Abstract: Whether a synchronous signal includes a synchronous pulse is determined by detecting whether there is a positive pulse higher than a positive threshold followed by a negative pulse lower than a negative threshold. The pulse signal detection method includes: comparing the synchronous signal with the positive threshold; comparing the synchronous signal with the negative threshold; and determining that the synchronous pulse exists when the positive pulse of the synchronous signal is higher than the positive threshold and the negative pulse of the synchronous signal is lower than the negative threshold in a post detection period after the positive pulse of the synchronous signal is determined higher than the positive threshold.

Abstract: A flyback power converter includes: a transformer, a primary side switch and a primary side controller circuit. The primary side controller circuit includes: a pulse modulation circuit and a protection control circuit. The pulse modulation circuit generates a pulse modulation signal. The protection control circuit is coupled to the pulse modulation circuit and compares an AC voltage related signal with an over voltage threshold. When the AC voltage related signal exceeds the over voltage threshold, the comparison circuit generates an over voltage protection trigger signal. When the pulse number of the over voltage protection trigger signal exceeds the over voltage counting threshold, the over voltage counter circuit triggers an over voltage protection signal, to indicate that an over voltage condition occurs, and a protection operation is performed.

Abstract: A metal oxide semiconductor (MOS) device includes: a semiconductor layer, an isolation structure, a well, a gate, a source, a drain, a first lightly doped region, and a second lightly doped region. The first lightly doped region is located right below a spacer layer and a portion of a dielectric layer of the gate. In a channel direction, the first lightly doped region is between and contacts the drain and an inversion current channel. The second lightly doped region includes a first part and a second part. The first part is located right below the spacer which is near the source, and the first part is between and contacts the source and the inversion current channel. The second part is located right below the spacer which is near the drain, and the second part is between and contacts the drain and the first lightly doped region.

Abstract: A high voltage MOS device includes: a well, a drift region, a gate, a source, a drain, and plural buried columns. A part of the gate is stacked on a part of the well, and another part of the gate is stacked on a part of the drift region. The source connects the well in a lateral direction. The drain connects the drift region in the lateral direction. The drain and the source are separated by the well and the drift region, and the drain and the source are located at different sides of the gate. The plural buried columns are formed beneath the top surface by a predetermined distance, and each buried column does not connect the top surface. At least a part of every buried column is surrounded by the drift region, and the buried columns and the drift region are arranged in an alternating manner.

Abstract: The present invention discloses a resonant wireless power transmitter circuit, which has an input impedance. The resonant wireless power transmitter circuit includes: a driver circuit coupled with a power supply, which includes at least a power switch; a switching resonant control circuit coupled with the driver circuit, such that the driver operates at a pre-determined or a variable resonant frequency; an adjustable impedance matching circuit coupled with the driver circuit, which includes at least a varactor; a transmitter circuit coupled with the impedance matching circuit and the driver circuit, which includes at least a transmitter coil; and an impedance control circuit coupled with the adjustable impedance matching circuit and the driver circuit, which provides an impedance control signal to control the reactance of the varactor, such that the input impedance of the resonant wireless power transmitter circuit is matched at the pre-determined or the variable resonant frequency.

Abstract: A power conversion apparatus for tracking maximum power point, includes: a signal processing circuit, which generates a sensing signal at a sensing node according to an input voltage; and a comparison circuit, which controls a converter circuit according to a difference between the sensing signal and a reference voltage, to convert the input voltage to an output power. The signal processing circuit includes: a bias sensing circuit, which generates the sensing signal at the sensing node according to the input voltage; and a clamp circuit coupled to the sensing node, for clamping the sensing signal to be not greater than a clamp voltage. The converter circuit adjusts an output voltage and/or an output current of the output power, so that a power retrieval source operates near its maximum power point.

