Patent application number | Description | Published |
20100115450 | COMBINABLE TABS FOR A TABBED DOCUMENT INTERFACE - A method and system for combining tabs of a tabbed document interface (“TDI”) is provided. A combinable TDI system allows tabs of a TDI to be combined to form a single tab of the TDI. To combine tabs, the combinable TDI system generates a combined tab name from the tab names of the tabs to be combined and combined tab content from the content of the tabs to be combined. If the width of the content is greater than what can be currently displayed in the window, the combinable TDI system may add a scroll bar to the TDI so that the user can scroll and make visible portions of the content that were previously not visible. The combinable TDI system then displays the combined tab and removes the tabs that have been combined. The combinable TDI system may also allow a user to split a combined tab into separate tabs. | 05-06-2010 |
20130139071 | PROXY FOR ASYNCHRONOUS MEETING PARTICIPATION - Embodiments described herein relate to enabling a lightweight way of recording and sharing video messages intended to provide input to a future meeting that cannot be personally attended. A person who cannot attend the meeting pre-records their thoughts and remarks for the meeting as video clips for presentation at the meeting. A physical device with at least a display is presented at the meeting. The physically present participants can play the pre-recorded clips on the device. Video of participants' responses to the clips is recorded and made available so that the represented attendee can view the participants' responses. | 05-30-2013 |
20140340208 | LOCALIZED KEY-CLICK FEEDBACK - Disclosed herein are techniques and systems for providing simulated, haptic feedback that is local to physical, non-actuating keys of a keyboard. A keyboard includes a plurality of non-actuating keys defined in a cover portion of the keyboard, a plurality of force-producing mechanisms coupled to a substrate underneath and adjacent the cover portion. The force-producing mechanisms may be positioned on suspended portions of the substrate that are mechanically isolated and arranged on the substrate to substantially correspond to a layout of the plurality of non-actuating keys. The force-producing mechanisms may be individually actuated to deflect the suspended portions of the substrate underneath the cover portion to create a tactile sensation for a user's finger that is local to a particular key. In some embodiments, the force-producing mechanisms are piezoelectric actuators. | 11-20-2014 |
20150237156 | LPC2468-BASED MVB-WTB GATEWAY AND WORKING METHOD THEREOF - The present invention discloses a LPC2468-based MVB-WTB gateway and associated operating methods in the field of train communications. The disclosed network gateway includes a MVB network card and a WTB network card. The WTB network card includes WTB-ARM and a WTB-FPGA module. The MVB network card includes MVB-ARM and MVB-FPGA module. The WTB-ARM module uses a LPC2468 processor to analyze data in the network layer and the data link layer based on gateway protocol. The WTB-FPGA module allows WTB to exchange data with other networks gateways, as well as between the WTB and MVB. The MVB-ARM module is responsible for executing protocols on the network cards. Via data communications on MVB, the MVB-FPGA module collects the process and message data of the MVB equipment, and exchange communication data between WTB within a network gateway. The present invention can increase speed and enhance reliability for communications between gateways. | 08-20-2015 |
20150261703 | PICOBLAZE-BASED MVB CONTROLLER - The present invention relates to the field of communications on rail trains. A PicoBlaze-based MVB controller includes a pMVB controller, a traffic memory, an ARM adapter, and a bus arbiter. The pMVB controller, the traffic memory, ARM adapter, and the bus arbiter are connected to an external bus BUS1. The pMVB controller is connected to the traffic memory. The ARM adapter is connected to an external ARM processor and the bus arbiter. The traffic memory can store network communication data and input control information, and send them to the pMVB controller. The pMVB controller responds to the control information, and sends the communication data, and after it is encoded, to the MVB bus via the external bus BUS1. The pMVB controller also decodes data received from the pMVB bus and triggers an interrupt. The bus arbiter is responsible for bus arbitration in accordance with the instructions from the pMVB controller. | 09-17-2015 |
