| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 21 | METHOD AND APPARATUS FOR SENSING | EP03709845.6 | 2003-03-17 | EP1485672A1 | 2004-12-15 | SUORSA, Ilkka; TELLINEN, Juhani; ULLAKKO, Kari; AALTIO, Ilkka |
| The present invention relates to a method for sensing electrical or magnetic and the like parameters and for utilizing the same, comprising taking a piece of material with stress-influenced parameters based on structural changes; directing on the material forces which effect a shape change on it; measuring the change in magnetic, electrical or the like parameters of the piece of material; and using the measured parameters for controlling further operations. The invention also relates to apparatus for this purpose. | ||||||
| 22 | Système de repérage du mouvement d'un véhicule à chenilles | EP87403008.3 | 1987-12-30 | EP0277447B1 | 1991-02-27 | Clément, Gilles; Detriche, Jean-Marie; Villedieu, Eric |
| 23 | METHOD AND APPARATUS FOR DETERMINING AT LEAST ONE CHARACTERISTIC VALUE OF MOVEMENT OF A BODY | EP85904447.1 | 1985-09-04 | EP0192719B1 | 1991-01-16 | Pötsch, Edmund R. |
| With the apparatus any acceleration/deceleration in the direction of movement is sensed by a pendulum. Electrical signals derived therefrom are used for solving the differential equation of oscillation of the pendulum for determining the acceleration, velocity and/or the distance covered by the moved body within a desired time period. | ||||||
| 24 | Method and apparatus for generating nose wheel speed signals | EP81200435.6 | 1981-04-15 | EP0038606B1 | 1985-01-30 | DeVlieg, Garrett Howard; Valaas, Andrew McClintock |
| 25 | Electronic tachometer circuit | EP79103350.9 | 1979-09-07 | EP0009663B1 | 1983-06-08 | Bradley, Edward Franklin; Mueller, Francis Edward |
| 26 | Electronic tachometer circuit | EP79103350.9 | 1979-09-07 | EP0009663A1 | 1980-04-16 | Bradley, Edward Franklin; Mueller, Francis Edward |
An electronic tachometer circuit uses a cyclically discontinuous position error signal PES to derive a velocity signal. The signal PES is differentiated by a narrow bandwidth high pass filter in a position channel 27. Motor current signals are used to derive a current reference signal by a low pass filter in a current channel 29. Discontinuous portions of the signal PES are detected by a level detector42 which then activates a track and fill circuit 32 to provide a fill-in signal from the current reference signal to the position channel 27. |
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| 27 | SPORT MONITORING SYSTEM FOR DETERMINING AIRTIME, SPEED, POWER ABSORBED AND OTHER FACTORS SUCH AS DROP DISTANCE | PCT/US9811268 | 1998-06-02 | WO9854581A9 | 1999-04-22 | VOCK CURTIS A; DARCY DENNIS; BODKIN ANDREW; YOUNGS PERRY; LARKIN ADRIAN F; FINBERG STEVEN; BURKE SHAWN; MARSHALL CHARLES; GREALISH KEVIN J |
| The invention detects the loft time, speed, power and/or drop distance of a vehicle, such as a sporting vehicle, during activities of moving and jumping. A loft sensor (14b) detects when the vehicle leaves the ground and when the vehicle returns to the ground. A controller subsystem (12) converts the sensed information to determine a loft time. A display (52) shows the recorded loft time to a user of the system. In addition, a speed sensor (14a) can detect the vehicle's speed for selective display to the user. A power sensing section (14d) informs the user of expended energy, which can be compared to other users. A drop distance sensing unit (14c) informs the user of the peak height of a jump, during an airtime. Gaming on the internet (84) is facilitated to connect worldwide sport enthusiasts. | ||||||
| 28 | SYSTEM AND METHOD FOR DETECTING MOVING OBSTACLES BASED ON SENSORY PREDICTION FROM EGO-MOTION | US15960513 | 2018-04-23 | US20180322640A1 | 2018-11-08 | Kyungnam Kim; Hyukseong Kwon; Heiko Hoffmann |
| Described is a system for detecting moving objects. During operation, the system obtains ego-motion velocity data of a moving platform and generates a predicted image of a scene proximate the moving platform by projecting three-dimensional (3D) data into an image plane based on pixel values of the scene. A contrast image is generated based on a difference between the predicted image and an actual image taken at a next step in time. Next, an actionable prediction map is then generated based on the contrast mage. Finally, one or more moving objects may be detected based on the actionable prediction map. | ||||||
