Systems and methods are disclosed for a signal convertor comprising a resistor or current source coupled to a positive virtual ground node and a negative virtual ground node, wherein the resistor or current source is configured to switch from the positive virtual ground node (VGP) to the negative virtual ground node (VGN), wherein the switching of the resistor or current source results in a shaping of the low frequency noise from the resistor.

A circuit for high accuracy element matching is provided. The circuit includes an analog to digital converter (ADC) configured to generate an output code. A current source is configured to provide a signal to the ADC. The current source includes a first current branch including a first unit element group having a first unit element coupled by way of a first set of switches to a first node and a second node and a second unit element coupled by way of a second set of switches to the first node and the second node. A second current branch includes a second unit element group having a third unit element coupled by way of a third set of switches to the first node and the second node and a fourth unit element coupled by way of a fourth set of switches to the first node and the second node. A control circuit is configured to provide control signals to the sets of switches based on the output code. The control circuit is further configured to sort unit element currents and to dynamically switch unit elements.

A device includes a plurality of digital-to-analog converters (DACs), a multiplexer, a plurality of electrodes including a first electrode, and a plurality of direct current (DC) offset circuits including a first DC offset circuit. At least one of the plurality of electrodes is located along a lane for movement of an ion. The multiplexer has multiple inputs coupled to the plurality of DACs and multiple outputs including a first output. The first output is configured to provide a first voltage. The first DC offset circuit is coupled between the first output and the first electrode. The first DC offset circuit is configured to add a first DC offset voltage to either the first voltage or the first voltage amplified by a first gain. The first DC offset voltage is configurable.

A multipath D/A converter is provided and has input terminals for a first and a second digital signal, and a signal combination unit D/A converting the digital signals supplied to the input terminals, and combining the generated analog signals. The signal combination unit includes a clock signal with a period having a first half period and a second half period. The signal combination unit combines the analog first and second signals by aggregating them with respective weighting coefficients. The signal combination unit has an output terminal for issuing an analog signal based on the aggregation. The signal combination unit applies a first set of weighting coefficients during the first half period of each period and a second set of weighting coefficients during said second half period of each period. The first set of weighting coefficients differs from the second set of weighting coefficients in at least one coefficient.

A Multipath D/A converter device is proposed having input terminals for a least a first and a second digital signal path, in at least one of the at least one first and second signal path, means for inverting every second sample of the digital signal, and each signal path comprising a D/A converter. The D/A converter of all signal paths are designed to operate at the same phase. The multipath converter device includes an analog combining unit designed for combining the analog signals output by each of the D/A converter.

A motion control system and method for controlling a stick-slip piezo motor includes an electronic controller and an analog driver for moving a mechanical device. When operating in a digital circuit mode, an electronic controller controls a digital-to-analog converter for moving the stick-slip piezo motor at a low speed. When operating in a faster analog circuit mode, the electronic controller, via an analog driver, operates to control an analog hardware circuit to move the stick-slip piezo motor at a high speed. The electronic controller operates in the digital circuit mode at start-up of the piezo motor.

An apparatus such as an electronic circuit includes an input operable to receive an input signal; a dynamic common mode adjustor operable to: i) derive a differential signal from the received input signal, and ii) control an offset of the differential signal as a function of the received input signal to produce an offset differential signal; and an output operable to output the offset differential signal. In one arrangement, the offset differential signal outputted from the output includes a first signal and a second signal; a difference between the second signal and the first signal proportionally varies with respect to the received input signal.

An apparatus such as an electronic circuit includes an input operable to receive an input signal; a dynamic common mode adjustor operable to: i) derive a differential signal from the received input signal, and ii) control an offset of the differential signal as a function of the received input signal to produce an offset differential signal; and an output operable to output the offset differential signal. In one arrangement, the offset differential signal outputted from the output includes a first signal and a second signal; a difference between the second signal and the first signal proportionally varies with respect to the received input signal.

An example apparatus includes a circuit and calibration circuitry. The circuit has complementary input ports to receive input signals including a monotonously rising and/or falling wave reference signal and a voltage-test signal to test at least one direct current (DC) voltage associated with the circuit by comparing the input signals using a first polarity and second polarity associated with the circuit to produce a first output signal and a second output signal. During operation, the circuit manifests an input voltage offset and a signal delay with each comparison of the input signals. The calibration circuitry processes the first and second output signals and, in response, calibrates or sets an adjustment for at least one signal path associated with the circuit in order to account for the input offset voltage and signal delay during normal operation of the circuit.

An example apparatus includes a circuit and calibration circuitry. The circuit has complementary input ports to receive input signals including a monotonously rising and/or falling wave reference signal and a voltage-test signal to test at least one direct current (DC) voltage associated with the circuit by comparing the input signals using a first polarity and second polarity associated with the circuit to produce a first output signal and a second output signal. During operation, the circuit manifests an input voltage offset and a signal delay with each comparison of the input signals. The calibration circuitry processes the first and second output signals and, in response, calibrates or sets an adjustment for at least one signal path associated with the circuit in order to account for the input offset voltage and signal delay during normal operation of the circuit.