Abstract: A first step sets a second inclination angle of a housing to an angle different from a reference housing angle by a limit angle; drives an actuator to set a first inclination angle to an angle different from a substrate inclination angle by the limit angle such that a beam axis is kept to be oriented to a specified direction; and measures, based on transmission and reception of a radar beam, first received power. A second step drives the actuator to set the first inclination angle to an angle located outside the adjustment range by a predetermined additional angle while the first inclination angle is maintained; and measures, based on transmission and reception of the radar beam, second received power. A third step determines whether a difference between the first received power and the second received power is greater than a predetermined determination threshold, and checks an operating state of the actuator based on a result of the determination.

Abstract: An imaging apparatus includes a light source that includes a diffusion plate and, in operation, emits, toward a subject, pulsed light that diverges; a photodetector that includes a photoelectric converter that, in operation, receives light from the subject and converts the light to an electric charge and an electric charge accumulator that, in operation, accumulates the electric charge, and, in operation, generates an electric signal based on the accumulated electric charge; and a control circuit that, in operation, controls the light source and the photodetector. The control circuit, in operation, causes the electric charge accumulator to start accumulating the electric charge when a period of time has passed after the control circuit has caused the light source to start emitting the pulsed light, and causes the electric charge accumulator to accumulate the electric charge corresponding to a component, among the light from the subject, that is scattered inside the subject.

Abstract: An image pickup apparatus includes: a first light source which, in operation, emits first pulsed light to project a first image of a first pattern at a first position in a predetermined region of a subject, and emits second pulsed light to project a second image of a second pattern at a second position, different from the first position, in the predetermined region of the subject; an image sensor including multiple pixels each including a photodetector that, in operation, converts received light into a signal charge, and a first accumulator and a second accumulator each of which, in operation, accumulates the signal charge; and a control circuit which, in operation, controls the first light source and the image sensor.

Abstract: An imaging apparatus according to an aspect of the present disclosure includes an image sensor which, in operation, acquires m kinds (m is an integer which is 1 or larger) of light, the m kinds of light each having wavelength characteristic different from each other and outputs one or more signals each corresponding to each of the m kinds of light, and a signal processing circuit which, in operation, processes the one or more signals to generate and output n, which is larger than m, pieces of images corresponding to respective wavelength regions different from each other.

Abstract: An imaging apparatus includes an imaging device, a first imaging optical system and a second imaging optical system that form respective input images from mutually different viewpoints onto the imaging device, and a first modulation mask and a second modulation mask that modulate the input images formed by the first imaging optical system and the second imaging optical system. The imaging device captures a superposed image composed of the two input images that have been formed by the first imaging optical system and the second imaging optical system, modulated by the first modulation mask and the second modulation mask, and optically superposed on each other, and the first modulation mask and the second modulation mask have mutually different optical transmittance distribution characteristics.

Abstract: A biological information measuring device according to an aspect of the present disclosure includes: a light source that, in operation, emits irradiation light for irradiating a test portion of a subject; a light detector that, in operation, detects light from the subject and outputs an electrical signal corresponding to the light; and a control circuit that, in operation, determines a power of the irradiation light emitted by the light source, and that, in operation, measures biological information related to a blood flow at the test portion based on the electrical signal. The control circuit, in operation, detects a distance between the light source and the test portion based on the electrical signal, and determines the power of the irradiation light such that the power of the irradiation light is increased as the distance increases.

Abstract: An imaging apparatus according to an aspect of the present disclosure includes a first coding element that includes regions arrayed two-dimensionally in an optical path of light incident from an object, and an image sensor. Each of the regions includes first and second regions. A wavelength distribution of an optical transmittance of the first region has a maximum in each of first and second wavelength bands, and a wavelength distribution of an optical transmittance of the second region has a maximum in each of third and fourth wavelength bands. At least one selected from the group of the first and second wavelength bands differs from the third and fourth wavelength bands. The image sensor acquires an image in which components of the first, second, third and fourth wavelength bands of the light that has passed through the first coding element are superimposed on one another.

Abstract: An image capture device according to the present disclosure includes: a lens optical system L; an image sensor N on which light that has passed through the lens optical system L is incident and which includes at least a plurality of first pixels and a plurality of second pixels; and an array of optical elements K which is arranged between the lens optical system and the image sensor. The lens optical system has a first optical region D1 which transmits mostly light vibrating in the direction of a first polarization axis and a second optical region D2 which transmits mostly light vibrating in the direction of a second polarization axis that is different from the direction of the first polarization axis. The array of optical elements makes the light that has passed through the first optical region D1 incident on the plurality of first pixels and also makes the light that has passed through the second optical region D2 incident on the plurality of second pixels.

Abstract: An imaging apparatus includes an image-forming optical system that forms an image by using optical signals; an imaging device that includes a plurality of pixels, receives, with the plurality of pixels, the optical signals used to form the image, and converts the optical signals into electric signals; and a color filter that is located between the image-forming optical system and the imaging device and has a light transmittance which differs according to positions on the color filter corresponding to the plurality of pixels and according to a plurality of wavelength bands.

Abstract: An imaging device according to an aspect of the present disclosure is provided with: a light source that, in operation, emits pulsed light including components of different wavelengths; an encoding element that has regions each having different light transmittance, through which incident light from a target onto which the pulsed light has been irradiated is transmitted; a spectroscopic element that, in operation, causes the incident light transmitted through the regions to be dispersed into light rays in accordance with the wavelengths; and an image sensor that, in operation, receives the light rays dispersed by the spectroscopic element.

