Abstract: A hall element is provided to suppress variations in a hall output voltage of the hall element due to a stacked structure of an electrode portion, an insulating film, and a magnetosensitive portion. The hall element may include a substrate, a magnetosensitive portion formed on the substrate, an insulating film formed on the magnetosensitive portion, electrode portions formed on the insulating film, and contact portions electrically connecting the electrode portions and the magnetosensitive portion to each other through the insulating film, in which the entire region surrounded by the contact portions is included in the region of the magnetosensitive portion, and the proportion of regions extending with the corresponding contact portions of the electrode portions as reference points is set to be equal to or less than a predetermined value in a quadrangle formed by the region surrounded by the contact portions.

Abstract: A light emitting device including: a light emitting element; a molded resin portion configured to seal at least a portion of the light emitting element; a temperature information acquiring unit configured to acquire temperature information; a humidity information calculating unit configured to calculate humidity information, based on information relating to at least either electrical characteristics or optical characteristics of the light emitting element and the temperature information; and a controlling unit configured to control the light emitting element, based on the temperature information and the humidity information.

Abstract: Disclosed is an infrared detecting device with a high SNR. The infrared detecting device 100 includes a semiconductor substrate 10; a first layer 20 formed on the semiconductor substrate and having a first conductivity type; a light receiving layer 30 formed on the first layer; and a second layer 40 formed on the light receiving layer and having a second conductivity type. The first layer includes, in the stated order: a layer containing Alx(1)In1-x(1)Sb; a layer having a film thickness ty(1) in nanometers and containing Aly(1)In1-y(1)Sb; and a layer containing Alx(2)In1-x(2)Sb, where ty(1), x(1), x(2), and y(1) satisfy the following relations: for j=1, 2, 0<ty(1)?2360×(y(1)?x(j))?240 (0.11?y(1)?x(j)?0.19), 0<ty(1)??1215×(y(1)?x(j))+427 (0.19<y(1)?x(j)?0.33), and 0<x(j)<0.18.

Abstract: A howling suppression device is provided, including: a plurality of filters in which a passband and a stopband are arranged alternately on a frequency axis; and a gain control unit which temporally varies an output gain of each of the plurality of filters and sums signals thus varied to output, wherein each of the plurality of filters has a passband in at least part of a stopband of another filter.

Abstract: The object of the present invention is to provide a current source which is capable of suppressing an increase in circuit size and by which a highly accurate constant current extremely stable to manufacturing variations or temperature fluctuations can be obtained. A current source circuit is provided with a nonvolatile storage element having a control gate region and a source region and operating as a field-effect transistor, and is configured to output a current in a state where a bias is applied between the control gate region and the source region.

Abstract: A magnetic sensor includes: a magnetic converging plate; Hall elements disposed on one surface side of the magnetic converging plate; wires connecting with the Hall elements; and a signal processing circuit that connects with these wires to receive a signal from the Hall element. Between the Hall element and the signal processing circuit, the two wires cross while being spaced apart from each other in a depth direction of a substrate, and forms a compensation loop between a cross of the two wires and the circuit, and in a planar view as seen in a depth direction, at least part of a region occupied by the compensation loop is covered by the magnetic converging plate. The compensation loop compensates an induced electromotive force caused to the closed loop formed by the wires including the Hall element.

Abstract: An optical concentration measuring device capable of power saving and lifespan extension of a light source is provided, including a light source emitting an amount of light corresponding to a supplied power; a light detection part receiving at least a part of the light emitted by the light source and generating a signal corresponding an amount of received light as an output signal; a smoothing filter smoothing a signal based on the output signal; a signal change amount calculation part calculating a first and a second change amounts corresponding to a change amount between at least two selected acquisition values selected from acquisition values based on the output signal at current or past time; a light source control part controlling the power supplied to the light source based on the first change amount; and a filter control part controlling characteristics of the smoothing filter based on the second change amount.

Abstract: Disclosed is an infrared light emitting device including: a semiconductor substrate; a first layer formed on the semiconductor substrate and having a first conductivity type; a light emitting layer formed on the first layer; and a second layer formed on the light emitting layer and having a second conductivity type, wherein the first layer includes, in the stated order: a layer containing Alx(1)In1?x(1)Sb; a layer having a film thickness ty(1) in nanometers and containing Aly(1)In1?y(1)Sb; and a layer containing Alx(2)In1?x(2)Sb, where ty(1), x(1), x(2), and y(1) satisfy the following relations: for j=1, 2, 0<ty(1)?2360×(y(1)?x(j))?240 (0.11?y(1)?x(j)?0.19), 0<ty(1)??1215×(y(1)?x(j))+427 (0.19<y(1)?x(j)?0.33), and 0<x(j)<0.18.

Abstract: The transmitter includes a phase shifter that shifts a phase of an input signal and outputs a shifted signal; a first control circuit changes a phase shift amount of the phase shifter; a phase difference signal output circuit outputs a phase difference signal between the shifted signal and the reference signal; an extreme value output circuit outputs a value of the phase difference signal when the phase difference signal becomes the extreme value; a target value output circuit outputs a target value based on an output from the extreme value output circuit; and a second control circuit controls the phase shift amount of the phase shifter such that a value of the phase difference signal coincides with the target value. The phase shifter outputs, as a transmission wave, the input signal the phase of which is shifted by the phase shift amount controlled by the second control circuit.