20150311955 | WIRELESS CHARGING METHOD AND SYSTEM, AND MOBILE TERMINAL - The embodiments of the present application provide a wireless charging method and system, and a mobile terminal. The wireless charging method includes: activating a wireless charging function by a first mobile terminal and a second mobile terminal; determining that the first mobile terminal is a wireless charging sender, and the second mobile terminal is a wireless charging receiver; and performing a wireless charging on the second mobile terminal by the first mobile terminal. The embodiments of the present application solve the problem that the power is insufficient in emergency situations. In addition, the operation is simple and the usage limitations are reduced. | 10-29-2015 |
Patent application number | Description | Published |
20120265354 | CIRCUIT AND METHOD FOR MAXIMUM POWER POINT TRACKING OF SOLAR PANEL - The present invention relates to a maximum power point tracking circuit for a solar panel. In one embodiment, the circuit can include: a real-time power calculator that receives a real-time output voltage and a real-time output current of the solar panel, and generates a real-time power of the solar panel; a memory power generator coupled to the real-time power calculator, and that generates a memory power based on the real-time power; a comparing circuit that compares the real-time power against the memory power, where an output of the comparing circuit is configured to control a controlling signal for a solar power supply apparatus; and a reset circuit that receives the real-time output voltage of the solar panel, where an output of the reset circuit is configured to control the controlling signal. | 10-18-2012 |
20130163300 | BOOST POWER FACTOR CORRECTION CONTROLLER - The present invention relates to a power factor correction (PFC) controller. In one embodiment, a boost PFC controller configured in an AC/DC converter can include: (i) a conductive signal generator configured to receive a first sampling signal, and to generate a conductive signal according to the first sampling signal and a first control signal; (ii) a shutdown signal generator configured to compare a second control signal against a third control signal, and to generate a shutdown signal when the second control signal reaches a level of the third control signal; and (iii) a logic controller coupled to the conductive signal generator and the shutdown signal generator to control a switching state of a power switch in AC/DC converter. | 06-27-2013 |
20130181620 | MULTI-OUTPUT SELF-BALANCING POWER CIRCUIT - The present invention relates to a multi-output self-balancing power circuit. In one embodiment, a multi-output self-balancing power circuit can include: a transformer formed by a primary winding and n (e.g., greater than 2) series connected secondary windings; n output circuits corresponding to the n secondary windings, where each of the n output circuits can include a rectifier diode and a filter capacitor, and a load can be parallel coupled with the filter capacitor; n output circuits series coupled between a first output terminal of a first secondary winding and a second output terminal of an n | 07-18-2013 |
20130207560 | MULTI-OUTPUT CURRENT-BALANCING CIRCUIT - The present invention relates to a multi-output current-balancing circuit, which in one embodiment can include: (i) a transformer having a primary winding and a plurality of secondary windings, where the primary winding receives an AC input current; (ii) a plurality of first and second rectifier circuits and a plurality of first current balancing components, where each of the first and second rectifier circuits and the first current balancing components is coupled to a corresponding secondary winding, where each the first current balancing component is configured for current balancing between each of the first and second rectifier circuits of the corresponding secondary winding; and (iii) at least one second current balancing component, where each second current balancing component is coupled to a pair of the second rectifier circuits that correspond to different secondary windings, where the second current balancing components are configured for current balancing between different the secondary windings. | 08-15-2013 |
20130223119 | BOOST PFC CONTROLLER - The present invention pertains to a boost power factor correction (PFC) controller. In one embodiment, a boost PFC controller for an AC/DC converter can include: an off signal generator that compares an inductor current sample signal against a first control signal, where the inductor current sample signal increases during an on time of a power switch of the AC/DC converter, and the off signal generator generates an off signal when the inductor current sample signal reaches the first control signal level; and an on signal generator that compares a second control signal against a third control signal, where the second control signal increases during the off time of the power switch, and the on signal generator generates an on signal when the second control signal reaches the third control signal level. | 08-29-2013 |
