46th week of 2015 patent applcation highlights part 62 |
Patent application number | Title | Published |
20150326023 | ELECTRICAL LOAD MANAGEMENT - Methods, systems, and apparatus, including computer programs encoded on computer storage media, for electrical load management. One of the systems includes a first electrical grid, one or more power sources coupled to the first electrical grid, a second electrical grid coupled to the first electrical grid by a power conversion system, one or more loads coupled to the second electrical grid, and one or more load control systems coupled to the one or more loads. A grid control system is configured to receive source information from the first electrical grid and send load instructions to the load control systems based on the source information. | 2015-11-12 |
20150326024 | Systems and Methods for Device and Power Receiver Pairing - Various exemplary embodiments of the present disclosure describe systems and methods for pairing electronic devices with wireless power receivers. The described systems include one or more wireless power transmitters, one or more wireless power receivers and one or more electronic devices. Electronic devices may be able to communicate with wireless power transmitters and wireless power receivers using suitable communications channels. The disclosed systems are capable of associating an electronic device with a wireless power receiver when the wireless power receiver is in close proximity or attached to the electronic device for a suitable period of time. | 2015-11-12 |
20150326025 | System and Method for Controlling Communication Between Wireless Power Transmitter Managers - A method for controlling communication between wireless power transmitter managers is disclosed. According to some aspects of this embodiment, wireless power transmission system may include one or more wireless power transmitter managers and one or more wireless power receivers for powering various customer devices. A WiFi connection may be established between wireless power transmitter managers to share information between system devices. Wireless power transmitter manager may need to fulfill two conditions to control power transfer over a customer device; customer device's signal strength threshold has to be significantly greater than 50%, such as 55% or more of the signal strength measured by all other wireless power transmitter managers and has to remain significantly greater than 50% for a minimum amount of time. | 2015-11-12 |
20150326026 | WIRELESS SOUND POWERING OF ELECTRONIC DEVICES WITH SELECTIVE DELIVERY RANGE - The present disclosure describes a methodology for wireless sound power transmission based on pocket-forming. This methodology may include one transmitter and at least one or more receivers, being the transmitter the sender of energy and the receiver connected to an electronic device that is desired to charge or power. The transmitters power devices within a predefined range. This configuration may be beneficial in retail store settings where improved interactivity between users and devices is required. In addition, the configuration provides a safety feature to avoid unauthorized usage of electronic devices. A variation of this configuration is given in an academic setting where electronic devices utilized for learning are required to stay within school premises. | 2015-11-12 |
20150326027 | WIRELESS SOUND CHARGING AND POWERING OF HEALTHCARE GADGETS AND SENSORS - The present disclosure provides wireless charging and powering methods for healthcare gadgets and wireless sensors. The method may include wireless power transmission through suitable techniques such as pocket-forming. The methods may include one or more transmitters and one or more receivers. In some embodiments the transmitters and receivers may be embedded to medical devices and wireless sensors, respectively. In other embodiments, the receiver may be integrated into wireless sensors. In yet another embodiment, the transmitters may be positioned on strategic places so as to have a wider range for wireless power transmission to portable electronic medical devices and wireless sensors. | 2015-11-12 |
20150326028 | WIRELESS POWER TRANSMITTING APPARATUS, WIRELESS POWER RECEIVING APPARATUS, AND WIRELESS POWER FEEDING SYSTEM - A wireless power transmitting apparatus ( | 2015-11-12 |
20150326029 | INDUCTIVELY POWERED MOBILE SENSOR SYSTEM - An inductively powered sensor system includes a primary conductive path | 2015-11-12 |
20150326030 | INDUCTIVELY POWERED MOBILE SENSOR SYSTEM - An inductively powered sensor system includes a primary conductive path | 2015-11-12 |
20150326031 | NON-CONTACT POWER SUPPLY APPARATUS - A non-contact power supply apparatus includes a transmission-side pad, a transmission-side resonant circuit, a reception-side pad, a reception-side resonant circuit, a power transmission circuit, a power reception circuit, and a control circuit. The control circuit controls an alternating-current voltage supplied to the transmission-side pad and an alternating-current voltage supplied to the power reception circuit, so that a power factor of the alternating current supplied from the power transmission circuit to the transmission-side pad connected to the transmission-side resonant circuit and direct-current power supplied from the power supply circuit to an on-board battery are respectively set to target values. As a result, change in power factor can be suppressed even when the coupling coefficient of the transmission-side pad and the reception-side pad changes, and predetermined electric power can be transmitted. | 2015-11-12 |
20150326032 | TRANSMISSION-GUARD SYSTEM AND METHOD FOR AN INDUCTIVE POWER SUPPLY - Wireless power transfer between a power transmitter and a power receiver may include a power transfer established by a detector of the wireless power transmitter detecting a magnetic field from a wireless power receiver in proximity to the wireless power transmitter and activating the wireless power transmitter to transfer power to the wireless power receiver. | 2015-11-12 |
20150326033 | POWER TRANSMISSION SYSTEM - A power transmission system includes a charging station and a power receiving device. The charging station has a pair of first electrodes, and a signal source that emits an alternating current signal; and a step-up transformer that applies a stepped-up voltage to the pair of first electrodes. The power receiving device has a pair of second electrodes opposite to and that capacitively couple with the first electrodes; a step-down transformer; a rectifying and smoothing circuit that rectifies and smoothes the stepped-down AC voltage; and a load circuit, The charging station further has a potential stabilizing electrode that capacitively couples with the electrode connected to a reference potential of the power receiving device and the potential stabilizing electrode is connected to a reference potential of the charging station via a charge controller. | 2015-11-12 |
20150326034 | POWER DENSITY CONTROL FOR WIRELESS POWER TRANSFER - A signal generator generates an electrical signal that is sent to an amplifier, which increases the power of the signal using power from a power source. The amplified signal is fed to a sender transducer to generate ultrasonic waves that can be focused and sent to a receiver. The receiver transducer converts the ultrasonic waves back into electrical energy and stores it in an energy storage device, such as a battery, or uses the electrical energy to power a device. In this way, a device can be remotely charged or powered without having to be tethered to an electrical outlet. | 2015-11-12 |
20150326035 | POWER-SUPPLYING DEVICE AND WIRELESS POWER SUPPLY SYSTEM - A wireless power supply device and a wireless power supply system of the present disclosure include a rectifier circuit to be connected to a commercial power source, a conversion unit which is connected to the rectifier circuit, a resonance circuit which is connected to the conversion unit and transmits power toward a power-receiving device wirelessly, a communication unit which receives, from the power-receiving device, information relating to power supply to a load supplied with power, and a control unit which is connected to the communication unit and the conversion unit and controls the conversion unit based on the information so that the value of power supply impedance of the load falls within a predetermined range. | 2015-11-12 |
20150326036 | Charging circuit and control method therefor - A charging circuit and a control method thereof are disclosed, which are used for charging different brands of mobile devices. The charging circuit comprises: a universal interface ( | 2015-11-12 |
