Abstract: It is described a magnetic field differential sensor system for measuring rotational movements of a shaft. The described magnetic field sensor system (200) comprises (a) a biasing magnet (210, 510) configured for generating a biasing magnetic field; (b) a magnetic wheel (230) having a wheel axis and a circumferential surface which comprises a regular structure of teeth (231) and gaps (232) arranged in an alternating manner, wherein (i) the magnetic wheel (230) is attachable to the shaft and (ii) the magnetic wheel (230) can be magnetized by the biasing magnetic field; and (c) a magnetic sensor arrangement (220) comprising four magnetic sensor elements (221, 222, 223, 224) being connected with each other in a Wheatstone bridge configuration. Respectively two of the magnetic sensor elements (221, 222, 223, 224) are assigned to one half bridge of the Wheatstone bridge.

Abstract: A magnetic field sensor system for measuring rotational movements of a shaft is disclosed. The sensor system includes a biasing magnet configured for generating a biasing magnetic field and a magnetic wheel having a wheel axis and a circumferential surface which comprises a regular structure of teeth and gaps arranged in an alternating manner. The magnetic wheel is attachable to the shaft and is magnetizable by the biasing magnetic field. A magnetoresistive sensor arrangement comprising four magnetoresistive sensor elements being connected with each other in a Wheatstone bridge, respectively two of the magnetoresistive sensor elements being assigned to one half bridge of the Wheatstone bridge. The four magnetoresistive sensor elements are arranged within an x-y plane.

Abstract: A magnetic field sensor assembly for measuring an angular direction of a sensed magnetic field relative to the assembly is disclosed. The sensor assembly includes a sensor of a first type configured to sense an orientation of the sensed magnetic field, a sensor of a second type configured to measure an orientation and a direction of the sensed magnetic field and processing circuitry connected to each of the magnetic field sensors. The processing circuitry being configured to process output signals from the sensor of the first type to determine an uncorrected sensed magnetic field angle and to apply an offset angle to the uncorrected magnetic field angle dependent on a logical combination of signs of output signals from the sensors of the first and second types.

Abstract: It is described a magnetic field differential sensor system for measuring rotational movements of a shaft. The described magnetic field sensor system (200) comprises (a) a biasing magnet (210, 510) configured for generating a biasing magnetic field; (b) a magnetic wheel (230) having a wheel axis and a circumferential surface which comprises a regular structure of teeth (231) and gaps (232) arranged in an alternating manner, wherein (i) the magnetic wheel (230) is attachable to the shaft and (ii) the magnetic wheel (230) can be magnetized by the biasing magnetic field; and (c) a magnetic sensor arrangement (220) comprising four magnetic sensor elements (221, 222, 223, 224) being connected with each other in a Wheatstone bridge configuration. Respectively two of the magnetic sensor elements (221, 222, 223, 224) are assigned to one half bridge of the Wheatstone bridge.

Abstract: A magnetic field sensor assembly for measuring an angular direction of a sensed magnetic field relative to the assembly is disclosed. The sensor assembly includes a sensor of a first type configured to sense an orientation of the sensed magnetic field, a sensor of a second type configured to measure an orientation and a direction of the sensed magnetic field and processing circuitry connected to each of the magnetic field sensors. The processing circuitry being configured to process output signals from the sensor of the first type to determine an uncorrected sensed magnetic field angle and to apply an offset angle to the uncorrected magnetic field angle dependent on a logical combination of signs of output signals from the sensors of the first and second types.

Abstract: The invention provides a method for recording information in the form of a pattern of magnetic domains in a recording layer. The recording layer includes a material having a Curie temperature and grains, the grains having boundaries over which the exchange coupling is small. The method includes a first step of applying heat to the material, thereby heating an area of the recording layer to a temperature above the Curie temperature during a first interval. In a second step a magnetic field is applied to the area during a second interval, the second interval ending after the first interval.

Abstract: A method of orienting the axis of magnetization of a first magnetic element with respect to a second magnetic element uses a first element and a second element lying on a substrate. Each of the elements has a magnetic layer with an axis of magnetization. The method includes depositing a pattern of flux-concentrating material close to the first element and subsequently orienting the axis of magnetization of the first element in an applied magnetic field. The semi-finished article for measuring a magnetic field includes a substrate, a first magnetic element, a second magnetic element, a third magnetic element and a fourth magnetic element on the substrate in a bridge configuration. A first bridge portion is provided wherein the first element and the second element are electrically connected in series. A second bridge portion is provided wherein the third element and the fourth element are electrically connected in series.

Abstract: A storage medium for thermally-assisted magnetic recording has a recording layer which substantially parallel tracks for recording information. The recording layer includes a series of recording regions, each region comprising a plurality of tracks for magnetically recording information. The tracks in a region have a pitch p, and a region extends a distance ½ p beyond a centre line of the outermost track of the region. Neighbouring regions are separated from one another by magnetically non-recording areas having a width substantially equal to or larger than the pitch p. The writing of one region does not have thermal cross-talk on other regions.

Abstract: The object of the invention is the shielding of a magnetic memory against high external magnetic fields. The magnetic memory (1) comprises an array of magnetic memory elements (2), each memory element (3) including at least one layer of magnetic material (4). The operation of the magnetic memory elements (3) is based on a magnetoresistance effect. The memory (1) is protected against high external magnetic fields by a shielding layer (14), which has been split into regions (5) covering the memory elements (3). The magnetic memory (1) is not erased by high external magnetic fields because of a strong attenuation of the external magnetic field by the regions (5) of the shielding layer (14).

Abstract: A storage medium for thermally-assisted magnetic recording has a recording layer which substantially parallel tracks for recording information. The recording layer includes a series of recording regions, each region comprising a plurality of tracks for magnetically recording information. The tracks in a region have a pitch p, and a region extends a distance ½ p beyond a centre line of the outermost track of the region. Neighbouring regions are separated from one another by magnetically non-recording areas having a width substantially equal to or larger than the pitch p. The writing of one region does not have thermal cross-talk on other regions.

Abstract: A method of orienting the axis of magnetization of a first magnetic element (2) with respect to a second magnetic element (3), wherein the first element (2) and the second element (3) are present on a substrate (1), and each of the magnetic elements has a first magnetic layer (10) with an axis of magnetization (11), said method including the step of depositing a pattern of flux-concentrating means (20) close to the first magnetic element (2) and subsequently orienting the axis of magnetization (11) of said first magnetic element (2) in an applied magnetic field.

Abstract: The object of the invention is the shielding of a magnetic memory against high external magnetic fields. The magnetic memory (1) comprises an array of magnetic memory elements (2), each memory element (3) including at least one layer of magnetic material (4). The operation of the magnetic memory elements (3) is based on a magnetoresistance effect. The memory (1) is protected against high external magnetic fields by a shielding layer (14), which has been split into regions (5) covering the memory elements (3). The magnetic memory (1) is not erased by high external magnetic fields because of a strong attenuation of the external magnetic field by the regions (5) of the shielding layer (14).