Systems and methods are provided for a clock generator is configured to generate N clock signals evenly spaced by phase. A clock generator includes a poly phase filter configured to utilize a differential clock signal to generate N intermediate signals, the intermediate signals being spaced approximately 360/N degrees apart in phase. A phase error corrector is configured to receive the intermediate signals and to generate N clock output signals, where a phase error is a measure of a difference in phase between consecutive ones of the clock output signals from 360/N degrees, the phase error corrector being configured to reduce phase error among the clock output signals based on a feedback signal. A phase error detection circuit is configured to receive the clock output signals and to generate the feedback signal based on detected phase errors among the clock output signals.

Systems and methods are provided for a clock generator is configured to generate N clock signals evenly spaced by phase. A clock generator includes a poly phase filter configured to utilize a differential clock signal to generate N intermediate signals, the intermediate signals being spaced approximately 360/N degrees apart in phase. A phase error corrector is configured to receive the intermediate signals and to generate N clock output signals, where a phase error is a measure of a difference in phase between consecutive ones of the clock output signals from 360/N degrees, the phase error corrector being configured to reduce phase error among the clock output signals based on a feedback signal. A phase error detection circuit is configured to receive the clock output signals and to generate the feedback signal based on detected phase errors among the clock output signals.

A LIDAR device includes an input node, an output node, and a sample-and-convert circuit. The input node receives a photodetector signal, and the output node generates an output signal indicating a light intensity value of the photodetector signal. The sample-and-convert circuit includes a number of detection channels coupled in parallel between the input node and the output node. In some aspects, each of the detection channels may be configured to sample a value of the photodetector signal during the sample mode and to hold the sampled value during the convert mode using a single capacitor.

There are provided a signal generation unit that generates a predetermined digital signal, a level conversion unit that converts a level of the digital signal generated by the signal generation unit, a DA converter that converts the digital signal of which the level is converted by the level conversion unit into an analog signal in a predetermined intermediate frequency bandwidth, and a control unit that creates correction data for correcting a linearity of a level of an output signal of the DA converter for all frequencies to be used, based on actual data which is data of a level of an actual output signal when a setting of the level of the output signal of the DA converter is changed at a predetermined level interval, at a predetermined frequency, and converts a level of an input signal of the DA converter with the correction data.

The present invention provides a non-drug cardio-cerebrovascular disease therapeutic apparatus. A waveform diagram of a pulse current for generating a pulse electromagnetic field includes four characteristic bands in a cycle range of 360° and reciprocates circularly: an abrupt-rising band T1 where a current intensity I(t) abruptly rises, wherein a highest value thereof is slightly lower than a maximum value Imax of an output current; a first slow-rising band T2 where the current intensity I(t) slowly rises to the maximum value Imax; an abrupt-decreasing band T3 where the current intensity I(t) abruptly decreases, wherein a minimum value Imin thereof is slightly higher than a minimum value (Imin) of the output current; and a slow-decreasing band T4 where the current intensity I(t) slowly decreases to the minimum value (Imin). The non-drug cardio-cerebrovascular disease therapeutic apparatus provided by the present invention can significantly improve and treat cardio-cerebrovascular diseases and achieve obvious effects.

The present invention provides a non-drug cardio-cerebrovascular disease therapeutic apparatus. A waveform diagram of a pulse current for generating a pulse electromagnetic field includes four characteristic bands in a cycle range of 360° and reciprocates circularly: an abrupt-rising band T1 where a current intensity I(t) abruptly rises, wherein a highest value thereof is slightly lower than a maximum value Imax of an output current; a first slow-rising band T2 where the current intensity I(t) slowly rises to the maximum value Imax; an abrupt-decreasing band T3 where the current intensity I(t) abruptly decreases, wherein a minimum value Imin thereof is slightly higher than a minimum value (Imin) of the output current; and a slow-decreasing band T4 where the current intensity I(t) slowly decreases to the minimum value (Imin). The non-drug cardio-cerebrovascular disease therapeutic apparatus provided by the present invention can significantly improve and treat cardio-cerebrovascular diseases and achieve obvious effects.

A bias circuit includes a mirror current source and a current-to-voltage converter. A first terminal of the mirror current source is connected to a supply voltage terminal, a second terminal of the mirror current source is connected to a reference voltage terminal, and a third terminal of the mirror current source is connected to the current-to-voltage converter. A mirror current source is configured to acquire a supply voltage transmitted at the supply voltage terminal through the first terminal, acquire a reference voltage transmitted at the reference voltage terminal through the second terminal, and regulate the supply voltage by using the reference voltage and a preset parameter to obtain a mirror current corresponding to the supply voltage. The preset parameter is parameter information of the mirror current source. The current-to-voltage converter is configured to convert the mirror current into a voltage to provide a bias voltage based on the voltage.

A bias circuit includes a mirror current source and a current-to-voltage converter. A first terminal of the mirror current source is connected to a supply voltage terminal, a second terminal of the mirror current source is connected to a reference voltage terminal, and a third terminal of the mirror current source is connected to the current-to-voltage converter. A mirror current source is configured to acquire a supply voltage transmitted at the supply voltage terminal through the first terminal, acquire a reference voltage transmitted at the reference voltage terminal through the second terminal, and regulate the supply voltage by using the reference voltage and a preset parameter to obtain a mirror current corresponding to the supply voltage. The preset parameter is parameter information of the mirror current source. The current-to-voltage converter is configured to convert the mirror current into a voltage to provide a bias voltage based on the voltage.

A processing device is provided. The processing device comprises one or more interfaces configured to transmit information to a nonlinear device and processing circuitry configured to control the one or more interfaces and to. Further, the processing circuitry is configured to transmit an excitation signal to the nonlinear device and to receive response information from the nonlinear device. Further, the processing circuitry is configured to determine a linear response of the nonlinear device based on the response information and to determine a nonlinear response of the nonlinear device based on the determined linear response.

A neurostimulator incorporating a novel chip design that uses the principle of redundant signal crossfiring to overcome electronic component mismatch error in general and transistor mismatch error in particular, to yield superior quality neurostimulation signal generation, useful in enhancing the bidirectional human-machine interface in prosthesis operation for the restoration of somatosensation for an amputee.