A computing apparatus triggered by an edge of a supply-line signal with a pulse width counter includes: a clock circuit to supply clock signals to a pulse width counter from an output port of said clock circuit; said pulse width counter triggered by said clock signals to count the pulse width of a supply-line signal from a power supply line, to set a circuit status of said computing apparatus in accordance with said pulse width, and to output said circuit status to an edge-triggered computing unit; and the edge-triggered computing unit to do computing triggered by an edge of a supply-line signal, and to output computing result as the output of said computing apparatus in accordance with said circuit status. The circuit status of the computing apparatus is set in accordance with pulse width counter of supply-line signals .

A counting circuit and a chip are disclosed. The counting circuit includes a charge counter module including a pulse processing module and a first capacitor. The pulse processing module is configured to covert a received pulse signal into a counting current and to transfer the converted counting current to the first capacitor. The first capacitor is configured to receive the counting current and store charge carried in the counting current. The counting circuit takes a voltage of the first capacitor as a basis for counting. The input voltage pulse signal is converted into a current signal in the form of micro pulses for charging the non-variable capacitor, and a counting result is obtained by detecting the voltage of the first capacitor, achieving the following advantages: no need to take care of whether the input pulse signal is continuous or discrete; high resistance to interference; adaptiveness to various input pulse signals of different waveforms and/or with different frequencies; and the ability to solve the problem with the conventional counting circuits that they may not be able to cope with irregular pulse signals and may even not be able to operate normally when such an irregular pulse signal is input.

A radar system includes: a plurality of first receiving devices for generating a plurality of first digital signals according to a plurality of first incoming signals, respectively; and a plurality of second receiving devices for generating a plurality of second digital signals according to a plurality of second incoming signals, respectively. A processing device is arranged to perform a first beamforming operation to generate a plurality of first beamforming signals according to the plurality of first digital signals and a first gain matrix, and to perform a second beamforming operation to generate a plurality of second beamforming signals according to the plurality of second digital signals and a second gain matrix; and to determine an altitude angle of a first object and a second object, and to determine a first azimuth angle of the first object and a second azimuth angle of the second object.

A radar system includes: a plurality of first receiving devices for generating a plurality of first digital signals according to a plurality of first incoming signals, respectively; and a plurality of second receiving devices for generating a plurality of second digital signals according to a plurality of second incoming signals, respectively. A processing device is arranged to perform a first beamforming operation to generate a plurality of first beamforming signals according to the plurality of first digital signals and a first gain matrix, and to perform a second beamforming operation to generate a plurality of second beamforming signals according to the plurality of second digital signals and a second gain matrix; and to determine an altitude angle of a first object and a second object, and to determine a first azimuth angle of the first object and a second azimuth angle of the second object.

A clock frequency divider circuit and a receiver are provided. The clock frequency divider circuit includes a reset retimer circuit configured to receive a reset signal and a clock signal, output a reset buffer signal of a differential signal pair obtained by buffering the reset signal, and output a reset synchronization signal obtained by synchronizing the reset signal with the clock signal, a clock buffer circuit configured to receive the clock signal and the reset synchronization signal and output a clock buffer signal of a differential signal pair obtained by buffering the clock signal, and an IQ divider circuit configured to output first through fourth output signals having different phases based on the reset buffer signal and the clock buffer signal.

A frequency multiplier system includes a first frequency multiplier circuit to generate a first signal having a first frequency. The first frequency multiplier circuit includes a first post-divider circuit to divide the first frequency of the first signal to a first output frequency within a bounded first range of frequencies, and a first programmable frequency transition controller to control a transitioning frequency relationship between the first signal having the first frequency and a target signal having a desired target frequency. The system includes a second frequency multiplier circuit to generate a second signal having a second frequency. The second frequency multiplier circuit includes a second post-divider circuit configured to divide the second frequency of the second signal to a second output frequency within a bounded second range of frequencies, and a second programmable frequency transition controller to control a transitioning frequency relationship between the second signal having the second frequency and the target signal having the desired target frequency. A multi-transition controller is coupled to both the first frequency multiplier circuit and the second frequency multiplier circuit to, upon a desired change from the first output frequency to the target output frequency, select one of the first output frequency or the second output frequency as a system output frequency.

A radar system includes: a plurality of first receiving devices for generating a plurality of first digital signals according to a plurality of first incoming signals, respectively; and a plurality of second receiving devices for generating a plurality of second digital signals according to a plurality of second incoming signals, respectively. A processing device is arranged to perform a first beamforming operation to generate a plurality of first beamforming signals according to the plurality of first digital signals and a first gain matrix, and to perform a second beamforming operation to generate a plurality of second beamforming signals according to the plurality of second digital signals and a second gain matrix; and to determine an altitude angle of a first object and a second object, and to determine a first azimuth angle of the first object and a second azimuth angle of the second object.

A radar system includes: a processing device arranged to generate a plurality of phase shifting digital signals; a plurality of transmitting devices for generating an RF beam according to the plurality of phase shifting digital signals during a first mode; a plurality of first receiving devices for generating a plurality of first digital signals according to a plurality of first incoming signals, respectively, during a second mode; and a plurality of second receiving devices for generating a plurality of second digital signals according to a plurality of second incoming signals, respectively, during the second mode. The processing device is further arranged to distinguish a first object and a second object when the RF beam hits the first object and the second object, and the first object and the second object have a same radial speed and are located at a same range.

In an embodiment a device includes a first circuit configured to send a signal comprising numbers successively separated by a constant value to at least one second circuit, each second circuit being in a clock domain different from a clock domain of the first circuit and at least one third circuit configured to determine whether the successive numbers of the signal received by the second circuit are separated by the constant value, wherein the signal is sent to a respective third circuit in each of the clock domains different from the clock domain of the first circuit.

A device for generating an output signal, formed as a pulse sequence, with a sensor and a controller. The sensor generates a sensor signal based on a measurand determined by the sensor. The controller determines a number of pulses of a timing signal that are generated chronologically between two pulse edges of the sensor signal, the timing signal being generated by a timing signal generator. The controller also generates an intermediate timing signal formed as a pulse sequence, where the period duration of the intermediate timing signal is equal to the period duration of the timing signal multiplied with a factor that is equal to the determined number of pulses of the timing signal, divided by a predetermined divisor. The controller generates the output signal based on the intermediate timing signal.