Abstract: [Object] To enable a user to easily recognize correspondence relationship among objects displayed in a plurality of different display modes upon switching of a mode. [Solution] There is provided a display control apparatus including: a display control unit configured to display a first screen in a first display mode and display a second screen in a second display mode. Upon switching of a mode from the first display mode to the second display mode, in the case where a first object included in the first screen corresponds to a second object included in the second screen, the display control unit performs seamless transition from the first object to the second object.

Abstract: A magnetic memory includes: a magnetoresistance element; a conductive portion that is laminated on the magnetoresistance element; and a control portion configured to determine a driving temperature of the magnetoresistance element based on a change in a resistance value of the conductive portion and to control the amount of current applied to the magnetoresistance element.

Abstract: A rectifying device includes: a one-dimensional channel (18) formed with a semiconductor, electrons traveling through the one-dimensional channel; an electrode (26) that applies an effective magnetic field generated from a spin orbit interaction to the electrons traveling through the one-dimensional channel by applying an electric field to the one-dimensional channel, the effective magnetic field being in a direction intersectional to the direction in which the electrons are traveling; and an external magnetic field generating unit (38) that generates an external magnetic field in the one-dimensional channel.

Abstract: Clock signals are distributed on a chip by applying an oscillating magnetic field to the chip. Local clock generation circuits including magnetic field sensors are distributed around the chip and are coupled to local clocked circuitry on the chip. The magnetic field sensors may include clock magnetic tunnel junctions (MTJs) in which a magnetic orientation of the free layer is free to rotate in the free layer plane in response to the applied magnetic field. The MTJ resistance alternates between a high resistance value and a low resistance value as the free layer magnetization rotates. Clock generation circuitry coupled to the clock MTJs senses voltage oscillations caused by the alternating resistance of the clock MTJs. The clock generation circuitry includes amplifiers, which convert the sensed voltage into local clock signals.

Abstract: A vertical Hall sensor includes first and second vertical Hall effect regions in a semiconductor substrate, with first and second pluralities of contacts arranged at one side of the first or second vertical Hall effect regions, respectively. The second vertical Hall effect region is connected in series with the first vertical Hall effect region regarding a power supply. The vertical Hall sensor further includes first and second layers adjacent to the first and second vertical Hall effect regions at a side other than a side of the first or second pluralities of contacts. The first and second layers have different doping properties than the first and second vertical Hall effect regions and insulate the first and second vertical Hall effect regions from a bulk of the semiconductor substrate by at least one reverse-biased p-n junction per vertical Hall effect region during an operation of the vertical Hall sensor.

Abstract: Embodiments of the present invention provide a Hall effect device that includes a Hall effect region of a first semiconductive type, at least three contacts and a lateral conductive structure. The Hall effect region is formed in or on top of a substrate, wherein the substrate includes an isolation arrangement to isolate the Hall effect region in a lateral direction and in a depth direction from the substrate or other electronic devices in the substrate. The at least three contacts are arranged at a top of the Hall effect region to supply the Hall effect device with electric energy and to provide a Hall effect signal indicative of the magnetic field, wherein the Hall effect signal is generated in a portion of the Hall effect region defined by the at least three contacts. The lateral conductive structure is located between the Hall effect region and the isolation arrangement.

Abstract: A Hall sensor array has two Hall sensors arranged in opposed quadrants of a two by two array. Each Hall sensor has four contacts, arranged as two pairs of opposite contacts, the axes of each pair being substantially perpendicular.

Abstract: In an offset cancelling circuit of a Hall element, a voltage is applied from four directions and from outside such that a current flowing in the Hall element is switched by 90°, to set a first state through a fourth state, and output voltages of the Hall element in the first state through the fourth state are averaged.

Abstract: The invention relates to a spring (1), in particular for a push button, for fixing to a carrier (2) and for registering a vertical force (F). The spring (3) is designed in such a way that when actuated it converts a vertical movement into a horizontal movement that can be detected by sensor means (4).

