A device for increasing a slew rate of a driving amplifier includes a driving amplifier, a slew rate improvement circuit, and a controller. The driving amplifier is configured to amplify an input voltage and output an output voltage. The slew rate improvement circuit is configured to provide or receive a current to increase the slew rate of the driving amplifier. The controller is configured to control an operation of the slew rate improvement circuit based on a difference between a first code corresponding to the input voltage of the driving amplifier during a current horizontal line time and a second code corresponding to the input voltage during a next horizontal line time.

A device is provided. The device includes an operational amplifier, an output circuit, a first capacitor, and a second capacitor. The operational amplifier is configured to generate an output according to a feedback signal. The output circuit is configured to generate a first current signal in response to a supply voltage and the output of the operational amplifier. The first current signal includes a first ripple signal. The first capacitor and the second capacitor are coupled in parallel between the operational amplifier and the output circuit. The first capacitor is configured to receive the first current signal and feedback to the operational amplifier the first ripple signal.

An RF transistor amplifier circuit comprises a Group III nitride based RF transistor amplifier having a gate terminal, a Group III nitride based self-bias circuit that includes a first Group III nitride based depletion mode high electron mobility transistor, the Group III nitride based self-bias circuit configured to generate a bias voltage, and a Group III nitride based depletion mode differential amplifier that is configured to generate an inverted bias voltage from the bias voltage and to apply the inverted bias voltage to the gate terminal of the Group III nitride based RF transistor amplifier. The Group III nitride based RF transistor amplifier, the Group III nitride based self-bias circuit and the Group III nitride based depletion mode differential amplifier are all implemented in a single die.

A low distortion transconductance amplifier provides current to a grounded load using a virtual ground input stage, a pair of current mirrors, and a bias current source. The virtual ground input stage may include transistors arranged as a Darlington pair. The low distortion transconductance amplifier can function as a voltage-controlled AC current source that is operable at high frequencies.

Disclosed examples include amplifier circuits with a first stage to amplify an input voltage signal according to a first stage gain to provide a first stage output voltage signal, and a second stage to provide an amplifier output voltage signal. A bias circuit provides an amplifier bias current signal to a current mirror circuit coupled with the first stage to control a first stage bias current, and an adjustment circuit to reduce the amplifier bias current signal and increase the first stage gain when the input voltage signal is near a first supply voltage or a second supply voltage.

Many electronic circuits rely on the ratio of one component to other components being well defined. Current flow in component can warm the component causing its electrical properties to change, for example the resistance of a resistor may increase due to self-heating as a result of current flow. The present disclosure provides a way to reduce temperature variation between components so as to reduce electrical mismatch between them or the consequences of such mismatch. This is important as even a change of resistance of, for example, 20-50 ppm in a resistor can result in non-linearity exceeding the least significant bit value of a 16 bit digital to analog converter.

An analog-to-digital converter (“ADC”) includes an input terminal configured to receive an analog input voltage signal. A first ADC stage is coupled to the input terminal and is configured to output a first digital value corresponding to the analog input voltage signal and a first analog residue signal corresponding to a difference between the first digital value and the analog input signal. An inverter based residue amplifier is configured to receive the first analog residue signal, amplify the first analog residue signal, and output an amplified residue signal. The amplified residue signal is converted to a second digital value, and the first and second digital values are combined to create a digital output signal corresponding to the analog input voltage signal.

An amplifier circuit includes an amplifier, a resistor, and an adaptive bias circuit. The amplifier includes an output and a tail input. The amplifier is configured to generate an output signal representative of a difference of a first input signal and a second input signal. The resistor is coupled to the output of the amplifier. The resistor is configured to lower an output resistance of the amplifier. The adaptive bias circuit is coupled between the output of the amplifier and the tail input of the amplifier. The adaptive bias circuit is configured to generate a detection current based on the output signal, and provide the detection current to the tail input of the amplifier to increase the gain of the amplifier based on the output signal.

A differential amplifier circuit amplifies a difference between an input analog signal and a ramp signal which changes over time and outputs a difference signal. An amplifying element amplifies the difference signal and outputs the same as an amplified signal. A time measuring unit measures a length of a conversion period until a level of the analog signal substantially coincides with a level of the ramp signal on the basis of a level of the amplified signal and outputs the same as a digital signal obtained by converting the analog signal. One end of a capacitor is connected to one of an input terminal and a predetermined connection terminal of the amplifying element. A switch connects the other end of the capacitor to the other of the input terminal or the predetermined connection terminal in the conversion period, and disconnects the other end outside the conversion period.

The present disclosure relates to current control circuitry for controlling a current through a load, the current control circuitry comprising: amplifier circuitry; reference voltage generator circuitry configured to supply a fixed reference voltage to a first input of the amplifier circuitry; an output stage comprising: a control terminal coupled to an output of the amplifier circuitry; a current input terminal configured to be coupled to the load; a current output terminal; a clock-controlled variable resistance coupled to the current output terminal of the output stage, wherein a resistance of the variable resistance is based on a digital code input to the variable resistance; and a feedback path between the current output terminal of the output stage and a second terminal of the amplifier circuitry for providing a feedback voltage to a second input of the amplifier circuitry.