20150326037 | OPTIMIZATION-BASED PREDICTIVE METHOD FOR BATTERY CHARGING - A battery management system for a rechargeable battery includes a battery monitor configured to acquire data regarding the rechargeable battery and a processor. The processor is configured to determine an initial state of charge of the battery based on the acquired data; determine a target state of charge for the battery; determine a plurality of charging solutions to achieve the target state of charge based on an optimization of one variable of the battery of a plurality of variables of the battery; narrow the plurality of charging solutions to charging solutions that meet an objective of each of the remaining plurality of variables of the battery; select the charging solution that corresponds with the fastest charge time for the battery from the charging solutions that meet the objective of each of the plurality of battery variables; and command a controller to regulate an amount of charge to the battery in accord with the selected charging solution. | 2015-11-12 |
20150326038 | SYSTEM AND METHOD FOR BATTERY POWER MANAGEMENT - A battery management system includes a battery pack and a controller. The controller is configured to receive pack terminal voltage and current data. In response, the controller may estimate battery model parameters in an equivalent circuit model and output state variable values indicative of fast and slow dynamics of the voltage responses. The controller may also output parameter values indicative of feedback gains to compute a current limit in a state feedback structure. The controller may further estimate battery current limits based on the state variable values and the feedback gains to control operation of the battery pack. | 2015-11-12 |
20150326039 | POWER DELIVERY CONTROLLER - A power delivery controller includes a detection unit, a regulation unit, and a control unit. The detection unit has a detection pin and an enable pin, wherein the detection pin is used for detecting a power delivery consumer device. The regulation unit is coupled to the detection unit, wherein when the detection pin detects the power delivery consumer device, the detection unit is used for turning on the regulation unit through the enable pin, and after the regulation unit is turned on, the regulation unit generates an internal voltage. The control unit is coupled to the regulation unit for providing power to the power delivery consumer device according to the internal voltage. When the detection pin fails to detect the power delivery consumer device, the regulation unit is turned off. | 2015-11-12 |
20150326040 | METHOD OF RECEIVING CHARGE, METHOD OF CONTROLLING CHARGE, CHARGE CONTROL UNIT AND CHARGING EQUIPMENT - Charging equipment and a charge control unit are provided, in which a plurality of devices mounted with battery can be simultaneously charged by the single charging equipment. Further, a method of controlling charge and a method of receiving charge are also provided. The charging equipment supplies electric power to the battery for charging, comprising a power output part which outputs DC power used for charging, a plurality of user operation units which can be connected with a vehicle equipped with a battery as a device mounted with battery, and the charge control unit which controls a power supply from the power output part to the user operation unit. Herein, the charge control unit distributes the electric power outputted from the power output part to supply the distributed power to the user operation unit connected with the vehicle. | 2015-11-12 |
20150326041 | BALANCING DEVICE AND ELECTRICAL STORAGE DEVICE - There is provided a balancing device that equalizes voltages between storage cells of a battery composed of a plurality of series-connected storage cells or voltages between electrical storage modules composed of a plurality of series-connected storage cells of the battery. The balancing device equalizes voltages between the energy storage modules by transferring electric power between the electrical storage modules through an element to which all of the electrical storage modules are connected, the transferring being realized by on-off control of current supply to each of the electrical storage modules, the on-off control being performed with a first duty cycle. Further, the balancing device introduces a period in which the on-off control is performed with a second duty cycle, the second duty cycle being different from the first duty cycle. Furthermore, the balancing device measures a voltage applied to each of the capacitance elements C | 2015-11-12 |
20150326042 | ON-BOARD CONTROL APPARATUS - An on-board control apparatus has a power generation means that has a communication part; a storage battery that is chargeable by receiving electric power from the power generation means; a control means that is configured to be communicatable with the communication part and controls charging of the storage battery; and a state-of-charge measurement means that measures a state of charge of the storage battery. The control means transmits a signal that is to prohibit charging the storage battery to the communication part when an ignition of a vehicle is turned off, and the state-of-charge measurement means measures the state of charge of the storage battery, during a period of time in which charging the storage battery is prohibited, after the ignition of the vehicle is turned off. | 2015-11-12 |
20150326043 | Battery System and Motor Vehicle with Battery System - A battery system is described, comprising a battery management unit, a battery cell monitoring unit, at least one battery cell and a safety electronics system for the battery cell. The safety electronics system has a first comparator and an alarm signal output for an alarm signal. The first comparator compares a battery cell voltage of the battery cell to a predetermined threshold voltage value and generates the alarm signal on the basis of the comparison. The battery threshold voltage is lower than the battery cell voltage in normal operation and higher than a critical voltage value. In addition, a motor vehicle with the battery system is described, the battery system being connected to a drive system of the motor vehicle. | 2015-11-12 |
20150326044 | BAG WITH POWER INTERFACE FOR MOBILE CONSUMER ELECTRONICS - A charging device includes a bag having an interface opening, a battery disposed within the bag, and a battery interface module adapted to be electrically coupled to the battery. The battery interface module has an interface input port for connecting to an external power source and an interface output port for connecting to an electronic device. The battery interface module is disposed within the interface opening of the bag such that the input port and the output port are accessible from an exterior of the bag. | 2015-11-12 |
20150326045 | APPARATUS FOR CHARGING WEARABLE DEVICE - A charging apparatus is provided. The charging apparatus includes a cradle and a charger module. The cradle includes a space for holding an electronic device, and includes at least one magnetic member for providing a magnetic connection with the electronic device. The charger module is connected with the cradle and supplies electric power to the electronic device. | 2015-11-12 |
20150326046 | Charging Method, Mobile Device, Charging Device, and Charging System - Embodiments of the present invention relate to a charging method, a mobile device, and a charging device. The mobile device includes a battery and a connector, where the connector includes a charging pin and a ground pin. When the charging pin establishes a connection to an output pin of the charging device by using a charging cable or a battery charging stand, the charging pin receives a first current signal transmitted by the output pin of the charging device, and transmits the first current signal to an anode pin of a battery, so as to charge the battery. | 2015-11-12 |
20150326047 | VEHICLE CHARGER - A vehicle charger includes a power supply device, a communication module, a reference changing unit, a compensator, a controller, and a gate driver. The power supply device changes an input voltage into a voltage required to charge a portable device and outputs the changed voltage. The communication module receives information on at least one of a voltage and a current, which are required to charge the portable device. The reference changing unit generates at least one of a reference voltage and a reference current based on the information on the at least one of the voltage and the current. The compensator generates a compensation signal based on a result obtained by comparing the at least one of the reference voltage and the reference current with at least one of a sensed voltage and a sensed current, which are obtained by sensing at least one of an output voltage of the power supply device and a current supplied from the power supply device to the portable device. The controller generates a gate driving signal according to the compensation signal. The gate driver generates a gate voltage for controlling switching operation of the power supply device according to the gate driving signal. | 2015-11-12 |
