| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 181 | JPS5024085B1 - | JP11484170 | 1970-12-19 | JPS5024085B1 | 1975-08-13 | |
| 182 | JPS5099707A - | JP269974 | 1973-12-29 | JPS5099707A | 1975-08-07 | |
| 183 | JPS5093119A - | JP14267973 | 1973-12-18 | JPS5093119A | 1975-07-25 | |
| 184 | JPS5052396U - | JP10686073 | 1973-09-12 | JPS5052396U | 1975-05-20 | |
| 185 | JPS4912558Y1 - | JP9296769 | 1969-09-27 | JPS4912558Y1 | 1974-03-27 | |
| 186 | COMMAND TRANSLATION FOR PHYSICAL CONTROL OF SEGMENTED ARRAY | PCT/IB2024057655 | 2024-08-07 | WO2025032523A1 | 2025-02-13 | PANAS ROBERT MATTHEW |
| A system includes a non-transitory computer-readable medium configured to store a mapping between a set of subapertures and a plurality of adjustable optical elements. The system includes a user interface module configured to store properties of the set of subapertures and selectively update the mapping in response to user input. The system includes a command generation module configured to generate element commands for controlling the plurality of adjustable optical elements based on the properties of the set of subapertures. Generating an element command for a first element of the plurality of adjustable optical elements includes identifying an applicable subaperture for the first element, generating an initial command for the first element, and outputting the element command for the first element based on the initial command. | ||||||
| 187 | PROVIDING FEEDBACK TO A USER OF A HAND-HELD INKJET PRINTER | PCT/US2021052200 | 2021-09-27 | WO2023048732A1 | 2023-03-30 | SOLA TAPIAS ORIOL; SILVESTRE RIVERO RICARD; OLIVA VENTAYOL XAVIER |
| There is provided a system for providing feedback to a user of a hand-held inkjet printer, the system comprising a controller configured to determine an acceptable range of speed of the hand-held printer during printing as a function of a print job and a feedback device to provide feedback depending on the acceptable range of speed and a current speed of the hand-held printer during printing. There are also provided a hand-held inkjet printer, a non-transitory machine-readable storage medium and a method for reacting to a usage of a hand-held inkjet printer. | ||||||
| 188 | CONTROL SYSTEM FOR FLEXIBLE JOINT ROBOT | PCT/KR2022002067 | 2022-02-11 | WO2022191448A1 | 2022-09-15 | OH SE HOON; LEE DEOK JIN |
| A control system for a flexible joint robot according to the disclosed present invention comprises: a dimension conversion unit for control input which receives a control input of a robot and converts the control input in the orthogonal coordinate system to the rotating coordinate system; an overall dynamics unit for flexible joint robot which receives the control input and a disturbance and outputs a control output by multiplying the control input, in which the disturbance is reflected, by at least one determinant; and a disturbance observer which calculates an estimated disturbance, which is an estimation of the disturbance, and reflects the estimated disturbance in the control input, wherein the disturbance observer comprises a reaction force removal unit including a determinant for removing the reaction force between the joints of the robot, a low-pass filter, and a dimension conversion unit for estimated disturbance. | ||||||
| 189 | 전자 장치 및 전자 장치에서 사용자 피드백 기반의 발열 제어 방법 | PCT/KR2020/014903 | 2020-10-29 | WO2021086049A1 | 2021-05-06 | 방성용; 이재범; 이상민; 김종우; 김학열; 김무영 |
다양한 실시예에 따르면, 전자 장치는, 통신 회로, 디스플레이, 적어도 하나의 온도 센서, 상기 통신 회로, 상기 적어도 하나의 온도 센서와 작동적으로 연결되는 적어도 하나의 프로세서, 및 메모리를 포함하며, 상기 메모리는, 실행 시에, 상기 적어도 하나의 프로세서가, 상기 적어도 하나의 온도 센서를 이용하여 획득된 상기 전자 장치의 제1 발열 온도와 지정된 제1 발열 제어 정보를 기반으로 발열 제어하고, 사용자 피드백 기반의 제2 발열 제어 정보를 획득하여 상기 제1 발열 제어 정보를 상기 제2 발열 제어 정보로 변경하고, 상기 적어도 하나의 온도 센서를 이용하여 획득된 상기 전자 장치의 제2 발열 온도와 상기 제2 발열 제어 정보를 기반으로 발열 제어하는 인스트럭션들을 저장할 수 있으며, 다른 실시예도 가능하다. |
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| 190 | ENERGY EFFECIENT BLOW MOLDER CONTROL | PCT/US2019/015564 | 2019-01-29 | WO2019152365A1 | 2019-08-08 | WOLFE, Georg, V.; SCHMIDT, William, E.; JEBADURAI, Sudha; COWDEN, Robert |
Blow molder system and associated method optimizes the performance, energy efficiency and/or operating costs of the blow molder. A blow molder controller executes a system model that relates blow molder input parameter changes to the characteristics of containers generated by the blow molder. Equipped with energy and/or operating cost data for operating the blow molder, the blow molder controller can select a set of blow molder input parameter changes for the blow molder that: drives the containers produced by the blow molder toward desired container characteristics, in an efficient amount of time, and in cost effective manner, considering the energy costs involved in implementing the changes. |
