A high frequency amplifier 1 includes an input terminal P.sub.IN, an output terminal P.sub.OUT, a transistor 5 configured to amplify an RF signal applied to the input terminal P.sub.IN, a matching circuit 9 for a fundamental of the RF signal and a reflection circuit 7 for a harmonic relative to the fundamental, the matching circuit 9 and the reflection circuit 7 being connected in series between the transistor 5 and the output terminal P.sub.OUT, an extraction circuit 13 configured to extract a harmonic appearing at the output terminal P.sub.OUT, processing circuits 15, 17 configured to adjust a phase and intensity of the harmonic extracted by the extraction circuit 13, and a multiplexing circuit 19 configured to multiplex the harmonic processed by the processing circuits 15, 17 to the harmonic reflected by the reflection circuit 7 and give the multiplexed harmonic to the transistor 5.

An example current mirror arrangement includes a current mirror circuit having an input transistor and an output transistor, where the base/gate terminal of the input transistor is coupled to its collector/drain terminal via a transistor matrix that includes a plurality of transistors. Transistors of the transistor matrix, together with the input transistor, form two parallel feedback loops, such that the input transistor is part of both loops. The first loop is a fast, low-gain loop, while the second loop is a slow, high-gain loop. At lower input frequencies, the high-gain loop may properly bias and accurately generate voltage at the base/gate terminal of the input transistor, while at higher input frequencies the fast loop may significantly extend the linear operating frequency band. Consequently, a current mirror arrangement with improvements in terms of linearity and signal bandwidth may be realized.

An amplifier includes a first capacitor connected between an input node and a floating node, a second capacitor connected between the floating node and an output node, an amplifying element connected between a power supply voltage and the output node and operating in response to a voltage level of the floating node, a current bias source connected between the output node and a ground voltage, a first reset switch connected between the floating node and an intermediate node and operating in response to a reset bias, a second reset switch connected between the intermediate node and the output node and operating in response to the reset bias, and a reset bias generator circuit that outputs the reset bias in response to a reset signal. The reset bias is one of a reset voltage of the intermediate node, the power supply voltage, and the ground voltage.

An amplifier circuit includes a high-voltage output stage. The high-voltage output stage includes an output terminal, a high-side output circuit, a low-side output circuit, and a feedback circuit. The high-side output circuit sources current to the output terminal, and includes a high-side input transistor, a first high-side cascode transistor coupled to the high-side input transistor, and a second high-side cascode transistor coupled to the first high-side cascode transistor and the output terminal. The low-side output circuit sinks current from the output terminal, and includes a low-side input transistor, a first low-side cascode transistor coupled to the low-side input transistor, and a second low-side cascode transistor coupled to the first low-side cascode transistor and the output terminal. The feedback circuit is configured to bias the second high-side cascode transistor and the second low-side cascode transistor based on a sense voltage generated by the high-side output circuit or the low-side output circuit.

A low-power, low-noise amplifier with a negative feedback loop is provided. A low noise amplifier (LNA) includes a common gate (CG) amplifier, a common source (CS) amplifier having a gate connected to a source of the CG amplifier, a differential current balancer (DCB) connected to an output end of the CG amplifier and an output end of the CS amplifier, a symmetric load connected to the DCB, and a current bleeding circuit with one end connected to the output end of the CS amplifier and another end connected to the symmetric load, the current bleeding circuit including an active element and a load corresponding to the symmetric load, and an output end of the active element is connected to a gate of the CG amplifier.

Various embodiments relate to an amplifier circuit including: a first transistor having a first and second current conducting terminals and a control terminal; a second transistor having a first and second current conducting terminals and a control terminal, in which the second current-conducting terminal of the first transistor is connected to the first current-conducting terminal of the second transistor; a first inductor with a first terminal coupled to a first current-conducting terminal of the first transistor and a second terminal coupled to an output of the amplifier circuit; a feedback circuit connected between the output and the control terminal of the second transistor, wherein the feedback circuit includes a first resistor, a second inductor, and a first capacitor; and an input of the amplifier circuit connected between the first resistor and the second inductor, wherein a second current-conducting terminal of the second transistor is connected to a first ground terminal, and wherein a control terminal of the first transistor is connected to a second ground terminal via a third capacitor.

A bias compensation circuit, coupled to an amplifying circuit, is disclosed. The bias compensation circuit comprises a transistor, comprising a first terminal, a second terminal and a control terminal; a first feedback transistor, comprising a control terminal, coupled to the first terminal of the transistor; a first terminal, coupled to the control terminal of the transistor; and a second terminal; and a second feedback transistor, comprising a control terminal, coupled to the first terminal of the transistor; a first terminal, coupled to the amplifying circuit; and a second terminal; and a first resistor, comprising a first terminal, coupled to the first terminal of the transistor; and a second terminal, configured to receive a first voltage.

Linearity is improved in an amplifier circuit without lowering gain.

The amplifier circuit includes a transistor, a load, an impedance element, and a variable current source. The transistor amplifies an input signal. The load is connected between the transistor and a power supply. The impedance element is connected between the transistor and a ground terminal, and passes a direct current. The variable current source is connected to a connection part between the transistor and the impedance element, and supplies a current in accordance with a voltage of the connection part.

A circuit for filtering a signal corresponding to a time of flight (TOF) of light from a laser reflected off an object to a photo detector, the circuit includes a preamplifier, a DC cancelation loop, and an AC cancelation loop. The preamplifier may be configured to receive the signal from the photo detector corresponding to an output of the laser reflected off an object remote from the laser and photo detector. The DC cancelation loop includes a current feedback DC servo loop. The AC cancelation loop includes a feedback network driven by a floating class AB output stage, and the preamplifier configured to drive the floating class AB output stage, wherein the preamplifier is driven by an error signal of the feedback network and creates an AC signal path with the feedback network and floating class AB output stage.

A low-power, low-noise amplifier with a negative feedback loop is provided. A low noise amplifier (LNA) includes a common gate (CG) amplifier, a common source (CS) amplifier having a gate connected to a source of the CG amplifier, a differential current balancer (DCB) connected to an output end of the CG amplifier and an output end of the CS amplifier, a symmetric load connected to the DCB, and a current bleeding circuit with one end connected to the output end of the CS amplifier and another end connected to the symmetric load, the current bleeding circuit including an active element and a load corresponding to the symmetric load, and an output end of the active element is connected to a gate of the CG amplifier.