20140043866 | HIGH EFFICIENCY AND LOW LOSS AC-DC POWER SUPPLY CIRCUIT AND CONTROL METHOD - Disclosed herein are high efficiency, low loss AC-DC power supply circuits, and associated control methods. In one embodiment, an AC-DC power supply circuit can include: (i) a rectifier configured to rectify an AC power supply to generate a DC input voltage; (ii) a first stage voltage converter configured to convert the DC input voltage to a first output voltage, and to convert a first control signal to a feedback signal that represents the first output voltage; and (iii) a second stage voltage converter configured to convert the first output voltage to a constant DC output signal, where the first control signal represents a duty cycle of the second stage voltage converter. | 02-13-2014 |
20140055168 | SOURCE-ELECTRODE DRIVING CONTROL CIRCUIT AND CONTROL METHOD THEREOF - Disclosed are driving control methods and circuits for quasi-resonant control of a main power switch of a switching power supply. In one embodiment, a driving control circuit can include: (i) a clamp circuit coupled to a gate of the main power switch, where the clamp circuit is configured to clamp a voltage of the gate to a clamping voltage that is greater than a threshold voltage of the main power switch; (ii) a valley voltage detection circuit configured to activate a valley control signal when a drain-source voltage of the main power switch is at a resonance valley level; and (iii) a source voltage control circuit configured to reduce a voltage of a source of the main power switch to turn on the main power switch in response to the valley control signal being activated. | 02-27-2014 |
20140078788 | SYNCHRONOUS RECTIFYING CONTROL METHOD AND CIRCUIT FOR ISOLATED SWITCHING POWER SUPPLY - Disclosed are synchronous rectifying control methods and circuits for an isolated switching power supply. In one embodiment, a method can include: (i) generating a ramp voltage based on a power terminal voltage, where the power terminal voltage includes a voltage between first and second power terminals of a synchronous rectifier in the isolated switching power supply; (ii) determining whether the power terminal voltage starts declining; (iii) comparing the ramp voltage to a threshold voltage when the power terminal voltage starts to decline, where the threshold voltage substantially matches a minimum conduction time of the synchronous rectifier; (iv) reducing the ramp voltage and controlling the synchronous rectifier in an off state when the ramp voltage is lower than the threshold voltage; and (v) reducing the ramp voltage and controlling the synchronous rectifier in on state when the ramp voltage is higher than the threshold voltage. | 03-20-2014 |
20140152239 | SELF-ADAPTIVE INPUT POWER CHARGER AND METHOD FOR CONTROLLING INPUT CURRENT OF CHARGER - Disclosed herein are circuits and methods for limiting a charger input current. In one embodiment, a self-adaptive input power charger for charging a battery, can include: (i) a power stage circuit configured to receive an external input power supply that supplies an input voltage and an input current to the charger; (ii) a comparison circuit configured to generate a comparison result indicating that the input power supply has entered a current-limiting state when the input voltage is less than a first reference voltage; (iii) a current regulation circuit configured to generate a first control signal in response to the comparison result; and (iv) a driving control circuit configured to limit the input current by the first control signal. | 06-05-2014 |
20140159605 | AC-DC POWER CONVERTER - In one embodiment, an AC-DC power converter can include: (i) a rectifier bridge and filter to convert an external AC voltage to a DC input voltage; (ii) a first energy storage element to store energy from the DC input voltage via a first current through a first conductive path when in a first operation mode; (iii) a second energy storage element configured to store energy from a second DC voltage via a second current through a second conductive path when in the first operation mode; (iv) a transistor configured to share the first and second conductive paths; (v) the first energy storage element releasing energy to a third energy storage element and a load through a third conductive path when in a second operation mode; and (vi) the second energy storage element releasing energy to the load through a fourth conductive path during the second operation mode. | 06-12-2014 |
20140176107 | FAST RESPONSE CONTROL CIRCUIT AND CONTROL METHOD THEREOF - In one embodiment, a control circuit configured to control a switch mode power supply, can include: (i) a compensation signal generating circuit configured to generate a compensation signal according to an error between an output voltage feedback signal and a first reference voltage of the switch mode power supply; (ii) a switching signal generating circuit configured to control a switching operation of a power switching device of the switch mode power supply according to the compensation signal; (iii) a judge circuit configured to determine an operation state of the switch mode power supply according to the output voltage feedback signal; and (iv) a loop gain regulating circuit configured to regulate a loop gain of the control circuit according to the operation state. | 06-26-2014 |
