An electronic control device includes: a logic circuit for reconfiguring a plurality of arithmetic circuits including a first circuit and a second circuit; a reconfiguration controller that reconfigures the arithmetic circuits and checks the reconfigured arithmetic circuits based on reconfiguration commands; and a process controller that transmits the reconfiguration commands to the reconfiguration controller and instructs the arithmetic unit to execute operations, in which when a first reconfiguration command is received, the reconfiguration controller reconfigures and checks the first circuit, when the check of the first circuit by the reconfiguration controller is completed, the process controller instructs the first circuit to execute an operation, the process controller transmits a second reconfiguration command to the reconfiguration controller and instructs the reconfiguration controller to start to reconfigure the second circuit until the execution of a predetermined process of the first circuit is completed after completion of the reconfiguration of the first circuit.

An instrument configured to process signal data is disclosed. The instrument is operable to control and or change the sampling rate of the signal data from a first sample rate to a second sample rate different than the first sample rate.

Disclosed is a method of generating electrical signal waveforms by a generator. The generator includes a processor and a memory in communication with the processor. The memory defines a first and second table. The processor retrieves information from the first table defined in the memory, where the information is associated with a first wave shape of a first electrical signal waveform for performing a surgical procedure. The processor retrieves information from the second table defined in the memory, where the information is associated with a second wave shape of a second electrical signal waveform for performing a surgical procedure. The processor combines the first and second wave shapes to create a combined wave shape of an electrical signal waveform for performing a surgical procedure and the combined wave shape electrical signal waveform for performing a surgical procedure is delivered to a surgical instrument.

A system for determine presence or quality of an external timing device is provided. The system may include a circuit (e.g., in a field-programmable gate array (FPGA)) having an input, an oscillator, an edge detector, a bit counter, and a calculator element. In some examples, the input may receive an input signal under test. The oscillator may advance a timer at a known rate to facilitate generation of clock samples for the input signal under test. The edge detector may measure edges of the input signal under test based on the clock samples. The circuit may include at least one bit counter to store a count associated with the measured edges for a shorter interval timer period and a longer interval timer period. The calculator element may determine presence or quality of an external timing device based on the count.

A signal generator with direct digital synthesis and tacking filter to generate an oscillator signal. A digital signal generator generates a digital signal; a digital to analog converter is connected to an output of the digital signal generator and converts the digital signal to an analog signal; a filter is coupled to an output of the DAC and filters the analog signal and generates the oscillator signal; a comparator is coupled to an output of the filter and generates a signal indicating zero crossings of the filter output signal; a digital control unit is coupled to outputs of the digital signal generator and comparator and generates a control signal to tune the filter to track a center frequency of the generated oscillator signal. The control signal is generated based on adjacent samples values from the digital signal generator before and after zero crossings of the filter output signal.

The embodiments of the present disclosure provide a method for designing a high freedom parameterized frequency-modulated coded waveform, comprising: S1: obtaining a frequency-modulated coded vector; S2: selecting a coding model order to be utilized; S3: obtaining an parameterized instantaneous frequency function of a signal based on the frequency-modulated coded vector and the coding model order, integrating the parameterized instantaneous frequency function to obtain a phase of the signal, and generating the high freedom parameterized frequency-modulated coded waveform. Embodiments of the present disclosure provide a high freedom parameterized frequency-modulated coded waveform. The waveform has a continuous phase function, precise spectral control, and is configured to have a parameterized frequency-modulated waveform with high freedom.

The embodiments of the present disclosure provide a method for designing a high freedom parameterized frequency-modulated coded waveform, comprising: S1: obtaining a frequency-modulated coded vector; S2: selecting a coding model order to be utilized; S3: obtaining an parameterized instantaneous frequency function of a signal based on the frequency-modulated coded vector and the coding model order, integrating the parameterized instantaneous frequency function to obtain a phase of the signal, and generating the high freedom parameterized frequency-modulated coded waveform. Embodiments of the present disclosure provide a high freedom parameterized frequency-modulated coded waveform. The waveform has a continuous phase function, precise spectral control, and is configured to have a parameterized frequency-modulated waveform with high freedom.

An arbitrary waveform generator includes at least one analog output, a digital-to-analog converter connected to the analog output and a waveform source connected to the digital analog converter. The waveform source includes a waveform memory, a signal player and a signal processor. The waveform generator is controlled by a sequencer having an instruction memory for instructions and an instruction interpreter adapted to sequentially execute the instructions. A command table unit, in addition to the sequencer, is connected to the waveform source and includes a command table memory holding a plurality of commands. The commands include a waveform identifier for a waveform to be played and a parameter identifier describing how to modify the waveform in the signal processor. The sequencer can trigger the command table unit to execute a command therein, thereby playing the waveform with the parameter as identified by the command.

A signal generator with direct digital synthesis and tacking filter to generate an oscillator signal. A digital signal generator generates a digital signal; a digital to analog converter is connected to an output of the digital signal generator and converts the digital signal to an analog signal; a filter is coupled to an output of the DAC and filters the analog signal and generates the oscillator signal; a comparator is coupled to an output of the filter and generates a signal indicating zero crossings of the filter output signal; a digital control unit is coupled to outputs of the digital signal generator and comparator and generates a control signal to tune the filter to track a center frequency of the generated oscillator signal. The control signal is generated based on adjacent samples values from the digital signal generator before and after zero crossings of the filter output signal.

A signal generator with direct digital synthesis and tacking filter to generate an oscillator signal. A digital signal generator generates a digital signal; a digital to analog converter is connected to an output of the digital signal generator and converts the digital signal to an analog signal; a filter is coupled to an output of the DAC and filters the analog signal and generates the oscillator signal; a comparator is coupled to an output of the filter and generates a signal indicating zero crossings of the filter output signal; a digital control unit is coupled to outputs of the digital signal generator and comparator and generates a control signal to tune the filter to track a center frequency of the generated oscillator signal. The control signal is generated based on adjacent samples values from the digital signal generator before and after zero crossings of the filter output signal.