An amplifier for headphones including a current digital-to-analog converter (DAC) configured to output a current based on a digital audio input signal, an output electrically connected to a speaker and configured to output an output signal to the speaker, and a pulse width modulation (PWM) loop configured to receive an error signal, the error signal based on a difference between the current from the current DAC and a current of the output signal, and generate the output signal based on the error signal. The PWM loop includes an analog-to-digital converter (ADC) configured to receive an analog signal based on the current from the current DAC and output a digital signal representing the analog signal, and an encoder configured to receive the digital signal and output a pulse having a width based on the analog signal.

A method and a system of calibrating a DC offset voltage on a resistor load are provided. The system may include a first operational amplifier, a second operational amplifier, a comparator, a digital signal processor, and a digital to analog convertor. At a calibration mode, under control of the digital signal processor, the system may utilize open-loop high gain characteristics of the first operational amplifier and the comparator to automatically detect and calibrate the DC offset voltage. At an operation mode, the system may automatically compensate the DC offset voltage based on the calibration of the DC offset voltage. In this way, the system and the method can automatically detect, calibrate, and compensate the DC offset voltage with reduced cost and technical complexity.

A device of integration of an electric current received on an integration node, includes an operational amplifier, an integration capacitor, and a circuit for modifying an output voltage of the operational amplifier formed by a charge transfer circuit configured to be connected on the integration node and to transfer charges into the integration capacitor. The device also includes a comparison circuit configured to trigger the modification circuit at least once during the integration duration, and a storage circuit configured to store the number of triggerings which have occurred during the integration duration. The received electric current is calculated according to the output voltage as well as to the number of triggerings multiplied by the modification of the output voltage induced by the modification circuit.

A voltage regulator and a power supply are provided. The voltage regulator includes an operational amplifier and an offset voltage control module. The offset voltage control module includes one or more stages of regulation branches connected in parallel, and controls an offset voltage of the operational amplifier with the one or more stages of regulation branches to regulate the output voltage. The offset voltage control module also includes a bandgap reference generation circuit, configured to generate a reference voltage irrelevant to a temperature coefficient that is received by the operational amplifier from the input terminal, wherein the bandgap reference generation circuit comprises at least one of: a V.sub.GS-based bandgap reference generation circuit having a full CMOS reference offset structure, a PTAT unit-based and V.sub.GS-based bandgap reference generation circuit having a full CMOS reference offset structure, and a PTAT unit-based and BJT-based bandgap reference generation circuit having a complementary structure.

The disclosure relates to a pre-5th-generation (5G) or 5G communication system to be provided for supporting higher data rates beyond 4th-generation (4G) communication system such as long term evolution (LTE). An operation method of a device for upconversion in a wireless communication system is provided. The method includes receiving a first local oscillator (LO) signal, generating a second LO signal, based on the first LO signal and cross-coupled latches, receiving an input signal, generating an upconverted frequency, based on the second LO signal and the input signal, generating an output signal obtained by processing a harmonic component included in the upconverted frequency, and transmitting the generated output signal.

Systems, apparatuses, and methods for performing offset correction for pseudo differential signaling are disclosed. An apparatus includes at least a sense amplifier and an offset correction circuit. The offset correction circuit generates an offset correction voltage by applying a positive or negative offset to a termination voltage. The offset correction circuit supplies the offset correction voltage to a negative input terminal of the sense amplifier. An input signal voltage is supplied to the positive input terminal of the sense amplifier. The sense amplifier generates an output based on a comparison of the voltages supplied to the positive and negative input terminals.

A leakage compensation circuit includes a buffer amplifier, a link coupling element, and a leakage compensation element. The buffer amplifier has an input coupled to a sense node, and an output. The link coupling element has an input coupled to the output of the buffer amplifier, and an output, wherein the link coupling element is unidirectional in a direction from the input to the output thereof. The leakage compensation element has a first current terminal coupled to the sense node, a control terminal coupled to the output of the link coupling element, and a second current terminal coupled to a reference voltage terminal.

A receiver includes a first T-coil circuit at an input of the receiver and configured to receive an input signal, a termination impedance coupled to the first T-coil circuit and configured to match an impedance of a transmission line coupled to the first T-coil circuit, and an amplifier including a first input and a second input and configured to amplify a differential signal at the first and second inputs, a calibration switch coupled to the amplifier and configured to selectively electrically connect or disconnect the first and second inputs of the amplifier, and a first receive switch configured to selectively electrically connect or disconnect a center node of the first T-coil circuit and the amplifier.

Systems, apparatuses, and methods for performing offset correction for pseudo differential signaling are disclosed. An apparatus includes at least a sense amplifier and an offset correction circuit. The offset correction circuit generates an offset correction voltage by applying a positive or negative offset to a termination voltage. The offset correction circuit supplies the offset correction voltage to a negative input terminal of the sense amplifier. An input signal voltage is supplied to the positive input terminal of the sense amplifier. The sense amplifier generates an output based on a comparison of the voltages supplied to the positive and negative input terminals.

A leakage compensation circuit includes a buffer amplifier, a link coupling element, and a leakage compensation element. The buffer amplifier has an input coupled to a sense node, and an output. The link coupling element has an input coupled to the output of the buffer amplifier, and an output, wherein the link coupling element is unidirectional in a direction from the input to the output thereof. The leakage compensation element has a first current terminal coupled to the sense node, a control terminal coupled to the output of the link coupling element, and a second current terminal coupled to a reference voltage terminal.