Abstract: A differential amplifier is provided, in which generation of unnecessary harmonic distortion in the differential output signal is suppressed. A common mode feedback circuit increases or decreases operating points of an inverting output terminal and a non-inverting output terminal such that an intermediate voltage of voltages respectively provided to an inverting input terminal and a non-inverting input terminal is consistent with to a reference voltage. Variations in voltage at the inverting input terminal and the non-inverting input terminal are suppressed, variations in electrical properties of elements connected to the input terminals are suppressed. Therefore, it is possible to suppress generation of harmonic distortion in the output signals from the inverting output terminal and the non-inverting output terminal.

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: An ANC system includes an AD converter which performs AD conversion on an external noise signal, an ANC signal generator which generates an ANC signal for canceling a noise component arriving at the ears of a user based on an output signal of the AD converter, and a level detector which detects a level of the output signal and causes the ANC signal generator to power down in response to the level. The level detector measures a time for which the level is equal to or less than a predetermined first threshold value, causes the ANC signal generator or a portion of blocks of the AD converter to power down after the measured time exceeds a predetermined value, and causes the ANC signal generator or a portion of blocks of the AD converter to return from the power down when the level exceeds a predetermined second threshold value.

Abstract: A lens drive device includes a position detecting unit that outputs a detection signal indicating a position of a detected lens and includes a plurality of operation modes allowing operation with different power consumptions, a selecting unit that select an operation mode in which the position detecting unit operates from the plurality of operation modes, a position signal generation unit that generates, a lens position signal based on either one of detection signals depending on the selected operation mode, a calculation unit that calculates a drive amount of the lens based on a target position signal indicating a target position of the lens and the lens position signal; and a drive unit that drives the lens based on the drive amount.

Abstract: A rectifying circuit includes: a voltage-current converting circuit that converts an input voltage into a current; a first transistor and a second transistor that are connected in series and that are connected to a first node into which the current converted by the voltage-current converting circuit flows; a third transistor and a fourth transistor that are connected in series, and that respectively mirror a current flowing through the first transistor and a current flowing through the second transistor; and a first diode that is connected between a second node connected to the third transistor and the fourth transistor, and an output terminal.

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 stable and highly accurate gas detections apparatus is provided. A gas detection apparatus 1 includes a light emitting element 3 provided on a main surface 20 of the substrate 2 for emitting light from a light emitting surface 31; a light receiving element 4 provided on the main surface 20 of the substrate 2 for receiving the light on a light receiving surface 41; and a light guide member 5 for guiding the light emitted by the light emitting element 3 to the light receiving element 4. In plan view of the main surface of the substrate, the light emitting surface 31 and the light receiving surface 41 are shaped to have corners, and side of the light emitting surface 31 after being subjected to a magnification or reduction and a translation do not overlap sides of the light receiving surface 41.

Abstract: A light emitting and receiving apparatus includes a controller and a calculator. The controller acquires a first detection current from a light-receiving element when supplying a first drive current to a light-emitting element and acquires a second detection current from the light-receiving element when supplying a second drive current to the light-emitting element. The calculator generates a signal indicating deterioration of the light-emitting element when a reference value and an aging value satisfy a deterioration judgment condition, the aging value being a ratio between the first detection current and the second detection current. The detection accuracy of the light emitting and receiving apparatus is thereby improved.

Abstract: A gas detection device 1 comprises: a light emitter 10 configured to emit light of a wavelength band including a wavelength absorbed by a detection target gas; a light detector 20 having sensitivity to the wavelength band; a package 40; a light guide 50 configured to guide the light to the light detector 20; a joint 60 joining the package 40 and the light guide 50; and a heat insulator 70 located in a gap between the package 40 and the light guide 50, wherein part of a surface of the package 40 facing the light guide 50 has a proximity region D where a distance between the package 40 and the light guide 50 is 500 ?m or less, and at least part of the heat insulator 70 and at least part of the joint 60 are located adjacent to each other in part of the proximity region D.

