Heatsinking in laser devices may be improved via a device, including: a header disk having a first face with a circumference; a header post that is thermally conductive, and having: a second face connected to the first face coterminously with the circumference; a third face opposite to the second face; and a fourth face perpendicular to the second face and the third face; a lens holder, having a fifth face connected to the third face; and an optical subassembly connected to the fourth face and optically aligned with the lens holder. The device may also be understood to comprise: a header disk having a circumference; a header post that is thermally conductive, the header post having: an arc coterminous to a portion of the circumference; a mounting face, perpendicular to a plane in which the arc and the circumference are defined; and a bonding face perpendicular to the mounting face.

An optical sensor package includes an emitter die mounted to an upper surface of a package substrate. A sensor die is mounted to the upper surface of the package substrate using a film on die (FOD) adhesive layer that extends over the upper surface and encapsulates the emitter die. The sensor die is positioned in a stacked relationship with respect to the emitter die such that a light channel region which extends through the sensor die is optically aligned with the emitter die. Light emitted by the emitter die passes through the light channel region of the sensor die. The emitter die and the sensor die are each electrically coupled to the package substrate.

An optical sensor package includes an emitter die mounted to an upper surface of a package substrate. A sensor die is mounted to the upper surface of the package substrate using a film on die (FOD) adhesive layer that extends over the upper surface and encapsulates the emitter die. The sensor die is positioned in a stacked relationship with respect to the emitter die such that a light channel region which extends through the sensor die is optically aligned with the emitter die. Light emitted by the emitter die passes through the light channel region of the sensor die. The emitter die and the sensor die are each electrically coupled to the package substrate.

A light emitting device includes: at least one semiconductor laser element; and a light-transmissive member including: an upper surface, a lower surface, and a light-transmissive region through which laser light emitted from the at least one semiconductor laser element is transmitted from the lower surface to the upper surface, wherein: at least the light-transmissive region is made of sapphire, the light-transmissive member includes an incident surface on which the laser light is incident, the incident surface being an a-plane of the sapphire, and the light-transmissive member is oriented such that a polarization direction of the laser light incident on the incident surface is parallel or perpendicular to a c-axis of the sapphire in a top view.

A light emitting device includes: at least one semiconductor laser element; and a light-transmissive member including: an upper surface, a lower surface, and a light-transmissive region through which laser light emitted from the at least one semiconductor laser element is transmitted from the lower surface to the upper surface, wherein: at least the light-transmissive region is made of sapphire, the light-transmissive member includes an incident surface on which the laser light is incident, the incident surface being an a-plane of the sapphire, and the light-transmissive member is oriented such that a polarization direction of the laser light incident on the incident surface is parallel or perpendicular to a c-axis of the sapphire in a top view.

An optical device and a light-source device. The optical device includes a first substrate having a first plane and elements, and a second substrate having a second face that faces the first plane. The elements are disposed on the first substrate to emit or receive light in a direction intersecting with the first plane. The second substrate includes lenses disposed to correspond to the elements, and the second substrate extends in a first direction parallel to the second face to contact the first plane. The second substrate has a joint used to determine spacing between the first substrate and the second substrate, and the joint contacts the first substrate with an area smaller than a maximum size of cross-sectional area parallel to the second face of the joint. The light-source device includes the optical device and a driver to drive the optical device.

An optical device and a light-source device. The optical device includes a first substrate having a first plane and elements, and a second substrate having a second face that faces the first plane. The elements are disposed on the first substrate to emit or receive light in a direction intersecting with the first plane. The second substrate includes lenses disposed to correspond to the elements, and the second substrate extends in a first direction parallel to the second face to contact the first plane. The second substrate has a joint used to determine spacing between the first substrate and the second substrate, and the joint contacts the first substrate with an area smaller than a maximum size of cross-sectional area parallel to the second face of the joint. The light-source device includes the optical device and a driver to drive the optical device.

A shutdown circuit may include a filter, for receiving a laser trigger signal for a laser emitter, that is configured to output a filtered signal. The shutdown circuit may include a logic gate configured to receive the filtered signal and at least one of a first signal based on a signal from a photodiode or a second signal based on a signal from a conductive path. The shutdown circuit may include a flip-flop configured to receive an output of the logic gate and to output an enablement signal that is based on the output of the logic gate, and a driver circuit for a switch configured to control current flow to the laser emitter. The driver circuit may be configured to receive the enablement signal and the laser trigger signal and to output the laser trigger signal based on whether the enablement signal is a first or a second voltage.

A laser package is described, the laser package comprising a plurality of laser diodes separately attached to at least one sub-mount having respective connecting pads, wherein, during operation, each of the laser diodes emits light having a fast axis and a slow axis defining a fast axis plane and a slow axis plane, wherein the fast axis planes of all laser diodes are parallel to each other and the distance between the fast axis planes of at least two laser diodes is smaller than the lateral distance between these laser diodes. Furthermore, a system with at least two laser packages is described.

A multilaser arrangement includes: a housing including a base plate, a housing cap fastened on the base plate, and a transparent element, the base plate including a bottom face, the housing cap including an opening with the transparent element assigned to the opening for the passage of electromagnetic radiation; lasers, each being arranged inside the housing at a distance from the bottom face of the base plate, the housing cap including an upper wall and a side wall, which includes a lower edge and a surface, is formed integrally with the upper wall, and ends with the lower edge fastened on the base plate, the side wall having a first thickness and a second thickness, the first thickness being measured in a direction perpendicular to the surface, the second thickness being measured at the lower edge and being less than or equal to the first thickness.