An electronic circuit is provided. The electronic circuit includes a full-bridge rectifier, a spurious tone detection circuit, and a controller. The rectifier circuit has a plurality of switching elements and first and second radio frequency (RF) terminals. The spurious tone detection circuit has a non-linear circuit element and is coupled between the first RF terminal and a first reference terminal. The spurious tone detection circuit provides a non-zero direct current (DC) voltage in response to detecting harmonic tones at the first RF terminal of the full-bridge rectifier circuit. The controller is coupled to the plurality of switching elements. The controller is for controlling the operation of the plurality of switching elements based at least in part on detecting the harmonic tones. In one embodiment, the electronic circuit may be a wireless charging receiver. In another embodiment, a method for detecting harmonic tones in the electronic device is provided.

An electronic circuit is provided. The electronic circuit includes a full-bridge rectifier, a spurious tone detection circuit, and a controller. The rectifier circuit has a plurality of switching elements and first and second radio frequency (RF) terminals. The spurious tone detection circuit has a non-linear circuit element and is coupled between the first RF terminal and a first reference terminal. The spurious tone detection circuit provides a non-zero direct current (DC) voltage in response to detecting harmonic tones at the first RF terminal of the full-bridge rectifier circuit. The controller is coupled to the plurality of switching elements. The controller is for controlling the operation of the plurality of switching elements based at least in part on detecting the harmonic tones. In one embodiment, the electronic circuit may be a wireless charging receiver. In another embodiment, a method for detecting harmonic tones in the electronic device is provided.

An electronic circuit is provided. The electronic circuit includes a full-bridge rectifier, a spurious tone detection circuit, and a controller. The rectifier circuit has a plurality of switching elements and first and second radio frequency (RF) terminals. The spurious tone detection circuit has a non-linear circuit element and is coupled between the first RF terminal and a first reference terminal. The spurious tone detection circuit provides a non-zero direct current (DC) voltage in response to detecting harmonic tones at the first RF terminal of the full-bridge rectifier circuit. The controller is coupled to the plurality of switching elements. The controller is for controlling the operation of the plurality of switching elements based at least in part on detecting the harmonic tones. In one embodiment, the electronic circuit may be a wireless charging receiver. In another embodiment, a method for detecting harmonic tones in the electronic device is provided.

An electronic circuit is provided. The electronic circuit includes a full-bridge rectifier, a spurious tone detection circuit, and a controller. The rectifier circuit has a plurality of switching elements and first and second radio frequency (RF) terminals. The spurious tone detection circuit has a non-linear circuit element and is coupled between the first RF terminal and a first reference terminal. The spurious tone detection circuit provides a non-zero direct current (DC) voltage in response to detecting harmonic tones at the first RF terminal of the full-bridge rectifier circuit. The controller is coupled to the plurality of switching elements. The controller is for controlling the operation of the plurality of switching elements based at least in part on detecting the harmonic tones. In one embodiment, the electronic circuit may be a wireless charging receiver. In another embodiment, a method for detecting harmonic tones in the electronic device is provided.

A power converter includes: an inverter converting DC power to AC power and outputting the AC power to first and second voltage terminals of a connection terminal unit; and switches RC. The switches RC include a first protection switch provided to a first line connecting the inverter and the first voltage terminal together, a second protection switch provided to a second line connecting the inverter and the second voltage terminal together, and a voltage switch connected in series between the second line and a neutral terminal. A load connection terminal is connected to a line connecting between the first line and the voltage switch.

A power converter includes: an inverter converting DC power to AC power and outputting the AC power to first and second voltage terminals of a connection terminal unit; and switches RC. The switches RC include a first protection switch provided to a first line connecting the inverter and the first voltage terminal together, a second protection switch provided to a second line connecting the inverter and the second voltage terminal together, and a voltage switch connected in series between the second line and a neutral terminal. A load connection terminal is connected to a line connecting between the first line and the voltage switch.

A method is provided for operating a power generation system that supplies real and reactive power to a grid, the power generation system including a generator/power converter, and a reactive power compensation device. A total reactive power demand (Qcmd) made on the power generation system is determined , as well as a maximum reactive power capacity for each of a generator stator-side reactive power (Qs), a generator line-side reactive power (Ql), and reactive power from the reactive power compensation device (Qmvb). Allocation of (Qs), (Ql), and (Qmvb) to supply (Qcmd) is coordinated by prioritizing (Qmvb) as a first source of reactive power, and one or both of (Qs) and (Ql) as a second source of reactive power.

A method is provided for operating a power generation system that supplies real and reactive power to a grid, the power generation system including a generator/power converter, and a reactive power compensation device. A total reactive power demand (Qcmd) made on the power generation system is determined , as well as a maximum reactive power capacity for each of a generator stator-side reactive power (Qs), a generator line-side reactive power (Ql), and reactive power from the reactive power compensation device (Qmvb). Allocation of (Qs), (Ql), and (Qmvb) to supply (Qcmd) is coordinated by prioritizing (Qmvb) as a first source of reactive power, and one or both of (Qs) and (Ql) as a second source of reactive power.

According to one embodiment, a wireless communication device includes a first surface, a power storage unit, an antenna board, a circuit board, a wireless communication unit and a signal line. The power storage unit has a second surface located oppositely to the first surface. The antenna board implemented with an antenna faces the first surface. The circuit board faces the second surface of the power storage unit. The wireless communication unit is implemented to the circuit board and is located oppositely to a surface facing the power storage. The signal line connects the antenna board and the wireless communication unit.

In the field of gate drivers there is provided a regulated voltage source (10; 10A, 10B), for a gate driver (200; 300) of a switching device (18) having a gate terminal (26) via which the switching device (18) can at least be turned on. The regulated voltage source (10; 10A, 10B) comprises an input terminal (12) via which the regulated voltage source (10; 10A, 10B) in use receives current. The regulated voltage source (10; 10A, 10B) also includes first and second connection terminals (22, 24) via at least one of which the regulated voltage source (10; 10A, 10B) in use applies a voltage (V) to a gate terminal (26) of a switching device (18). In addition the regulated voltage source (10; 10A, 10B) includes a regulated energy storage stage (28) which is electrically connected between the input and output terminals (12, 22, 24) and which includes a primary energy storage device (30; 30A, 30B) connected in parallel with a storage limiter (34) to limit the amount of energy stored in the primary energy storage device (30; 30A, 30B). Between the primary energy storage device (30; 30A, 30B) and the storage limiter (34) lies an energy retainer (46) to prevent the escape of energy from the primary energy storage device (30; 30A, 30B) via the storage limiter (34). The regulated voltage source (10; 10A, 10B) further includes a freewheel diode (50) that is arranged in parallel with the energy storage stage (28) and a secondary energy storage device (52; 52A, 52B) which is arranged in parallel with each of the freewheel diode (50) and the energy storage stage (28).