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| 191 | AUTOMATIC WAFER CENTERING METHOD AND APPARATUS | PCT/US2019/015553 | 2019-01-29 | WO2019152360A1 | 2019-08-08 | KRUPYSHEV, Alexander; SHARROCK, Leigh |
A substrate transport apparatus including a transport chamber, a drive section, a robot arm having an end effector at a distal end configured to support a substrate and being connected to the drive section generating at least arm motion in a radial direction extending and retracting the arm, an imaging system with a camera mounted in a predetermined location to image at least part of the robot arm, and a controller connected to the imaging system to image the arm moving to a predetermined repeatable position, the controller effecting capture of a first image of the robot arm proximate to the repeatable position decoupled from encoder data of the drive axis, wherein the controller calculates a positional variance of the robot arm from comparison of the first image with a calibration image, and from the positional variance determines a motion compensation factor changing the extended position of the robot arm. |
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| 192 | METHOD AND APPARATUS FOR PRE-POSITIONING A STATIC, RADIALLY SYMETRIC, COAXIAL SAMPLE AND SHEATH COMBINATION TO PROVIDE UNIFORM SAMPLE DELIVERY DURING FLOW | PCT/US2018/055665 | 2018-10-12 | WO2019075364A1 | 2019-04-18 | EVANS, Nathaniel; HAYENGA, Jon W. |
A method for pre-positioning a coaxial sample and sheath combination includes calculating a load shape profile including a plurality of layers of substantially equal volume. The calculated load shape profile is incrementally divided into cross-sectional slices at a first set of distance coordinates along a first axis. Each cross-sectional slice transects the plurality of layers. A sample includes a number of objects residing in solution. A sample chamber is loaded with the sample by incrementally dispensing the sample in a plurality of portions along a vertical axis divided into a second set of distance coordinates proportional to the first set of distance coordinates, where each portion has a volume proportional to the cross-sectional slice at the first distance coordinate nearest in value to the second distance coordinate. |
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| 193 | ADAPTIVE DIGITAL CONTROLLER INCLUDING LINEAR AND NON-LINEAR CONTROL MECHANISM | PCT/US2018/025897 | 2018-04-03 | WO2018191067A1 | 2018-10-18 | MAHAJAN, Tarun; MUTHUKARUPPAN, Ramnarayanan; SIDANA, Rajesh; PAI, Srinath B. |
Some embodiments include apparatuses and methods of using such apparatuses. One of the apparatuses includes a control circuitry to generate error information based on a value of the feedback voltage generated from an output voltage, generate output information to control a power switching unit based on the error information provided to a forward path in the control circuitry, and adjust a gain of the forward path based on a gain factor computed based at least in part on a first value of the output information in order to cause the output information to have a second value. The control circuitry also computes a value of correction information when the output voltage is within a target value range, and adjusts the control information, based on the correction information, when the output voltage is outside the target value range. |
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| 194 | A SYSTEM FOR CALIBRATING VIBRATIONS IN THE CONTEXT OF SIMULATION | PCT/IB2018/052088 | 2018-03-27 | WO2018178865A1 | 2018-10-04 | MARCOTTE, Nicolas |
The present system and simulation environment calibrate vibrations. The system and simulation environment comprise a synthesizer for generating an electrical signal and a transducer for converting the electrical signal into vibrations propagated through a physical component and refracted in a physical space of the simulation environment. The system also comprises a vibration sensor measuring the vibrations propagated in the physical component. The system further comprises a configurator for calibrating the electrical signal generated by the synthesizer based on a vibration target for a simulated event and vibrations measured by the vibration sensor. |
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| 195 | TUNING METHOD OF PI AND PID CONTROLLERS | PCT/PL2012000036 | 2012-05-28 | WO2012165980A4 | 2013-03-07 | WCISLIK MIROSLAW; LASKAWSKI MICHAL |