20150326048 | CHARGE FARE METER - A charge fare meter includes a charge module and a display. The charge module is used for outputting a direct (DC) current and calculating total charges, wherein the charge module includes an input interface, a calculating unit, and an output interface. The input interface is used for converting power provided by an alternating current power source or the DC power source into the DC current. The calculating unit is electrically connected to the input interface for calculating the total charges. The output interface is electrically connected to the calculating unit for outputting the DC current. The display is electrically connected to the charge module for displaying the DC current, a voltage corresponding to the DC current, or a charge fare corresponding to the total charges. | 2015-11-12 |
20150326049 | POWER SYSTEM FOR HIGH TEMPERATURE APPLICATIONS WITH RECHARGEABLE ENERGY STORAGE - A power system adapted for supplying power in a high temperature environment is disclosed. The power system includes a rechargeable energy storage that is operable in a temperature range of between about seventy degrees Celsius and about two hundred and fifty degrees Celsius coupled to a circuit for at least one of supplying power from the energy storage and charging the energy storage; wherein the energy storage is configured to store between about one one hundredth (0.01) of a joule and about one hundred megajoules of energy, and to provide peak power of between about one one hundredth (0.01) of a watt and about one hundred megawatts, for at least two charge-discharge cycles. Methods of use and fabrication are provided. Embodiments of additional features of the power supply are included. | 2015-11-12 |
20150326050 | METHOD AND CONTROLLER FOR CONTROLLING SCHEDULED CHARGING OF ELECTRIC VEHICLE - A method and controller for controlling scheduled charging of an electric vehicle. A charging start time is scheduled in the electric vehicle. The electric vehicle is connected to a charger by means of a control line. A standby signal is transfers on the control line, and the charger enters into a charging standby mode. A charging control switch of the electric vehicle is then turned on (and subsequently off) for a first time at every first period so that the charger stays in the charging standby mode. At the scheduled charging start time, the charging control switch is turned on and left on so that the charger starts charging the electric vehicle. | 2015-11-12 |
20150326051 | Systems and Methods for Managing and Controlling a Wireless Power Network - A system for managing a wireless power network is disclosed here. The system includes a graphical user interface from which a user may perform managing functions in a wireless power network. The disclosed system may connect and request information from a plurality of power transmitter manager applications embedded as software in wireless power transmitters. Wireless power transmitters may receive input data from wireless power receivers. Received data may be stored in a device database in memory of the wireless power transmitter. The system may request, modify and update data from the device database in each wireless power transmitter. The system may also determine actions to be performed by the wireless power transmitter. | 2015-11-12 |
20150326052 | WIRELESS SOUND CHARGING METHODS AND SYSTEMS FOR GAME CONTROLLERS, BASED ON POCKET-FORMING - The present invention provides wireless charging methods and systems for powering game controllers. The methods and systems may include one or more transmitters and one or more receivers. In some embodiments the transmitters and receivers may be embedded to game console and game controllers, respectively. In other embodiments, the transmitters and receivers may be connected as a separate device to the game console and game controllers, respectively. The method may include wireless power transmission through suitable techniques such as pocket-forming utilizing sound waves. | 2015-11-12 |
20150326053 | FOLDABLE WIRELESS CHARGING SYSTEM - A wireless charging system may provide charging to a portable device. A docking station in the system may include a first transmission source configured to emit wireless charging power along a first transmission axis from a first body. The docking station may include a second power transmission source configured to emit wireless charging power along a second transmission axis from a second body. In some embodiments, the first transmission axis may not intersect with the second transmission axis. In some embodiments, the first transmission axis may be divergent from the second transmission axis. | 2015-11-12 |
20150326054 | PORTABLE TERMINAL HAVING A WIRELESS CHARGING MODULE - A portable terminal is provided. The portable terminal includes a back surface on which a battery-mounting groove is formed; and a receiving-side resonant antenna arranged around the battery-mounting groove on the body. The receiving-side resonant antenna is arranged parallel to at least three sides of the battery-mounting groove. | 2015-11-12 |
20150326055 | MOBILE TERMINAL - Provided is a mobile terminal comprising a connecting hole for connecting the inside and the outside of a housing, a camera unit that is mounted to a circuit substrate, and a secondary-side non-contact charging module that is accommodated in the housing. The camera unit comprises a camera module that is capable of capturing images through the connecting hole. The secondary-side non-contact charging module is arranged at a position so as to not overlap with the camera unit in a plan view that follows the thickness direction of the housing, and is arranged within a length that follows the thickness direction (direction indicated by the arrow) of the housing at the camera unit. | 2015-11-12 |
20150326056 | MOBILE TERMINAL - A mobile terminal is provided with a housing, a circuit substrate, a secondary-side non-contact charging module, and a heat dissipating sheet. The circuit substrate comprises a substrate, an electronic component that is mounted to the substrate, and a shield case that covers the electronic component. The heat dissipation sheet is in contact with the shield case. | 2015-11-12 |
20150326057 | MOBILE TERMINAL - A mobile terminal is provided with a housing, a battery pack, and a secondary-side non-contact charging module. In a plan view along the thickness direction of the housing, the battery pack is arranged in a first area, and the secondary-side non-contact charging module is arranged in a second area that is adjacent to the first area. The secondary-side non-contact charging module overlaps with the intersection of a center line for the second area, said center line following the direction in which the first area and the second area are adjacent to each other, and a center line for the width direction of the housing, said center line being orthogonal to the direction in which the first area and the second area are adjacent to each other in the second area. | 2015-11-12 |
20150326058 | Electronic Device for Handling Sharing of Communication Hardware in Wireless Charging System - An electronic device of a wireless charging system for handling sharing of communication hardware includes a processing means and a storage unit. The processing means is utilized for executing a program. The storage unit is utilized for storing the program, which instructs the processing means to perform the following steps: receiving wireless power from a wireless charger by communicating with the wireless charger via a communication module of the electronic device; detecting a request of utilizing the communication module from an application; delivering a message to a user to indicate that the request is detected; receiving a response to the message from the user; and stopping receiving wireless power from the wireless charger and switching the communication module to be utilized for the application, or keeping on receiving wireless power from the wireless charger and rejecting the request from the application according to the response from the user. | 2015-11-12 |
20150326059 | SYSTEM AND METHOD FOR TRANSMITTING RF ENERGY - Systems and methods for wirelessly harvesting power are disclosed. The method may include, for example, transmitting radio frequency waves to a receiver and receiving, using one or more antennas, the radio frequency waves. Further, the method may include extracting energy from the radio frequency waves. Transmitter and receiver RF circuitry may be provided to execute the disclosed methods. | 2015-11-12 |
20150326060 | Bulk Wireless Charger - An improved bulk wireless charger station may be constructed of a number of individual wireless charger modules. Each module may include an embedded wireless charger transmitter with the capability of wirelessly charging a device inserted into the module. The device may have the capability of being wirelessly charged via a wireless charging receiver in communication with the wireless charger transmitter. Charging the device may include charging a battery or other electrical storage element within the device, which, once charged, may power the device during use. The charger modules may be stackable horizontally and/or vertically to form the charger station. Each charger module may also include a power interface for receiving power from either a power base or other charger modules, and/or a communication interface for communicating with other charger modules and/or control station(s). The embedded wireless charger transmitter may be a transmitter coil controlled through a power conversion/control board. | 2015-11-12 |