Abstract: When a ramp signal intersects a feedback related signal, a constant time switching regulator enters a first state and maintains in the first state for a constant time, and after the constant time ends, when the ramp signal exceeds the feedback related signal, the switching regulator enters a second state, while when the ramp signal does not exceed the feedback related signal, the switching regulator enters a third state. In the first state, the first end of an inductor is connected to input voltage and the second end of the inductor is connected to output voltage; in the second state, the first end is connected to ground and the second end is connected to output voltage; and in the third state, the first end is connected to input voltage and the second end is connected to ground.

Abstract: A memory circuit includes a memory unit, a memory control circuit and a pseudo ground voltage generation circuit. The memory control circuit includes: a level shifter circuit coupled to a variable supply voltage; a driver circuit coupled to the pseudo ground voltage generation circuit at the pseudo ground node. The driver circuit is powered by the variable supply voltage and generates an access signal according to the driving signal, to access data from the memory unit. Under a high-voltage operation, the variable supply voltage provides a first supply voltage level, so that a high level of the access signal corresponds to the first supply voltage level and the pseudo ground voltage generation circuit provides a pseudo ground voltage level at the pseudo ground node. A voltage difference between the first supply voltage level and the pseudo ground voltage level is smaller than a withstand voltage of the driver circuit.

Abstract: A high voltage MOS device includes: a first drift region with a first conductive type, a body region with a second conductive type, plural second drift regions with the second conductive type, a gate, a source region with the first conductive type, a drain with the first conductive type, and a body contact region with the second conductive type. The plural second drift regions contact the body region along the lateral direction, and are located separately in the width direction. Any neighboring two second drift regions do not contact each other. Each of the second drift regions is separated from the drain by the first drift region.

Abstract: A high voltage MOS device includes: a well, a body region, a gate, a source, plural body contact regions and a drain. The plural body contact regions are formed in the body region, wherein each of the body contact region is located beneath the top surface and contacts the top surface in the vertical direction, and is in contact or not in contact with the gate in the lateral direction. The plural body contact regions are arranged substantially in parallel in the width direction and any two neighboring body contact regions are not in contact with each other in the width direction. The gate includes a poly-silicon layer which serves as the only electrical contact of the gate, and every part of the poly-silicon layer is the first conductivity type.

Abstract: A switching regulator includes a power stage circuit, an auxiliary winding, a start-up switch, and a power switch controller circuit. The power switch controller circuit includes a multifunction pin, a start-up controller circuit, and a feedback compensation circuit. The multifunction pin is coupled to a control terminal of the start-up switch, to deliver different signals with different functions under at least two different modes, respectively. The start-up controller circuit generates a start-up signal in a start-up mode, wherein the start-up signal is delivered to a control terminal of the start-up switch through the multifunction pin. An output terminal of the feedback compensation circuit is coupled to the multifunction pin, to provide a compensation signal at the multifunction pin in an operation mode.

Abstract: The present invention provides a resonant wireless power transmitter circuit, including: a load circuit, a power conversion circuit which is coupled between an input power supply and the load circuit, and a phase detection and control circuit. The power conversion circuit includes plural power switches and a current sensing device. The plural power switches operate with an operating frequency to convert the input power supply to an output power for driving the load circuit, wherein the load circuit has a load current. The load current has a load current phase difference from the switching frequency. The phase detection and control circuit detects a voltage difference between the current inflow terminal and the current outflow terminal of the current sensing device within a dead time in which the plural power switches are not conductive. The voltage difference corresponds to the load current phase difference.

Abstract: The present invention provides a charging apparatus, a charging control circuit, and a charging control method. The charging apparatus includes a power conversion circuit for generating a DC output voltage and charging a battery by a DC output current, and a charging control circuit for controlling the power conversion circuit. When the DC output voltage or the battery voltage rises to a first reference threshold voltage, the DC output current is adjusted downward by a current down step, and when the DC output voltage or the battery voltage falls to a second reference threshold voltage, the DC output current is adjusted upward by a current up step.

