node of the guard trigger circuit, a second node coupled to the output node of the timeout circuit.

A circuit includes a guard trigger circuit that includes a first input node adapted to be coupled to a first state signal, a second input node adapted to be coupled to a second state signal and an output node. The circuit also includes a reset synchronizer circuit that includes an input node coupled to the output node of the guard trigger circuit, a clock node adapted to be coupled to a clock signal and an output node. The circuit further includes a timeout circuit including an input node coupled to the output node of the reset synchronizer circuit, a clock node adapted to be coupled to the clock signal and an output node. The circuit still further includes a reset requestor circuit that includes a first input node coupled to the output node of the guard trigger circuit, a second node coupled to the output node of the timeout circuit.

A cooking system for automating cooking steps of a recipe on a stove comprising a stove including a plurality of cooking elements; power controller for controlling the operation of each one of the cooking elements; and computer system in communication with the power controller, said computer system including a processor, computer readable data storage, and a visual display unit. The processor causes the computer system to perform the steps of: for each automated step of said recipe, generates a control signal for actuating at least one of the cooking elements and sends said control signal to the power controller; and for each manual or user step of said recipe, generates data representing user readable instructions for performing the user step and displays said data on the visual display unit. The power controller is adapted to actuate the cooking elements in accordance with each control signal received from the computer system.

A cooking system for automating cooking steps of a recipe on a stove comprising a stove including a plurality of cooking elements; power controller for controlling the operation of each one of the cooking elements; and computer system in communication with the power controller, said computer system including a processor, computer readable data storage, and a visual display unit. The processor causes the computer system to perform the steps of: for each automated step of said recipe, generates a control signal for actuating at least one of the cooking elements and sends said control signal to the power controller; and for each manual or user step of said recipe, generates data representing user readable instructions for performing the user step and displays said data on the visual display unit. The power controller is adapted to actuate the cooking elements in accordance with each control signal received from the computer system.

A method of operating a measurement instrument, such as a digital oscilloscope, includes receiving multiple analog input signals from a measurement target over respective channels, converting the analog input signal on each channel into a respective digital signal, and comparing signal values of the digital signal on each channel to at least one threshold to generate a stream of levels for each channel. The method includes combining the stream of levels for each channel into a combined stream of levels that reflects combined features of the multiple analog input signals, detecting a pattern in the combined stream of levels using a combined-feature matching procedure implemented by hardware, such as a Finite State Machine (FSM), and triggering the measurement instrument according to a result of the combined-feature matching procedure.