A multiple output current stimulator circuit with fast turn on time is described. At least one pair of input side and output side transistors is arranged in a current mirror connected to a supply transistor by cascode coupling. The output side transistor supplies stimulation current to an electrode in contact with tissue. An operational amplifier connected to a reference voltage and to the output side transistor drives the supply transistor to maintain the voltage at the output side transistor equal to the reference voltage. The at least one pair of transistors includes multiple pairs of transistors whose output side transistors drive respective electrodes with stimulation currents. The stimulator determines the initiation and duration of stimulation current pulses supplied to each electrode. At circuit activation, large currents are generated which discharge capacitances in the output side transistors causing rapid output side transistor turn on.

A drive circuit for a transistor component is described. The drive circuit comprises: an output, which is designed to be connected to a drive input of a transistor component and which has a first output node and a second output node; an input, which is designed to receive an input signal, which is referred to a reference potential, and which has a first input node and a second input node; a differential amplifier arrangement, which is connected to the first input node, the second input node, and the second output node, and which is designed to generate a drive signal based on the input signal; and a driver circuit, which is designed to receive the drive signal and to generate a drive voltage between the first and second output node based on the drive signal.

A drive circuit for a transistor component is described. The drive circuit comprises: an output, which is designed to be connected to a drive input of a transistor component and which has a first output node and a second output node; an input, which is designed to receive an input signal, which is referred to a reference potential, and which has a first input node and a second input node; a differential amplifier arrangement, which is connected to the first input node, the second input node, and the second output node, and which is designed to generate a drive signal based on the input signal; and a driver circuit, which is designed to receive the drive signal and to generate a drive voltage between the first and second output node based on the drive signal.

A voltage detection system includes a first voltage detector and a second voltage detector. The first voltage detector is configured for detecting whether an input voltage reaches a first voltage level. The second voltage detector, coupled to the first voltage detector, is configured for detecting whether the input voltage reaches a second voltage level. The first voltage detector outputs a control signal to control a status of the second voltage detector according to a detection result of the first voltage detector.

A voltage detection system includes a first voltage detector and a second voltage detector. The first voltage detector is configured for detecting whether an input voltage reaches a first voltage level. The second voltage detector, coupled to the first voltage detector, is configured for detecting whether the input voltage reaches a second voltage level. The first voltage detector outputs a control signal to control a status of the second voltage detector according to a detection result of the first voltage detector.

An example analog-test-bus (ATB) apparatus includes a plurality of comparator circuits, each having an output port, and a pair of input ports of opposing polarity including an inverting port and a non-inverting port, a plurality of circuit nodes to be selectively connected to the input ports of a first polarity, and at least one digital-to-analog converter (DAC) to drive the input ports of the plurality of comparator circuits. The apparatus further includes data storage and logic circuitry that accounts for inaccuracies attributable to the plurality of comparator circuits by providing, for each comparator circuit, a set of calibration data indicative of the inaccuracies for adjusting comparison operations performed by the plurality of comparator circuits.

In an embodiment an oscillator circuit comprises a first integrator-comparator unit, a second integrator-comparator unit, and a logic circuit. The first integrator-comparator unit is prepared to provide a first signal as a function of a first integration of a first charging current and a subsequent comparison of a first integration signal resulting from the first integration with a reference signal. The second integrator-comparator unit is prepared to provide a third signal as a function of a second integration of a second charging current and a subsequent comparison of a second integration signal resulting from the second integration with the reference signal. The logic circuit is adapted to provide a clock signal, a first and a second measurement signal for respectively controlling the first and the second integrator-comparator unit.

An oscillator circuit uses a comparator, and the oscillator circuit controls charge-discharge of the Miller capacitance between the gate and the drain of a MOSFET serving as an amplifier of the gain unit and the gate capacitance of the MOSFET, and enables the comparator output to follow a relatively high-frequency control signal that is input externally. The oscillator circuit uses a comparator having a differential unit and a gain unit. The oscillator circuit includes a charge-discharge control unit that connects to the output of the differential unit and is configured to control charge-discharge of the Miller capacitance between the gate and the drain of a MOSFET (N2) serving as an amplifier of the gain unit and the gate capacitance of the MOSFET, and an output control unit configured to control the output of the gain unit.

A receiver system for an on-off key (OOK) isolator system may include a pair of receivers. A first receiver may generate a first current signal representing a received OOK signal, and a second receiver may generate a second current signal from a common mode representation of the received OOK signal. The receiver system may include circuitry to compare the first and second current signals and generate an output signal therefrom.

A receiver system for an on-off key (OOK) isolator system may include a pair of receivers. A first receiver may generate a first current signal representing a received OOK signal, and a second receiver may generate a second current signal from a common mode representation of the received OOK signal. The receiver system may include circuitry to compare the first and second current signals and generate an output signal therefrom.