Abstract: An imaging apparatus according to an aspect of the present disclosure includes a light source that, in operation, emits pulsed light to a living body, an image sensor that includes at least one pixel including a photodiode and charge accumulators that, in operation, accumulate signal charge from the photodiode, and a control circuit that, in operation, controls the image sensor. The charge accumulators, in operation, accumulate the signal charge corresponding to a component of the pulsed light scattered inside the living body.

Abstract: An imaging apparatus according to an aspect of the present disclosure includes a light source that, in operation, emits first pulsed light and second pulsed light, an image sensor that includes at least one pixel including a photodiode, a first charge accumulator and a second charge accumulator, the first charge accumulator and the second charge accumulator, in operation, accumulating signal charge from the photodiode, and a control circuit that, in operation, controls the image sensor. The control circuit, in operation, causes the first charge accumulator to begin to accumulate the signal charge a period of time after the light source begins to emit the first pulsed light. The control circuit, in operation, causes the second charge accumulator to begin to accumulate the signal charge the period of time after the light source begins to emit the second pulsed light.

Abstract: A method of fabricating an electronic device is provided, where the electronic device includes a port, an A/D converter, a memory, and a determination circuit. The determination circuit is configured to determine whether or not there is an abnormality by comparing an A/D converted value as a result of the A/D converter converting a voltage based on a power-supply voltage inputted to the port with a limit value stored in the memory. The method includes a step of inputting a predetermined voltage to the port of the electronic device to be fabricated, and a step of recording an A/D converted value as a result of the A/D converter converting a voltage based on the predetermined voltage inputted to the port as the limit value in the memory.

Abstract: An axial displacement judgment device has a first detector acquiring a first detection value from a G sensor which detects an acceleration applied to a radar device, a second detector acquiring a second detection value from a YG sensor which detects the acceleration applied to a vehicle body, and a difference calculator calculating a detection difference value, which is a difference between the first detection value and the second detection value, every first period. The device further has an average difference value calculator calculating an average difference value as an average value of the detection difference values calculated during an acquisition period including the first periods, a deviation calculator calculating a difference standard deviation of the detection difference values calculated during the acquisition period, and a judgment section detecting occurrence of an axial displacement of the radar device based on the average difference value and the difference standard deviation.

Abstract: A determination unit that determines a positional change of a radar apparatus mounted on a vehicle including a vehicle body is provided with a reference member, a displacement sensor and displacement determining means. The reference member is fixed to the vehicle body and disposed such that at least a part of the reference member is adjacent to the radar apparatus. The displacement sensor detects a displacement of the radar apparatus with respect to the reference member. The determining means determines whether or not a position of the radar apparatus has changed with respect to the vehicle body, based on the displacement detected by the displacement sensor.

Abstract: A method for designing an optical system having a stepped diffraction grating surface includes a flare computation step of defining a temporary shape of the diffraction grating surface and computing a flare amount, and a determination step of determining whether or not the flare amount is within a permissible range, and setting the temporary shape as a shape of the diffraction grating surface if the flare amount is within the permissible range, and returning to the flare computation step if the flare amount is out of the permissible range.

Abstract: An imaging apparatus according to an aspect of the present disclosure includes an image sensor which, in operation, acquires m kinds (m is an integer which is 1 or larger) of light, the m kinds of light each having wavelength characteristic different from each other and outputs one or more signals each corresponding to each of the m kinds of light, and a signal processing circuit which, in operation, processes the one or more signals to generate and output n, which is larger than m, pieces of images corresponding to respective wavelength regions different from each other.

Abstract: An imaging apparatus disclosed in the present application includes a lens optical system, an imaging element and an optical array element. The lens optical system includes first and second areas having different optical characteristics with each other. The imaging element includes first and second pixels each including a filter of a first spectral transmittance characteristic, third pixels including a filter of a second spectral transmittance characteristic, and fourth pixels including a filter of a third spectral transmittance characteristic. The optical array element causes the light passing through the first area to be incident on the first pixels and one of the third and fourth pixels and causes the light passing through the second area to be incident on the second pixels and the other of third and fourth pixels.

Abstract: An imaging apparatus according to an aspect of the present disclosure includes a first coding element that includes regions arrayed two-dimensionally in an optical path of light incident from an object, and an image sensor. Each of the regions includes first and second regions. A wavelength distribution of an optical transmittance of the first region has a maximum in each of first and second wavelength bands, and a wavelength distribution of an optical transmittance of the second region has a maximum in each of third and fourth wavelength bands. At least one selected from the group of the first and second wavelength bands differs from the third and fourth wavelength bands. The image sensor acquires an image in which components of the first, second, third and fourth wavelength bands of the light that has passed through the first coding element are superimposed on one another.

Abstract: An image pickup apparatus includes an encoder which is arranged on an optical path of light incident from an object and which has a plurality of regions with first light transmittance and a plurality of regions with second light transmittance lower than the first light transmittance, a dispersive element which is arranged on an optical path of at least one part of light after passage through the encoder and which spatially shifts the at least one part of the light in accordance with wavelength, and at least one image pickup device which is arranged to receive light after passage through the dispersive element and light without passage through the dispersive element and which acquires a first image, in which light components for respective wavelengths spatially shifted by the dispersive element are superimposed, and a second image based on the light without passage through the dispersive element.