| 29 | CPR CHEST COMPRESSION MONITOR WITH REFERENCE SENSOR | US15338747 | 2016-10-31 | US20170042763A1 | 2017-02-16 | Annemarie E. Silver; Ulrich R. Herken |
| Methods and devices for chest compression depth measurement for CPR. | ||||||
| 30 | Magnetic based contactless measuring sensor | US14116422 | 2012-05-04 | US09476691B2 | 2016-10-25 | Lutz May |
| Contactless measurement sensor for measuring at least one of a distance to an object to be sensed, a motion with respect to an object to be sensed, a speed with respect to an object to be sensed, a torque applied to an object to be sensed and a force applied to an object to be sensed the contactless measurement sensor comprises a first magnetic field generating unit being adapted for generating a magnetic field towards the object to be sensed, a first magnetic field detector unit being adapted for detecting a first magnetic field which field being generated by the first field generator unit and being influenced by a respective distance, motion, speed, applied torque and applied force to be measured, wherein the first magnetic field detector unit is further adapted for outputting a first signal being representative for the detected magnetic field, and an evaluating unit being adapted for evaluating a signal strength of the first signal and determining the respective distance, motion, speed, applied torque and applied force based on the first signal. | ||||||
| 31 | CPR Chest Compression Monitor for Infants | US14068649 | 2013-10-31 | US20150120201A1 | 2015-04-30 | Annemarie E. Silver; Ulrich R. Herken |
| Methods and devices for chest compression depth measurement for CPR performed on infants. | ||||||
| 32 | Activity monitoring systems and methods | US13231624 | 2011-09-13 | US08352211B2 | 2013-01-08 | Curtis A. Vock; Peter Flentov; Dennis M. Darcy |
| An activity monitor, comprises housing for attachment to a person; at least one accelerometer disposed within the housing; and a processor disposed within the housing, for processing signals from the accelerometer to assess activity of the person. A method assesses activity of a person, including: sensing acceleration at a first location on the person; processing the acceleration, over time, to assess activity of the person; and wirelessly communicating information indicative of the activity to a second location. | ||||||
| 33 | System including signal offset estimation | US12428137 | 2009-04-22 | US08183856B2 | 2012-05-22 | Simon Hainz; Christof Bodner; Mario Motz; Tobias Werth; Dirk Hammerschmidt |
| A system includes a first circuit configured to convert a first analog signal to a first digital signal. The system includes a second circuit configured to determine an area of the first digital signal above a set value and an area of the first digital signal below the set value to provide a second digital signal indicating an offset of the first analog signal. | ||||||
| 34 | MAGNETIC DETECTION APPARATUS | US12907599 | 2010-10-19 | US20110260724A1 | 2011-10-27 | Yoshinori TATENUMA; Hideki SHIMAUCHI; Masahiro YOKOTANI; Yuji KAWANO; Hiroshi KOBAYASHI; Kazuyasu NISHIKAWA; Manabu TSUKAMOTO |
| A magnetic detection apparatus includes a first comparison circuit that waveform-shapes the amplitude of a detection signal from magneto-electric transducers by DC coupling, a third comparison circuit that waveform-shapes the detection signal by AC coupling, an oscillation circuit having a natural frequency, a control circuit that counts the output of the first comparison circuit by using the oscillation means, and a selection circuit that selects the output of the first comparison means and the output of the second comparison means. The control circuit counts rising from the next rising or falling from the next falling of an output rectangular wave of the first comparison circuit, and provides output to the selection circuit at the time point at which the count value reaches a desired value. The selection circuit selects and outputs the output rectangular wave of the first comparison circuit or the third comparison circuit. | ||||||
| 35 | METHOD AND DEVICE FOR DETECTING THE ROTATION OF A BRUSH-OPERATED D.C. MOTOR | US12564668 | 2009-09-22 | US20100072933A1 | 2010-03-25 | Holger Wuerstlein; Wolf-Christian Mueller; Wolfgang Uebel |