Abstract: A shock detector, such as for disk drives, which eliminates discrete external capacitors used in prior art devices. A first stage operational amplifier (without external capacitors) provides part of the gain required. This is followed by a second stage switched capacitor high pass filter (without external capacitors) that provides the remaining gain required while filtering out the DC offset of the first stage operational amplifier. In order to cover the range of frequencies expected without aliasing problems, two switched capacitor high pass filters in parallel are used, each designed with a different cut-off frequency.

Abstract: A system includes a sensing system, a first chopped circuit, a second chopped circuit, and a multiplexer. The sensing system is configured to provide input signals. The first chopped circuit is configured to switch in response to the input signals crossing a first limit and to provide a first output signal that is valid during some chopping phases. The second chopped circuit is configured to switch in response to the input signals crossing a second limit and to provide a second output signal that is valid during other chopping phases. The multiplexer is configured to switch between the first output signal and the second output signal to provide a valid output signal during all chopping phases.

Abstract: A system including a sensing system, a first chopped circuit, a second chopped circuit, and a clock generator. The sensing system is configured to provide sensed input signals. The first chopped circuit is configured to provide a switched output signal that switches in response to values of the sensed input signals crossing a limit. The second chopped circuit is configured to provide a high resolution output signal that corresponds to the sensed input signals and has a higher resolution than the switched output signal. The clock generator is configured to provide clock signals that synchronize chopping of the first chopped circuit and the second chopped circuit.

Abstract: A system including a spinning current Hall sensor and a chopping circuit. The spinning current Hall sensor is configured to provide input signals and the chopping circuit is configured to receive the input signals. Spinning phases of the spinning current Hall sensor are lengthened in residual offset adjustment phases to obtain signals that correspond to the residual offset voltages of the spinning phases.

Abstract: A method of manufacturing a sensor module includes providing a substrate comprising a magnetically sensitive sensor element. The sensor element and the substrate are encapsulated with at least one mold material that is configured to apply a bias magnetic field to the sensor element.

Abstract: Apparatus and methods determine a frequency associated with a relatively strong interfering signal (interferer) using relatively simple run-length counting techniques. Counts of run-lengths can be analyzed to estimate a frequency of the interferer. For example, a peak run-length can be associated with a frequency. In one embodiment, counts of run-lengths are used to construct a theoretical peak run-length, which is then associated with a frequency for the interferer. A theoretical count associated with the theoretical peak run-length can also be used as an indication of a signal strength of the interferer.

Abstract: A circuit including Hall plates and an amplifier. The Hall plates are configured to provide Hall voltages in a homogenous magnetic field such that a first Hall plate has a first positive voltage and a first negative voltage and a second Hall plate has a second positive voltage and a second negative voltage. The amplifier is configured to receive the Hall voltages and provide a first output voltage that corresponds to the first positive voltage and the second positive voltage and a second output voltage that corresponds to the first negative voltage and the second negative voltage.

Abstract: A magneto-sensitive integrated circuit which amplifies a magneto-sensitive output voltage of a Hall element by an amplifier to generate an amplified voltage, converts an output voltage of the amplifier into a digital signal by an A/D converter; and generates a reference voltage of magnitude corresponding to an indicated value. The amplifier includes a voltage superposition element which superposes a DC voltage corresponding to the reference voltage on the amplified voltage to generate the output voltage of the amplifier.

Abstract: A machine having an operator interface for requesting an action from an actuator of the machine includes a movable component of the operator interface. The movable component is movable among at least two positions. One of a magnet and a Hall effect sensor is positioned to move in response to movement of the movable component. The other of the magnet and the Hall effect sensor has a stationary position relative to the movable component. A pulse width modulator is operably coupled to the Hall effect sensor for producing a first pulse width modulated signal. The first pulse width modulated signal is altered in response to movement of one of the Hall effect sensor and the magnet relative to the other. An electronic controller is in communication with the pulse width modulator and the actuator and is configured to actuate the actuator in response to evaluation of the first pulse width modulated signal.

