The disclosure provides a receiver with high dynamic range. The receiver includes a photodiode that generates a current signal. A coupling capacitor is coupled to the photodiode, and generates a modulation signal in response to the current signal received from the photodiode. A sigma delta analog to digital converter (ADC) is coupled to the coupling capacitor, and generates a digital data in response to the modulation signal. A digital mixer is coupled to the sigma delta ADC, and generates an in-phase component and a quadrature component corresponding to the digital data. A processor is coupled to the digital mixer, and processes the in-phase component and the quadrature component corresponding to the digital data.

An image processing circuit includes a first dual sample-and-hold circuit that samples a first data and a second data from a first pixel, a second dual sample-and-hold circuit that samples a third data and a fourth data from a second pixel, a voltage-to-current circuit including a resistor and a current source, that receives the first data and the second data to output a first difference data, and that receives the third data and the fourth data to output a second difference data; and an analog-to-digital converter that converts the first and second difference data from an analog form to a digital form.

A device for generating a ramp signal with a changing slope is disclosed. The device may comprise a processor configured to generate a variable signal. The device may also comprise a phase-locked loop (PLL) circuit configured to receive the variable signal and a reference clock signal, generate a changing ramp clock signal based on the variable signal and the reference clock signal, and output the generated changing ramp clock signal as an input of an analog-to-digital-converter (ADC) circuit.

Described is an analog to digital converter (ADC) which comprises: a sigma-delta modulator to receive an analog signal, the sigma-delta modulator operable to perform chopping to cancel common-mode noise; and one or more counters coupled to the sigma-delta modulator to generate a digital code representative of the analog signal.

An error feedback system for a delta sigma modulator is disclosed. The error feedback system has an error transfer function where at least k1 coefficients are set to zero. This allows the error feedback system to be divided into k feedback paths that are performed in parallel at a clock speed that is 1/k of the system clock of the delta sigma modulator (i.e. the rate at which the output of the delta sigma modulator changes).

A method that comprises converting a first electrical signal to a second electrical signal using a converter coupled between a micro-mechanical structure and an analog-to-digital converter (ADC). The method also comprises actuating a switch to selectively interpolate at least one datum between two neighboring converted second electrical signals based on a selected clock signal, wherein the selected clock signal is one of a plurality of clock signals, each clock signals of the plurality of clock signals has a corresponding frequency, and the selected clock signal corresponds to an operating mode of the micro-mechanical structure.

Various examples in accordance with the present disclosure provide example methods, systems, and apparatuses that may calibrate a resistor-capacitor (RC) circuit.

Provided are a wireless access system provided with a remote unit capable of handling a high-frequency region without being made complicated, and a control method for the same. A wireless access system according to the present invention is provided with: a center unit (1); and a remote unit (3) that converts a baseband signal generated by the center unit (1) into a high-frequency signal and emits the high-frequency signal from an antenna (12). The center unit (1) includes a 1-bit modulator (5) that converts the baseband signal into a 1-bit signal on the basis of a generated clock signal and outputs the 1-bit signal. The remote unit (3) includes: a local generation unit (10) that extracts the clock signal from the 1-bit signal output from the center unit (1), and generates a local signal using the extracted clock signal as a reference signal; a filter (13) that extracts a desired band component from the 1-bit signal; and an up-converter (14) that converts, using the local signal, an output signal of the filter into a high-frequency signal.

An apparatus includes a first oscillator to generate an output signal that has a first frequency. The apparatus further includes a second oscillator to generate an output signal that has a second frequency. The second frequency varies as a function of temperature. The apparatus further includes a controller that counts a number of cycles of the output signal of the second oscillator in order to determine whether to calibrate the first oscillator.

The present disclosure relates to a compressive encoding apparatus, a compressive encoding method, a decoding apparatus, a decoding method, and a program which can provide a lossless compression technology having a higher compression rate. An encoding unit of the compressive encoding apparatus converts M bits of a -modulated digital signal into N bits (M>N) with reference to a first conversion table, and when the M bits are not able to be converted into the N bits with the first conversion table, converts the M bits into the N bits with reference to a second conversion table. When the number of bit patterns of the N bits is P, the first conversion table is a table storing (P1) number of codes having higher generation frequencies for past bit patterns, and the second conversion table is a table storing (P1) number of codes having higher generation frequencies for past bit patterns, which follow those of the first conversion table. The present disclosure is applicable to a compressive encoding apparatus that compressively encoding an audio signal, and the like, for example.