20140203719 | MULTI-OUTPUT CURRENT-BALANCING CIRCUIT - The present invention relates to a multi-output current-balancing circuit, which in one embodiment can include: (i) a transformer having a primary winding and a plurality of secondary windings, where the primary winding receives an AC input current; (ii) a plurality of first and second rectifier circuits and a plurality of first current balancing components, where each of the first and second rectifier circuits and the first current balancing components is coupled to a corresponding secondary winding, where each the first current balancing component is configured for current balancing between each of the first and second rectifier circuits of the corresponding secondary winding; and (iii) at least one second current balancing component, where each second current balancing component is coupled to a pair of the second rectifier circuits that correspond to different secondary windings, where the second current balancing components are configured for current balancing between different the secondary windings. | 07-24-2014 |
20140203763 | STEP-UP BATTERY CHARGING MANAGEMENT SYSTEM AND CONTROL METHOD THEREOF - In one embodiment, a battery charger can include: (i) a step-up converter configured to generate an output signal by boosting a DC input voltage, where a threshold voltage is greater than the DC input voltage; (ii) a charging control circuit configured to receive the output signal from the step-up converter, and to control charging of a battery; (iii) the charging control circuit being configured to regulate the output signal to maintain a charging current for the battery charging as a trickle current when a battery voltage is less than the threshold voltage; and (iv) the charging control circuit being configured to charge the battery directly by the output signal when the battery voltage is greater than the threshold voltage. | 07-24-2014 |
20140207977 | USB DEVICE AND CONTROL METHOD THEREOF - In one embodiment, a universal serial bus (USB) device can include: (i) an interface module having a power supply port, a ground port, and first and second data ports, where the interface module is configured to connect to corresponding ports of a USB host at a USB interface; (ii) a property identification module coupled to the first and second data ports, where the property identification module is configured to determine properties of the USB interface; (iii) a data transmission module configured to exchange data between the USB device and the USB host according to the determined properties; and (iv) a charging module coupled to the power supply port and the ground port, where the charging module is configured to charge the USB device based on the determined properties. | 07-24-2014 |
20140292290 | SOURCE-ELECTRODE DRIVING CONTROL CIRCUIT AND CONTROL METHOD THEREOF - Disclosed are driving control methods and circuits for quasi-resonant control of a main power switch of a switching power supply. In one embodiment, a driving control circuit can include: (i) a clamp circuit coupled to a gate of the main power switch, where the clamp circuit is configured to clamp a voltage of the gate to a clamping voltage that is greater than a threshold voltage of the main power switch; (ii) a valley voltage detection circuit configured to activate a valley control signal when a drain-source voltage of the main power switch is at a resonance valley level; and (iii) a source voltage control circuit configured to reduce a voltage of a source of the main power switch to turn on the main power switch in response to the valley control signal being activated. | 10-02-2014 |
20140306677 | CURRENT DETECTION CIRCUIT AND SWITCHING REGULATOR THEREOF - In one embodiment, a current detection circuit configured for a switching regulator can include: (i) a feedback controlling circuit configured to control a feedback signal to be consistent with a reference signal, and to generate a feedback control signal; and (ii) a feedback signal generator configured to receive a rise time and a fall time of inductor current of the switching regulator, and to generate the feedback signal in direct proportion with the feedback control signal. | 10-16-2014 |
20140355312 | ISOLATED POWER SUPPLY, CONTROL SIGNAL TRANSMISSION CIRCUIT AND METHOD THEREOF - In one embodiment, method of generating a control signal for an isolated power supply, can include: (i) generating a first ground noise component with a first predetermined proportionality to a ground noise signal; (ii) generating a first peak signal based on a first control signal having the ground noise signal, where the first peak signal comprises a second ground noise component with a second predetermined proportionality to the ground noise signal; (iii) generating a second control signal based on a difference between the first peak signal and the first ground noise component; and (iv) controlling, by the second control signal, a switch of the isolated power supply. | 12-04-2014 |