20150326061 | WIRELESS BATTERY CHARGER AND CHARGE-RECEIVING DEVICE - A wireless charger includes a plurality of conductive coils and electronic circuitry. The coils are disposed around a perimeter and face a generally central area of the perimeter. The coils are connected to and controlled by the electronic circuitry, which includes an electric power receiving circuit and a coil controller. The electric power receiving circuit receives electrical power from an external source and conditions the power for provision to the coil controller. The coil controller controls provision of an oscillating current to select coils within the plurality of coils. A protective enclosure or portable electronic device may have receiving coils disposed at its sides for corresponding to at least two of the conductive coils of the wireless charger. | 2015-11-12 |
20150326062 | SYSTEM AND METHOD FOR REDUCING INTERFERENCE BETWEEN WIRELESS CHARGING AND AMPLITUDE MODULATION RECEPTION - A method for reducing interference in an inductive charging system is provided. The method includes steps of inductively charging a chargeable device with an inductive charger, detecting the operation of a receiver in an AM band, and adjusting at least one of a frequency band employed by the charger and an amount of power provided to the chargeable device by the charger based on the operation of the receiver in the AM band. | 2015-11-12 |
20150326063 | PORTABLE WIRELESS CHARGING PAD - The present disclosure provides a method and apparatus for improved wireless charging pads for charging and/or powering electronic devices. Such pads may not require a power cord for connecting to a main power supply, for example a wall outlet. In contrast, power may be delivered wireless to the foregoing pads through pocket-forming. A transmitter connected to a power source may deliver pockets of energy to the pads which through at least one embedded receiver may convert such pockets of energy to power. Lastly, the pads may power and/or charge electronic devices through suitable wireless power transmission techniques such as magnetic induction, electrodynamics induction or pocket-forming. | 2015-11-12 |
20150326064 | BATTERY CHARGER CRADLE - In a battery charger cradle, a battery incorporated in a battery built-in device is charged by electric power induced to an induction coil. The cradle includes a primary coil for inducing electromotive force to the induction coil, a casing having a top plate atop of which the battery built-in device is placed, a movement mechanism for moving the primary coil along an inner surface of the top plate, and a position detection controller for detecting a position of the battery built-in device placed on the top plate and controlling the movement mechanism to bring the primary coil closer to the induction coil in the battery built-in device. When the battery built-in device is placed on the top plate, the position detection controller detects the position of the battery built-in device, and the movement mechanism moves the primary coil closer to the induction coil in the battery built-in device. | 2015-11-12 |
20150326065 | Precharging Circuit for Charging an Intermediate Circuit Capacitor - A pre-charging circuit for charging an intermediate circuit capacitor is provided having a first electronic component, a second electronic component and a diagnostic circuit. The diagnostic circuit is designed for functional testing of the first electronic component and/or of the second electronic component and comprises an energy source with a terminal voltage. A voltage drop can be induced on the first electronic component by the energy source, as a result of which the functional performance of the first electronic component and/or of the second electronic component can be tested. The diagnostic circuit has a diagnosis switch via which the energy source can be connected to the first electronic component in such a manner that the dropping voltage on the first electronic component corresponds to the terminal voltage. | 2015-11-12 |
20150326066 | POWER SUPPLY DEVICE - A power supply device for supplying power to a load by combining a secondary battery and a capacitor connected in parallel to the secondary battery includes an insulation type DC-DC converter with a primary coil connected in parallel to the secondary battery and configured to accumulate energy by a current supplied from the secondary battery and a secondary coil connected in series to the capacitor and configured such that an induction current flows therein by the accumulated energy from the primary coil. | 2015-11-12 |
20150326067 | Power-Conditioned Solar Charger for Directly Coupling to Portable Electronic Devices - The present invention relates to methods, tools and systems for manufacturing a durable and portable power-conditioned personal solar system charging apparatus. Various voltage and amperage matching algorithms are manipulated to particularize the personal solar system to power and/or charge an intended portable device or a set of intended portable devices having direct current (DC) load requirements. The optimized personal solar system that is matched to an intended device allows direct coupling to the intended device without the use of an internal battery or ancillary electronic circuit boards to distract the personal solar system output, and facilitates “fast” charging modes. | 2015-11-12 |
20150326068 | Systems and methods for wireless transmission of power - Systems and methods for real time communication between wireless power transmitters and wireless power receivers based on software embedded on a microprocessor. The systems and methods described here may allow wireless power transmitters to communicate with one or more wireless power receivers in real time within intervals of one second. The systems and methods described here may also enable full control of the wireless power receivers by letting the user decide which wireless power receivers to charge, when to charge them, and set priorities and charging schedules among other functions. | 2015-11-12 |
20150326069 | Enhanced Receiver for Wireless Power Transmission - An enhanced receiver for wireless power transmission is disclosed. The receiver may be able to convert RF waves into continuous, stable and suitable voltage or power that can be used for charging or powering an electronic device. The receiver may include an antenna array for extracting and rectifying power from RF waves or pockets of energy. An input boost converter in the receiver may step up and stabilize the rectified voltage, while charging a storage element in the receiver. An output boost converter in the receiver may step up the output voltage of the storage element to deliver continuous and suitable power or voltage to a load. A microcontroller in the receiver may perform power measurements at different nodes or sections to adjust the operation of the input and output boost converters so that load power requirements can be satisfied at all times. | 2015-11-12 |
20150326070 | Methods and Systems for Maximum Power Point Transfer in Receivers - A MPPT management method in a receiver used for wireless power transmission may include the monitoring of the power extracted from RF waves at a dedicated antenna element in the receiver; detecting MPPT at an intelligent input boost converter in the receiver; comparing the detected MPPT with MPPT tables stored or calculated within a main system micro-controller in the receiver; adjusting the MPPT at the intelligent boost converter to find a suitable maximum peak that may enable an optimal power extraction from RF waves. | 2015-11-12 |
20150326071 | Compact PIFA Antenna - Various planar inverted-F antenna configurations may include an antenna element formed on the top of a PCB and a ground element formed on the bottom of the PCB. Two or more slots may be included in the antenna element for reducing the antenna area while maintaining a suitable impedance bandwidth. A slot may be included in the ground element for reducing the ground area while increasing radiation efficiency. A folded ground may be formed on the top of the PCB for reducing system area while maintaining suitable performance. By moving the folded ground closer to the antenna element and increasing the PCB thickness, significant reductions in system area may be achieved, while maintaining or improving performance in terms of radiation pattern, radiation efficiency and impedance bandwidth. | 2015-11-12 |
