Abstract: A three-dimensional projection apparatus includes a display including a display surface having a plurality of subpixels arranged in a grid along a first direction and a second direction substantially orthogonal to the first direction, an optical element configured to define a light beam direction of an image light emitted from the subpixels for each strip-shaped region of a plurality of strip-shaped regions extending in the second direction on the display surface, an optical member configured to project the image light, the light beam direction of which is defined by the optical element, so that a virtual image of the display surface is formed, and a controller configured to acquire information related to a position of an eye of a subject and to correct, in accordance with the position of the eye, the optical element and an image to be displayed by the display surface.
Abstract: Provided is an imaging apparatus having: an imaging optical system including at least one optical element; an image sensor configured to capture an object image formed by the imaging optical system; a substrate on which an image sensor is mounted; a holding member configured to hold the imaging optical system, the holding member including a substrate bonding face that is bonded to the substrate; a first bonding member configured to bond at least a part of a first face of the substrate, that faces the substrate bonding face, to the substrate bonding face; and a second bonding member configured to bond at least a part of a second face of the substrate, that is opposite to the first face of the substrate, to the substrate bonding face.
Abstract: An electronic element mounting substrate includes a first substrate that has a first main surface, has a rectangular shape, and has a mounting portion for an electronic element on the first main surface, and a second substrate that is located on a second main surface opposite to the first main surface, is made of a carbon material, has a rectangular shape, has a third main surface facing the second main surface and a fourth main surface opposite to the third main surface, in which the third main surface or the fourth main surface has heat conduction in a longitudinal direction greater than heat conduction in a direction perpendicular to the longitudinal direction, and that has a recessed portion on the fourth main surface.
Abstract: A cutting tool holder may include an upper surface; a first side surface; a second side surface adjacent to the first side surface; a pocket opening into the upper surface, the first side surface, and the second side surface; a first portion located lower than the pocket and protruded outward from the first side surface; and a flow path including an inflow port and an outflow port. The first side surface may include a first recess. The flow path may include a first outflow port opening into the first portion as the outflow port and a first flow path extending from the first outflow port into the holder. The first outflow port is located at a region of the first portion corresponding to the first recess.
Abstract: A cutting insert includes an upper surface and upper edge. The upper surface includes a second side part, a first corner part, and a second corner part. The upper surface further includes a first surface and a second surface. The upper edge includes a first edge located at the first corner part, a second edge located at the second side part, and a third edge located at the second corner part. The second surface includes a first region extending toward the first corner part, and a second region extending toward the second corner part. A distance between the first region and the upper edge is smaller at a side of the second edge than at a side of the first edge. A distance between the second region and the upper edge is smaller at a side of the second edge than at a side of the third edge.
Abstract: A cell stack device in the present disclosure includes a cell stack including a plurality of arranged cells, and a first manifold configured to fix a first end of each of the cells with a sealing material and supply reactive gas to the cells. The first manifold includes a frame body configured to fix the first end of each of the cells with the sealing material inside the frame body, and a plate body bonded to a first end portion of the frame body and having a rigidity lower than that of the frame body. A module in the present disclosure includes a housing and the cell stack device housed in the housing. Furthermore, a module housing device in the present disclosure includes an external casing, the module in the external casing, and an auxiliary device configured to operate the module in the external casing.
Abstract: An electronic device includes a proximity sensor and a controller configured to determine a direction of a gesture by a user on the basis of an output from the proximity sensor and in accordance with the hand the user uses to operate the electronic device.
Abstract: A measurement apparatus includes a housing, a display disposed on the front face of the housing, a contact interface, to be contacted by a test site, disposed on a different surface than the front face of the housing, a laser light source that emits laser light from the contact interface, a light receiver that receives scattered laser light from the test site, a biological information generator that generates biological information based on output from the light receiver, and a controller that controls emission of laser light in the laser light source.
Abstract: An electronic device comprising: a display; a communication unit; a storage configured to store response method data in which pre-set keywords and response methods corresponding to incoming calls are associated with each other; and a processor configured to, when an incoming call containing a text message comes in, acquire the response method data that is stored in the storage and execute a process relating to the incoming call according to a response method that is defined in the response method data.
Abstract: A camera module includes a lens unit, a holding member, and a fixing member. The lens unit includes a lens for causing light to enter an internal space. The holding member holds an image sensor for capturing an image formed by the light. The fixing member fixes the lens unit and the holding member. The fixing member is cured resin. The lens unit further includes a groove at least partially housing the fixing member, and having an opening which faces the holding member. In a state such that the lens unit and the holding member are fixed to the fixing member, more of the fixing member is exposed to the outside of the lens unit than to the internal space surrounded by the lens unit and the holding member.
