Abstract: A Hall element including a contact is provided. A Hall element is provided, including: a substrate; a magnetosensitive portion formed on the substrate; an insulating film formed on the magnetosensitive portion; and a conductive portion which is formed on the insulating film, extends from a peripheral region of the magnetosensitive portion toward a central region of the magnetosensitive portion, penetrates the insulating film, and is electrically connected to the magnetosensitive portion, wherein when observing a cross section passing through a center of the magnetosensitive portion in plan view and a portion at which the conductive portion is in contact with the magnetosensitive portion, at least a part of the conductive portion extends below the insulating film in the cross section.

Abstract: The object of the present invention is to provide a nonvolatile storage element capable of suppressing retention degradation. A nonvolatile storage element is provided with a semiconductor substrate and a floating gate provided above the semiconductor substrate, in which the floating gate has an area of 30 ?m2 or more.

Abstract: Provided is a magnetic field detection device capable of detecting with a higher accuracy. A magnetic field detection device 1 includes a first magnetic sensor unit 1000a, a second magnetic sensor unit 1000b, a third magnetic sensor unit 1000c and a fourth magnetic sensor unit 1000d. The first and the second magnetic sensor units are disposed side by side so that a sensitive axis directions of the first and the second magnetic sensor units are oriented in a first direction, and the third and the fourth magnetic sensor units are disposed side by side so that the sensitive axis directions of the third and the fourth magnetic sensor units are oriented in a second direction.

Abstract: Sticking of core layer is suppressed, and deterioration of sensitivity of a sensor is prevented. An optical waveguide (10) includes a substrate (15), a core layer (11), a support, and a protrusion (18). The core layer (11) can transmit light. The support connects at least a portion of the substrate (15) and a portion of the core layer (11) together. The support supports the core layer (11). The protrusion (18) is arranged at a position different from a position of the support in a space between the substrate (15) and the core layer (11). The protrusion (18) has a maximum height at a position deviated from a central position cp of the core layer (11) in a width direction. The protrusion (18) protrudes toward the core layer (11) from the substrate (15).

Abstract: Provided is a delta-sigma AD converter including a delta-sigma modulating section that outputs a digital signal obtained by performing delta-sigma modulation with an oversampling ratio on an input analog signal; a digital filtering section that filters the digital signal with the oversampling ratio; a control terminal into which an external control signal is input; an output control section that performs control to output an output signal based on the filtered digital signal, according to the external control signal; and a setting section that sets the oversampling ratio based on interval information of the external control signal.

Abstract: In-package temperature is controlled with higher accuracy. To this end, a temperature control circuit includes a temperature sensor arranged in a package and detecting temperature in the package, a heater current detection circuit detecting a driving amount of a heater, a target temperature generation circuit generating a target temperature from an intended temperature of a resonator and a detection value of the driving amount detected by the heater current detection circuit, a heater current driver controlling the heater so that the detection temperature detected by the temperature sensor coincides with the target temperature, and an Nth-order correction circuit receiving the detection value of the driving amount detected by the heater current detection circuit or a signal based on the target temperature and cancelling influence of a second or higher order fluctuation component generated in the heater current detection circuit on temperature of the resonator.

Abstract: A magnetic field measuring device that can measure a weaker magnetic field is provided. A magnetic field measuring device is provided, the magnetic field measuring device including: a sensor unit that has at least one magnetoresistive element; a reference voltage generating unit that outputs a reference voltage; a magnetic field generating unit that generates a magnetic field to be applied to the sensor unit; a feedback current generating unit that supplies, according to a difference between an output voltage of the sensor unit and the reference voltage, the magnetic field generating unit with a feedback current that generates a feedback magnetic field to diminish an input magnetic field to the sensor unit; a magnetic field measuring unit that outputs a measurement value corresponding to the feedback current; and an adjusting unit that uses the output voltage of the sensor unit to adjust the reference voltage.

Abstract: The present invention relates to a hall electromotive force signal detection circuit and a current sensor thereof each of which is able to achieve excellent wide-band characteristics and fast response as well as high accuracy. A difference calculation circuit samples a component synchronous with a chopper clock generated by a chopper clock generation circuit, out of an output voltage signal of a signal amplifier circuit, at a timing obtained from the chopper clock, so as to detect the component. An integrating circuit integrates an output from the difference calculation circuit in the time domain. An output voltage signal from the integrating circuit is fed back to a signal amplifier circuit via a third transconductance element.

Abstract: A magnetic sensor device includes three magnetic sensors for detecting components of an external magnetic field that are in three directions, a magnetic field generation section, and a correction processor. The magnetic field generation section generates additional magnetic field components in three directions used for measurements of main- and cross-axis sensitivities of the three magnetic sensors. The correction processor corrects respective detection signals of the three magnetic sensors on the basis of the measurement results of the main- and cross-axis sensitivities of the magnetic sensors.

Abstract: An optical concentration measurement device includes an LED light source, alight receiving unit having a rectangular light receiving surface and outputting a detection signal representing intensity of received light, and light guiding units guiding light emitted by the LED light source to the light receiving unit, wherein a shape on the rectangular light receiving surface of light radiated on the light receiving surface is rectangular, the optical concentration measurement device measures concentration of an object to be measured existing in a light path formed by the light guiding units, based on the detection signal output from the light receiving unit, and the light guiding units guide light at a diffraction limit or greater in such a way that area of the light on the rectangular light receiving surface is ½ or less of area of the rectangular light receiving surface.

