A trimming resource includes an adjustable driver resource, a differential voltage generator, and a trim current generator. The adjustable driver resource produces an output signal. The differential voltage generator receives the output signal from the adjustable driver resource and produces a differential drive signal. The trim current generator derives a trim signal from the differential drive signal received from the differential voltage generator. According to one configuration, the trim current generator outputs the trim signal to an electronic component, correcting an operational parameter of the electronic component.

A half-power buffer amplifier includes an amplification unit including first and second nodes, the amplification unit configured to differentially amplify a differential input signal and to output a differentially amplified output signal, a first output unit including a first buffer unit between a first power source having a first voltage and a second power source having a second voltage, a second buffer unit between the first and second power sources, and a first switch unit between the first and second buffer units, and a second output unit including a third buffer unit between the second power source and a third power source having a third voltage, a fourth buffer unit between the second and third power sources, and a second switch unit between the third and fourth buffer units. Each of the first to third buffer units receives the differentially amplified output signal. The first switch unit is turned on or off based on or in response to a pre-driving control signal.

In one example an amplifier includes a bias circuit, an open-loop gain stage including a first PMOS having a gate coupled to a first node, a source coupled to a second node, a drain coupled to a third node, and a bulk coupled to the bias circuit, a second PMOS having a gate coupled to a ground node, a source coupled to the second node, a drain coupled to a fourth node, and a bulk coupled to the bias circuit, a first NMOS having a drain and a gate coupled to the third node and a source coupled to a fifth node, a second NMOS having a drain coupled to the fourth node, a gate coupled to the third node, and a source coupled to the fifth node, an adjustable resistor coupleable between the third and fourth nodes, and a buffer stage coupled to the open-loop gain stage.

An amplifier includes an input transistor, an input terminal, a first current source, a cascode transistor, and a second current source. The input transistor is coupled to the input terminal. The first current source is coupled to the input transistor and is configured to provide a bias current to the input transistor that is proportional to absolute temperature. The cascode transistor is coupled to the input transistor. The second current source is coupled to the cascode transistor and is configured to provide a bias current to the cascode transistor that is complementary to absolute temperature.

An electronic circuit comprises an input stage, a gain stage operatively coupled to the input stage, a primary output stage operatively coupled to the gain stage, a replica output stage operatively coupled to the gain stage in parallel to the primary output stage, and a clock circuit. The clock circuit operates the electronic circuit in multiple phases including a sampling phase to disconnect the primary output stage and the replica output stage from the gain stage to obtain an offset voltage, an active phase to reconnect the primary output stage to apply the offset voltage to reduce an offset at the primary output stage, and an intermediate phase to first reconnect the replica output stage to the gain stage prior to the active phase.

An offset cancellation circuit and method are provided where successive stages of cascaded amplifiers are operated in a saturated state. Biasing is provided, by a feedback amplifier, connected in a feedback loop for each cascaded amplifier, so as to be responsive, in a non-saturated state, to the input of an associated amplifier stage operating in the saturated state.

An electronic circuit comprises an input stage, a gain stage operatively coupled to the input stage, a primary output stage operatively coupled to the gain stage, a replica output stage operatively coupled to the gain stage in parallel to the primary output stage, and a clock circuit. The clock circuit operates the electronic circuit in multiple phases including a sampling phase to disconnect the primary output stage and the replica output stage from the gain stage to obtain an offset voltage, an active phase to reconnect the primary output stage to apply the offset voltage to reduce an offset at the primary output stage, and an intermediate phase to first reconnect the replica output stage to the gain stage prior to the active phase.

In one example an amplifier includes a bias circuit, an open-loop gain stage including a first PMOS having a gate coupled to a first node, a source coupled to a second node, a drain coupled to a third node, and a bulk coupled to the bias circuit, a second PMOS having a gate coupled to a ground node, a source coupled to the second node, a drain coupled to a fourth node, and a bulk coupled to the bias circuit, a first NMOS having a drain and a gate coupled to the third node and a source coupled to a fifth node, a second NMOS having a drain coupled to the fourth node, a gate coupled to the third node, and a source coupled to the fifth node, an adjustable resistor coupleable between the third and fourth nodes, and a buffer stage coupled to the open-loop gain stage.

An amplifier circuitry includes a current source circuit, a voltage regulator circuit, and an amplifier. The current source circuit generates a first bias current. The voltage regulator circuit regulates a reference voltage to generate a supply voltage. The voltage regulator circuit includes a first and a second compensation resistors, the first and the second compensation resistors are configured to generate the reference voltage according to a reference a second bias currents, and a first ratio is present between the first and the second biasing currents. The amplifier includes first load resistors which are configured to generate a first common-mode output signal based on the supply voltage and the first bias current. The second ratio is present between the second compensation resistor and one of the first load resistors, and the first and the second ratios are arranged to compensate the first common-mode output signal.

A half-power buffer amplifier includes an amplification unit including first and second nodes, the amplification unit configured to differentially amplify a differential input signal and to output a differentially amplified output signal, a first output unit including a first buffer unit between a first power source having a first voltage and a second power source having a second voltage, a second buffer unit between the first and second power sources, and a first switch unit between the first and second buffer units, and a second output unit including a third buffer unit between the second power source and a third power source having a third voltage, a fourth buffer unit between the second and third power sources, and a second switch unit between the third and fourth buffer units. Each of the first to third buffer units receives the differentially amplified output signal. The first switch unit is turned on or off based on or in response to a pre-driving control signal.