Patent application number | Description | Published |
20110121762 | LED Mixture Control Device and Controlling Method Thereof - A light source mixture control device for controlling a light source emitting different spectrums is provided. A coordination conversion unit receives and converts a hue signal and a luminance signal into a first to a third undecoupled color light component. A first color light component decoupling control unit decouples a first color light component from the first to the third undecoupled color light component. A second color light component decoupling control unit decouples the first undecoupled color light component into a first decoupled color light component. A third color light component decoupling control unit decouples the second undecoupled color light component into a second decoupled color light component. A fourth color light component decoupling control unit decouples the third undecoupled color light component into a third decoupled color light component. The first to the third decoupled color light component respectively control the light source. | 05-26-2011 |
20110205762 | INTEGRATED-TYPE HIGH STEP-UP RATIO DC-AC CONVERSION CIRCUIT WITH AUXILIARY STEP-UP CIRCUIT - An integrated-type high step-up ratio DC-AC conversion circuit with an auxiliary step-up circuit applies to converting a low DC voltage of alternative energy into a high AC voltage. The conversion circuit uses an isolated Cuk integration unit and an auxiliary step-up unit to form a multi-phase input and uses parallel charging and cascade discharging to boost the DC voltage in the DC side with a low voltage power switches and low duty cycle and then converts the boosted DC voltage into AC voltage. The auxiliary step-up unit not only shares the entirety of power but also exempts the DC-side circuit from using high voltage power switches, whereby the cost of elements is reduced. Further, the conversion circuit can decrease the switching loss and conduction loss of the DC-side switches and promote the efficiency of the circuit. | 08-25-2011 |
20120249100 | HIGH BOOST RATIO DC CONVERTER - Disclosed is a high boost ratio DC converter, wherein the first and second switches are controlled by a control chip and the control chip controls the first and second switches in the following sequence: the first and second switches both conduct; the first switch conducts and the second switch is cut off; the first and second switches both conduct; the first switch is cut off and the second switch conducts thus making a first and second inductors and a first and second clamp capacitors charge to a first and second output capacitors. Then the first and second output capacitors discharge a load. Therefore, the load voltage output from the DC power supply will be boosted owing to the discharged load from the first and second output capacitors. The boost ratio is 4/(1−D). | 10-04-2012 |
20130169176 | NON-ISOLATED AC/DC CONVERTER WITH POWER FACTOR CORRECTION - A non-isolated AC/DC converter having power factor correction, comprising an active switch connected to a waveform controller for control, and sequentially showing conduction, cut off, making the alternating current power supply pass through one circuit rectifier for rectifying and forming one positive half sine wave electricity supply, which passes through a voltage step-down circuit to proceed with decreasing the voltage, then passing through a filter/storage circuit for filtering and forming direct current power supply, which is stored on this filter/storage circuit, then releasing the energy and supplying electricity to the electricity end; as a transformer isn't required, the circuit volume can be reduced, lowering costs, raising circuit conversion rates and achieving power factor correction and increasing the lifespan of the transformer, moreover, through the waveform controller controlling the output waveform, the storage circuit utilizes a lower capacity capacitor to avoid using an electrolytic capacitor, thereby increasing the circuits lifespan. | 07-04-2013 |
20130170266 | TWO-STAGE ISOLATED DC/AC CONVERSION CIRCUIT STRUCTURE - A two-stage isolated DC/AC conversion circuit structure, consisting of a main switch, a second switch attached to a controller, another controller for controlling, and in work mode 1 and 2, after passing through the capacitor filter the low frequency half sine wave power is stored on this capacitor. After an inductor outputs the low frequency half sine wave power through this capacitor filter, it can respectively pass through the first and second transformers to increase the voltage, and then pass through the first and second secondary diode rectifiers, outputting the positive and negative half waves AC to the end user, and allow the end user to obtain the whole wave of the AC. Using the first and second diodes prevents outputting in reverse, and has the effect of isolation, and prevents all the stored energy for the later stage end user recharging to the front stage DC/AC conversion circuit. | 07-04-2013 |
