An optical coupling device includes a light receiving element including a first output terminal and a second output terminal, a light emitting element provided on the light receiving element, a first switching element, a first electrode plate, and a sealing member. The first switching element includes a first main terminal connected to the first output terminal, a first control terminal connected to the second output terminal, and a second main terminal. An upper surface of the first electrode plate is connected to the second main terminal. The sealing member covers the light receiving element, the light emitting element, and the first switching element. A lower surface of the first electrode plate is exposed on a lower surface of the sealing member. The lower surface of the first electrode plate and the lower surface of the sealing member form the same plane.

According to one or more embodiments, a semiconductor device includes a mounting substrate and a semiconductor element on the mounting substrate. The mounting substrate has a first electrode pad and a second electrode pad. The semiconductor element has a supporting substrate, third and fourth electrode pads, first slits and second slits. The third and fourth electrode pads are provided on a first surface of the supporting substrate facing the mounting substrate. The first slits are provided both in the supporting substrate and in the third electrode pad. The second slits are provided both in the supporting substrate and in the fourth electrode pad. The semiconductor device further includes a first conductive bonding agent that connects the first electrode pad to the third electrode pad and a second conductive bonding agent that connects the second electrode pad to the fourth electrode pad.

According to one or more embodiments, a semiconductor device includes a mounting substrate and a semiconductor element on the mounting substrate. The mounting substrate has a first electrode pad and a second electrode pad. The semiconductor element has a supporting substrate, third and fourth electrode pads, first slits and second slits. The third and fourth electrode pads are provided on a first surface of the supporting substrate facing the mounting substrate. The first slits are provided both in the supporting substrate and in the third electrode pad. The second slits are provided both in the supporting substrate and in the fourth electrode pad. The semiconductor device further includes a first conductive bonding agent that connects the first electrode pad to the third electrode pad and a second conductive bonding agent that connects the second electrode pad to the fourth electrode pad.

The present invention relates to a device and method for detecting light allowing retrieval of a physiological parameter of a user carrying said device. To improve the efficiency of light capturing, the device (1, 2, 3, 4) comprises a light source (10) arranged for emitting light of at least a first wavelength into tissue of the subject, a wavelength converter (20) arranged for receiving at least part of the emitted light after interaction of the emitted light with the tissue and for converting the received light into at least a second wavelength different from the first wavelength, and a light sensor (30) arranged for receiving light converted by said wavelength converter.

An optical coupling device includes a leadframe, a light-emitter, a light-receiver, and first to fourth resins. The light-emitter is located on the leadframe. The first resin is located on the leadframe. The first resin includes first and second portions. The first portion surrounds the light-emitter. The second portion is positioned between the first portion and the light-emitter. A first thickness of the first portion is greater than a second thickness of the second portion. The second resin is located between the light-emitter and the light-receiver in the first direction and is light-transmissive. The third resin is located between the second resin and the light-receiver and is light-transmissive. The fourth resin houses the light-emitter, the light-receiver, and the first to third resins and is light-shielding.

An optoelectronic sensor module and a method for producing an optoelectronic sensor module are disclosed. In an embodiment an optoelectronic sensor module includes a first semiconductor transmitter chip configured to emit radiation of a first wavelength, a second semiconductor transmitter chip configured to emit radiation of a second wavelength different from the first wavelength, a semiconductor detector chip configured to detect the radiation of the first and second wavelengths, and a first potting body being opaque to the radiation of the first and the second wavelength, wherein the first potting body directly covers side surfaces of the chips and mechanically connects the chips located in a common plane to one another, wherein a distance between the chips is less than or equal to twice an average diagonal length of the chips, and wherein the sensor module is adapted to rest against a body part to be examined.

An optical numerical computation method obtains operands that have respective values, and modulates light sources to output light at amplitudes proportional to the operands. The light output for a given operand depends on whether the operand is positive or negative. The positive operands are output at wavelengths different from the negative operands. For operands that have multiple digits, the digits are separately treated so that the least significant digits are modulated with light sources at one frequency, and the most significant digits in two-digit numbers are modulated at another frequency, with positive and negative operands modulated at different frequencies. The light from the light sources enters a light collection cavity where it is sensed with sensors that generate resultant outputs at values indicative of the sensed light value.

An electronic device may include a light sensor system. The light sensor system may have a light source that emits light and a light detector that receives the emitted light after the emitted light has interacted with an external object. The light source may include a ring of light-emitting diodes or other light-emitting devices surrounding the light detector or may have light-emitting devices that are surrounded by a ring-shaped light detector. Polarizer structures may be incorporated into the light sensor system. Control circuitry in the device may control the light source so that different polarizations of light are emitted at different times. The control circuitry may process signals from the light detector that are gathered under different polarizations to discriminate between specular and non-specular reflections from the external object.

An electronic device may include a light sensor system. The light sensor system may have a light source that emits light and a light detector that receives the emitted light after the emitted light has interacted with an external object. The light source may include a ring of light-emitting diodes or other light-emitting devices surrounding the light detector or may have light-emitting devices that are surrounded by a ring-shaped light detector. Polarizer structures may be incorporated into the light sensor system. Control circuitry in the device may control the light source so that different polarizations of light are emitted at different times. The control circuitry may process signals from the light detector that are gathered under different polarizations to discriminate between specular and non-specular reflections from the external object.

A pair of optical components is used in an isolator that enables electric isolation. Each of the optical components includes: first lens portions arranged on different optical paths and transmitting light in a first direction; second lens portions arranged on different optical paths and transmitting light in the second direction orthogonal to the first direction; and a reflection portion reflecting, in the second direction, the light in the first direction transmitted through the first lens portion and guiding the light to the second lens portion, or reflecting, in the first direction, the light in the second direction transmitted through the second lens portion and guiding the light to the first lens portion The second lens portion included in one of the pair of optical components and the second lens portion included in the other optical component are spaced apart from each other and face each other.