Abstract: A hall element is provided to suppress fluctuation in a Hall output voltage of the hall element which is generated due to a fluctuation in stress. The hall element may be formed to include a substrate, a magnetosensitive portion formed on the substrate, an insulating film formed on the magnetosensitive portion, four conductive portions (electrode portions and contact portions) which are formed on the insulating film, electrically connected to the magnetosensitive portion through the insulating film, and disposed at positions serving as vertexes of a quadrangle, and ball portions electrically connected to the conductive portions, and at least one ball portion is disposed on a diagonal line of the quadrangle formed by a region surrounded by the four conductive portions and above a portion where the conductive portion and the insulating film are in contact with each other.

Abstract: A switch apparatus is provided, including: a main switch connected between first and second terminals, and electrically connecting or disconnecting the first and second terminals according to gate voltage applied to a gate terminal; a voltage output unit having a voltage divider including a first voltage-division resistance on the first terminal side and a second voltage-division resistance on the second terminal side, and outputting voltage corresponding to voltage of the first terminal and voltage of the second terminal if the main switch is caused to enter a connected state; a buffer outputting voltage following output voltage of the voltage output unit in a connected state of the main switch; and a switch control circuit supplying first voltage corresponding to output voltage of the buffer to the gate terminal, and supplying a second voltage corresponding to output voltage of the buffer to a bulk terminal of the main switch.

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 direct conversion receiver configured to down-convert a received RF signal by using a local signal and demodulate the down-converted signal, the direct conversion receiver including: a power detector unit configured to detect a signal strength of the down-converted signal; a power determinator unit configured to determine whether the signal strength detected by the power detector unit is equal to or smaller than a previously set threshold value; and a local oscillator circuit configured to output, as the local signal, a first local signal when the power determinator unit determines that the signal strength is equal to or smaller than the threshold value, and output, as the local signal, a second local signal set to a frequency obtained by adding a previously set offset frequency to a frequency of the first local signal when the power determinator unit determines that the signal strength is larger than the threshold value.

Abstract: A light-emitting/receiving device including: a diode-type light-emitting element formed on a semiconductor substrate; a diode-type light-receiving element formed on the semiconductor substrate; a light source driving unit configured to supply a first common voltage to an anode or a cathode of the light-emitting element to drive the light-emitting element; and a light signal processing unit configured to perform current/voltage conversion on an output current outputted from the light-receiving element, by referring to a second common voltage.

Abstract: A current sensor includes a first current pathway, a first magnetic sensor arranged near the first current pathway, a second magnetic sensor arranged opposite the first magnetic sensor with the first current pathway in between, a second current pathway, a third magnetic sensor arranged near the second current pathway, a fourth magnetic sensor arranged opposite the third magnetic sensor with the second current pathway in between, and a signal processor that generates a signal based on a quantity of the first measured current from output of the first magnetic sensor and output of the second magnetic sensor, and also generates a signal based on a quantity of the second measured current from output of the third magnetic sensor and output of the fourth magnetic sensor.

Abstract: A small-size reliable gas sensor that can reduce a measurement error can be provided. The gas sensor includes a first light source; a first sensor unit and a second sensor unit disposed to receive light output from the first light source; a first substrate having a first principal surface on which the first light source and the first sensor unit are provided; and a second substrate having a first principal surface on which the second sensor unit is provided. The first sensor unit is disposed at a location where light output from the first light source and reflected on the second principal surface strikes the first principal surface of the first substrate.

Abstract: An adjusting method of a camera module, a lens position control device, a control device of a linear movement device, and a controlling method of the same are provided in a state of the cameral module in which an imaging element and an actuator are combined. The camera module includes a position sensor (53) that detects a position of a lens (50) to output a detection position signal, a storage unit (541) that stores and rewrites a position code value corresponding to the position of the lens, a target position signal generation unit (542) that outputs a target position signal based on the position code value and the target position code value, and a control unit (543) that generates a control signal based on the target position signal and the detection position signal.

Abstract: To provide a current sensor excellent in insulation resistance. A current sensor (1) includes a conductor (10); a support part (30) for supporting a signal processing IC (20); a magnetoelectric conversion element (13) configured to be electrically connectable to the signal processing IC (20), and arranged in a gap (10a) of the conductor (10) so as to detect a magnetic field generated by a current flowing through the conductor (10); and an insulation member (14) supporting the magnetoelectric conversion element (13).

Abstract: A light receiving device including: a light receiving element configured to receive at least a portion of light incident from an outside and output an output signal corresponding to amount of received light; a molded resin portion configured to seal at least a portion of the light receiving element; a temperature information acquiring unit configured to acquire temperature information; a humidity information calculating unit configured to calculate humidity information, based on information relating to at least either electrical characteristics or optical characteristics of the light receiving element and the temperature information; and a compensating unit configured to compensate the output signal, based on the temperature information and the humidity information.

Abstract: Provided is an oscillation apparatus and an oscillation control apparatus including a first control section that generates a first control signal that controls an oscillation frequency of an oscillator, based on a temperature detection result of a temperature detecting section; an encoder that generates a feedback signal; a second control section that generates a second control signal that controls the oscillation frequency of the oscillator, based on the temperature detection result of the temperature detecting section, an external input signal input from outside, and the feedback signal; an oscillation circuit that sets the oscillation frequency of the oscillator, based on the first control signal and the second control signal; and a reference voltage generating section that generates a reference voltage, wherein the encoder generates the feedback signal by comparing the second control signal and the reference voltage.