A cam is immersed in water at an elevated temperature and/or pressure. A reciprocating cam follower also immersed in the water contacts a surface of the cam. The cam follower includes a permanent magnet. An electrically conductive coil is magnetically coupled with the permanent magnet such that movement of the cam follower induces an electrical signal in the electrically conductive coil. A sealed housing also immersed in the water contains the electrically conductive coil and seals it from contact with the water. Leads of the coil are electrically accessible from outside the sealed housing and from outside the water. Alternatively, the cam includes magnetic inserts, the cam follower is replaced by a sensor arm of magnetic material, and the sensor arm and/or the inserts are magnetized whereby rotation of the rotary element causes time modulation of the magnetic coupling and induces coil voltage.

A detecting device includes a shift selector, a magnet disposed in the shift selector, four or more sensors arranged at positions facing the magnet and an ECU. The ECU is configured to (i) determine a shift position based on signals output from the four or more sensors when the magnet is relatively displaced with respect to the four or more sensors in response to an operation of the shift selector, (ii) determine the shift position based on signals output from three or more of the four or more sensors determined to be normal when any one of the four or more sensors is abnormal, and (iii) determine the abnormality based on whether or not the three or more sensors output, during the traveling of the vehicle, a signal to a shift position pertaining to a case of traveling in the direction opposite to a traveling direction of the vehicle.

A device and a method for simultaneous recording, in real time, parameters characterising the mechanical tension, elasticity, dynamical stiffness, creepability and mechanical stress of soft biological tissue are provided. By means of the myometer, a constant external pre-pressure is created, independently of the device's position, between the tissue and the testing end of the device. Next, the tissue is subjected to a short-term external dynamic influence. A mechanical change in the shape of the tissue and its mechanical response are registered as a graph of the tissue's oscillations. For calculating the parameters, a time span on the graph is used which involves an oscillation period from the beginning to the end of the effect on the tissue plus its subsequent first 1.5 self-oscillation period. This enables recording and data-processing to be carried out simultaneously as well as statistically significant estimates to be made in real time.

A method for determining a position of a magnet assembly relative to an array of inductive elements arranged adjacent to a magnetically permeable material, the method involving: measuring electrical characteristics of each of one or more inductive elements of the array of inductive elements; and from information derived from the measured electrical characteristics of the one or more inductive elements of the array of inductive elements, determining the position of the magnet assembly relative to the array of inductive elements.

A rotational angle detection apparatus is provoded with a magnet disposed so as to be rotatable integrally with an axis of rotation, having a substantially circular shape when viewed along the axis of rotation, and including a magnetization vector component in a direction orthogonal to the axis of rotation; a magnetic sensor that outputs a sensor signal on the basis of change in a magnetic field accompanying rotation of the magnet; and a rotational angle detector that detects a rotational angle of the rotating body on the basis of the sensor signal output by the magnetic sensor; wherein the magnet has a curved inclined surface with a concave shape along the axis of rotation from a prescribed position on the outer side in a radial direction toward the axis of rotation, and when a circular virtual plane orthogonal to the axis of rotation and centered at the axis of rotation is established at a position opposed to the curved inclined surface, the magnetic sensor is disposed at a position at which the amplitudes of a magnetic field intensity H.sub.r in a radial direction and a magnetic field intensity H.sub.θ in a circumferential direction on the virtual plane are substantially the same, and the magnetic field intensities H.sub.r and H.sub.θ in the radial direction and/or the circumferential direction is output as the sensor signal.

Described is a method comprising: forming a magnet on a substrate or a template, the magnet having an interface; and forming a first layer of non-magnet conductive material on the interface of the magnet such that the magnet and the layer of non-magnet conductive material are formed in-situ. Described is an apparatus comprising: a magnet formed on a substrate or a template, the magnet being formed under crystallographic, electromagnetic, or thermodynamic conditions, the magnet having an interface; and a first layer of non-magnet conductive material formed on the interface of the magnet such that the magnet and the layer of non-magnet conductive material are formed in-situ.

