A signal processing apparatus includes: a difference signal acquirer configured to obtain a difference signal reflecting a change in an input signal at a preset time interval based on a reference signal; a signal amplifier configured to amplify the difference signal; and a signal restorer configured to generate an output signal by converting the amplified difference signal to a digital signal and summing the digital signal.

To effectively suppress an idle tone in a delta-sigma modulator that generates a feedback signal by a digital-to-analog converter. A filter integrates a difference between an input analog signal and a feedback signal, and outputs the integrated difference as an integrated signal. A preceding-stage quantizer quantizes an integrated signal into a digital signal, and outputs the resulting digital signal as a preceding-stage output signal. An adder adds a predetermined dithering signal to a preceding-stage output signal, and outputs the resulting signal as a subsequent-stage input signal. A subsequent-stage quantizer configured to quantize the subsequent-stage input signal into a digital signal of a shorter number of bits than a preceding-stage output signal, and outputs the resulting digital signal as a subsequent-stage output signal. A digital-to-analog converter configured to convert a subsequent-stage output signal into an analog signal, and outputs the resulting analog signal to a filter as a feedback signal.

A coarse tuning synthesizer for wireless communication includes a digital control unit, a digital-to-analog converter, and a comparator. The digital control unit includes an output node coupled to a first input node of a VCO (voltage controlled oscillator). The digital-to-analog converter includes a first node coupled to the first input node of the VCO. The comparator includes an output node coupled to an input node of the digital control unit. The comparator also includes a first input node coupled to a second node of the digital-to-analog converter and a second input node coupled to an output node of the VCO.

A coarse tuning synthesizer for wireless communication includes a digital control unit, a digital-to-analog converter, and a comparator. The digital control unit includes an output node coupled to a first input node of a VCO (voltage controlled oscillator). The digital-to-analog converter includes a first node coupled to the first input node of the VCO. The comparator includes an output node coupled to an input node of the digital control unit. The comparator also includes a first input node coupled to a second node of the digital-to-analog converter and a second input node coupled to an output node of the VCO.

A band-pass filter is described comprising a first first-order filter stage comprising a first resistor characterized by a first impedance and connected to a first node, referred to as a filter input node, and, through a second node to a first reactive component connected to a third node, the first impedance being such that a first current therethrough is dependent on the difference between the voltages at the first and second nodes; and a second first-order filter stage comprising a second resistor characterized by a second impedance and connected to the second node, and, through a fourth node, to a second reactive component connected to a fifth node. The second impedance is such that a second current therethrough is dependent on the negative of the sum of the voltages at the second and fourth nodes. The band-pass filter further comprises summing means for summing the voltages at the second and fourth nodes to output a voltage at a sixth node.

Provided is a transmission system including: a signal processing apparatus 2 configured to transmit, via a signal cable 4, a delta-sigma modulated signal obtained by performing delta-sigma modulation on a transmission signal that is an RF signal; and a wireless apparatus 3 configured to transmit, via the signal cable 4, a reception signal that is an RF signal. The signal processing apparatus 2 transmits the delta-sigma modulated signal to the wireless apparatus 3, and the wireless apparatus 3 transmits the reception signal to the signal processing apparatus 2. In the delta-sigma modulated signal, quantization noise is suppressed at the frequency of the reception signal. The reception signal is transmitted to the signal processing apparatus 2 while the delta-sigma modulated signal is being transmitted to the wireless apparatus 3.

A method for improving performance of a superconducting, flux-quantizing analog to digital converter (SFADC), comprising the following steps. The first step involves providing a known digitally-modulated signal as an input to the SFADC. Another step provides for generating an output with the SFADC based on the known digitally-modulated signal. Another step provides for comparing the characteristics of the output with ideal characteristics to identify an individual rapid single flux quantum (RSFQ) element of the SFADC that is contributing one or more of noise and error to the output. Another step provides for altering one or more of a bias, a delay, and a temperature of the individual RSFQ element to reduce one or more of the noise and the error.

The disclosure provides a circuit that includes an integrator that generates an integrated signal in response to a current signal. A comparator is coupled to the integrator and receives the integrated signal and a primary reference voltage signal. The comparator generates a feedback signal. A switched capacitor network is coupled across the integrator. The feedback signal activates the switched capacitor network.

An A/D converter includes an integrator having an operational amplifier, a first feedback capacitor, and a second feedback capacitor, a quantizer outputting a quantization result of an output signal of the operational amplifier, and a D/A converter having a D/A converter capacitor. The D/A converter capacitor has a first terminal connected to an input terminal of the operational amplifier and a second terminal connected to an output terminal of the operational amplifier. The D/A converter performs a subtraction operation by repeating subtraction of charges accumulated in the first and second feedback capacitors based on the quantization result, and performs a cyclic operation by sequentially repeating subtraction and amplification of the charges accumulated in one of the first and second feedback capacitors based on the quantization result.

An A/D converter includes an integrator having an operational amplifier, a first feedback capacitor, and a second feedback capacitor, a quantizer outputting a quantization result of an output signal of the operational amplifier, and a D/A converter having a D/A converter capacitor. The D/A converter capacitor has a first terminal connected to an input terminal of the operational amplifier and a second terminal connected to an output terminal of the operational amplifier. The D/A converter performs a subtraction operation by repeating subtraction of charges accumulated in the first and second feedback capacitors based on the quantization result, and performs a cyclic operation by sequentially repeating subtraction and amplification of the charges accumulated in one of the first and second feedback capacitors based on the quantization result.