A power factor calibration circuit includes a multiplier, a boost inductor, an auxiliary winding, a detection resistor, a compensation capacitor, a comparator, and an auxiliary switch. The comparator is configured to detect inductor current flowing through the boost inductor. When the detected inductor current is too small, the energy stored in the compensation capacitor is transmitted to the auxiliary winding for generating compensation current, thereby enhancing the level of the inductor current.

The present invention provides a high voltage regulated DC power supply with full range 24 pulse input for ripple free output for high power RF amplifier, comprising: full range 24 pulse 3 phase 11 kV input system configured to provide uncontrolled low voltage DC bus, low input harmonics and high input power factor; a plurality of DC-DC power modules having their output connected in a series and coupled to the said DC bus voltage; each power module comprising a DC source, an inverter bridge IGBTs operating at predefined duty cycle and staggered to reduce the output ripple and output stored energy; and a combination of feed forward and feedback control circuit adapted to regulate the variations in the input line voltage and the variation in output at various load current to finally obtain ripple free high voltage output.

A power supply circuit includes: an output terminal for supplying power for a semiconductor device at the terminal; a control circuit configured to control a power level of the supplied power based on a control signal; and an input for receiving one or more timing signals, wherein the power supply circuit is configured to derive an indication for a scheduled change of a load current of the supplied power using the one or more timing signals. The power supply circuit is configured to adapt the control signal based on the indication for the scheduled change of the load current.

An electrical supply device is connected on a network side to an electrical supply network and includes a frequency converter having a network-side power converter and an intermediate circuit, and a network filter, which is connected upstream of the network-side power converter. In a method for operating the electrical supply device, during a pulse-blocking operating state of the frequency converter, a check is carried out for the presence of a dangerous state of the network filter, and only in the presence of the dangerous state, only the network-side power converter is actuated such that a network perturbation causing the dangerous state of the network filter is at least damped to protect the network filter from the dangerous state.

A control method for regulating the switching frequency of a resonant converter having an input terminal to receive an input voltage and an output terminal to output an output voltage. The control method is sensing the input voltage and adjusting the switching frequency based on the comparison of the input voltage with a reference threshold voltage. When the input voltage is less than the reference threshold voltage, the switching frequency is adjusted to decrease, and when the input voltage is higher than the reference threshold voltage, the switching frequency is adjusted to increase.

Embodiments of a circuit for controlling DC offset error for an inductor current ripple based, constant-on time DC-DC converter are disclosed. The circuit includes a ripple generation circuit coupled to a reference voltage input and to a sense voltage input, and having a reference voltage output to form a main loop. The circuit also includes a DC error correction circuit connected between the reference voltage input and the sense voltage input, and the reference voltage output of the ripple generation circuit. The DC error correction circuit includes a coarse DC error correction loop coupled between the sense voltage input and the reference voltage output and a fine DC error correction loop coupled between the reference voltage input and the reference voltage output. A method for controlling DC offset error for an inductor current ripple based, constant-on time DC-DC converter, is also disclosed.

A calibration circuit including mode, bias, calibration, offset, resistance and code modules. The mode module selects operation in a first or second mode. The bias module generates, for the preamplifier, a first and second bias currents respectively while in first and second modes. The calibration module, during calibration of first mode, connects inputs of preamplifier together to receive a predetermined voltage. The offset module determines an offset based on output voltages of preamplifier or output voltage of comparator and generates a control signal based on whether the offset is within a predetermined range. The resistance module, based on control signal and during calibration of first mode, adjusts a resistance of a resistor in a first resistance set of preamplifier for the first mode. The code module generates a calibration code based on the resistance. The resistance module calculates a second resistance set for second mode based on the calibration code.

Provided is regulation of a line current. The regulation of the line current includes comparing a reference voltage with a line sensing voltage to generate a feedback voltage, and controlling a switching operation of a power switch using the feedback voltage. The reference voltage may be a voltage having a constant level, a voltage which varies according to an output current, or a voltage which follows a sine wave to compensate a power factor. Provided is sensing of an output current. The sensing of the output current includes sensing the output current using a feedback voltage corresponding to a voltage between both terminals of an inductor connected to a power switch, a peak of current flowing through the power switch, and a switching cycle of the power switch.

Generally, this disclosure provides circuitry and methods for determining the output capacitance of an output load capacitor of a power supply. The output capacitance is generally determined by beginning a calibration period and charging an output capacitor with a current source to generate an output voltage. The output voltage may be compared to a reference voltage, and a time period is determined during which the output voltage is less than the reference voltage. The capacitance value, C, of the output capacitor may be determined based on, at least in part, the determined time period. This disclosure also provides circuitry and methods to adjust certain parameters of the power supply based on the determined C value. For example, in a ramp compensation portion of the power supply, the value of a ramp capacitor and/or reset resistor may be adjusted once the value of C is determined. This may enable, for example, increased efficiency, greater stability and increased bandwidth operation of the power supply when the output load capacitor is changed for different applications.

A controller, and related method, configured to generate a duty cycle control signal for controlling an output voltage of a switched mode power supply as a function of a reference signal. In one embodiment, the controller is configured to sample a signal indicative of the output voltage to generate a first sampled signal, filter out a ripple component of the first sampled signal to generate a filtered signal, and generate a feedback control signal based on the filtered signal. The controller is also configured to sample a signal indicative of an input voltage of the switched mode power supply to generate a second sampled signal, generate a feed-forward control signal based on the second sampled signal and a feed-forward reference voltage, and generate the duty cycle control signal based on the feedback control signal and the feed-forward control signal.