Patent application number | Description | Published |
20100188157 | ELECTRONIC CIRCUIT - This invention makes it possible to reduce a power consumption of an electronic circuit (microcomputer, for example) while preventing malfunctioning of an oscillator by appropriately setting a power supply impedance of a low frequency oscillator corresponding to an operation mode. A high frequency oscillator, a medium frequency oscillator and a low frequency oscillator are provided as sources of system clocks. In addition, there is provided a quartz oscillator to generate a clock for a timepiece. When the high frequency oscillator is in operation, a power supply impedance of the quartz oscillator is reduced to improve a noise tolerance. In a waiting period during which the high frequency oscillator, the medium frequency oscillator and the low frequency oscillator are halted, on the other hand, the power supply impedance of the quartz oscillator is increased to suppress the power consumption. | 07-29-2010 |
20110033194 | REMOTE CONTROL SIGNAL RECEIVING CIRCUIT - The invention is directed to decreasing the power consumption of a remote control signal receiving circuit. A receiving circuit includes a timing signal generation circuit generating a timing signal, a power supply circuit intermittently operating a light receiving element receiving a remote control signal by supplying power to the light receiving element when the timing signal is at a first level and by halting supplying power to the light receiving element when the timing signal is at a second level, a sampling signal generation circuit generating a sampling signal during the operation of the light receiving element corresponding to the timing signal, a sampling circuit sampling an output signal from the light receiving element corresponding to the sampling signal, and a detection circuit detecting the output signal sent from the light receiving element and sampled by the sampling circuit. | 02-10-2011 |
20110080210 | MICROCOMPUTER - A power consumption of a light-receiving device is reduced while a power consumption of a microcomputer that controls the light-receiving device is reduced as well. The microcomputer is structured to include a drive circuit, a sampling/detection circuit, a timer, a system clock generation circuit, a CPU, a ROM and a RAM. The CPU stops providing the light-receiving device with a power supply by turning off a P channel type MOS transistor with the drive circuit and sets the microcomputer in a standby state for a predetermined period of time. When the microcomputer is released from the standby state, the CPU starts providing the light receiving device with the power supply by turning the P channel type MOS transistor on with the drive circuit. | 04-07-2011 |
20120056596 | REMAINING BATTERY POWER CALCULATION CIRCUIT - A remaining battery power calculation circuit includes: a detection unit configured to detect an output voltage of a battery; a data storage unit configured to store data in an associated manner with each of a plurality of current values for charge or discharge of the battery, the data indicating a relationship between the output voltage and a ratio of remaining power of the battery to a capacity of the battery in a case where the battery is charged or discharged with each of the plurality of current values; and a first calculation unit configured to calculate a charging/discharging current of the battery based on the data and the output voltage. | 03-08-2012 |
20130197831 | FLUID FLOW RATE MEASURING DEVICE AND WATER METER - A water meter that requires neither a smoothing capacitor of large capacitance nor a high frequency reference clock is offered. A rotation detection unit is formed to include a first coil, a first capacitor, a charging transistor, a power supply line, an activation transistor, an output buffer circuit, a DA converter, a comparator and a counter. A first LC resonant circuit is provided with the activation transistor connected in series with the first coil, the first capacitor connected in parallel with the first coil and the charging transistor for charging the first capacitor. The first LC resonant circuit is activated by turning on the activation transistor after the first capacitor is charged by turning on the charging transistor. | 08-01-2013 |
20130220028 | FLUID FLOW RATE MEASURING DEVICE AND WATER METER - There is offered a water meter that requires no coil so that its cost is reduced. The water meter is formed to include an impeller, a rotation reduction unit, a first circular plate, a second circular plate, a rotation detection unit and an arithmetic unit. The rotation detection unit forms first, second and third combination capacitors with a switching circuit. The rotation detection unit detects changes in capacitances of the first, second and third combination capacitors associated with a rotation of the first circular plate. The arithmetic unit is configured so as to electrically detect the rotation angle θ of the first circular plate based on the changes in the capacitances. | 08-29-2013 |
20140015476 | CHARGING SYSTEM FOR PORTABLE ELECTRONIC EQUIPMENT - In a charging system for portable electronic equipment, providing the charging current is automatically restarted even in the case where an amount of charging current taken into the portable electronic equipment exceeds charging current providing capacity of a USB battery charger and the USB battery charger stops providing the charging current. When a voltage at a VBUS terminal is lower than a first predetermined voltage, a CPU assumes that the USB battery charger has stopped providing the charging current and turns off a first switching device. And the CPU turns on a second switching device for a predetermined period of time. As a result, the voltage at the VBUS terminal falls to 0.7V or below during the predetermined period of time. In response to the change in the voltage at the VBUS terminal, the USB battery charger restarts providing the charging current to the VBUS terminal. | 01-16-2014 |
20140176146 | METHOD FOR DETERMINING A POWER LEVEL OF A BATTERY AND CIRCUIT THEREFOR - A remaining battery power calculation circuit includes: a detection unit configured to detect an output voltage of a battery; a data storage unit configured to store data in an associated manner with each of a plurality of current values for charge or discharge of the battery, the data indicating a relationship between the output voltage and a ratio of remaining power of the battery to a capacity of the battery in a case where the battery is charged or discharged with each of the plurality of current values; and a first calculation unit configured to calculate a charging/discharging current of the battery based on the data and the output voltage. | 06-26-2014 |
Patent application number | Description | Published |
20090091980 | SEMICONDUCTOR INTEGRATED CIRCUIT - In the semiconductor integrated circuit incorporating non-volatile memory that is not electrically rewritable, updating stored data and reusing the non-volatile memory are made possible. The data stored in the non-volatile memory can be updated and the non-volatile memory can be reused by dividing the non-volatile memory into a plurality of blocks and replacing a used block with an unused block. When data “1” is set in the first flag of a certain block, a block selection circuit judges that data is already written in the block and rewriting new data into the block is not possible. To update the stored data, the updated data is written into a block that is selected by the block selection circuit out of the rest of the blocks. At that time, the first flag of the block is set to data “1”. Stored data is updated one after another as described above. When data of final update is written into a certain block, the second flag of the block is set to data “1”. | 04-09-2009 |
20090100117 | SEMICONDUCTOR INTEGRATED CIRCUIT - The invention reduces unnecessary electromagnetic radiation noise due to an operation clock signal generated by an oscillator circuit. Random number data outputted by a random number generation circuit is stored in a frequency variable data register. The data stored in the frequency variable data register is replaced by random number data sequentially generated by the random number generation circuit. An oscillator circuit is a circuit generating a clock signal, and the clock signal is supplied as an operation clock signal to an internal circuit through an operation clock signal generation circuit. The frequency of the clock signal from the oscillator circuit is variably controlled in response to the random number data stored in the frequency variable data register. A frequency variable range control register which stores control data for controlling the range of the frequency variably controlled in response to the random number data stored in the frequency variable data register is further provided. | 04-16-2009 |
20090100119 | SEMICONDUCTOR INTEGRATED CIRCUIT - The invention reduces unnecessary electromagnetic radiation noise associated with a step pulse of an output signal. A random number control register is a register for controlling start, standby, stop, timing or the like of output of random number data from a random number generation circuit. Random number data outputted by the random number generation circuit is stored in a rise/fall time variable data register. The data stored in the rise/fall time variable data register is replaced by random number data sequentially generated by the random number generation circuit. An output circuit is a circuit for outputting a signal from an internal circuit of a microcomputer to an external device, and the rise/fall times of the output signal from the output circuit are variably controlled in response to the random number data stored in the rise/fall time variable data register. | 04-16-2009 |