Abstract: An electronic device is configured to perform electric field communication via an electric field transmission medium. The electronic device includes a housing. The electronic device also includes a first electrode portion for electric field communication including a first electrode and a second electrode, a second electrode portion for electric field communication including a third electrode and a fourth electrode, and a differential amplifier. The second electrode is disposed further in a direction towards the inside of the housing than the first electrode. The fourth electrode is disposed further in a direction towards the inside of the housing than the third electrode. The first electrode and the second electrode are connected to a first input terminal of the differential amplifier. The second electrode and the fourth electrode are connected to a second input terminal of the differential amplifier.
Abstract: A base station according to one embodiment includes: a transmitter configured to transmit a synchronization signal in a cell using a predetermined subcarrier spacing, the cell being managed by the base station; and a controller configured to arrange, based on the predetermined subcarrier spacing, the synchronization signal in a plurality of discrete subcarriers not continuous in a frequency direction.
Abstract: A radio terminal according to one embodiment comprises a controller configured to be capable of relaying traffic between another radio terminal and a network by a proximity service. The controller performs a control for transmitting first information and second information, in a sidelink. The first information is used for identifying a location of a radio resource in which the second information is arranged.
Abstract: A UE 100 interrupts, in response to a predetermined message received from a connection target cell in a random access procedure, the random access procedure and selects a selection target cell used as a serving cell from among a plurality of cells.
Abstract: A tactile sensation providing apparatus includes a panel, an actuator configured to vibrate the panel, and an elastic member in contact with the panel. When the actuator vibrates the panel, the elastic member suppresses inhibition of vibration at a position where the panel is pressed.
Abstract: An information processing apparatus includes a communication interface and a controller. The communication interface receives, from a sensor container, information indicating an orientation of the sensor container. The controller, based on the information indicating the orientation of the sensor container, calculates a calculated value indicating a remaining amount of contents of the sensor container. The controller determines an estimated value of the remaining amount on the basis of the calculated value. The communication interface transmits the estimated value indicating the remaining amount to an external device. When the calculated value indicating the remaining amount decreases by a first predetermined value or more within a predetermined time period, the controller does not perform the determination of the estimated value on the basis of the calculated value.
Abstract: A base station according to this disclosure includes a plurality of antennas used for transmission and reception, an adaptive array processing unit that performs adaptive array processing on reception signals received by the plurality of antennas, and a control unit that decides a transmission antenna used for the transmission from the plurality of antennas at a time when a transmission signal is transmitted, and the control unit decides the transmission antenna based on transmission weight vectors respectively corresponding to the plurality of antennas obtained from a processing result of the adaptive array processing unit.
Abstract: A mobile electronic device comprises a communication unit obtaining a first atmospheric pressure value from a roadside unit associated with a pedestrian bridge, an atmospheric pressure sensor obtaining a second atmospheric pressure value of the mobile electronic device, and a controller. The controller calculates a correction value of the second atmospheric pressure value based on the first atmospheric pressure value.
Abstract: An electromagnetic wave detection apparatus 10 includes a separator 16, a first detector 17, a switching unit 18, and a second detector 20. The separator 16 is capable of switching between a separation state and a non-separation state. The separator 16 separates incident electromagnetic waves to travel in a first direction d1 and a second direction d2, in the separation state. The first detector 17 detects electromagnetic waves traveling in the first direction d1. The switching unit 18 includes a plurality of switching elements “se”. Each switching element “se” is capable of switching a traveling direction of electromagnetic waves traveling in the second direction d2 between a third direction d3 and a fourth direction d4. The second detector 20 detects electromagnetic waves traveling in the third direction d3.
August 3, 2018
July 9, 2020
Hiroki OKADA, Eri UCHIDA, Yukitoshi KANAYAMA
Abstract: In an angular velocity sensor, a pair of support parts are separated from each other in an x-axis direction in an orthogonal coordinate system xyz. A main part extends along the x-axis. A pair of extension parts connect two ends of the main part and inner sides of the support parts. The driving arms extend from the main part alongside each other in a y-axis direction separated from each other in the x-axis direction. The detecting arm extends from the main part in the y-axis direction at a position which is between the pair of driving arms. The driving circuit supplies voltages so that the pair of driving arms vibrate so as to bend to inverse sides from each other in the x-axis direction. The detecting circuit detects the signal generated due to bending deformation of the detecting arm in the z-axis direction.