Abstract: Provided is a gas sensor comprising first and second light emitting parts, first and second light receiving parts, a first optical path region and a second optical path region, wherein the optical path regions have a common region, an optical path length of the first optical path region is longer than that of the second optical path region, a rate of change of an output signal with respect to a gas to be measured of the first light receiving part is larger than that of the second light receiving part, a rate of change of an output signal with respect to an interference gas of the second light receiving part is larger than that of the first light receiving part, and a sensitivity peak wavelength of the second light receiving part overlaps with an absorption wavelength of water vapor.

Abstract: The optical concentration measuring device 1 includes: a first optical filter 41; a second optical filter 42; and an operation part 60, wherein a difference between a peak wavelength of the first effective sensitivity spectrum based on the first transmission band in the first light receiving part 51 and a peak wavelength of the second effective sensitivity spectrum based on the second transmission band in the second light receiving part 52 is ±0.2 times or more and ±0.8 times or less the full width at half maximum of the first effective sensitivity spectrum, wherein the operation part removes an attenuation amount of the first intensity by the interference gas and an attenuation amount of the second intensity by the interference gas.

Abstract: Provided is a magnetic field measuring apparatus for: acquiring the measurement data measured by a magnetic sensor array that is configured by arraying the plurality of magnetic sensor cells to form a surface covering at least a part of a target object to be measured; performing signal separation on a magnetic field spatial distribution indicated by the measurement data based on a position and magnetic sensitivity of each magnetic sensor; generating a calibration magnetic field at a position on a straight line that can be drawn without crossing the plurality of magnetic sensor cells from the measurement space outside the measurement space; and calibrating a sensor error for the magnetic sensor based on a separation error in a case where signal separation has been performed on a spatial distribution of the calibration magnetic field.

Abstract: An FMCW radar is used to sense an object. A sensor device that senses an object by using an FMCW radar is provided. The sensor device includes: a signal processing unit that acquires a reception signal that is based on a reception wave of the FMCW radar, and senses the object; and a phase converting unit that acquires phase information from the reception signal, and tracks the object by monitoring a peak BIN, and a phase offset between the peak BIN and another BIN based on the phase information. As the reception signal, the signal processing unit may use micro-vibration data about the object to sense the object. A system including: a transceiving unit that transmits and receives an FMCW radar signal; and the sensor device according to the first aspect of the present invention is provided.

Abstract: A camera module includes a lens, a first magnet and a second magnet mounted on a mobile body including the lens, a coil portion arranged near the first magnet and configured to move the first magnet in a first direction, and the magnetic sensor arranged near the second magnet and configured to detect the position of the second magnet in the first direction as a detection direction.

Abstract: Provided is an optical element, in which: an internal wiring portion electrically connects a first contact electrode portion and a second contact electrode portion to each other; a second region, an active layer and a second conductive semiconductor layer form a mesa structure; a pad electrode is placed so as to cover a plurality of unit elements, and is electrically connected to at least one of the first contact electrode portion and the second contact electrode portion; a first insulating portion is placed between the pad electrode and a first region of a side surface of a mesa structure and a first conductive semiconductor layer; and a diameter of a circle circumscribed to a region where the pad electrode and a connection portion are in contact with each other is 15% or more of a length of a short side of a substrate.

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.

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: An optical device comprises an optical filter having a substrate and a multilayer film having layers with different refractive indexes formed on at least one side of the substrate; and an infrared light emitting and receiving device having a first conductive-type semiconductor layer, an active layer, and a second conductive-type semiconductor layer. The multilayer film has alternatively stacked first second layers each having refractive indexes of 1.2 or more and 2.5 or less, and 3.2 or more and 4.2 or less, respectively, in a wavelength range of 2400 nm to 6000 nm. The optical filter includes a wavelength range having an average transmittance of 70% or more with a width of 50 nm or more in a wavelength range of 2400 nm to 6000 nm, and has a maximum transmittance of 5% or more in a wavelength range of 6000 nm to 8000 nm.

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: 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.