Methods and apparatuses for signal attenuation is described. In an example, an attenuator can be configured to perform attenuation of signals for an integrated circuit. The attenuator can vary the attenuation with an ambient temperature. The attenuator can further adjust the attenuation based on a control signal applied to the attenuator. The control signal can be based on one or more of a temperature profile of the attenuator and a target gain variation of the integrated circuit.

Methods and apparatuses for signal attenuation is described. In an example, an attenuator can be configured to perform attenuation of signals for an integrated circuit. The attenuator can vary the attenuation with an ambient temperature. The attenuator can further adjust the attenuation based on a control signal applied to the attenuator. The control signal can be based on one or more of a temperature profile of the attenuator and a target gain variation of the integrated circuit.

A high-voltage power supply system including a high-voltage regulator, a function generator, and a triggering circuit. The high-voltage regulator includes a microcontroller, a digital-to-analog convertor in communication with the microcontroller, and a high-voltage DC-DC converter in communication with the digital-to-analog converter. The function generator includes a high-voltage inverter including one or more MOSFET switches. The high-voltage inverter is in communication with the microcontroller of the high-voltage regulator. The triggering circuit includes one or more high-voltage electromechanical switches.

A high-voltage power supply system including a high-voltage regulator, a function generator, and a triggering circuit. The high-voltage regulator includes a microcontroller, a digital-to-analog convertor in communication with the microcontroller, and a high-voltage DC-DC converter in communication with the digital-to-analog converter. The function generator includes a high-voltage inverter including one or more MOSFET switches. The high-voltage inverter is in communication with the microcontroller of the high-voltage regulator. The triggering circuit includes one or more high-voltage electromechanical switches.

A bias current generation circuit and a flash memory. The bias current generation circuit includes a voltage source, a switching circuit and a current generation circuit. The voltage source is configured to provide a voltage for generating a bias current. An input terminal of the switching circuit is connected to the voltage source, a control terminal of the switching circuit is configured to receive a control signal. The current generation circuit includes a first MOS transistor and a second MOS transistor, an input terminal and a control terminal of the first MOS transistor are connected to an output terminal of the switching circuit, an output terminal of the first MOS transistor is connected to an input terminal and a control terminal of the second MOS transistor, and an output terminal of the second MOS transistor is grounded.

Described is a new partial power converter (PPC) for the DC-DC stage of rapid-charging stations for electric vehicles (EV). The proposed converter manages only a fraction of the total power delivered from the grid to the battery, which increases the general efficiency of the system and the power density while potentially reducing the cost of the charger. The proposed topology is based on a switched capacitor between the AC terminals of a bridge converter H and does not require high-frequency isolation transformers in order to provide a source of controllable voltage between the CC link and the battery. The proposed concept can be implemented by using interposed power cells, which can improve energy quality, reduce the size of the inductor, and allow scalability for chargers of higher nominal power.

Techniques and mechanisms for generating an output voltage with a switched capacitor voltage converter (SCVR). In an embodiment, the SCVR comprises converter cores which are coupled in parallel via multiple buses including a first bus, which is to receive an input voltage, and a second bus with which the SCVR is to provide the output voltage based on the input voltage. A first converter core comprises a capacitor and a first hierarchical switch network (HSN) which is coupled between the capacitor and the multiple buses. The first HSN switchedly provides any of multiple conductive paths each between the capacitor and a different respective one of the multiple buses. Two or more of the conductive paths are each provided with at least one same switch circuit of the first HSN. In another embodiment, the first converter core comprises two HSNs which each have a respective branching tree topology.

Techniques and mechanisms for generating an output voltage with a switched capacitor voltage converter (SCVR). In an embodiment, the SCVR comprises converter cores which are coupled in parallel via multiple buses including a first bus, which is to receive an input voltage, and a second bus with which the SCVR is to provide the output voltage based on the input voltage. A first converter core comprises a capacitor and a first hierarchical switch network (HSN) which is coupled between the capacitor and the multiple buses. The first HSN switchedly provides any of multiple conductive paths each between the capacitor and a different respective one of the multiple buses. Two or more of the conductive paths are each provided with at least one same switch circuit of the first HSN. In another embodiment, the first converter core comprises two HSNs which each have a respective branching tree topology.

A bandgap voltage generator includes a plurality of calibration transistors. A test circuit measures the bandgap reference voltage generated by the bandgap voltage generator and enables a subset of the calibration transistors to correct to the bandgap reference voltage.

A discharge circuit for a diode reverse leakage current includes an input positive terminal, an input negative terminal, an output positive terminal coupled to the input positive terminal, an output negative terminal coupled to the input negative terminal, a diode and a current source device. The diode has an anode terminal coupled to the input positive terminal and a cathode terminal coupled to the output positive terminal. The current source device has a first end coupled to the anode terminal of the diode and a second end coupled between the input and output negative terminals. The voltage difference across the current source device is reduced by less than about 1 V when input voltage is switched off. The current source device continues to operate when the input voltage is normal. As P=VI, the loss is proportional to the input voltage, therefore achieving the objective of low loss.