Abstract: The present invention discloses a high voltage device and a manufacturing method thereof. The high voltage device is formed in a semiconductor substrate, and includes: a gate, a source, a drain, and at least one plug plate electrode. The plug plate electrode is in direct contact with the gate, and is electrically connected to the gate. The plug plate electrode extends downwards from the bottom of the gate to the semiconductor substrate, through a current vertical height of a conductive current when the high voltage is ON. The plug plate electrode is between the source and the drain in a lateral direction. The plug plate electrode includes a dielectric layer and a conductive layer.

Abstract: The present invention discloses a method for outputting a command by detecting a movement of an object, which includes the following steps. First, an image capturing device captures images generated by the movement of the object at different timings by. Next, a motion trajectory is calculated according to the plurality of images. Further next, a corresponding command is outputted according to the motion trajectory. The present invention also provides a system which employs the above-mentioned method.

Abstract: The invention provides a power device, which includes: an operation layer, including a top surface, a body region and a drift region, the body region and the drift region being connected in a lateral direction, to form a PN junction along a channel width direction between the body region and the drift region; a gate, formed on the top surface, and the PN junction is located under the gate; a source, formed in a portion of the operation layer between the body region and the top surface; a drain, formed in another portion of the operation layer between the drift region and the top surface; a first conduction portion, formed on the top surface for electrically connecting the source; a conduction layer, formed on the first conduction portion and electrically connected to the source via the first conduction portion; and a second conduction portion, formed on the top surface and between the conduction layer and the drift region in a thickness direction, for electrically connecting the drift region and the conductio

Abstract: The invention provides a bio-detection device, including a carrier, a plurality of spacers, an electronic circuit, and a package layer, wherein an open platform is formed. The carrier includes a test region and a signal transmission wiring, wherein the test region is configured to carry a fluid under test. The spacers are located on the test region and electrically connected to two different voltage levels to form a capacitor for sensing a capacitance of the fluid. The spacers are connected to the signal transmission wiring. The electronic circuit receives and processes a sensing signal corresponding to the capacitance of the fluid. The package layer covers a portion of the carrier but does not cover the test region. The open platform is formed whereby a user can easily put in the fluid. The open platform has a bottom which includes the test region, and an area of the open platform is defined by the spacers and the package layer.

Abstract: A switching power converter circuit includes a power switch for operating an inductor to convert the input voltage to the output voltage to drive a load circuit; and a control circuit, including: a pulse width modulation circuit comparing an output related signal with a ramp signal to generate a pulse width modulation signal for controlling the power switch, wherein the output related signal is related to the output voltage; an error amplifier circuit generating an error amplified signal according to a difference between the output related signal and a reference signal; and a ramp signal generation circuit generating the ramp signal, wherein an amplitude of the ramp signal is determined according to the input voltage and the output voltage; and/or the slope of the ramp signal is determined according to the error amplified signal.

Abstract: A transmission interface with noise reduction function includes a first circuit and a second circuit, for transmitting a signal from the first circuit to the second circuit or from the second circuit to the first circuit. The first circuit includes a first sub-winding and a first wire unit, and the second circuit includes a second sub-winding and a second wire unit. When an electromagnetic noise passes through the first sub-winding and the first wire unit, two loop currents are respectively generated, and the currents have opposite directions to cancel each other so as to reduce the electromagnetic noise. Or, when an emitting current corresponding to the signal flows through the first sub-winding and the first wire unit, two magnetic fields are respectively generated, and the magnetic fields have opposite directions to cancel each other so as to reduce the electromagnetic interference.

Abstract: The present invention provides a wireless power transmitter circuit which includes a power converter circuit, a power inverter circuit, a resonant transmitter circuit and a power control circuit. The power conversion circuit converts an input power to a conversion output power which includes a conversion output voltage. The power inverter circuit converts the conversion output power to an AC output power. The resonant transmitter circuit converts the AC output power to a resonant wireless power. The power control circuit generates a current reference signal according to the conversion output voltage, and generates a conversion control signal according to a difference between the current reference signal and a resonant current related signal, to control the power converter circuit such that the resonant wireless power is regulated substantially at a predetermined power level.