Abstract: A position sensor including at least one magnet producing a magnetic field, at least one magnetic flux sensing device sensing the magnetic field, and a ferrous sleeve. The ferrous sleeve being rotatable about a longitudinal axis of the magnet. The magnetic field detected by the magnetic flux sensing device being substantially unaffected by rotation of the ferrous sleeve relative to the magnet.

Abstract: A position sensor including a rotatable shaft, a first threaded member, a second threaded member, at least one magnet, and at least one magnetic flux detection device. The first threaded member is connected to the rotatable shaft. The second threaded member is threadably engaged with the first threaded member. The at least one magnet is connected to the second threaded member. The at least one magnetic flux detection device is positioned to detect a magnetic field from the at least one magnet.

Abstract: A position sensor for sensing an angular position including at least two magnetic conductive structures, at least two magnets, a magnetic flux responsive device, and an arcuate magnet. The at least two magnetic conductive structures include a first magnetic conductive structure and a second magnetic conductive structure. The first magnetic conductive structure is substantially arcuately parallel with the second magnetic conductive structure. The at least two magnets include a first magnet and a second magnet. The first magnet being magnetically coupled with the first magnetic conductive structure and with the second magnetic conductive structure. The second magnet being magnetically coupled with both the first magnetic conductive structure and the second magnetic conductive structure. The magnetic flux responsive device is constrained to travel a path that is partially located between the first magnetic conductive structure and the second magnetic conductive structure.

Abstract: A position sensor including a rotatable shaft, a first threaded member, a second threaded member, at least one magnet, and at least one magnetic flux detection device. The first threaded member is connected to the rotatable shaft. The second threaded member is threadably engaged with the first threaded member. The at least one magnet is connected to the second threaded member. The at least one magnetic flux detection device is positioned to detect a magnetic field from the at least one magnet.

Abstract: A position sensor for sensing linear or radial position including at least two magnetic conductive structures, at least two magnets and a magnetic flux responsive device. The at least two magnetic conductive structures, include a first magnetic conductive structure and a second magnetic conductive structure. The first magnetic conductive structure being substantially parallel with the second magnetic conductive structure. The at least two magnets, including a first magnet and a second magnet. The first magnet being in contact with the first magnetic conductive structure and with the second magnetic conductive structure. The second magnet being in contact with both the first magnetic conductive structure and the second magnetic conductive structure. The magnetic flux responsive device constrained to travel a path that is partially located between the first magnetic conductive structure and the second magnetic conductive structure, with the path extending beyond at least one of the at least two magnets.

Abstract: A sensor system including a sensor having at least one magnet and a plurality of magnetic flux responsive devices fixedly adjacent to the at least one magnet. Each of the plurality of magnetic flux responsive devices have a primary sensing plane, at least two of the primary sensing planes being offset from each other. A quadrature normalization circuit is communicatively connected to the sensor.

Abstract: The present invention is directed to a resin ceramic composition that includes a ceramic filler in an amount effective for providing a single composition with a magnetic field of at least one gauss.

Abstract: A position sensor for sensing linear or radial position, including at least four magnets, a first ferrous plate having at least two of the at least four magnets located at spaced locations along the first ferrous plate, the at least two magnets being oriented such that a north pole of at least one of the at least two magnets is directed toward the first ferrous plate and a south pole of an other of the at least two magnets is directed toward the first ferrous plate, a second ferrous plate having at least two of the at least four magnets located at spaced locations along the second ferrous plate, the at least two magnets being oriented such that a north pole of at least one of the at least two magnets is directed toward the second ferrous plate and a south pole of an other the at least two magnets is directed toward the second ferrous plate, the first ferrous plate and the second ferrous plate being generally parallel and spaced apart and at least one magnetic flux responsive device disposed between the first

Abstract: A sensor system including a sensor having at least one magnet and a plurality of magnetic flux responsive devices fixedly adjacent to the at least one magnet. Each of the plurality of magnetic flux responsive devices have a primary sensing plane, at least two of the primary sensing planes being offset from each other. A quadrature normalization circuit is communicatively connected to the sensor.

