A receiver module for receiving an electromagnetic signal, including an analog frontend and at least a first receiving channel and a second receiving channel is described. The receiving channels are both connected to the analog frontend, wherein the frontend is configured to receive an input signal including a symbol sequence and to forward the input signal to the receiving channels, wherein the receiving channels each include an analog to digital converter, wherein the second receiving channel includes an attenuator, wherein the first receiving channel and the second receiving channel each include a soft-input-soft-output-decoder, and wherein the soft-input-soft-output decoders each are configured to process the symbol sequence. Moreover, a data transmission system and a method for receiving an electromagnetic signal are described.

An A/D conversion circuit converts an analog signal into numerical data. The A/D conversion circuit includes: a pulse delay circuit that includes an odd number of delay units connected in series, and inverting and delaying a pulse signal, and that changes the numeral number of the delay units which the pulse signal passes through in accordance with a value of the analog signal; latch circuits that synchronize the pulse signal with sampling clocks, and latch the pulse signal; encoders that set a position of the pulse signal to the numerical data by circulating encode values periodically set in order from an initial value to a final value to synchronously sample the encode values; subtractors that calculate each of differences between a previous value and a current value; and an adder that adds subtraction results. The encode values are set to be shifted between at least two encoders.

A gain calibration device for an ADC residue amplifier includes a DAC and a flash ADC. The DAC is configured to convert the digital signal to an analog signal, and the DAC includes a calibration module used in the gain calibration of the ADC residual amplifier. The flash ADC is configured to generate a digital signal, the flash ADC includes a plurality of comparators, the total number of the plurality of comparators is equal to the number of output bits of the flash ADC, and the comparators are configured to be unevenly distributed in an input range.

The present invention provides a time-interleaved analog-to-digital converter device, wherein the time-interleaved analog-to-digital converter device includes a random number generator, a plurality of ADCs and an output circuit. The random number generator is configured to generate a random number sequence. The plurality of ADCs are configured to receive an analog input signal to generate a plurality of digital signals, respectively, and each ADC is further configured to generate a selection signal according to the random number sequence. The output circuit is configured to select one of the digital signals according to the selection signals generated by the ADCs, to generate a digital output signal.

The present disclosure relates to blended analog-to-digital conversion for digital test and measurement devices. A first analog-to-digital converter (ADC) converts an analog signal into a first digital signal a first sampling rate. A digital filtering component generates a filtered digital signal by processing the first digital signal. An analog low pass filter filters the analog signal to generate a filtered analog signal. A second ADC converts the filtered analog signal into a second digital signal. A digital subtractor circuit subtracts the filtered digital signal from the first digital signal or the second digital signal. A digital adder circuit generates a blended digital signal by processing an output of the digital subtractor circuit and one of the first digital signal or the second digital signal.

There provided an AD converter that includes an analog processing part configured to select one of the measurement target voltages and a plurality of reference voltages for each channel, to output an analog voltage signal; a first selection part configured to select one of a plurality of analog voltage signals; a first AD conversion part configured to perform AD conversion on the analog voltage signal to generate a first original digital signal; a second selection part configured to select one of the plurality of analog voltage signals; a second AD conversion part configured to perform AD conversion on the analog voltage signal to generate a second original digital signal; a digital processing part configured to receive the first original digital signal and the second original digital signal; and a controller configured to control contents selected in the analog processing part, the first selection part, and the second selection part.

A comparator offset calibration system having a comparator offset evaluator and a switched-capacitor network is disclosed, which is in an analog and digital dual domain structure. The comparator offset evaluator receives digital data from an analog-to-digital conversion module, evaluates an offset of a comparator of the analog-to-digital conversion module based on the received digital data, and outputs an evaluated result. The switched-capacitor network processes the evaluated result to generate a control signal. The analog-to-digital conversion module adjusts the offset of the comparator according to the control signal.

Describe is a buffer which comprises: a differential source follower coupled to a first input and a second input; first and second current steering devices coupled to the differential source follower; and a current source coupled to the first and second current steering devices. The buffer provides high supply noise rejection ratio (PSRR) together with high bandwidth.

A digital equalizer with reduced number of multipliers for correction of the frequency responses of an interleaved analog-to-digital-converter (ADC) is disclosed. An exemplary interleaved analog to digital converter with digital equalization includes at least one composite ADC including M time-interleaved sub-ADCs, and an equalization configuration deploying a Pre-FIR transformers unit, a FIRs assembly unit, and a Post-FIR transformers unit. The FIRs assembly unit includes a finite impulse response (FIR) filter network which is operative pursuant to a Fast Filtering Algorithm as an alternative to a conventional finite impulse response network, enabling a reduction of the number of multipliers compared to conventional FIR filter-based equalization networks for ADCs.

Describe is a buffer which comprises: a differential source follower coupled to a first input and a second input; first and second current steering devices coupled to the differential source follower; and a current source coupled to the first and second current steering devices. The buffer provides high supply noise rejection ratio (PSRR) together with high bandwidth.