Patent application number | Description | Published |
20090013785 | Detection circuit, physical quantity measurement circuit, physical quantity measurement device, and electronic instrument - A detection circuit includes a detection terminal to which an alternating current signal from a physical quantity transducer is input, a detection current/voltage conversion amplifier circuit that converts the alternating current signal input through the detection terminal into a voltage signal, an evaluation terminal that supplies an evaluation voltage signal to the detection current/voltage conversion amplifier circuit, an input resistor that has a given resistance ratio with respect to a feedback resistor; and a switch circuit of the detection circuit provided in a signal path that connects the evaluation terminal and an input node of the detection current/voltage conversion amplifier circuit. | 01-15-2009 |
20090033432 | OSCILLATION DRIVER DEVICE, PHYSICAL QUANTITY MEASURING DEVICE, AND ELECTRONIC INSTRUMENT - An oscillation driver device includes a gain control amplifier, an automatic gain control circuit, and a mode setting circuit. When the mode setting circuit has switched a mode from a normal operation mode to a low power consumption mode, the automatic gain control circuit is disabled, and the gain in an oscillation loop that drives the vibrator changes from a state in which the gain in the oscillation loop is controlled to be unity by the automatic gain control circuit to a state in which the gain in the oscillation loop is set to be larger than unity. When the mode setting circuit has switched the mode from the low power consumption mode to the normal operation mode, the automatic gain control circuit resumes operation, and the gain in the oscillation loop changes from the state in which the gain in the oscillation loop is set to be larger than unity to the state in which the gain in the oscillation loop is controlled to be unity by the automatic gain control circuit. | 02-05-2009 |
20090078045 | Driver device, physical quantity measuring device, and electronic instrument - A driver device that forms an oscillation loop with a vibrator and causes the vibrator to produce driving vibrations includes a current-voltage converter that is provided in the oscillation loop and converts a current that flows through the vibrator into a voltage, and a GCA as a comparator that is provided in the oscillation loop and outputs a signal corresponding to a comparison result between an output from the current-voltage converter and a given voltage. The GCA outputs a first high-level voltage or a low-level voltage during oscillation startup, and outputs a second high-level voltage or the low-level voltage in a steady oscillation state. The first high-level voltage is a voltage higher in potential than the second high-level voltage. | 03-26-2009 |
20090084180 | OSCILLATION DRIVER CIRCUIT, OSCILLATION DRIVER DEVICE, PHYSICAL QUANTITY MEASUREMENT CIRCUIT, PHYSICAL QUANTITY MEASUREMENT DEVICE, AND ELECTRONIC INSTRUMENT - An oscillation driver circuit that drives a physical quantity transducer includes a one-input/two-output comparator. The one-input/two-output comparator includes a shared differential section that compares a voltage signal input from a drive current/voltage conversion amplifier circuit with a given voltage, a first output section that receives a signal output from the differential section, variably adjusts a voltage amplitude of the received signal, and outputs the resulting signal, and a second output section that receives the signal output from the differential section, and outputs a synchronous detection reference signal of which the voltage amplitude is fixed. | 04-02-2009 |
20090133496 | Driver device, physical quantity measuring device, and electronic instrument - An oscillation driver circuit includes a current-voltage converter which converts a current value of an oscillation signal in an oscillation loop into a voltage value, and a comparator which outputs a signal corresponding to the result of comparison between the output signal from the current-voltage converter and a given reference signal. The comparator has an output current limiting function. The oscillation driver circuit causes the vibrator to produce driving vibrations based on the output from the comparator. | 05-28-2009 |
20090237151 | TEMPERATURE COMPENSATION CIRCUIT - A temperature compensation circuit performing temperature compensation of an analog reference voltage, includes: a first reference voltage generating circuit generating a first voltage of which a voltage level varies depending on a temperature; a second reference voltage generating circuit generating a second voltage of which a voltage level is independent of a temperature and having a circuit configuration that is same as a circuit configuration of the first reference voltage generating circuit; an inverting amplifier having a gain of 1, which inverts and amplifies a voltage difference between the first voltage and the second voltage so as to generate a third voltage; and a differential amplifier amplifying a voltage difference between the third voltage and the first voltage so as to generate a fourth voltage In the temperature compensation circuit, the differential amplifier includes: a first operational amplifier; a first resistor coupled between a first node and a second node that is an inverting input terminal of the first operational amplifier; a second resistor coupled between a third node and a fourth node that is a non-inverting input terminal of the first operational amplifier; a third resistor coupled between the second node and a fifth node that is an output node of the first operational amplifier; and a fourth resistor coupled between the fourth node and a sixth node to which an analog reference voltage is applied. Further, in the circuit, resistance values of the first resistor and the second resistor are set to be same as each other, and resistance values of the third resistor and the fourth resistor are set to be same as each other. | 09-24-2009 |
