A comparator system and a method for comparing an input signal and a reference signal are presented. The system has a controller to adjust a rising output delay and/or a falling output delay of a system output signal. The system output signal is dependent on the comparison between the input signal and the reference signal. This system provides a more efficient comparator with reduced power consumption whilst still providing the required rising output delay and falling output delay for a given application. Techniques used in prior art will always resort to running the comparators at a speed that supports the speed requirements in the worst case conditions and does not exploit any asymmetries in the required rising output delay and falling output delay for a given application. When these asymmetries are exploited, further increases in power efficiency can be achieved.

Systems and methods are provided for implementing a hardware accelerator. The hardware accelerator emulates a neural network, and includes a memristor crossbar array, and a non-linear filter. The memristor crossbar array can be programmed to calculate node values of the neural network. The nodes values can be calculated in accordance with rules to reduce an energy function associated with the neural network. The non-linear filter is coupled to the memristor crossbar array and programmed to harness noise signals that may be present in analog circuitry of the hardware accelerator. The noise signals can be harnessed such that the energy function associated with the neural network converges towards a global minimum and modifies the calculated node values. In some embodiments, the non-liner filter is implemented as a Schmidt trigger comparator.

A method for controlling operation of a comparator that includes an amplifier that is connected at an input of the comparator includes neutralizing any change of state of a signal output by the comparator starting from each moment in time at which the change of state of the output signal occurs and lasting for a duration of propagation to compensate for a duration of propagation of signals within the amplifier.

A circuit arrangement is disclosed for controlling the switching of a field effect transistor (FET). A current controlled amplifier may be configured to amplify a current in a current sense device to generate an amplified current, wherein the current in the current sense device indicates a current through the FET. A comparator may be coupled to the current sense amplifier to compare a voltage corresponding to the amplified current with a voltage reference and to generate a comparator output based on the comparison, wherein the comparator output controls whether the FET is on or off.

A driver IC (100) includes a pair of output terminals in each of a plurality of channels and in each of the channels, power is supplied from the pair of output terminals (OUT1 and OUT2, OUT3 and OUT4, OUT5 and OUT6 or OUT7 and OUT8) to a load (M1, M2, M3 or M4). In each of the channels, the pair of output terminals are adjacent to each other.

A capacitive-coupled level shifter includes: an input having a positive input terminal and a negative input terminal, the input configured to receive a modulated signal in a first voltage domain; a comparator circuit configured to shift the modulated signal to a second voltage domain higher than the first voltage domain; and a capacitive divider circuit comprising a first capacitive divider branch coupling the positive input terminal of the input to a positive input terminal of the comparator circuit and a second capacitive divider branch coupling the negative input terminal of the input to a negative input terminal of the comparator circuit. The first capacitive divider branch and the second capacitive divider branch are symmetric so as to cancel out a common mode voltage of the modulated signal. A level shifter system which includes the capacitive-coupled level shifter is also described.

A first terminal receives a first DC voltage. A switch selectively couples the first terminal to a second terminal providing an output. A control circuit selectively actuates the switch in response to a comparison of the first DC voltage to a second DC voltage. A low-dropout (LDO) linear voltage regulator, connected between the first and third terminals, operates to provide the second DC voltage from the first DC voltage.

A hysteresis control method for inverter and an inverter based on hysteresis control are disclosed. The inverter is electrically connected to a power grid, and the method includes: Step S1, sampling a grid voltage V.sub.g(z) and an output current I.sub.g(z) of the inverter; Step S2, calculating a present period hysteresis bandwidth H(z) based on the grid voltage V.sub.g(z) sampled in step S1; Step S3, predicting a next period hysteresis bandwidth H(z+1); Step S4, correcting the present period hysteresis bandwidth H(z) based on the next period hysteresis bandwidth H(z+1) obtained in step S3, to obtain a final hysteresis bandwidth H.sub.out(z); and Step S5, controlling an output driving signal according to the output current I.sub.g(z) of the inverter and the final hysteresis bandwidth H.sub.out(z) to control the operation of the inverter.

A circuit includes an analog-to-digital converter (ADC) and a hysteresis circuit. The ADC is configured to generate a series of digital codes. The hysteresis circuit is configured to: (a) determine that a first digital code of the series of digital codes represents a change in a same direction as previous digital codes and store the first digital code in the register; and (b) determine that a second digital code of the series of digital codes represents a change in direction from previous digital codes, determine that the second digital code is less than a hysteresis value different than a preceding digital code, and not store the second digital code in the register.

A comparator circuit includes a first transistor, a second transistor, a first switch, a second switch, and a timing circuit. The first transistor and the second transistor are coupled as a differential pair and are configured to compare an input signal to a hysteresis voltage. The first switch is coupled to the first transistor and is configured to selectably enable the first transistor. The second switch is coupled to the second transistor and is configured to selectably enable the second transistor. The timing circuit is coupled to the first switch and the second switch and is configured to close the first switch responsive to a signal transition at an output of the comparator circuit and close the second switch a predetermined delay time after the first switch is closed.