| The invented controller tuning method relies on the following procedure. To the controlled system with known proportional gain the integral type controller is connected in series. The controller gain k 1 is increased to get the closed loop system to the stability limit. At this stage the controller ultimate gain k u and the sustained oscillation period T OSC of the controlled value are assessed. It is assumed that the controlled system dynamics can be approximated by the first order filter with dead time model. The following formulas allow to estimate the first order filter time constant F (1) and the coefficient ?= L/T = (arcctg(? OSC T))/(? OSC T) where L is the dead time constant of the controlled system model. From the formulas: F (2) the controller model parameters are calculated. After that on the basis of the calculated controller model parameters values the real controller parameters are calculated from the formulas: F (3) the proportional controller gain, the TiN is the integral controller time constant and the TdN is the derivative controller time constant. | ||||||
| 196 | 电液比例流量阀调速控制系统和方法 | PCT/CN2008/073091 | 2008-11-17 | WO2009067938A1 | 2009-06-04 | 石培科 |
| An electro-hydraulic proportional flow valve speed regulating control system includes a PWM regulating device, an electro-hydraulic proportional flow valve, a hydraulic executing element, a speed measuring module, an electro-hydraulic proportional flow valve characteristic measuring module, and a feedforward control module. The speed measuring module measures a speed of the hydraulic executing element and sends the measured result to the electro-hydraulic proportional flow valve characteristic measuring module which measures a minimum actuating current and a maximum actuating current of the electro-hydraulic proportional flow valve and a maximum speed of the hydraulic executing element and inputs these measured results to the feedforward control module. With these measured results, the feedforward control module establishes a corresponding relationship between the speed of the hydraulic executing element and the valve core current and inputs the valve core current in correspondence with the setting speed value to the PWM regulating device, thereby driving the electro-hydraulic proportional flow valve. | ||||||
| 197 | A METHOD AND APPARATUS FOR ELIMINATING STALL AND COGGING IN MULTI-PHASE STEPPING MOTORS | PCT/US2007022788 | 2007-10-29 | WO2008054687A2 | 2008-05-08 | COUTU DAVID |
| The lead or lag relationship between the stator and rotor of a stepper motor is monitored on a continuing basis by an incremental encoder, in feed-back relation, and adjusts the lead or lag to within optimum range values to thereby prevent motor stalls and motor cogging. | ||||||
| 198 | ANORDNUNG UND VERFAHREN ZUR TEMPERATURKOMPENSATION EINES WIDERSTANDS | PCT/EP2006/003206 | 2006-04-07 | WO2006108575A1 | 2006-10-19 | DENIER, Urs; SHARMA, Vivek |
Es ist eine Anordnung und ein Verfahren zur Temperaturkompensation eines Widerstands (1) angegeben. Ein bezüglich seines Widerstandswerts steuerbarer Widerstand (1) wird mit einem Referenzwiderstand (2) verglichen, der als Switched-Capacitor ausgebildet ist. Ein Vergleicher (3) vergleicht beide Widerstandswerte miteinander. In Abhängigkeit von einem Fehlersignal steuert der Vergleicher (3) den steuerbaren Widerstand (1) an. Somit ist ein temperaturstabiler Widerstand geschaffen. Das Prinzip ist bevorzugt in Transimpedanzverstärkern anwendbar. |
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| 199 | MICROMIRROR RESONANCE SUPRESSION USING CONFIGURABLE FILTER | PCT/US2023018763 | 2023-04-16 | WO2023229745A1 | 2023-11-30 | LIAO WENJUN; GUDAITIS ALGIRD MICHAEL; SUN RUIPENG |
| The configuring of a micromirror to suppress a resonance of the micromirror. As part of the configuring process, the micromirror is subjected to multiple actuation frequencies, and the micromirror response is measured in response to at least some of these actuation frequencies. A resonant frequency of the micromirror is then determined using at least some of the measured mechanical responses. Then, depending on this determined resonant frequency of the micromirror, notch filter parameters are selected. There is more than one possibility for notch filter parameters, where the selected possibility depends on the determined resonant frequency. The notch filter is then configured with the selected notch filter parameters. | ||||||
| 200 | POWER RATIOS FOR POWER ADJUSTMENTS | PCT/US2020047207 | 2020-08-20 | WO2022039747A1 | 2022-02-24 | ZHANG PETER; DAI FANGYONG; WANG LAN; CHEN QIJUN; LLOYD JON |
| Examples of electronic devices are described herein. In some examples, an electronic device includes a processor, a cooling device to provide thermal cooling to the processor, and a controller. In some examples, the controller is to determine a measured power ratio of processor power to cooling device power. In some examples, the controller is to compare the measured power ratio to a reference power ratio. In some examples, the controller is to determine a power adjustment for the electronic device based on the comparison of the measured power ratio to the reference power ratio. | ||||||