20150077072 | CONTROL CIRCUIT OF INTERLEAVED SWITCHING POWER SUPPLY AND CONTROL METHOD THEREOF - In one embodiment, a control circuit configured for an interleaved switching power supply, can include: (i) a feedback compensation signal generation circuit configured to sample an output voltage of the interleaved switching power supply, and to generate a feedback compensation signal; (ii) a first switch control circuit configured to compare a first branch voltage signal that represents an inductor current of a first voltage regulation circuit against the feedback compensation signal, where when the first branch voltage signal is consistent with the feedback compensation signal, a first switch on signal is generated to control a first main power switch of the first voltage regulation circuit to be on for a predetermined time, and then off; and (iii) a second switch control circuit configured to compare a second branch voltage signal that represents an inductor current of a second voltage regulation circuit against the feedback compensation signal. | 03-19-2015 |
20150077073 | CONTROL CIRCUIT OF INTERLEAVED SWITCHING POWER SUPPLY - In one embodiment, a control circuit configured for an interleaved switching power supply having first and second voltage conversion circuits, can include: a feedback compensation signal generation circuit that generates a feedback compensation signal; a first power switch control circuit that activates a first on signal when a first voltage signal that represents an inductor current of the first voltage conversion circuit is less than the feedback compensation signal, a first power switch of the first voltage conversion circuit being turned on based on the first on signal, and turned off after a predetermined time; and a second power switch control circuit that activates a second on signal after half of a switching period from a rising edge of the first on signal, and a second power switch control signal to turn on a second power switch of the second voltage conversion circuit based on the second on signal. | 03-19-2015 |
20150091455 | LED DRIVER - A LED driver is disclosed herein. In one embodiment, the LED driver comprises a rectifier circuit, a driving current generating circuit, a bus voltage detection circuit, a LED configuration control circuit, and a LED array. The LED driver according to the present disclosure reconfigures the prior LED array, balances usage of each LED by switching operation of each LED, which results in long lifetime of the LED driver while reducing power dissipation or increasing a PF value. | 04-02-2015 |
20150115814 | PULSE CURRENT LED DRIVING CIRCUIT - In one embodiment, a pulse current light-emitting diode (LED) driving circuit, can include: (i) an AC power supply configured to generate an AC input; (ii) a rectifier circuit that receives the AC input voltage, and generates a DC input voltage; (iii) a sampling circuit that receives the DC input voltage, and generates a DC sense voltage; (iv) a comparison circuit that receives the DC sense voltage, and generates a first comparison signal; (v) a feedback compensating circuit that samples a current that flows through a transistor, and generates a compensation signal; (vi) a signal processing circuit that receives the first comparison signal and the compensation signal, and generates an on signal; and (vii) the transistor having a gate configured to receive the on signal, a drain configured to receive the DC input voltage, and a source coupled to a first terminal of a sampling resistor. | 04-30-2015 |
20150115917 | CONTROL CIRCUIT FOR INTERLEAVED SWITCHING POWER SUPPLY - In one embodiment, a control circuit configured for an interleaved switching power supply, can include: (i) a feedback compensation signal generation circuit configured to sample an output voltage of the interleaved switching power supply, and to generate a feedback compensation signal; (ii) a first switch control circuit configured to compare a voltage signal indicative of an inductor current in the first voltage regulation circuit against the feedback compensation signal, and to control a first main power switch in the first voltage regulation circuit; and (iii) a second switch control circuit configured to turn on a second main power switch in the second voltage regulation circuit after half of a switching cycle after the first main power switch is turned on, and to regulate an on time of the second main power switch. | 04-30-2015 |