The invention relates to a method for determining the position that a magnet has at a time of measurement relative to a row of sensors extending in a row direction, wherein the position of the magnet relative to the row of sensors can be changed in the direction of the row direction or in the direction parallel to the row direction, wherein the row of sensors has a first magnetic-field-sensitive sensor and a second magnetic-field-sensitive sensor, which is arranged spaced apart from the first sensor in the row direction, wherein a first sensor signal is generated by the first sensor, the value of which, at the time of measurement, depends on the position of the magnet relative to the first sensor at the time of measurement, and a second sensor signal is generated by the second sensor, the value of which, at a time of measurement, depends on the position of the magnet relative to the second sensor at the time of measurement, wherein, in a first examination, the value that the first sensor signal has generated at the time of measurement is compared with a first reference value and/or is checked as to whether it belongs to a first value range, in a second examination, the value that the second sensor signal has generated at the time of measurement is compared with a second reference value and/or is checked as to whether it belongs to a second value range, a relative value is formed from the value that the first sensor signal has generated at the time of measurement and the value that the second sensor signal has generated at the time of measurement, and, in a third examination, this relative value is compared with a third reference value and/or is checked as to whether it belongs to a third value range, and from the result of the first examination and the result of the second examination and the result of the third examination, a determination is carried out as to which of the sensor signals should be regarded as the leading signal for the time of measurement, wherein the position of the magnet relative to the row of sensors at the time of measurement is determined by evaluating the leading signal determined in this manner.

A rotational angle detection apparatus is provided with a magnet disposed so as to be rotatable integrally with an axis of rotation, having a substantially circular shape when viewed along the axis of rotation, and including a magnetization vector component in a direction orthogonal to the axis of rotation; a magnetic sensor that outputs a sensor signal on the basis of change in a magnetic field accompanying rotation of the magnet; and a rotational angle detector that detects a rotational angle of the rotating body on the basis of the sensor signal output by the magnetic sensor; wherein the magnet has a curved inclined surface with a concave shape along the axis of rotation from a prescribed position on the outer side in a radial direction toward the axis of rotation, and when a circular virtual plane orthogonal to the axis of rotation and centered at the axis of rotation is established at a position opposed to the curved inclined surface, the magnetic sensor is disposed at a position at which the amplitudes of a magnetic field intensity H.sub.r in a radial direction and a magnetic field intensity H.sub.θ in a circumferential direction on the virtual plane are substantially the same, and the magnetic field intensities H.sub.r and H.sub.θ in the radial direction and/or the circumferential direction is output as the sensor signal.

A rotational angle detection apparatus is provided with a magnet disposed so as to be rotatable integrally with an axis of rotation, having a substantially circular shape when viewed along the axis of rotation, and including a magnetization vector component in a direction orthogonal to the axis of rotation; a magnetic sensor that outputs a sensor signal on the basis of change in a magnetic field accompanying rotation of the magnet; and a rotational angle detector that detects a rotational angle of the rotating body on the basis of the sensor signal output by the magnetic sensor; wherein the magnet has a curved inclined surface with a concave shape along the axis of rotation from a prescribed position on the outer side in a radial direction toward the axis of rotation, and when a circular virtual plane orthogonal to the axis of rotation and centered at the axis of rotation is established at a position opposed to the curved inclined surface, the magnetic sensor is disposed at a position at which the amplitudes of a magnetic field intensity H.sub.r in a radial direction and a magnetic field intensity H.sub.θ in a circumferential direction on the virtual plane are substantially the same, and the magnetic field intensities H.sub.r and H.sub.θ in the radial direction and/or the circumferential direction is output as the sensor signal.

A linear contactless displacement sensor assembly is provided. The sensor assembly can include a shaft configured to translate linearly, and a sleeve rotatably coupled about the shaft and linearly fixed such that the shaft can linearly translate through the sleeve as the sleeve rotates. The sleeve includes an outer surface having a threading that varies in pitch. A tooth is disposed in the threading and fixed on a linear track such that the tooth moves linearly as the sleeve rotates. A sensor is configured to sense a location of the tooth along the linear track. This allows the sensor assembly to measure an amount of linear movement and a corresponding amount of rotation of the sleeve.