Abstract: A pedal assembly including a pedal support and a pedal member rotatably coupled to the pedal support to allow pivotal movement of the pedal member about a pivot axis. The pedal assembly further includes a friction member having a bearing surface, and a clamp member engaged with the pedal member and having an engagement surface abutting the bearing surface of the friction member to define at least two separate and distinct surface contact regions. The pedal assembly also includes a biasing member arranged to bias the clamp member to provide frictional engagement along the separate and distinct surface contact regions to resist pivotal movement of the pedal member. In one embodiment, the clamp member is engaged with the pedal member by a sliding pivot configured to allow the clamp member to be pivotally and slidably displaced relative to the pedal member during pivotal movement of the pedal member.

Abstract: A pedal assembly for use in association with a vehicle includes a pedal support adapted for mounting to the vehicle. The pedal support includes a pivot shaft extending along a pivot axis and having an outer bearing surface. A pedal arm is rotatably engaged to the pivot shaft to allow pivotal movement of the pedal arm about the pivot axis. A clamp arm is pivotally coupled to the pedal arm and has a compression surface. A biasing member is engaged between the pedal support and the clamp arm and is arranged to apply a biasing force to the clamp arm to pivot the clamp arm relative to the pedal arm and toward the pivot shaft.

Abstract: A magnetic rotational position sensor including first and second magnets spaced apart to define an air gap and cooperating with one another to generate a magnetic field within the air gap extending along an axis of rotation. At least one magnetic flux sensor is positioned within the magnetic field and is operable to sense varying magnitudes of magnetic flux in response to relative rotational movement between the magnetic field and the magnetic flux sensor about the axis of rotation.

Abstract: A position sensor including a magnetic circuit comprising a magnet having opposite first and second magnetic poles, a first pole piece having a proximal portion positioned adjacent the first magnetic pole and a distal portion positioned adjacent the second magnetic pole to define a first air gap area with a first magnetic field provided adjacent thereto, and a second pole piece having a proximal portion positioned adjacent the second magnetic pole and a distal portion positioned adjacent the first magnetic pole to define a second air gap area with a second magnetic field provided adjacent thereto. A first magnetic flux sensor is disposed within the first magnetic field to sense varying magnitudes of magnetic flux density and to generate a first output signal. A second magnetic flux sensor is disposed within the second magnetic field to sense varying magnitudes of magnetic flux density and to generate a second output signal.

Abstract: A magnetic rotational position sensor comprising a magnetic circuit including a loop pole piece and a magnet, and a magnetic flux sensor adapted to sense varying magnitudes of magnetic flux density associated with the magnetic circuit. The loop pole piece has a peripheral outer wall defining an inner air gap, with the outer wall including an inwardly projecting portion extending into the air gap. The magnet is positioned within the air gap generally opposite the inwardly projecting portion of the loop pole piece. The magnet and the loop pole piece cooperate to generate a magnetic field within the air gap. The magnetic circuit is rotatable about a rotational axis to correspondingly rotate the magnetic field about the rotational axis. The magnetic flux sensor is disposed within the magnetic field to sense a different magnitude of magnetic flux density in response to rotation of the magnetic field about the rotational axis.

Abstract: A magnetic position sensor including a pair of magnets of opposite polarity which are spaced apart to define an air gap extending along an axis, and a pair of shaped pole pieces at least partially disposed within the air gap and positioned adjacent respective ones of the magnets. The pole pieces are formed of a composite material comprising a non-magnetic material and a magnetizable material. The pole pieces cooperate with the magnets to generate a magnetic field that is substantially symmetrical relative to the axis and which has a magnetic flux density that linearly varies along the axis. A magnetic flux sensor is positioned within the magnetic field to sense varying magnitudes of magnetic flux density along the axis through a sensing plane oriented substantially perpendicular to the axis. The magnetic flux sensor generates an output signal uniquely representative of a sensed magnitude of the magnetic flux density.

Abstract: A non-contacting magnetic position sensor that produces a magnetic field having improved linear characteristics over an extended sensing range. The magnetic position sensor includes a pair of magnets, a pair of pole pieces extending between the magnets and spaced apart to define an air gap, and a magnetic flux sensor operable to sense varying magnitudes of magnetic flux density along the length of the air gap. The pole piece segments form a stepped interface with each of the magnets and cooperate with the magnets to provide a magnetic field having a magnetic flux density that varies in a substantially linear manner along substantially the entire length of the air gap. The magnetic flux sensor is positioned within the magnetic field and is operable to sense a magnitude of the varying magnetic flux density along the air gap and to provide an output signal representative of a position of the magnetic flux sensor relative to the magnetic field.

Abstract: A magnetic incremental motion detection system (110) for outputting a plurality of voltage and/or current signals in digital form wherein the voltage and/or current signals are a collective representation of any incremental rotational, linear, or pivotal movement of an object. A target (120) of the system (110) is adjoined to an object to synchronously move with the object. A plurality of indications (121c, 121d) are adjoined to the target (120), and uniformly and serially disposed along an area (121a) of a surface (121) of the target (120). The system further comprises one or more magnetic sensors (80, 180) spatially positioned from the area of the surface to define air gap areas therebetween. Each of the magnetic sensors (80, 180) are operable to output an analog signal in response to a synchronous movement of the target with the object, and one of two digital circuits (85, 185) output a digital signal in response to the analog signal.