20130250637 | Single-Stage Single-Switch Voltage Converter - The present invention is a single-stage voltage converter. With only one switch, a higher DC (direct current) voltage at input end is converted into a lower DC voltage at output end. Thus, a lower-voltage load is provided with the lower DC voltage. The present invention is characterized in power factor correction and high step down voltage ratio. The present invention can be applied to multiple DC pairs. | 09-26-2013 |
20140056046 | PASSIVE POWER FACTOR CORRECTION CIRCUIT, ELECTRONIC DEVICE APPLYING THE SAME AND OPERATION METHODS THEREOF - A passive power factor correction circuit includes: a DC capacitor and an input capacitor, coupled to a rectifying circuit and charged by a DC voltage from the rectifying circuit; an output capacitor, coupled to a load; first diode and a second diode, coupled to the input capacitor and the output capacitor; and an inductor, coupled to the load, the input capacitor and the output capacitor. Charging into and discharging from the DC capacitor are completed within a half cycle of an input AC voltage. | 02-27-2014 |
20140092662 | DC TO AC CONVERSION CIRCUIT - A DC to AC conversion circuit including an inverter, a first inductor, a first capacitor, a second inductor and a second capacitor is provided. The inverter has two input contact points and two output contact points. The input contact points receive a DC signal, and the output contact points output an AC signal. The first terminal of the first inductor is coupled to one of the two output contact points. The first capacitor is coupled to the first inductor in parallel. The first terminal of the second capacitor is coupled to the second terminal of the first inductor, and the second terminal of the second capacitor is coupled to another one of two output contact points. The first terminal of the second inductor is coupled to the first terminal of the second capacitor, and the second terminal of the second inductor is coupled to a load. | 04-03-2014 |
20140104893 | ISOLATED INTERLEAVED DC CONVERTER - An isolated interleaved DC converter has a main circuit architecture integrating a transformer, a dual-phase interleaved step-up circuit, a voltage type auto charge pump circuit with a double-voltage rectifier circuit. The circuit of the invention integrates with the transformer, and combines the dual-phase interleaved boost circuit and the voltage type auto charge pump circuit at a primary side of the transformer to reduce the input current ripple. At a secondary side of the transformer, the circuit of the invention further combines the double-voltage rectifier circuit. The active switching elements can be further integrated in the dual-phase interleaved boost circuit to realize the soft switching technology while reducing EMI and the switching loss and increasing the circuit conversion efficiency. | 04-17-2014 |
20140112026 | RESONANT DC CONVERTER - A resonant DC converter, combines a voltage type auto charge pump circuit with a full-bridge or half-bridge resonant DC conversion circuit at a primary side of a transformer, combines a double-voltage rectifier circuit at a secondary side of the transformer, and grants the circuit of the invention with characteristics of variable circuit architecture by means of the design of circuit parameters and the action of the LC resonant circuit. Integration of switching elements of the converter circuit and the use of characteristics of automatically changing the circuit architecture contribute to reduce the switching losses and increase the circuit conversion efficiency. Low output voltage ripple enables the circuit of the invention to avoid using large-capacitance electrolytic capacitors and be able to extend the service life of the transformer. The operation of the circuit of the invention at boost or buck mode can be controlled by adjusting the circuit parameters. | 04-24-2014 |
20140132231 | DC Conversion Circuit - A DC conversion circuit in the disclosure includes a buck-boost converter and a resonant stage circuit. The buck-boost converter has two input ends, a negative output end and a positive output end. The buck-boost converter receives a first DC signal via its two input ends, and outputs a second DC signal via its two output ends. The resonant stage circuit has two input ends and two output ends. The resonant stage circuit receives the second DC signal via its two input ends, converts the second DC signal into energy for power charging, and outputs the energy to a load via its two output ends. Then, the resonant stage circuit converts the energy, which is used for power charging, to form a negative voltage by a resonance effect, and outputs the energy to the load via its two output ends. | 05-15-2014 |