Abstract: A Hall element outputs a Hall voltage generated at a first terminal pair or a second terminal pair to first and second output terminals by switching the voltage in a first status and a second status. Based on the voltages of the first and the second output terminals and a reference voltage, first and second capacitors are charged. Then, the voltages of the first and the second capacitors are compared, and a detection signal is obtained. Thus, a magnetic sensor circuit which reduces influence of an element offset voltage of the Hall element and also reduces influence of an input offset voltage generated at an amplifier, and a portable terminal provided with such magnetic sensor circuit are provided.

Abstract: According to one embodiment, a system, apparatus, and method for receiving high-speed signals using a receiver with a transconductance amplifier is presented. The apparatus comprises a transconductance amplifier to receive input voltage derived from an input signal, a clocked current comparator to receive output current from the transconductance amplifier, and a storage element to receive a binary value from the clocked current comparator.

Abstract: A sensor circuit has: a sensor portion that obtains, as an electrical signal, information on an object to be measured or detected; and a control circuit that controls the operation of the sensor portion. The control circuit receives a start input signal inputted thereto from outside for making the sensor portion operate only for a given duration after the start input signal is inputted thereto. With this configuration, it is possible to reduce the current consumption by arbitrarily controlling a period of an intermittent operation of the sensor circuit.

Abstract: To provide a rotary tool driven by a brushless motor with which constant torque tightening work for screws or the like can always be performed properly and efficiently, in which overall downsizing and improved torque control precision enhancement can easily be achieved, and with which it is possible to eliminate occurrences of switch contact-induced sparking and wear and of the damage imparted to the peripheral electronic equipment and electronic circuitry as occurred in drive switches or torque detection mechanisms that use a conventional mechanical switch mechanism, so that the constituting parts are able to have a reduced size and an extended life.

Abstract: A method (500), a handheld electronic device (102) and an external accessory (402) for controlling at least one function of a plurality of functions of the handheld electronic device is provided. The method includes determining (504) whether the handheld electronic device is docked in an external accessory. Further, the method includes measuring (506) a first magnetic field density when the handheld electronic device is docked in the external accessory. Furthermore, the method includes generating (508) a signal to activate at least one function, based on an electrical parameter.

Abstract: A machine having an operator interface for requesting an action from an actuator of the machine includes a movable component of the operator interface. The movable component is movable among at least two positions. One of a magnet and a Hall effect sensor is positioned to move in response to movement of the movable component. The other of the magnet and the Hall effect sensor has a stationary position relative to the movable component. A pulse width modulator is operably coupled to the Hall effect sensor for producing a first pulse width modulated signal. The first pulse width modulated signal is altered in response to movement of one of the Hall effect sensor and the magnet relative to the other. An electronic controller is in communication with the pulse width modulator and the actuator and is configured to actuate the actuator in response to evaluation of the first pulse width modulated signal.

Abstract: The inventive circuitry on a semiconductor chip includes a first functional element having a first electronic functional-element parameter that exhibits a dependence relating to the mechanical stress present in the semiconductor circuit chip in accordance with a first functional-element stress influence function. The first functional element provides a first output signal based on the first electronic functional-element parameter and mechanical stress. A second functional element has a second electronic functional-element parameter that exhibits a dependence in relation to the mechanical stress present in the semiconductor circuit chip in accordance with a second functional-element stress influence function. The second functional element is configured to provide a second output signal based on the second electronic functional-element parameter and the mechanical stress.

