Abstract: A light emitting element (102) is formed on a substrate (100), and includes an organic layer (120). Terminals (112 and 132) are formed on the substrate (100), and are connected to the light emitting element (102). A protective film (140) covers the light emitting element (102) and the terminals (112 and 132). An intermediate layer (150) is provided between the terminal (112) and the protective film (140) and between the terminal (132) and the protective film (140). For example, the glass transition temperature or phase transition temperature of the intermediate layer (150) is lower than the glass transition temperature or phase transition temperature of the protective film (140).

Abstract: An organic EL element (102) is formed on a substrate (100), and an insulating layer (120) surrounds the organic EL element (102). A conductive layer (300) is located between the substrate (100) and the insulating layer (120) in a thickness direction, and is across an edge (126) of the insulating layer (120) opposite the organic EL element (102). The conductive layer (300) includes a first layer (310) and a second layer (320). The second layer (320) is formed on the first layer (310). The conductive layer (300) does not include a portion of the second layer (320) in a portion overlapped with the edge (126) of the insulating layer (120).

Abstract: A light emitting apparatus (10) includes a substrate (100), an insulating layer (160), a light emitting element (102), a coating film (140), and a structure (150). The insulating layer (160) is formed over one surface of the substrate (100), and includes an opening (162). The light emitting element (102) is formed in the opening (162) . The coating film (140) is formed over the one surface of the substrate (100), and covers a portion of the light emitting element (102), the insulating layer (160), and the one surface of the substrate (100). The coating film (140) does not cover another portion of the substrate (100) (for example, a portion of an end portion: hereinafter, referred to as a first portion). The structure (150) is located between the first portion of the substrate (100) and the insulating layer (160).

Abstract: An antenna system includes: a belt-shaped sheet portion to which a receiving antenna is detachably attached to receive information transmitted from a body-insertable apparatus introduced into a subject, the sheet portion being configured to be wrapped around and attached on a trunk of the subject; shape detection units provided on the sheet portion along a longitudinal direction of the sheet portion to detect a shape of the sheet portion; a position defining unit configured to specify an attachment position of the receiving antenna on an outer surface of the sheet portion based on the shape of the sheet portion detected by the shape detection units; and a display unit configured to display the attachment position specified by the position defining unit.

Abstract: A body-introducable apparatus includes: a light source unit having a first light source that outputs first light and a second light source that outputs second light in a wavelength band different from that of the first light; a light distribution matching unit that matches distributions of the first light and the second light; an illuminating control unit that illuminates the inside of the subject by driving the light source unit; and an imaging unit that captures an image of the inside of the subject.

Abstract: A receiving-side integrated optical circuit of an optical transceiver has an optical wavelength demultiplexer to separate signal light components of the different wavelengths contained in a wavelength division multiplexed signal received from each of N links of a transmission path, a set of N optical amplifiers inserted between the transmission path and the optical wavelength demultiplexer, each optical amplifier being configured to collectively amplify the signal light components of the different wavelengths contained in the received wavelength division multiplexed signal, and a set of photo detectors arranged after the optical wavelength demultiplexer and to detect the signal light components of the different wavelengths.

Abstract: A guidance device includes: a permanent magnet; an accommodating portion; a shielding member configured to shield the magnetic field generated by the permanent magnet; a supporting mechanism configured to support the permanent magnet between a first position and a second position; a driving unit configured to operate the supporting mechanism upon receiving an electric power supply; and a shielding member moving mechanism configured to move the shielding member between a shielding position and a non-shielding position in conjunction with an operation of the supporting mechanism causing the permanent magnet to move in a vertical direction. When the electric power supply to the driving unit stops, the shielding member moving mechanism moves the shielding member to the shielding position in conjunction with an operation of the supporting mechanism causing the permanent magnet to move to the first position.

Abstract: A manufacturing method for an optical semiconductor device, including disposing a semiconductor element that has a polarization dependent gain or polarization dependent loss between optical waveguide modes differing in the direction of polarization, positioning a lens at one end face side of the semiconductor element based on an optical coupling loss between the lens and the semiconductor element, and repositioning the lens based on the polarization dependent gain or the polarization dependent loss of the semiconductor element.

Abstract: A sealing structure has: a plate portion that is formed with a harder material than a bendable substrate and interposes an electronic device via the substrate from a top surface and a back surface of the substrate on which the electronic device is mounted; and an elastic body that is provided on an outer periphery of the plate portion to cover a part of the plate portion and integrally molded so as to press the plate portion against the substrate.

Abstract: An optical device includes a silicon waveguide core having a tapered portion having a sectional size that decreases toward a terminal end portion thereof, a dielectric waveguide core contiguous to the silicon waveguide core while covering at least the tapered portion, the dielectric waveguide core having a refractive index lower than that of the silicon waveguide core and configuring a single-mode waveguide, and a diffraction grating provided at the single-mode waveguide and configuring a distributed Bragg reflection mirror.

Abstract: A semiconductor optical amplifier includes a semiconductor substrate; an active layer that includes a first region and a second region formed over the semiconductor substrate; and a reflection part that is formed along the second region and includes a first portion that reflects a first wavelength light and a second portion that reflects a second wavelength light with an optical gain lower than an optical gain of the first wavelength light; wherein, the first portion is formed closer to the first region side than the second portion.