Abstract: A magnetic sensor is provided which includes a pair of magnets and a pair of shaped pole pieces positioned adjacent respective ones of the magnets and spaced apart to define an air gap therebetween. The magnets and the shaped pole pieces cooperate to provide a magnetic field having a magnetic flux density that varies along a length of the air gap. A magnetic flux sensor is positioned within the magnetic field to sense varying magnitudes of magnetic flux density along the length of the air gap and to generate an output signal representative of a position of the magnetic flux sensor relative to the magnetic field. In one embodiment, the air gap defines a varying width to provide varying magnitudes of magnetic flux density along the length. In another embodiment, the shaped pole pieces include portions of varying thickness to provide varying magnitudes of magnetic flux density along the length.

Abstract: A magnetic position sensor including a pair of magnets of opposite polarity which are spaced apart to define an air gap extending along an axis, and a pair of shaped pole pieces at least partially disposed within the air gap and positioned adjacent respective ones of the magnets. The pole pieces are formed of a composite material comprising a non-magnetic material and a magnetizable material. The pole pieces cooperate with the magnets to generate a magnetic field that is substantially symmetrical relative to the axis and which has a magnetic flux density that linearly varies along the axis. A magnetic flux sensor is positioned within the magnetic field to sense varying magnitudes of magnetic flux density along the axis through a sensing plane oriented substantially perpendicular to the axis. The magnetic flux sensor generates an output signal uniquely representative of a sensed magnitude of the magnetic flux density.

Abstract: A combined hub temperature and wheel speed sensor system comprises a sensor assembly coupled to an axle and a wheel assembly fixedly coupled to the wheel, which in turn is free to rotate with respect to the axle. The wheel assembly includes a ring magnet. The sensor assembly includes a temperature sensor in proximity to the wheel bearing, Hall effect sensors positioned to detect the rotation of the ring magnet, and a circuit for generating and transmitting signals corresponding to the wheel rotation speed, rotation direction, and bearing temperature.

Abstract: A magnetic rotational position sensor senses each rotational position of a control shaft about a first rotational axis over a definable range of rotation of the control shaft. The magnetic rotational position sensor includes a magnetic circuit, a magnetic flux sensor, a drive circuit, and an output signal amplifier. The magnetic circuit encloses an equally balanced magnetic field, and is adjoined to the control shaft to synchronously rotate the magnetic field about a second rotational axis. The magnetic flux sensor is disposed within the magnetic field to sense each rotational position of the control shaft as the control shaft is rotated about the first rotational axis over the definable range of rotation. The drive circuit is operable to generate a constant current drive signal and a constant voltage drive signal.

Abstract: A magnetic rotary transducer for providing a signal indicative of a rotational position of a control shaft about a rotational axis over a defined range of rotation is disclosed. The magnetic rotary transducer comprises a pair of magnets and a rotor including a pair of loop pole pieces, and an elongated pole piece having a first end adjoined to one of the loop pole pieces and a second end adjoined to the other loop pole piece. Each loop pole piece includes an inner surface defining an air gap area. The control shaft is positioned within the air gap area of one of the loop pole pieces and adjoined thereto whereby the rotor synchronously rotates with the control shaft about the axis over the defined range of rotation. The pair of magnets are adjoined to the other loop pole piece whereby two separate and distinct magnetic fields are generated within the air gap are of the loop pole piece. The magnetic rotary transducer further comprises a magnetic flux sensitive transducer positioned within the air gap area.

Abstract: A magnetic rotational position sensor for sensing each rotational position of a control shaft about a first axis over a definable range of rotation. The position sensor generally includes a magnetic circuit and a pair of magnetic flux sensors. The magnetic circuit is comprised of a ring pole piece defining an air gap area and a magnet disposed within the air gap area. The ring pole piece and the magnet cooperate to produce a magnetic field within the air gap area. The magnetic circuit is adjoined to the control shaft to synchronously rotate the magnetic field about a second axis. The pair of magnetic flux sensors are disposed within the magnetic field to sense each rotational position of the control shaft as the control shaft is rotated about the first axis over the definable range of rotation.

Abstract: A magnetic incremental motion detection system for outputting a plurality of voltage and/or current signals in digital form wherein the voltage and/or current signals are a collective representation of any incremental rotational, linear, or pivotal movement of an object. A target of the system is adjoined to an object to synchronously move with the object. A plurality of indications are adjoined to the target, and uniformly and serially disposed along an area of a surface of the target. The system further comprises one or more magnetic sensing devices spatially positioned from the area of the surface to define air gap areas therebetween. Each of the magnetic sensing devices are operable to output a digital signal in response to a synchronous movement of the target with the object. The outputted digital signals have the same duty cycle, and are consistently out of phase with each other by the same degree.

Abstract: A magnetic rotational position sensor for sensing the rotational position of a control shaft about a first axis over a definable range of rotation is disclosed. The magnetic rotational position sensor includes a magnetic circuit formed by a peripherally interrupted outer pole piece defining an air gap and a magnet disposed within the air gap to generate a magnetic field. The magnetic circuit is adjoined to the control shaft to synchronously rotate the magnetic field about a second axis. A magnetic flux sensor is disposed within the magnetic field to sense the rotational position of the control shaft as the control shaft is rotated about the first axis over the definable range of rotation.