Abstract: A semiconductor chip includes a first functional element having a first electronic functional-element parameter exhibiting a dependence relating to the mechanical stress present in the semiconductor circuit chip, and being configured to provide a first output signal, a second functional element having a second electronic functional-element parameter exhibiting a dependence in relation to the mechanical stress present in the semiconductor circuit chip, and being configured to provide a second output signal in dependence on the second electronic functional-element parameter and the mechanical stress, and a combination means for combining the first and second output signals to obtain a resulting output signal exhibiting a predefined dependence on the mechanical stress present in the semiconductor circuit chip, the first and second functional elements being integrated on the semiconductor circuit chip and arranged, geometrically, such that that the first and second functional-element stress influence functions ar

Abstract: A current sensor includes a semiconductor substrate, a ring shaped magnetic core having a center opening and a gap and provided to a surface of the substrate, and a Hall element provided to the surface and placed in the gap of the magnetic core such that a control current for operating the Hall element flows perpendicular to the surface of the substrate. The magnetic core and the Hall element are formed to the substrate by semiconductor manufacturing techniques. Therefore, the Hall element can be placed in the gap to be accurately positioned with respect to the magnetic core and the gap can have a reduced separation distance. Thus, the current sensor can have an increased sensitivity and accurately measure a current to be detected.

Abstract: A compensation signal, which derives the mechanical stress, which acts on an integrated semiconductor circuit, from two partial compensation signals, which are generated by semiconductor elements with different stress characteristics, can be determined in more detail when the temperature dependence of a ratio of the partial compensation signals is also considered, wherein particularly a deviation of the ratio of the partial compensation signal to an ideal ratio is considered. Thereby, the rise in accuracy of the stress determination results from determining a deviation of the partial compensation signals, on which the stress determination is based, from a nominal behavior in a stress-free state, so that the deviation of the nominal behavior, which can be based, for example, on a variation of the process parameters in a production process of a semiconductor circuit, can also be considered, in addition to the known temperature behavior.

Abstract: A device, system and method for adaptively tracking amplitude boundary values of a real time sensor output signal. In accordance with the method of the present invention, an amplitude boundary value, which may be a peak or min amplitude value, representing the current amplitude boundary of the sensor output signal is stored within a digital counter. A two-tap DAC is utilized to convert the digitally stored amplitude boundary value into a reference signal level corresponding in amplitude to the amplitude boundary value. The DAC also converts the amplitude boundary value into an offset reference signal level corresponding in amplitude to the amplitude boundary value offset by a specified multiple of the DAC resolution. The reference signal level and offset reference signal are compared with the real time sensor signal and the digitally stored amplitude boundary value is adjusted in accordance with which reference signal level exceeds the real time sensor signal.

Abstract: A sensor circuit includes a sensor element, a current source for supplying an operating current for the sensor element and an amplifier circuit for amplifying a sensor voltage produced by the sensor element when applying the operating current, wherein the amplifier circuit has a resistor influencing the amplification of it. The resistor of the amplifier current and the sensor element are formed equally as regards technology so that variations, due to technology, of the sensor sensitivity of the sensor element are counteracted by an amplification factor of the amplifier circuit changing in the opposite way.

Abstract: A circuit for generating an output signal, which depends on a physical useful quantity includes means for detecting the physical useful quantity, wherein the means for detecting is arranged to generate an output signal, which depends on the physical useful quantity, a control signal for the means for detecting and, with an unchanged control signal, on an external control quantity. The circuit further includes sensor means for detecting the external disturbing quantity and for providing a sensor signal, which depends on the external disturbing quantity and means for processing the sensor signal to influence the control signal dependent on the sensor signal such that the influence of the external disturbing quantity on the output signal is reduced.

Abstract: A modified hybrid Hall effect device is provided which is the combination of a conventional Hall effect device and a second Hall effect device having a Hall plate coupled to a ferromagnetic layer. The hybrid Hall effect device can be used to determine the independent magnetic field vector components comprising a vector magnetic field, such as for determining the {circumflex over (x)} and the {circumflex over (z)} components of a magnetic field, or for measuring the total magnitude of a vector magnetic field of any orientation. The modified Hall Effect device can be adapted for use as a magnetic field sensor for the detection of macroscopic objects that have associated magnetic fields, or for microscopic objects that have been tagged by microscopic magnetic particles.

