Disclosed is a device for detecting an output current of an inverter. The device for detecting an output current of an inverter according to the present disclosure includes a shunt resistor connected to an output end of a capacitor of a direct current (DC) link; a detector connected to the shunt resistor and configured to detect the output current; and a controller configured to control a sampling timing of a current in the detector.

Disclosed is a device for detecting an output current of an inverter. The device for detecting an output current of an inverter according to the present disclosure includes a shunt resistor connected to an output end of a capacitor of a direct current (DC) link; a detector connected to the shunt resistor and configured to detect the output current; and a controller configured to control a sampling timing of a current in the detector.

A power conversion circuit is provided. A power level of the power conversion circuit is determined by taking a first sample of a voltage potential of a resonant capacitor at a first time. A second sample of the voltage potential of the resonant capacitor voltage is taken at a second time. An electric current is determined based on the first sample and second sample.

To reduce switching losses, an inverter circuitry of this disclosure may operate using triangular current mode (TCM) control for the semiconductor devices to achieve zero voltage switching (ZVS) at the turn-on of the semiconductor switches. In contrast to other techniques, such as operating the inverter circuitry in continuous conduction mode (CCM), switching devices experience hard switching (usually associated to body-diode hard commutation) at turn-on, and therefore experience the associated switching losses. The inverter circuitry of this disclosure is controlled by processing circuitry, which is configured to apply a smart frequency modulation scheme that enables TCM operation.

To reduce switching losses, an inverter circuitry of this disclosure may operate using triangular current mode (TCM) control for the semiconductor devices to achieve zero voltage switching (ZVS) at the turn-on of the semiconductor switches. In contrast to other techniques, such as operating the inverter circuitry in continuous conduction mode (CCM), switching devices experience hard switching (usually associated to body-diode hard commutation) at turn-on, and therefore experience the associated switching losses. The inverter circuitry of this disclosure is controlled by processing circuitry, which is configured to apply a smart frequency modulation scheme that enables TCM operation.

A method is described for the pulse-width-modulated control of switching elements of a pulse-controlled inverter, the impulses of successive signal periods of the control signal, in a first control mode, respectively having a uniform start or end time within the signal period, or being situated uniformly centered in the middle of the signal period, and the impulses of successive signal periods of the control signal, in a second control mode, being situated alternately at the beginning of the signal period and at the end of the signal period.

A method is described for the pulse-width-modulated control of switching elements of a pulse-controlled inverter, the impulses of successive signal periods of the control signal, in a first control mode, respectively having a uniform start or end time within the signal period, or being situated uniformly centered in the middle of the signal period, and the impulses of successive signal periods of the control signal, in a second control mode, being situated alternately at the beginning of the signal period and at the end of the signal period.

To reduce switching losses, an inverter circuitry of this disclosure may operate using triangular current mode (TCM) control for the semiconductor devices to achieve zero voltage switching (ZVS) at the turn-on of the semiconductor switches. In contrast to other techniques, such as operating the inverter circuitry in continuous conduction mode (CCM), switching devices experience hard switching (usually associated to body-diode hard commutation) at turn-on, and therefore experience the associated switching losses. The inverter circuitry of this disclosure is controlled by processing circuitry, which is configured to apply a smart frequency modulation scheme that enables TCM operation.