20150326072 | Boost-Charger-Boost System for Enhanced Power Delivery - A controlled-power delivery system may operate with RF waves for supplying continuous and suitable power to a load. The controlled-power delivery system may include one or more receiving antennas, one or more rectifiers, a first boost converter, a charger, a storage element, and a second boost converter. The first boost converter may step up the rectified DC voltage obtained from the receiving antenna and rectifier to supply a suitable voltage level that can be used for charging the storage element. The second boost converter may increase the voltage from the storage element to a suitable level that may satisfy the power requirements of the load. The charger in conjunction with the first and second boost converters may be configured to allow a plurality of modes of operation for delivering power to the load and charging the storage element. | 2015-11-12 |
20150326073 | SYSTEMS AND METHODS FOR WIRELESSLY CHARGING ELECTRONIC DEVICES - Systems and methods presented herein provide for powering of electronics. One powering system disclosed herein includes a database comprising subscription information for a plurality of network users and an electromagnetic energy source. The powering system also includes a communication hub colocated with the electromagnetic energy source and operable to establish a communication link with an electronic device of a first of the network users. The powering system also includes a network element communicatively coupled to the communication hub through a communication network to receive subscription information from the electronic device via the communication hub. The network element is further operable to access the database to verify the subscription information of the first user, and to direct the electromagnetic energy source to radiate towards the electronic device to power to the electronic device upon verification of the subscription information of the first user. | 2015-11-12 |
20150326074 | ELECTRIC MACHINE AND SYSTEMS COMPRISING THE SAME - An electric machine is presented. The electric machine includes a hollow rotor; and a stator disposed within the hollow rotor, the stator defining a flow channel. The hollow rotor includes a first end portion defining a fluid inlet, a second end portion defining a fluid outlet; the fluid inlet, the fluid outlet, and the flow channel of the stator being configured to allow passage of a fluid from the fluid inlet to the fluid outlet via the flow channel; and wherein the hollow rotor is characterized by a largest cross-sectional area of hollow rotor, and wherein the flow channel is characterized by a smallest cross-sectional area of the flow channel, wherein the smallest cross-sectional area of the flow channel is at least about 25% of the largest cross-sectional area of the hollow rotor. An electric fluid pump and a power generation system are also presented. | 2015-11-12 |
20150326075 | Fuel Pump - A fuel pump with an electric motor having a stator, a shaft, and a rotor arranged on the shaft. The rotor is a magnetic rotor, and an impeller is driven by the shaft, which impeller is rotatably mounted in a pump housing. The rotor is made from a laminated core on which a plastic-bonded magnetic material is sprayed. On at least one side, the laminated core has a greater axial length than the plastic-bonded magnetic material. | 2015-11-12 |
20150326076 | ROTOR STRUCTURE FOR MOTOR - A rotor structure for a motor includes: a core body in which a shaft passes through an axial center and teeth are radially arranged along an outer circumference and include first slide connection portions at front ends; field windings individually wound around outer circumferences of the teeth and maintaining a state of being spaced apart from one another while being wound around the teeth; and a cylindrical core tip part configured to surround the outside of the core body, the cylindrical core tip part including second slide connection portions in an inner circumference such that the front ends of the teeth are slidably connected thereto along an axial direction through a mating engagement. | 2015-11-12 |
20150326077 | Synchronous Machine Having a Flux Exciter Remote from the Rotor - A brushless synchronous electrical machine with an unwound rotor comprising poles excited through radial air gaps at both ends of rotor by stationary exciters comprising high permeable cores and electrical winding. | 2015-11-12 |
20150326078 | MOTOR ROTOR SUPPORT AND METHOD FOR MANUFACTURING SAME - An object of the present invention is to provide a motor rotor support suitable for an axial gap motor and a method for manufacturing the same. The motor rotor support for supporting a magnetic body disposed on a rotor of a motor is configured by a nonmagnetic steel having a relative permeability of less than 1.005 and a 0.2% yield strength at room temperature of 550 MPa or more. | 2015-11-12 |
20150326079 | MAGNETIC MOTOR - A magnetic motor includes a rotor and a stator, in which there are magnets and materials of high magnetic permeability. The stator magnets are arranged with surfaces facing the rotor magnets in a staggered arrangement. The motor may be used to boost torque, for example in bicycles. | 2015-11-12 |
20150326080 | ROTOR AND MOTOR - A rotor includes: a circular rotor core; and a plurality of θ magnets. The θ magnets are contained in a magnet holding sections such that the same magnetic pole of one magnet as that of another magnet adjacent to said one magnet faces the same magnet pole of the adjacent magnet in circumferential directions of the rotor core. Given that the number of magnetic poles of the rotor is denoted by P, the maximum outside diameter of the rotor core is denoted by Dr [mm], and the thickness of the plate-like magnet in a circumferential direction of the rotor core is denoted by Lm [mm], the following inequality (2) is satisfied: | 2015-11-12 |
20150326081 | ROTOR OF AN ELECTRIC MOTOR, WITH AN OUTER SLEEVE FORMED BY WINDING, METHOD FOR PRODUCING SUCH A ROTOR, AND ELECTRIC MOTOR COMPRISING SUCH A ROTOR - An electric motor rotor including a magnetic core, magnets fastened to the periphery of the magnetic core, and a wire wound with touching turns around the magnetic core and the magnets. The wire includes a metal core surrounded by an electrically insulating layer, itself covered by an outer sheath of thermo-adhesive material, the turns being fastened to one another by adhesion between mutually contacting portions of the outer sheath. A method of fabricating such a rotor. An electric motor including such a rotor. | 2015-11-12 |
20150326082 | SINGLE-PHASE INDUCTION MOTOR - A single-phase induction motor includes a stator including a main winding with a first coil (P | 2015-11-12 |
20150326083 | COOLING STRUCTURE FOR MOTOR - A cooling structure for a motor includes: a stator in which a plurality of teeth are arranged along an inner circumference of a hollow at which a rotor is disposed, and spacing portions are formed between the teeth; coils individually wound around outer circumferences of the teeth and configured to generate a magnetic force by external power; and cooling tubes individually wound around the teeth to surround outer circumferences of the coils and configured to cool the coils by circulating a refrigerant supplied from the outside. | 2015-11-12 |
20150326084 | ROTARY ELECTRIC MACHINE - A rotary electric machine is a rotary electric machine including a stator of a distributed winding type including a plurality of first slots, in each of which winding wires of a plurality of same phases or winding wires of one phase are arranged, and a plurality of second slots, in each of which winding wires of a plurality of different phases are arranged. The total number of turns in each of the first slots is same as one another. The total number of turns in each of the second slots is same as one another. The total number of turns in the first slot and the total number of turns in the second slot are different from each other. | 2015-11-12 |
20150326085 | ROTOR FOR WOUND-ROTOR INDUCTION MOTOR HAVING ANTI-SPATTERING MEMBERS - Provided is a rotor for a wound-rotor induction motor having anti-spattering members. The rotor includes: a core that includes a base part having a hollow into which a shaft of the rotor is inserted, a plurality of winding parts that extend outward from a circumference of the base part and are spaced a predetermined distance from one another, and a plurality of panel parts that are provided at ends of the winding parts and are wider than the winding parts; coils wound around the winding parts; and anti-spattering members which are in contact with the panel parts and each of which is provided between the pair of winding parts adjacent to each other and prevents the coils adjacent to each other from spattering. | 2015-11-12 |
