A digital technique to reduce or minimize switching in a DAC by using a partial DAC data ignore switching mode. In the partial DAC data ignore switching mode, a control circuit compares first and second data, such a first and second digital words, and operates corresponding switches only when the first data differ from the second data. The techniques are applicable to many types of DACs, including voltage output DACs, current output DACs, variable resistance DACs, digital rheostats, digital potentiometers, digiPOTs.

In accordance with embodiments of the present disclosure, a processing system may include a plurality of processing paths and a controller. The plurality of processing paths may include a static processing path configured to generate a first digital signal based on an analog input signal and a dynamic processing path configured to generate a second digital signal based on the analog input signal, wherein a parameter of the dynamic processing path is determined based on a characteristic of the analog input signal. The controller may be configured to select the first digital signal as a digital output signal of the processing system when a change is occurring to the characteristic and select the second digital signal as the digital output signal in the absence of change occurring to the characteristic.

A digital correlated double sampling (CDS) circuit includes a first latch circuit, a first converting circuit, a second converting circuit, a second latch circuit, and a calculating circuit. The first latch circuit latches an input phase shift code based on a first control signal to store first and second phase shift codes. The first converting circuit converts the first and second phase shift codes into first and second Gray codes. The second converting circuit converts the first Gray code and the second Gray code into a first binary code and a second binary code. The second latch circuit latches an output of the second converting circuit based on a second control signal to store the first binary code. The calculating circuit operates on the first binary code and the second binary code to generate a third binary code, and outputs the third binary code.

An integrating Analog-to-digital converter has a global counter that outputs a counter code signal including a multiphase signal. It also has a column circuit including: a ramp wave generation circuit outputting a ramp wave voltage; a comparator comparing the ramp wave voltage with a pixel voltage; and a latch circuit latching the counter code signal at output inversion timing of the comparator. An output value of the latch circuit is used as a digital conversion output value per the column circuit. The counter has a phase division circuit outputting, as an LSB of the digital conversion output value of the integrating analog-to-digital converter, a phase division signal to the latch circuit, the phase division signal dividing a phase of the counter code signal. The phase division circuit is arranged to a plurality of column circuits, and the LSB is shared by a plurality of phase division circuits.

Disclosed herein is a digital to analog converter including a first dynamic latch receiving a data signal and an inverse of the data signal. The first dynamic latch is clocked by a clock signal and configured to generate first and second quad switching control signals as a function of the data signal and the inverse of the data signal. A second dynamic latch receives the data signal and the inverse of the data signal, is clocked by an inverse of the clock signal, and is configured to generate third and fourth quad switching control signals as a function of the data signal and the inverse of the data signal. A quad switching bit cell is configured to generate an analog representation of the data signal as a function of the first, second, third, and fourth quad switching signals.

Disclosed herein is a digital to analog converter including a first dynamic latch receiving a data signal and an inverse of the data signal. The first dynamic latch is clocked by a clock signal and configured to generate first and second quad switching control signals as a function of the data signal and the inverse of the data signal. A second dynamic latch receives the data signal and the inverse of the data signal, is clocked by an inverse of the clock signal, and is configured to generate third and fourth quad switching control signals as a function of the data signal and the inverse of the data signal. A quad switching bit cell is configured to generate an analog representation of the data signal as a function of the first, second, third, and fourth quad switching signals.

In a semiconductor device, a sine wave signal is input to a first input part and a cosine wave signal is input to a second input part. A multiplexer alternately selects one of the sine wave signal and the cosine wave signal. An analog to digital converter converts the output signal of the multiplexer into a digital value. A switching circuit is coupled between at least one of the first and second input parts and the multiplexer. The switching circuit is configured to be able to invert the input sine wave signal or the input cosine wave signal, in order to reduce the angle detection error due to the non-linearity error of the A/D converter.

To prevent that the noise occurs at timing switching between PCM data and DSD data by a simple configuration. An AV receiver 1 includes a mute circuit 5 that mutes output from a DAC 4, a detection circuit 6 that detects that a digital audio signal is zero data and supplies a detection signal, a microcomputer 2 that supplies a control signal at timing switching from PCM data to DSD data before switches from PCM mode that the DAC 4 converts PCM data into an analog audio signal to DSD mode that the DAC 4 converts DSD data into the analog audio signal, and an AND circuit 7 that activates the mute circuit 5 in case that the detection signal from the detection circuit 6 and the control signal from the microcomputer 2 are supplied.

In a semiconductor device, a sine wave signal is input to a first input part and a cosine wave signal is input to a second input part. A multiplexer alternately selects one of the sine wave signal and the cosine wave signal. An analog to digital converter converts the output signal of the multiplexer into a digital value. A switching circuit is coupled between at least one of the first and second input parts and the multiplexer. The switching circuit is configured to be able to invert the input sine wave signal or the input cosine wave signal, in order to reduce the angle detection error due to the non-linearity error of the A/D converter.

In accordance with embodiments of the present disclosure, a processing system may include a plurality of processing paths and a controller. The plurality of processing paths may include a static processing path configured to generate a first digital signal based on an analog input signal and a dynamic processing path configured to generate a second digital signal based on the analog input signal, wherein a parameter of the dynamic processing path is determined based on a characteristic of the analog input signal. The controller may be configured to select the first digital signal as a digital output signal of the processing system when a change is occurring to the characteristic and select the second digital signal as the digital output signal in the absence of change occurring to the characteristic.