Abstract: An electronic circuit for automatically compensating for errors in the output signal of a displacement sensor. The electronic circuitry includes an analog to digital converter for converting an analog output signal from a linear displacement type sensor. The digital output signal from the sensor is processed by a microcontroller which automatically compensates for errors in the output signal. Ideal values, stored in an electronic memory, are used for compensation.

Abstract: A sensor assembly senses one of position, velocity, acceleration or change of acceleration. The assembly includes at least one magnet having a north and south pole and a magnetic axis defined therebetween; a magnetic flux responsive device, the at least one magnet being fixedly adjacent to the magnetic flux responsive device; and a ferrous target selectively movable relative to the at least one magnet.

Abstract: A resin magnetic material composition including a resin and a non-ceramic magnetic filler.

Abstract: A sensor assembly senses one of position, velocity, acceleration or change of acceleration. The assembly includes at least one magnet having a north and south pole and a magnetic axis defined therebetween; a magnetic flux responsive device, the at least one magnet being fixedly adjacent to the magnetic flux responsive device; and a ferrous target selectively movable relative to the at least one magnet.

Abstract: A position sensor for sensing linear or radial position, including at least four magnets, a first ferrous plate having at least two of the at least four magnets located at spaced locations along the first ferrous plate, the at least two magnets being oriented such that a north pole of at least one of the at least two magnets is directed toward the first ferrous plate and a south pole of an other of the at least two magnets is directed toward the first ferrous plate, a second ferrous plate having at least two of the at least four magnets located at spaced locations along the second ferrous plate, the at least two magnets being oriented such that a north pole of at least one of the at least two magnets is directed toward the second ferrous plate and a south pole of an other the at least two magnets is directed toward the second ferrous plate, the first ferrous plate and the second ferrous plate being generally parallel and spaced apart and at least one magnetic flux responsive device disposed between the first

Abstract: The present invention is directed to a resin ceramic composition that includes a ceramic filler in an amount effective for providing a single composition with a magnetic field of at least one gauss.

Abstract: An electronic circuit for automatically compensating for errors in the output signal of a displacement sensor. The electronic circuitry includes an analog to digital converter for converting an analog output signal from a linear displacement type sensor. The digital output signal from the sensor is processed by a microcontroller which automatically compensates for errors in the output signal. Ideal values, stored in an electronic memory, are used for compensation.

Abstract: An electronic circuit dynamically compensates a sensor output signal subject to varying conditions. In particular, the circuitry dynamically determines the DC offset level of an incoming sensor analog output signal. The DC amplitude or offset level varies as a result of changing conditions, such as speed, airgap, alignment and temperature. The circuitry compares the DC offset level with the original sensor analog output signal by way of a comparator to provide a digital output signal with a zero DC offset, which compensates for the varying conditions.

Abstract: The present invention is directed to a resin ceramic composition that includes a ceramic filler in an amount effective for providing a single composition with a magnetic field of at least one gauss.

Abstract: An electronic circuit for automatically compensating for errors in the output signal of a displacement sensor. The electronic circuitry includes an analog to digital converter for converting an analog output signal from a linear displacement type sensor. The digital output signal from the sensor is processed by a microcontroller which automatically compensates for errors in the output signal. Ideal values, stored in an electronic memory, are used for compensation.

Abstract: A gear tooth sensor having increased sensitivity and temperature tolerance enables relatively small ferrous targets to be detected, which lends itself for use in relatively compact applications, such as the sensing of an automotive cam shaft drive wheel. All of the embodiments include a magnet having opposing north and south pole faces and a single input Hall effect IC which defines a sensing plane, and may include one or more flux concentrators. In one embodiment the sensor is configured such that the magnet is disposed adjacent the periphery of the target wheel such that the magnetic axis is generally parallel to the direction of travel of the ferrous target at an instant when the ferrous target is adjacent the magnet. In this embodiment, the Hall effect IC and flux concentrator are disposed adjacent one side of the ferrous target wheel and at least partially below the magnet.