20150326086 | STATOR AND ROTATING ELECTRIC MACHINE - A stator includes an annular stator core, a stator coil and a resin adhesive. The stator coil is comprised of a plurality of electric wires. The electric wires are partially received in slots of the stator core so that the stator coil has a pair of coil end parts protruding outside the slots respectively from opposite axial end faces of the stator core. The resin adhesive is filled in the slots of the stator core and/or applied to the coil end parts of the stator coil. Moreover, each of the electric wires includes an electric conductor and an insulating coat that covers an outer surface of the electric conductor. The insulating coat is two-layer structured to include an inner coat and an outer coat. The adhesion strength of the outer coat to the resin adhesive is lower than the adhesion strength of the inner coat to the resin adhesive. | 2015-11-12 |
20150326087 | ALTERNATING-CURRENT PERMANENT MAGNET DRAINAGE PUMP - The present invention discloses an alternating-current permanent magnet drainage pump, including a pump cover, a pump body, a magnetic core, a rotating shaft, a stator core and coils. The coils are wound around a coil former, and the stator core is assembled to the coils. The pump body is a shell formed by surrounding a contour of the coils, the coil former, and the stator core which have been assembled to perform a integrated injection molding. The shell defines a magnetic core accommodating space which is used for accommodating the magnetic core and has an opening at a top portion and the magnetic core accommodating space extends from the opening to a center of the pump body. A supporting member is arranged in the opening at the top portion of the magnetic core accommodating space for supporting a bearing of the rotating shaft. The pump body includes a first pump body portion and a second pump body portion. The second pump body portion is provided therein with a cylinder-shaped rotor housing for supporting the rotor assembly, and the magnetic core accommodating space is surrounded and formed by an inner surface of the rotor housing; and a concave arc portion of the stator core is embedded in the rotor housing. The present invention may reduce the magnetic air gap between the stator core and the rotor, improve the operation efficiency of the product, reduce the overall size of the pump body, lower the manufacturing cost of the product, avid resonance and noise generated by the pump body and improve the heat dissipation performance of the pump. | 2015-11-12 |
20150326088 | Electric Linear Actuator - An electric linear actuator has a housing, an electric motor, a speed reduction mechanism, and a ball screw mechanism. The ball screw mechanism has a nut and a screw shaft. Both include a helical screw groove. The nut is supported by rolling bearings mounted on the housing. The screw shaft is coaxially integrated with the drive shaft. The screw shaft is inserted into the nut, via a large number of balls. The housing has a first housing and a second housing. The electric motor is mounted on the first housing. The second housing abuts against an end face of the first housing. At least one of the first and second housings is formed with ribs. The ribs extend from each of securing portions to a containing portion that contains the screw shaft. The securing portions are arranged on the periphery of the housing to receive fastening bolts. | 2015-11-12 |
20150326089 | Actuator - An actuator includes a metal housing that consists of multiple housing parts, an electric motor, an actuating member, a transmission mechanism that adapts the movement of the electric motor to the actuating member and an electronic system for controlling the electric motor. A heat sink is situated in a housing part consisting of plastic, said heat sink being connected to a metal housing part. | 2015-11-12 |
20150326090 | INVERTER-INTEGRATED ELECTRICALLY DRIVEN COMPRESSOR - The purpose is to provide an inverter-integrated electrically driven compressor by which the danger of contacting an inverter device while power is being applied can be overcome in a reliable manner, without the need to provide any extra components, such as safety devices or the like. In this inverter-integrated electrically driven compressor, the inverter device is arranged housed within an inverter housing part hermetically sealed by a cover, and power and communication lines from an external power supply and a control device are connectable to the inverter device through connectors. The connector on the compressor side is furnished to the cover side, and at least one bolt of a fastening means for fastening the cover to the inverter housing part is furnished at location covered by the connector on the power line side, making access impossible, when the connector on the power line side has been coupled to the connector on the compressor side. | 2015-11-12 |
20150326091 | Explosion-Protected Housing - An explosion-protected housing, such as a switchboard, junction box, distribution box, or the like, comprising sidewalls, one back or bottom wall connecting the sidewalls, and a lid or door wall part closing a housing opening. In the housing interior, electronic and/or electric components are arranged, wherein the housing comprises a cooling device. To allow the cooling of a plurality of electronic and/or electric components in the housing interior in a simple way and without higher costs and requiring more space, at least one cooling pipe as a cooling device is provided in at least one wall or a wall part and is closed to the housing interior and flowed through by a cooling fluid. | 2015-11-12 |
20150326092 | MOTOR AND BLOWER - A motor includes a metal base plate and a resin holder extending upward from the base plate. The base plate includes a flat plate portion, a through hole passing through the flat plate portion, and a plurality of claw portions extending upward from an edge of the flat plate portion which includes the through hole. A portion of the holder is in the through hole. The holder covers a portion of each claw portion. The holder is thus engaged with each claw portion to prevent the holder from turning around a rotation axis and from coming off in an upward direction. The holder includes a gate mark near a lower surface of the flat plate portion and at a circumferential position between adjacent ones of the claw portions to make it easier for the resin to fill a cavity inside molds during a molding process. | 2015-11-12 |
20150326093 | PUMP UNIT - A pump assembly has an electrical drive motor arranged in a stator housing ( | 2015-11-12 |
20150326094 | Subsea Compressor or Pump with Hermetically Sealed Electric Motor and with Magnetic Coupling - A submersible fluid system for operating submerged in a body of water includes a fluid-end with a fluid rotor disposed in a fluid-end housing. An electric machine housing is coupled to the fluid-end housing and has a hermetically sealed cavity containing a fluid at a pressure less than a hydrostatic pressure at a specified depth at which the submersible fluid system is designed to operate. An electric machine is disposed in the cavity of the electric machine housing and includes an electric machine rotor coupled to the fluid rotor and an electric machine stator. | 2015-11-12 |
20150326095 | POWER GENERATOR POWER GENERATION FACILITY - In a power generation facility, there are provided a plurality of diesel engines, a plurality of turbochargers driven by exhaust gas from the diesel engines, a plurality of power generators connected to the plurality of turbochargers, a plurality of converters for converting AC power generated by the plurality of power generators to DC power, one inverter for converting the DC power outputted from the plurality of converters to AC power, and a main controller for controlling the converters in accordance with the AC power from the inverter, by which stable electric power can be generated. | 2015-11-12 |
20150326096 | ELECTRIC MOTOR - A metal gear cover 43, which is provided so as to cover a worm wheel housing 36 | 2015-11-12 |
20150326097 | METHOD AND STRUCTURE FOR MOUNTING SENSOR SUBSTRATE OF BRUSHLESS MOTOR - The present invention provides a method and a structure for mounting a sensor substrate of a brushless motor, in which a rotation detection element is arranged near a permanent magnet of a rotor and the sensor substrate can be securely mounted with a simple method, and thus, it is not necessary to elongate the dimension of the permanent magnet of the rotor in an axial direction. In the present invention, insulating members that insulate a location for winding of a stator coil from an outside are formed on a stator core ( | 2015-11-12 |
20150326098 | ELECTRIC POWER TOOL - In an electric power tool, a stator of a motor is housed in a grip and the stator is located coaxial to the grip. An electric wire for the motor is passed through a ferrite core. Further, the ferrite core is located inside an outer peripheral surface of the stator in a radial direction. | 2015-11-12 |