Abstract: A magnetic field sensor including an amplifier and a magnetic field element for outputting a signal to a switch circuit according to the strength of an applied magnetic field. The switch circuit outputs a signal selected by an external two-phase signal to an amplifier that amplifies the signal and outputs a resulting voltage to a first end of a memory element. A switch, having one end connected to a second end of the memory element, is controlled by the two-phase signal. The switch closes in a first phase of the two-phase signal causing the memory element to store the output voltage of the amplifier, and opens in a second phase causing a vector sum of the output voltage the amplifier to be stored in the memory element and providing the output voltage to a signal output terminal connected to the second end of the memory element.

Abstract: Magnetic sensing methods and systems are disclosed. A minimum magnetic signal output and a maximum magnetic signal output can be detected utilizing a sensor comprising a peak detector circuit associated with a filter averaging circuit and one or more magnetic elements (e.g., a Hall element and/or magnetoresistive bridge). An average magnetic signal output can then be determined utilizing the filter averaging circuit when a target begins to rotate in front of the sensor.

Abstract: The circuit configuration converts an input signal into a binary output signal. The circuit has at least one comparator, at least one demodulation unit, and at least one clock unit. The demodulation unit has two or more capacitors and two or more switches controlled by the clock unit. The switches connect the capacitors of the demodulation unit to the comparator, and the comparator compares an input signal demodulated by the demodulation unit with a reference value and forms from that the binary output signal.

Abstract: A Hall device biasing circuit includes a plurality of terminals for applying a bias voltage to a plurality of Hall devices connected in series, respectively. A magnetism detection circuit includes a plurality of Hall devices connected in series; and a Hall device biasing circuit including at least a plurality of terminals corresponding to the plurality of Hall devices for supplying a constant bias voltage to each of the plurality of Hall devices respectively from the plurality of terminals.

Abstract: A proximity detector includes an offset circuit for bringing at least one of a magnetic field signal and a tracking signal towards the other one of the magnetic field signal and the tracking signal when the detector output signal changes state. A magnetic field-to-voltage transducer provides the magnetic field signal indicative of an ambient magnetic field and a peak detector responsive to the magnetic field signal provides the tracking signal which substantially follows the magnetic field signal. A comparator generates the detector output signal which changes state when the magnetic field signal varies from the tracking signal by a predetermined amount.

Abstract: A method and apparatus for minimizing errors in a sensor device due to signal amplitude variation are disclosed herein. A signal output from the sensor device is amplified and, thereafter, AC-coupled to a comparator such that the amplification and AC-coupling of the signal minimize offset shift-related errors associated with the sensor device. The signal can be coupled to eliminate offset shifts due to component mismatches, calibration, aging and/or temperature associated with the sensor device. An AC-coupled sensor signal conditioning circuit is utilized to amplify the signal through an amplifier and then AC-couple the signal to a comparator.

Abstract: A switch which is magnetic pole insensitive is described. The switch includes a Hall effect sensor coupled to a threshold circuit which provides an output signal indicative of the proximity of a magnet, and hence a magnetic field, to the Hall effect sensor regardless of the orientation of the magnet to the Hall effect sensor.

Abstract: A method for isolatively coupling an input signal to an output signal, where the input signal is a first voltage differential, comprises three steps. Step one calls for generating a magnetic field that is indicative of the input signal in at least one magnetic sensor in an integrated circuit by generating a current through a conductor in the integrated circuit. The current is generated by applying the first voltage differential across the conductor, which is proximate the magnetic sensor. Step two requires generating a second voltage differential between two points of the magnetic sensor by providing a current through the magnetic sensor in a direction having a component transverse to the magnetic field. Step three calls for providing a signal indicative of the second voltage differential as the output signal, thereby isolatively coupling the input signal to the output signal.

Abstract: A non-linear Hall IC that stores conversion information for converting Hall voltage output from a Hall element, and converts the Hall voltage into an output voltage based on the conversion information stored. The Hall voltage is converted into the output voltage such that a relation between the magnetic field strength and the output voltage becomes a non-linear relation.