20150311720 | POWER SUPPLY INCLUDING BI-DIRECTIONAL DC CONVERTER AND CONTROL METHOD THEREOF - A power supply including a bi-directional DC converter and a control method thereof are disclosed herein. The power supply includes first to third terminals, first and second semiconductor switches and a mode switching means. The first terminal is electrically coupled to an external power source. The second terminal is electrically coupled to a load. The third terminal is electrically coupled to a battery. The first and second semiconductor switches are electrically coupled in series between the first and second terminals. The mode switching means is electrically coupled to the first semiconductor switch, the second semiconductor switch and a bi-directional DC converter, respectively. The bi-directional DC converter is further electrically coupled to an intermediate node between the first semiconductor switch and the second semiconductor switch, and to the third terminal. The bi-directional power supply is operative to switch between a first operating mode in which the battery is charged and a second operating mode in which the battery supplies power to the load. In the power supply, the mode switching means operates the first and second semiconductor switches so that a single chip has both the function of charging and the function of supplying power. | 10-29-2015 |
20150357839 | ELECTRONIC CIGARETTE AND INTEGRATED CIRCUIT THEREFOR - The present disclosure relates to an electronic cigarette and an integrated circuit therefor. The integrated circuit incorporates a bi-directional control scheme for a charging process of a rechargeable battery and a discharging process of the rechargeable battery, and includes power devices used in both the processes. Thus, the integrated circuit has less semiconductor devices and lowered manufacturer cost. The integrated circuit has a temperature detection function for providing overheat protection of the system so that it operates in a safe temperature range. The integrated circuit also has a battery current-limiting function for limiting an output current of the rechargeable battery and protecting the same. The integrated circuit further has a short-circuit protection function for limiting an output current of the integrated circuit when the output current is too large and protecting the system. | 12-10-2015 |
20150365004 | AC-DC POWER CONVERTER - In one embodiment, an AC-DC power converter can include: (i) a rectifier bridge and filter to convert an external AC voltage to a DC input voltage; (ii) a first energy storage element to store energy from the DC input voltage via a first current through a first conductive path when in a first operation mode; (iii) a second energy storage element configured to store energy from a second DC voltage via a second current through a second conductive path when in the first operation mode; (iv) a transistor configured to share the first and second conductive paths; (v) the first energy storage element releasing energy to a third energy storage element and a load through a third conductive path when in a second operation mode; and (vi) the second energy storage element releasing energy to the load through a fourth conductive path during the second operation mode. | 12-17-2015 |
20150380944 | POWER SUPPLY DEVICE, INTEGRATED CIRCUIT, ENERGY TRANSMITTER AND IMPEDANCE MATCHING METHOD - A resonance contactless power supply device can include: (i) a converter configured to convert an input power signal to an adjustable DC voltage; (ii) an inverter configured to receive the adjustable DC voltage, and to generate an AC voltage with a leakage inductance resonance frequency; (iii) a first resonance circuit having a transmitting coil, and being configured to receive the AC voltage from the inverter; (iv) a second resonance circuit comprising a receiving coil that is contactlessly coupled to the transmitting coil, where the second resonance circuit is configured to receive electric energy from the transmitting coil; and (v) a control circuit configured to control the adjustable DC voltage according to a phase difference between the AC voltage and an AC current output by the inverter, such that the phase difference is maintained as a predetermined angle. | 12-31-2015 |
20160056657 | CHARGE AND DISCHARGE MANAGEMENT SYSTEM AND MOVABLE POWER SOURCE USING THE SAME - An apparatus can include: (i) a first switch coupled to an external interface and an inductor; (ii) a second switch coupled to ground and a common node between the first switch and the inductor; (ii) a third switch coupled to ground and a common node between the inductor and a fourth switch, where the inductor and first, second, third, and fourth switches form a power converter; (iii) a charge and discharge control circuit coupled to the power converter, and being configured to control the first, second, third, and fourth switches; and (iv) a chargeable battery coupled to the fourth switch, where the power converter is configured to provide a current to the battery when the external interface is coupled to an external power supply, and where the power converter is configured to provide a current to a load when the external interface is coupled to the load. | 02-25-2016 |