20150326099 | Brush Assembly - An electric power steering assembly includes a motor which includes a brush assembly. The brush assembly includes a brush base, a plurality of brush units and a plurality of fixing units for fixing the brush units to the brush base. The brush unit includes a brush, a guide rail and a spring. The rail includes two guiding arms, a closed end interconnecting the guiding arms and wings extending from free ends of the guiding arms. Grooves in the brush receive the guiding arms. The fixing unit includes a first fixture and a second fixture. The closed end of the guide rail engages the first fixture. The second fixture includes two columns spaced from each other. Each column defines a slot in a top end. Protrusions extend from a side of each slot to lock the wings in the slots. | 2015-11-12 |
20150326100 | ELECTRONICALLY CONTROLLED UNIVERSAL MOTOR - An electric motor apparatus and method of controlling the same are provided. The electric motor apparatus includes a stator and a rotor rotationally mounted coaxially with the stator; an intermediate screen having a magnetic material and rotationally mounted between the stator and the rotor to provide magnetic screening between the rotor and the stator; and control circuitry to control power supplied to windings on the rotor and the stator in dependence upon a desired output rotational speed. | 2015-11-12 |
20150326101 | ROTARY ELECTRIC MACHINE - This disclosure discloses a rotary electric machine including a magnetic body and a rotor core. The magnetic body includes at least a first columnar part, a second columnar part and a third columnar part. The rotor core includes an outer peripheral part, a first inner peripheral part, a second inner peripheral part, a first connecting part and a second connecting part. The first inner peripheral part is capable of facing a radial outer side of the first columnar part. The second inner peripheral part is capable of facing a radial outer side of the second columnar part. | 2015-11-12 |
20150326102 | MINIMUM ON-TIME CONTROL FOR LOW LOAD DC/DC CONVERTER - Aspects of the present invention provide a DC/DC converter for use with a supply voltage and operable to drive a load, wherein the DC/DC converter includes a V | 2015-11-12 |
20150326103 | SWITCH CONTROL CIRCUIT AND POWER SUPPLY DEVICE INCLUDING THE SAME - A switch control circuit includes a first pin connected to a first voltage, and a second pin connected to another end of a first resistor including an end connected to the first pin and a first capacitor. In the switch control circuit, at least two of first dead time information, second dead time information, and a protection mode are set by using a multi-voltage of the second pin. The first dead time information is information about a dead time of a first switch and a second switch controlling power supply, the second dead time information is information about a dead time for synchronous rectification, and the protection mode includes an auto-restart mode and a latch mode. | 2015-11-12 |
20150326104 | Power Supply Bus Circuit - A power supply bus circuit, includes a voltage regulator circuit, and an impedance isolation circuit, and further including one or more voltage adjustment circuits, where the voltage regulator circuit receives a direct current signal, adjusts a voltage of the direct current signal to a first preset voltage, and outputs a direct current signal of the first preset voltage to the impedance isolation circuit; the impedance isolation circuit receives the direct current signal of the first preset voltage, adjusts the direct current signal of the first preset voltage to an alternating current signal, and outputs, by using a transformer, the alternating current signal in an isolated way and converts the alternating current signal that is output in an isolated way to an isolated direct current signal, and outputs the isolated direct current signal to the voltage adjustment circuit. | 2015-11-12 |
20150326105 | Pulsating Current Ripple Cancelling Circuit and Power Converting System Using the Same - The present invention relates to a pulsating current ripple cancelling circuit and a power converting system using the same cancelling circuit. The pulsating current ripple cancelling circuit includes a first transformer having a primary winding side and a secondary winding side; a second transformer having a primary winding side and a secondary winding side, wherein the primary winding side of the second transformer is electrically coupled with the primary winding side of the first transformer; a first diode electrically coupled with the secondary winding side of the first transformer; a first equivalent capacitor combination electrically coupled with the primary winding side of the first transformer; and a second equivalent capacitor combination electrically coupled with the secondary winding side of the second transformer. | 2015-11-12 |
20150326106 | SOFT START CIRCUIT FOR SWITCHING CONVERTER AND ASSOCIATED SOFT START METHOD - A soft start circuit for a switching converter, the soft start circuit has an internal soft start voltage generating circuit, an amplifier circuit and a buffer circuit, the internal soft start voltage generating circuit provides an internal soft start voltage, the amplifier circuit has a first input terminal receiving the internal soft start voltage, a second input terminal receiving a soft start reference signal and an output terminal, the buffer circuit has an input terminal coupled to the output terminal of the amplifier circuit and an output terminal providing the soft start reference signal. An external soft start capacitor coupled to the output terminal of the amplifier circuit is charged to provide an external soft start voltage, and the soft start reference signal is provided based on the internal soft start voltage and the external soft start voltage. | 2015-11-12 |
20150326107 | ELECTRIC POWER FEEDBACK APPARATUS AND ELECTRIC POWER FEEDBACK METHOD - An electric power feedback apparatus is electrically connected to a power supply apparatus. The power supply apparatus includes a power supply module, a main power output terminal and a standby power output terminal. The main power output terminal and the standby power output terminal output electric power to a power conversion system respectively. The electric power feedback apparatus includes a constant voltage compensating module, a compensating and clamping module, an adaptive current weighting module and a controller. The constant voltage compensating module is electrically connected to the main power output terminal. The compensating and clamping module is electrically connected to the standby power output terminal, the constant voltage compensating module and the power conversion system. The adaptive current weighting module is electrically connected to the standby power output terminal, the constant voltage compensating module and the power conversion system. | 2015-11-12 |
20150326108 | DUAL SOURCE DC TO DC CONVERTER - A system includes a first buck type direct current (DC) to DC converter having: a first control switch; a first synchronized switch; an inductor; and a capacitor. The system further includes a second buck type DC to DC converter having: a second control switch; a second synchronized switch; the inductor; and the capacitor. The system further includes a controller operatively connected to the first buck type DC to DC converter and the second buck type DC to DC converter, wherein the controller controls a conduction state of the first control switch and the second control switch; and an output terminal pair operatively connected to the capacitor. | 2015-11-12 |
20150326109 | VOLTAGE SMOOTHING CIRCUIT, VOLTAGE CONVERSION CIRCUIT, AND METHOD FOR CONTROLLING VOLTAGE TO BE APPLIED TO MULTILAYER CAPACITOR - A voltage smoothing circuit includes a multilayer capacitor including a first capacitance unit and a second capacitance unit and a regulator including an input terminal which is electrically connected to the second capacitance unit and an output terminal which is electrically connected to the first capacitance unit. The regulator calculates a first voltage which is applied to the first capacitance unit based on a second voltage which is applied to the second capacitance unit from the input terminal such that a potential difference which is applied to the first capacitance unit decreases or increases when a potential difference which is applied to the second capacitance unit increases or decreases, and outputs the first voltage from the output terminal. | 2015-11-12 |
20150326110 | POWER SUPPLY APPARATUS WITH REDUCING VOLTAGE OVERSHOOTING - A voltage generating unit generates a standard output voltage and sends to a voltage output side. A voltage detection unit detects a voltage of the voltage output side and informs a voltage gain control unit. When the voltage of the voltage output side is decreasing due to a dynamic load, the voltage gain control unit is configured to control the voltage generating unit to increase a gain of a voltage generated by the voltage generating unit, and the voltage generated by the voltage generating unit is lower than the standard output voltage. Then, the voltage gain control unit is configured to control the voltage generating unit to decrease the gain of the voltage generated by the voltage generating unit, and the voltage generated by the voltage generating unit is equal to the standard output voltage. | 2015-11-12 |