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 head testing apparatus is provided for testing a magnetic data recording head. The apparatus includes a test volume adapted to receive the magnetic data recording head and a magnetic field source positioned to generate a magnetic field within the test volume. A Hall sensor is positioned relative to the test volume and has bias current input terminals, voltage output terminals, an operating temperature and an impedance between the bias current input terminals, which varies with the operating temperature. A bias current source is electrically coupled to the bias current input terminals and is adapted to provide a bias current, which is modulated based on the impedance of the Hall sensor.

Abstract: A magnetic sensor with a signal processing circuit includes a magnetic sensor section 4 composed of a compound semiconductor thin film or a magnetic thin film, and a signal processing circuit 5 for amplifying a magnetic signal the magnetic sensor section detects as an electrical output. The signal processing circuit 5 includes an operational amplifier 51 and a constant current circuit 52 for carrying out feedback. The constant current circuit 52 in the signal processing circuit 5 includes a plurality of resistors with two or more different temperature coefficients, and the current output from the constant current circuit has a temperature coefficient inversely proportional to the temperature coefficient of the combined resistance of the plurality of the resistors.

Abstract: Described is a magnetic field sensor with a Hall element and a rectangular change-over switch, which controls the Hall element, dependent upon a timing signal. An active ladder-type filter creates a low pass filtered outlet signal. It uses OTA modules, which work with gyrator switching. By means of a chopper operation, capacitors, dependent on the timing signal, are charged alternately from the outlets of the OTA modules.

Abstract: A Hall sensor has a Hall plate having terminals for supplying a supply current and for tapping a Hall voltage. A Hall circuit connects the terminals. A device for orthogonally switching the supply current and the Hall voltage between a first set of the terminals and a second set of the terminals, arranged orthogonally to the first set of terminals, is provided wherein a geometry of the Hall plate is identical for the first and second sets of the terminals. A summation device is configured to receive measured Hall voltage values from the first and second sets of the terminals and to determine an offset-compensated Hall voltage value. The summation device is configured to receive and/or process the Hall voltage values of the first and second set of the terminals such that, for stress measurement, a portion of the Hall voltage values resulting from the magnetic field acting on the Hall sensor are compensated and only the portion of the Hall voltage values resulting from the offset are measured.

Abstract: A switch which is magnetic pole insensitive is described. The switch includes a Hall effect sensor coupled to a threshold circuit which provides an output signal indicative of the proximity of a magnet, and hence a magnetic field, to the Hall effect sensor regardless of the orientation of the magnet to the Hall effect sensor.

Abstract: A sensor for measuring a parameter includes at least one transducer adapted to provide an analog transducer signal, and at least one converter adapted to convert the analog transducer signal into a digitized transducer signal, and a memory device associated with the converter capable of receiving the digitized transducer signal directly from the converter. The memory device is configured to provide a digitized output value from a memory location, the memory location being associated with or corresponding to the digitized transducer signal received by the memory device.

Abstract: A magnetic field sensor for measurement of the three components (Bx, By, Bz) of a magnetic field comprises a Hall-effect element (1) and an electronic circuit (22). The Hall-effect element (1) comprises an active area (18) of a first conductivity type which is contacted with voltage and current contacts (2-5 or 6-9). Four voltage contacts (2-5) are present which are connected to inputs of the electronic circuit (22). By means of summation or differential formation of the electrical potentials (V2, V3, V4, V5) present at the voltage contacts (2-5), the electronic circuit (22) derives three signals (Vx, Vy, Vz) which are proportional to the three components (Bx, By, Bz) of the magnetic field.

Abstract: A current detector includes a Hall-effect device 18 for detecting a magnetic field generated by a current flowing across a conducting portion; a magnetic core 19 having a first end face for concentrating a magnetic flux and a second end face having a smaller area than the first end face, only the second end face being disposed at a position in close proximity to or in abutment against a magnetic field detecting surface of the Hall-effect device; and a signal processing circuit 26 for processing an output signal from the Hall-effect sensor 18 into a signal representing the current flowing across the conducting portion.