20100071466 | SYNCHRONOUS DETECTION CIRCUIT, SENSING CIRCUIT, PHYSICAL QUANTITY MEASURING DEVICE, GYRO SENSOR, AND ELECTRONIC APPARATUS - A synchronous detection circuit includes: an offset compensation circuit which generates an offset compensation voltage to compensate an offset voltage superposed on a direct current voltage signal; and a temperature compensation circuit which generates a temperature compensation voltage to compensate variation of a direct current reference voltage that depends on a temperature in a signal path of a sensing circuit. In the circuit, the synchronous detection circuit synchronously detects an alternating current signal, the offset compensation voltage and the temperature compensation voltage are respectively superposed on the alternating current signal which is input into the synchronous detection circuit, and the synchronous detection circuit synchronously detects the alternating current signal on which the offset compensation voltage and the temperature compensation voltage have been superposed. | 03-25-2010 |
20100206074 | OSCILLATION DRIVE DEVICE, PHYSICAL QUANTITY MEASUREMENT DEVICE AND ELECTRONIC APPARATUS - There is provided an oscillation drive device that forms an oscillation loop with a vibrator for exciting a driving vibration on the vibrator. The oscillation drive device includes: a comparator that excites a driving vibration on the vibrator based on a signal in the oscillation loop with a given voltage as a reference; an oscillation detector that detects oscillation in the oscillation loop; a signal generation circuit that generates a switching control signal based on an oscillation result given by the oscillation detector; and a switch circuit inserted between the vibrator in the oscillation loop and an output of the comparator, wherein, during an oscillation startup stage in which oscillation in the oscillation loop is not detected by the oscillation detector, the switch circuit alternately switches, based on the switching control signal, between a period in which the output of the comparator and the vibrator are electrically connected and a period in which a predetermined set voltage is supplied to the vibrator. | 08-19-2010 |
20110121907 | Driver device, physical quantity measuring device, and electronic instrument - A driver device that forms an oscillation loop with a vibrator and causes the vibrator to produce driving vibrations includes a current-voltage converter that converts a current that flows through the vibrator into a voltage, an output circuit that causes the vibrator to produce the driving vibrations based on a signal that is converted into a voltage with respect to a given voltage, and a high-pass filter that is provided in the oscillation loop between the current-voltage converter and the output circuit. The driver device causes the vibrator to produce the driving vibrations while changing a reference potential of the high-pass filter, and then causes the vibrator to produce the driving vibrations while fixing the reference potential. | 05-26-2011 |
20120183016 | TEMPERATURE DETECTION CIRCUIT AND SENSOR DEVICE - A temperature detection circuit capable of generating a temperature detection voltage with reduced noise level, and a sensor device using the same are provided. The temperature detection circuit includes a temperature detection voltage generator that generates a first temperature detection voltage of which the voltage level based on a reference voltage varies according to the temperature; a temperature detection voltage inverter that inverts the first temperature detection voltage on the basis of the reference voltage, and amplifies or attenuates the first temperature detection voltage to generate a second temperature detection voltage; and a temperature detection voltage adder that adds up the first temperature detection voltage and the second temperature detection voltage. | 07-19-2012 |
Patent application number | Description | Published |
20090084500 | PROCESSING APPARATUS, EXHAUST PROCESSING PROCESS AND PLASMA PROCESSING PROCESS - There is disclosed an exhaust processing process of a processing apparatus for processing a substrate or a film, which comprises after the processing of the substrate or the film, introducing a non-reacted gas and/or a by-product into a trap means comprising a filament comprised of a high-melting metal material comprising as a main component at least one of tungsten, molybdenum and rhenium; and processing the non-reacted gas and/or the by-product inside the trap means. This makes it possible to prevent lowering in exhaust conductance, to lengthen the maintenance cycle of the processing apparatus, and to provide a high-quality product (processed substrate or film). | 04-02-2009 |