Abstract: An optical waveguide 15 includes a substrate 19, a core layer 12, a support 20, and a suppressing portion. The core layer 12 includes a light propagating portion 10 and a diffraction grating portion 11. The diffraction grating portion 11 includes a fine line pattern formed therein. The support 20 is made from a material having a smaller refractive index than a refractive index of the core layer 12. The support 20 supports the core layer 12 with respect to the substrate 19. The suppressing portion suppresses deformation of fine lines 13 that form the fine line pattern. The support 20 is not provided in an entire region between the light propagating portion 10 and the substrate 19 in a cross-section perpendicular to a longitudinal direction of the core layer 12 at least at a position in the longitudinal direction.

Abstract: A successive approximation analog-digital (AD) converter and method performed by the converter are provided. The successive approximation AD converter comprises a digital-analog (DA) converter; a comparator which determines a magnitude relation between an input signal and an output signal of the DA converter; and a successive approximation register which generates a first digital signal based on a determination result. The method comprises: switching an operation selection signal from a first logic to a second logic; performing a logical operation so that a digital signal input to the DA converter has a larger value or a smaller value than the first digital signal, when the operation selection signal has transited to the second logic, based on a portion of the determined first digital signal until transition; and inputting the first digital signal to the DA converter when the operation selection signal is the first logic.

Abstract: The optical device includes a photoelectric conversion block including a photoelectric conversion chip configured to include photoelectric conversion elements arranged in a matrix and a first sealing member configured to cover side faces of the photoelectric conversion chip to expose the photoelectric conversion chip and a lens block including a lens and a second sealing member configured to cover side faces of the lens to expose one surface and an other surface of the lens. In the lens block, the one surface of the lens and the second sealing member forms a recessed portion, at least a part of a bottom surface of the recessed portion being formed by the one surface of the lens, a sidewall of the recessed portion being formed by the second sealing member, and the recessed portion being arranged such that the photoelectric conversion chip exposed from the first sealing member is covered.

Abstract: Sticking of core layer is suppressed, and deterioration of sensitivity of a sensor is prevented. An optical waveguide (10) includes a substrate (15), a core layer (11), a support, and a protrusion (18). The core layer (11) can transmit light. The support connects at least a portion of the substrate (15) and a portion of the core layer (11) together. The support supports the core layer (11). The protrusion (18) is arranged at a position different from a position of the support in a space between the substrate (15) and the core layer (11). The protrusion (18) has a maximum height at a position deviated from a central position cp of the core layer (11) in a width direction. The protrusion (18) protrudes toward the core layer (11) from the substrate (15).

Abstract: The switch circuit includes a MOS transistor one end of which is coupled to a power supply line and to a control terminal of which voltage is input, a switch coupled between the power supply line and one end of the MOS transistor or one end of which is coupled to the other end of the MOS transistor, a MOS transistor coupled between an output terminal and ground potential, and a series-connected switch and constant current source coupled to a connection point between an opposite-side end of the whole series-connected MOS transistor and switch to the power supply line and the control terminal of the MOS transistor and performing adjustment to prevent current from flowing from the MOS transistor to ground potential after the switch turns on until the MOS transistor turns on.

Abstract: To achieve a size reduction of a semiconductor package while securing stability in mounting. Three terminals t1, t2, and t4 are individually arranged on a semiconductor package 10 having a rectangular shape as viewed in plan in such a manner that the center in the longitudinal direction of the semiconductor package 10 of each of the three terminals t1, t2, and t4 and the center in the longitudinal direction of each of the other terminals are not overlapped with each other as viewed from the side of the long side.

Abstract: A rotation angle sensor includes first and second magnetic detection elements disposed at positions where a first disposition angle relative to a magnet center is greater than 0 degrees and less than 90 degrees and configured to acquire magnetic field in a first direction varying by a rotation of a magnet; third and fourth magnetic detection elements configured to acquire the magnetic field in a second direction; a calculation signal generator configured to output a first magnetic field calculation signal, based on outputs of the first and second magnetic detection elements, and configured to output a second magnetic field calculation signal, based on outputs of the third and fourth magnetic detection elements; and an angle signal generator configured to generate and output an angle signal indicative of a rotation angle of the magnet, based on the first and second magnetic field calculation signal.

Abstract: To achieve the miniaturization of and the enhancement of the strength of a semiconductor element.

Abstract: An LNA circuit includes: paths provided between an input and an output terminals, an LNA provided in at least one path, and a selector selecting one path. The LNA includes: a MOS transistor coupled between a first and a second power supplies, a first inductor coupled to a source of the MOS transistor, a capacitor formed between a gate and the source of the MOS transistor, a second inductor coupled between the gate of the MOS transistor and the input terminal, and a changeover switch coupled parallelly with at least one of the capacitor, and the first and the second inductors. The selector switches between a first state that one path is selected and the changeover switch is on, and a second state that another path is selected and the changeover switch is off. Alternatively, the one path and the another path are respectively provided without and with the LNA.

Abstract: A phase adjusting circuit is provided, including a signal generation circuit receiving a frequency adjusting signal and generating a reference signal having a frequency corresponding to the frequency adjusting signal; a first path receiving the reference signal and providing a first signal; a second path receiving the reference signal and providing a second signal, and time for the reference signal passing through the second path is different from time for the reference passing through the first path; a phase shifter disposed on the first path or the second path and shifting a phase of the reference signal based on a phase adjusting signal; a phase difference detection circuit detecting a phase difference between the first and the second signals; and an adjusting signal generation circuit generating the frequency adjusting signal and the phase adjusting signal based on the phase difference so that the phase difference becomes a target value.