Hybrid zero-voltage switching (ZVS) control for power inverters

The invention claimed is: 1. A power inverter combination, comprising: a half-bridge power inverter (power inverter) comprising at least one phase including a series connected first and second semiconductor power switch configured for receiving input power (Vin) from a power source having an intermediate node between said first and second semiconductor power switch providing an inductor current through an inductor, and a controller including input comparison circuitry receiving a measure of said inductor current having outputs coupled to first inputs of pulse width modulation (PWM) generation circuitry, and a predictive control block having an output coupled to second inputs of said PWM generation circuitry, wherein said predictive control block is coupled to receive a measure of a voltage provided by said Vin and of an output voltage at a grid connection point (Vo), and an associated memory which stores a current control algorithm configured for: whenever said inductor current reaches a predetermined upper or lower limit, resetting a PWM period of a switching signal applied to a control node of said first semiconductor power switch and said second semiconductor power switch, wherein a PWM pulse train is applied to said control node when said inductor current during a positive half cycle exceeds said predetermined lower limit, and said resetting said PWM period comprising resetting when said inductor current exceeds said predetermined lower limit during said positive half cycle and resetting when said inductor current exceeds said upper limit during a negative half cycle. 2. The power inverter combination of claim 1 , wherein said phase comprises a first, a second and a third phase so that said power inverter comprises a three-phase inverter. 3. The power inverter combination of claim 1 , wherein said controller is provided by a digital signal processor (DSP) chip or a microcontroller unit (MCU) chip and said input comparison circuitry comprises a comparator. 4. The power inverter combination of claim 1 , wherein said first and second semiconductor power switches comprise first and second metal-oxide semiconductor field-effect transistor (MOSFET) switches. 5. The power inverter combination of claim 1 , wherein said resetting of said PWM period of said switching signal utilizes a same shape waveform for both said positive half cycle and said negative half cycle. 6. The power inverter combination of claim 1 , wherein said current control algorithm is further configured for implementing dual zero-voltage switching (ZVS) zero-voltage switching (ZCS) current modulation which switches said first semiconductor power switch and said second semiconductor power switch of said power inverter between ZVS operation and ZCS operation during each half cycle. 7. A method of operating a power inverter, comprising: providing a half bridge power inverter (power inverter) comprising at least one phase including a series connected first and second semiconductor power switch configured for receiving input power (Vin) from a power source having an intermediate node between said first and second semiconductor power switch providing an inductor current through an inductor, and using a controller including input comparison circuitry receiving said inductor current from said phase having outputs coupled to first inputs of pulse width modulation (PWM) generation circuitry, and a predictive control block having an output coupled to second inputs of said PWM generation circuitry, wherein said predictive control block is coupled to receive a measure of a voltage provided by said Vin and of an output voltage at a grid connection point (Vo), and an associated memory which stores a current control algorithm configured for: whenever said inductor current reaches a predetermined upper limit or a predetermined lower limit, resetting a PWM period of a switching signal coupled to control nodes of said first and second semiconductor power switches, and wherein a PWM pulse train is applied to said control nodes when said inductor current during a positive half cycle exceeds said predetermined lower limit, and said resetting said PWM period comprising resetting when said inductor current exceeds said predetermined lower limit during said positive half cycle and resetting when said inductor current exceeds said upper limit during a negative half cycle. 8. The method of claim 7 , wherein said phase comprises a first, a second and a third phase so that said power inverter comprises a three-phase inverter. 9. The method of claim 7 , wherein said first and second semiconductor power switches comprise first and second metal-oxide semiconductor field-effect transistor (MOSFET) switches. 10. The method of claim 7 , wherein said resetting of said PWM period of said switching signal utilizes a same shape waveform for both said positive half cycle and said negative half cycle. 11. The method of claim 7 , wherein said current control algorithm is further configured for implementing dual zero-voltage switching (ZVS) zero-voltage switching (ZCS) Current Modulation which switches said first semiconductor power switch and said second semiconductor power switch of said power inverter between ZVS operation and ZCS operation during each half cycle. 12. The method of claim 7 , wherein said PWM period of said switching signal is reset whenever said inductor current reaches said predetermined upper limit and said predetermined lower limit.