20090095420 | PROCESSING APPARATUS, EXHAUST PROCESSING PROCESS AND PLASMA PROCESSING PROCESS - There is disclosed an exhaust processing process of a processing apparatus for processing a substrate or a film, which comprises after the processing of the substrate or the film, introducing a non-reacted gas and/or a by-product into a trap means comprising a filament comprised of a high-melting metal material comprising as a main component at least one of tungsten, molybdenum and rhenium; and processing the non-reacted gas and/or the by-product inside the trap means. This makes it possible to prevent lowering in exhaust conductance, to lengthen the maintenance cycle of the processing apparatus, and to provide a high-quality product (processed substrate or film). | 04-16-2009 |
20090114155 | PROCESSING APPARATUS, EXHAUST PROCESSING PROCESS AND PLASMA PROCESSING PROCESS - There is disclosed an exhaust processing process of a processing apparatus for processing a substrate or a film, which comprises after the processing of the substrate or the film, introducing a non-reacted gas and/or a by-product into a trap means comprising a filament comprised of a high-melting metal material comprising as a main component at least one of tungsten, molybdenum and rhenium; and processing the non-reacted gas and/or the by-product inside the trap means. This makes it possible to prevent lowering in exhaust conductance, to lengthen the maintenance cycle of the processing apparatus, and to provide a high-quality product (processed substrate or film). | 05-07-2009 |
20090145555 | PROCESSING APPARATUS, EXHAUST PROCESSING PROCESS AND PLASMA PROCESSING PROCESS - There is disclosed an exhaust processing process of a processing apparatus for processing a substrate or a film, which comprises after the processing of the substrate or the film, introducing a non-reacted gas and/or a by-product into a trap means comprising a filament comprised of a high-melting metal material comprising as a main component at least one of tungsten, molybdenum and rhenium; and processing the non-reacted gas and/or the by-product inside the trap means. This makes it possible to prevent lowering in exhaust conductance, to lengthen the maintenance cycle of the processing apparatus, and to provide a high-quality product (processed substrate or film). | 06-11-2009 |
Patent application number | Description | Published |
20130008371 | METHOD FOR MANUFACTURING POLYCRYSTALLINE SILICON INGOT, AND POLYCRYSTALLINE SILICON INGOT - A method for manufacturing a polycrystalline silicon ingot includes unidirectionally solidifying a molten silicon upwardly from the bottom of a crucible, wherein the crucible is provided with silica deposited on the bottom of the crusible; and then dividing the degree of solidification in the crucible into a first zone from 0 mm to X in height (10 mm≦X<30 mm), a second zone from X to Y in height (30 min≦Y<100 mm) and a third zone of Y or more in height, based on the bottom of the crucible, wherein a solidification rate V1 in the first zone is set in the range of 10 mm/h≦V1≦20 mm/h and a solidification rate V2 in the second zone is set in the range of 1 mm/h≦V2≦5 mm/h. | 01-10-2013 |
20130015318 | LAYERED CRUCIBLE FOR CASTING SILICON INGOT AND METHOD OF PRODUCING SAMEAANM Wakita; SaburoAACI Noda-shiAACO JPAAGP Wakita; Saburo Noda-shi JPAANM Tsuzukihashi; KojiAACI Akita-shiAACO JPAAGP Tsuzukihashi; Koji Akita-shi JPAANM Ikeda; HiroshiAACI TokyoAACO JPAAGP Ikeda; Hiroshi Tokyo JPAANM Kanai; MasahiroAACI Akita-shiAACO JPAAGP Kanai; Masahiro Akita-shi JP - Provided are a layered crucible for casting a silicon ingot that can suppress dissolution of oxygen into the silicon ingot and a method of producing the same crucible. The layered crucible for casting a silicon ingot is used in the production of a silicon ingot by melting and casting a silicon raw material. The layered crucible comprising: a silica layer provided on the inner side of a mold; and a barium coating layer provided on the surface of the silica layer. | 01-17-2013 |
20130028825 | MANUFACTURING METHOD FOR POLYCRYSTALLINE SILICON INGOT, AND POLYCRYSTALLINE SILICON INGOT - A method for manufacturing a polycrystalline silicon ingot includes: solidifying a silicon melt retained in a crucible unidirectionally upward from a bottom surface of the silicon melt, wherein a silicon nitride coating layer is formed on inner surfaces of side walls and an inner side surface of a bottom of the crucible, a solidification process in the crucible is divided into a first region from 0 mm to X (10 mm≦X<30 mm) in hight, a second region from X to Y (30 mm≦Y<100 mm), and a third region of the Y or higher, with the bottom of the crucible as a datum, a solidification rate V1 in the first region is in a range of 10 mm/h≦V1≦20 mm/h, and a solidification rate V2 in the second region is in a range of 1 mm/h≦V2≦5 mm/h. | 01-31-2013 |
20130122278 | POLYCRYSTALLINE SILICON INGOT MANUFACTURING APPARATUS, POLYCRYSTALLINE SILICON INGOT MANUFACTURING METHOD, AND POLYCRYSTALLINE SILICON INGOT - A polycrystalline silicon ingot manufacturing apparatus, a polycrystalline silicon ingot manufacturing method, and a polycrystalline silicon ingot are provided. The apparatus comprises: a crucible having a rectangular shape in a cross-section; an upper heater provided above the crucible; and a lower heater provided below the crucible. A silicon melt stored in the crucible is solidified from a bottom surface of the crucible upward unidirectionally. The apparatus further comprises an auxiliary heater that heats at least a bottom-surface-side portion of a sidewall of the crucible. The production yield can be improved by using the apparatus and by reducing the oxygen concentration at the location where the oxygen concentration tends to be high locally at the bottom part of the ingot. | 05-16-2013 |