Abstract: When a coating film 4 is formed on a substrate 1, on which elements 3 are formed, by an ALD film forming method or the like, the coating film 4 is partially removed in a simple step. A method for manufacturing an electronic device includes a step of coating the substrate 1 partially with a partially coating member 2, a step of forming the elements 3 on the substrate 1, a step of forming the coating film 4 on the substrate 1 to cover the elements 3 and the partially coating member 2, and a step of forming a crack 4A in the coating film 4 on the partially coating member 2.

Abstract: A capsule-medical-device dedicated power source starter that allows switching, by an application of a magnetic field to a magnetic switch that is provided in an inside of a capsule medical device and has a particular sensitivity direction in the magnetic field, a driving of the capsule medical device from an OFF state to an ON state, includes: an insertion part that is formed in a central axis direction and to which the capsule medical device is inserted so that a longitudinal axis direction of the capsule medical device is along the central axis direction; and a magnetic circuit that generates magnetic force lines which are substantially symmetric about the central axis as an axis of symmetry in any planar surfaces including the central axis of the insertion part.

Abstract: A receiving-side integrated optical circuit of an optical transceiver has an optical wavelength demultiplexer to separate signal light components of the different wavelengths contained in a wavelength division multiplexed signal received from each of N links of a transmission path, a set of N optical amplifiers inserted between the transmission path and the optical wavelength demultiplexer, each optical amplifier being configured to collectively amplify the signal light components of the different wavelengths contained in the received wavelength division multiplexed signal, and a set of photo detectors arranged after the optical wavelength demultiplexer and to detect the signal light components of the different wavelengths.

Abstract: A semiconductor optical amplifier includes an n-type semiconductor layer, a p-type semiconductor layer an active layer provided between the n-type semiconductor layer and the p-type semiconductor layer, the active layer transmitting an optical signal and a current-injection part that injects current into the active layer via the n-type semiconductor layer and the p-type semiconductor layer, the active layer including a first active layer that includes AlGaInAs, and a second active layer that includes GaInAsP, the second active layer provided closer to an output side than the first active layer, and the first active layer and the second active layer being butt-jointed.

Abstract: Two or more first reflectors are formed on a substrate. Each of the first reflectors reflects the light input to its input port and returns it there, while exhibiting a reflection spectrum featuring a peak at the target wavelength. A first optical coupler is formed on the substrate to divide the light output from an optical amplifier and output the divided lights to the input ports of the two or more first reflectors, as well as combining the reflected lights from the first reflector and re-inputting the combined light to the optical amplifier. Each of the first reflectors contains a ring resonator of the same size, and the delay for the light input to the input port of a first reflector to return there after being reflected is the same for all first reflectors.

Abstract: An antenna apparatus is configured to acquire information from a body-insertable apparatus that is configured to be inserted into a subject to move inside the subject. The antenna apparatus includes an antenna that includes one sheet on which plural receiving antennas are fixed and in which a first positioning hole is formed; and an antenna holder that includes a container portion which is configured to hold the antenna at a predetermined position and in a predetermined orientation and in which second positioning hole is formed at a position corresponding to the first positioning hole when the antenna is held. The antenna holder is configured to be attached to a predetermined position of the subject using the first and second positioning holes as an index when the antenna is held in the antenna holder.

Abstract: A semiconductor optical device includes a first clad layer, a second clad layer and an optical waveguide layer sandwiched between the first clad layer and the second clad layer, wherein the optical waveguide layer includes a first semiconductor layer, a second semiconductor layer disposed on the first semiconductor layer and extending in one direction, and a third semiconductor layer covering a top surface of the second semiconductor layer, and wherein the first semiconductor layer includes an n-type region disposed on one side of the second semiconductor layer, a p-type region disposed on the other side of the second semiconductor layer, and an i-type region disposed between the n-type region and the p-type region, and wherein the second semiconductor layer has a band gap narrower than band gaps of the first semiconductor layer and the third semiconductor layer.

Abstract: An indwelling apparatus (5) for holding a capsule endoscope (3) is arranged with a control device (57) including an optical sensor (73), a control board (66) configuring a controller and a reset circuit, a driver board (68) configuring an electromagnet driver, and an electromagnet (70), where when the optical sensor (73) detects the light, the controller performs the drive control of the electromagnet (70) at every constant time interval to turn ON the reed switch (14) and supply power to the capsule endoscope (3) thereby operating the capsule endoscope (3) only when observation is necessary, and thus the battery drain of the capsule endoscope is reduced.

Abstract: A semiconductor optical amplifier includes a semiconductor substrate, a lower cladding layer formed on the semiconductor substrate, a light absorption layer and an optical amplification layer formed on the lower cladding layer, and an upper cladding layer formed on the light absorption layer and the optical amplification layer. The band gap of a semiconductor material that forms the light absorption layer is wider than the band gap of a semiconductor material that forms the optical amplification layer. The difference between the band gap of the semiconductor material that forms the light absorption layer and the band gap of the semiconductor material that forms the optical amplification layer is 0.12 eV or more.