20150326111 | HIGH EFFICIENCY VOLTAGE LEVEL MULTIPLIER - A voltage multiplier circuit. The voltage multiplier circuit includes a storage element, a first transistor, a second transistor and third transistor. The storage element has a first end and a second end. The second end is coupled to a clock signal input. The first transistor has a gate coupled to a voltage node, a first terminal coupled to a supply node, and a second terminal coupled to the first end of the storage element. A second transistor has a first terminal coupled to the first end of the storage element and a second terminal coupled to the voltage output. The third transistor has a gate in communication with the clock input and a first terminal coupled to the voltage node. | 2015-11-12 |
20150326112 | POWER STABILIZATION CIRCUIT AND METHOD - A power stabilization circuit including a first reference power supply, a second reference power supply, and a combiner circuit coupled to the first reference power supply and the second reference power supply. The first reference power supply is configured to receive a first control signal, generate a first reference signal based on the first control signal, and provide the first reference signal to a first output power supply. The second reference power supply is configured to receive a second control signal, generate a second reference signal based on the second control signal, and provide the second reference signal to a second output power supply. The combiner circuit is configured to generate a combined reference signal based on the first reference signal and the second reference signal and drive a reference load based on the combined reference signal. | 2015-11-12 |
20150326113 | CHARGE PUMP WITH TEMPORALLY-VARYING ADIABATICITY - Operation of a charge pump is controlled to optimize power conversion efficiency by using an adiabatic mode with some operating characteristics and a non-adiabatic mode with other characteristics. The control is implemented by controlling a configurable circuit at the output of the charge pump. | 2015-11-12 |
20150326114 | SELF-BOOTSTRAP DRIVING CIRCUIT AND DC-DC CONVERTER - A self-bootstrap driving circuit includes a first input receiving a first control signal; an output, to which a load having an electro-inductive component may be connected; a power switch having first and second current terminals and a control terminal, and being arranged to drive power from a power supply terminal to the load; a bootstrap circuitry arranged to drive the control terminal of the power switch based on the control signal; and a current path between the electro-inductive component of the load and the control terminal of the switch, said current path being arranged to provide direct transfer from said electro-inductive component to said control terminal of the switch of an overvoltage generated at the electro-inductive component to provide an overdrive voltage to said control terminal of the switch. | 2015-11-12 |
20150326115 | POWER SUPPLY CIRCUIT AND DISPLAY DEVICE - A power supply circuit and a display device are provided. The power supply circuit includes: a load, a DC power supply; a DC booster circuit; a load feedback circuit configured to generate a converted voltage in accordance with the current passing through the load, integrate the converted voltage to generate an integrated voltage and generate a first triggering signal in accordance with the integrated voltage; and a control circuit configured to generate a second triggering signal in according with the boosted voltage, a DC power supply voltage and a reference voltage, generate a switching signal for controlling the operation of the DC booster circuit in accordance with the first triggering signal and the second triggering signal, and output the switching signal to the DC booster circuit. | 2015-11-12 |
20150326116 | FREQUENCY JITTERING CONTROL CIRCUIT AND METHOD - A frequency jittering control circuit includes a frequency jittering circuit, a feedback compensation circuit, a comparator and a control circuit. The frequency jittering circuit generates a frequency jittering signal. The feedback compensation circuit generates a feedback compensation signal in response to the frequency jittering signal and an output signal. The comparator outputs a comparison output signal according to the feedback compensation signal and an oscillation signal. The control circuit outputs a frequency jittering control signal for switching a main switch in a power supply apparatus, according to the comparison output signal, such that the power supply apparatus correspondingly generates the output signal. | 2015-11-12 |
20150326117 | ILLUMINATION DEVICE CONTROL SYSTEMS AND METHODS - In various embodiments, a control system for an electronic circuit iteratively applies voltage to and senses current from a load to regulate operation of the load. | 2015-11-12 |
20150326118 | DRIVER METHOD - The invention provides advances in the arts with useful and novel driver methods. The invention provides circuit driver and control methods for relatively high-current drivers, usable with relatively low-voltage battery power sources. Preferred embodiments include one or more high series resistance capacitors electrically connected with a power source. A low resistance driver circuit regulates power supplied from the capacitors to the load. | 2015-11-12 |
20150326119 | VOLTAGE REGULATOR AND VOLTAGE REGULATING METHOD AND CHIP USING THE SAME - A voltage regulator with an on/off control on the control terminal of the power transistor of the voltage regulator. The power transistor of the voltage regulator drives the conversion from a first voltage to a second voltage. The voltage regulator provides a power-saving switch at the control terminal of the power transistor, and includes a power-saving control circuit controlling the power-saving switch. When the power-saving switch is turned on, the control signal for the power transistor is conveyed into the control terminal of the power transistor. When the power-saving switch is turned off, the connection between the control signal for the power transistor and the control terminal of the power transistor broken. | 2015-11-12 |
20150326120 | METHOD FOR CONTROLLING A DC-TO-DC CONVERTER - Methods and circuits for power supply arrangement and control are disclosed herein. More specifically the application relates to a control method and a controller for a DC-to-DC converter, such as a synchronous Buck converter, which implements a transient detection scheme together with response generation to allow the converter to recover from a positive and/or negative load current step in the robust way, with low undershoot/overshoot at the output voltage. The control method may be implemented by either an analog or a digital circuit. The controller may be integrated with existing controller schemes (such as voltage-mode controllers) to provide superior dynamic performance during large-signal transient conditions while providing stable operation during steady state conditions. The methods and circuits provided herein are applicable to Buck converters and Buck-derived converters such as forward, push-pull, half-bridge, and full-bridge converters. | 2015-11-12 |
20150326121 | METHOD AND CIRCUITRY FOR SENSING AND CONTROLLING A CURRENT - An inductor conducts a first current, which is variable. A first transistor is coupled through the inductor to an output node. The first transistor alternately switches on and off in response to a voltage signal, so that the first current is: enhanced while the first transistor is switched on in response to the voltage signal; and limited while the first transistor is switched off in response to the voltage signal. A second transistor is coupled to the first transistor. The second transistor conducts a second current, which is variable. On/off switching of the second transistor is independent of the voltage signal. Control circuitry senses the second current and adjusts the voltage signal to alternately switch the first transistor on and off in response to: the sensing of the second current; and a voltage of the output node. | 2015-11-12 |
20150326122 | CONVERTER ARRANGEMENT AND METHOD FOR OPERATING A CONVERTER ARRANGEMENT - A converter arrangement, in particular a switched DC/DC converter arrangement, comprises a control die and a converter die. The control die comprises a control logic for generating a control signal and a control output for controlling the converter die by means of the control signal. The converter die comprises at least one converter that is designed for converting an input signal into an output signal in dependence on the control signal, wherein the control signal can be received at a control input. A single-line interface connects the control output to the control input. | 2015-11-12 |