Negative impedance converter

About: Negative impedance converter is a research topic. Over the lifetime, 5801 publications have been published within this topic receiving 87636 citations.

Bus Pre-Charge Control Using a Buck Converter

Abstract: A vehicle is disclosed having a traction battery and an electrical impedance connected by a contactor. A pre-charge circuit is disclosed that controls current flow from the traction battery through the pre-charge circuit to the electrical impedance to increase voltage at the electrical impedance such that as the voltage approaches a voltage of the traction battery, a duty cycle of the pre-charge circuit approaches a maximum value and a current through the pre-charge circuit approaches a minimum value. In response to current falling below a predetermined value, the contactor is closed. A current sensor is disclosed that is located in the pre-charge circuit. A method of operating the pre-charge circuit is disclosed.

Technique for limiting current through a reactive element in a voltage converter

Abstract: A current limiting technique for a voltage converter. A current through a reactive element in a voltage converter is limited. Current from a supply is switched through a reactive element in accordance with a switch control signal for forming a regulated output voltage in a feedback loop. A first signal that is representative of the input current is sensed. A voltage that is representative of the output voltage of the voltage converter is sensed. A second signal that is representative of a difference between the output voltage and a desired voltage is formed. A selected one of the first signal and the second signal is compared to a ramp signal for forming the switch control signal wherein the selected one of the first signal and the second signal is selected according to the relative magnitudes of the first and second signal.

CMOS high-speed differential to single-ended converter circuit

Abstract: A CMOS differential to single-ended converter is implemented. A differential input stage comprised of a pair of N-channel transistors draws current through two fixed current P-channel load transistors. A first N-channel differential transistor provides negative feedback bias control of a current source transistor coupled to the differential input stage. The negative feedback control provides increased current gain in the second N-channel transistor, which drives a CMOS inverter to a full rail-to-rail voltage swing on its output.

Isolated switching power supply apparatus

Abstract: A switching power supply apparatus includes a PFC converter, a DC-DC converter, and primary-side and secondary-side digital control circuits that control the PFC converter and the DC-DC converter On the basis of a voltage detected by an output voltage detection circuit, the primary-side digital control circuit transmits data about the on-time of a switching element of the DC-DC converter to the primary-side digital control circuit On the basis of this data, the primary-side digital control circuit controls the on-time of the switching element

Method of controlling a grid side converter of a wind turbine and system suitable therefore

Abstract: According to an embodiment of the present invention, a method of controlling a grid side converter of a wind turbine is provided, wherein an output of the grid side converter is connected or connectable via a power line to an input of a grid transformer, the method comprising: determining a converter volt-sec occurring at the output of the grid side converter based on a converter voltage occurring at the output of the grid side converter; determining a volt-sec error between the determined converter volt-sec and a converter volt-sec reference, wherein the converter volt-sec reference is determined based on active power reference, reactive power reference, line current and a line voltage occurring at the input of the grid transformer (or at wind turbine terminals); and controlling, based on the determined volt-sec error, the grid side converter such that the volt-sec error is partly or fully compensated. The method is capable of supporting the demanded power quality even during abnormal voltage conditions, and is easy to realize. The method can seamlessly transit from linear to non-linear region of converter operation.