| a method and a device for detecting the rotation of a brush-operated d.c. motor comprising a number of winding branches which are electrically connected between brushes, during the operation of the motor, by means of plates, according to the rotational angle. According to the invention, an alternating voltage signal is modulated on the basis of a supply direct voltage for the brushes, by which means the course of the complex resistance of the direct current motor is determined and used for the detection of rotation. In this way, the invention enables a cost-effective rotation detection that can be used in motor vehicle technology without requiring additional mechanical components. | ||||||
| 36 | SYSTEM INCLUDING SIGNAL OFFSET ESTIMATION | US12428137 | 2009-04-22 | US20090273341A1 | 2009-11-05 | Simon Hainz; Christof Bodner; Mario Motz; Tobias Werth; Dirk Hammerschmidt |
| A system includes a first circuit configured to convert a first analog signal to a first digital signal. The system includes a second circuit configured to determine an area of the first digital signal above a set value and an area of the first digital signal below the set value to provide a second digital signal indicating an offset of the first analog signal. | ||||||
| 37 | ACTIVITY MONITORING SYSTEMS AND METHODS | US12370795 | 2009-02-13 | US20090150114A1 | 2009-06-11 | Curtis A. Vock; Peter Flentov; Dennis M. Darcy |
| An activity monitor, comprises housing for attachment to a person; at least one accelerometer disposed within the housing; and a processor disposed within the housing, for processing signals from the accelerometer to assess activity of the person. A method assesses activity of a person, including: sensing acceleration at a first location on the person; processing the acceleration, over time, to assess activity of the person; and wirelessly communicating information indicative of the activity to a second location. | ||||||
| 38 | Activity monitoring systems and methods | US11434588 | 2006-05-15 | US07451056B2 | 2008-11-11 | Peter Flentov; Dennis M. Darcy; Curtis A. Vock |
| An activity monitor, comprises housing for attachment to a person; at least one accelerometer disposed within the housing; and a processor disposed within the housing, for processing signals from the accelerometer to assess activity of the person. A method assesses activity of a person, including: sensing acceleration at a first location on the person; processing the acceleration, over time, to assess activity of the person; and wirelessly communicating information indicative of the activity to a second location. | ||||||
| 39 | Mobile GPS systems for providing location mapping and/or performance data | US11484199 | 2006-07-10 | US07158912B2 | 2007-01-02 | Curtis A. Vock; Dennis Darcy; Peter Flentov |
| A location measurement system comprises: a GPS receiver for attachment to a person and for determining earth location of the person; a display for attachment to the person; memory for storing map data; a processor configured to process earth location and the map data to instruct display the person's current location with a map on the display. Other GPS systems for example determine speed with or without map capability or altimeters. | ||||||
| 40 | Methods and systems for assessing athletic performance | US09992966 | 2001-11-06 | US06885971B2 | 2005-04-26 | Curtis A. Vock; Dennis Darcy; Andrew Bodkin; Charles Marshall; Peter Flentov |
| The invention detects the loft time, speed, power and/or drop distance of a vehicle, such as a sporting vehicle, during activities of moving and jumping. A loft sensor detects when the vehicle leaves the ground and when the vehicle returns to the ground. A controller subsystem converts the sensed information to determine a loft time. A display shows the recorded loft time to a user of the system. In addition, a speed sensor can detect the vehicle's speed for selective display to the user. A power sensing section informs the user of expended energy, which can be compared to other users. A drop distance sensing unit informs the user of the peak height of a jump, during an airtime. Gaming on the internet is facilitated to connect worldwide sport enthusiasts. | ||||||
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