Described herein are one or more methods for integrating an optical component into an integrated photonics device. The die including a light source, an outcoupler, or both, may be bonded to a wafer having a cavity. The die can be encapsulated using an insulating material, such as an overmold, that surrounds its edges. Another (or the same) insulating material can surround conductive posts. Portions of the die, the overmold, and optionally, the conductive posts can be removed using a grinding and polishing process to create a planar top surface. The planar top surface enables flip-chip bonding and an improved connection to a heat sink. The process can continue with forming one or more additional conductive layers and/or insulating layers and electrically connecting the p-side and n-side contacts of the laser to a source.

Described herein are one or more methods for integrating an optical component into an integrated photonics device. The die including a light source, an outcoupler, or both, may be bonded to a wafer having a cavity. The die can be encapsulated using an insulating material, such as an overmold, that surrounds its edges. Another (or the same) insulating material can surround conductive posts. Portions of the die, the overmold, and optionally, the conductive posts can be removed using a grinding and polishing process to create a planar top surface. The planar top surface enables flip-chip bonding and an improved connection to a heat sink. The process can continue with forming one or more additional conductive layers and/or insulating layers and electrically connecting the p-side and n-side contacts of the laser to a source.

A light emitting device includes first to third semiconductor laser elements. Each of the semiconductor laser elements includes at least two emitters, and configured to emit red-color light, green-color light, or blue-color light. The mount member includes first to third conduction parts, each including a plurality of metal films including mounting regions that are aligned in a predetermined direction. The first to third semiconductor laser elements are respectively mounted on the first to third conduction parts of the mount member in a junction-down configuration.

A light emitting device includes first to third semiconductor laser elements. Each of the semiconductor laser elements includes at least two emitters, and configured to emit red-color light, green-color light, or blue-color light. The mount member includes first to third conduction parts, each including a plurality of metal films including mounting regions that are aligned in a predetermined direction. The first to third semiconductor laser elements are respectively mounted on the first to third conduction parts of the mount member in a junction-down configuration.

Various embodiments of the present disclosure are directed towards a method for forming a vertical cavity surface emitting laser (VCSEL) device. The method includes forming a bond bump and a bond ring over a substrate. A semiconductor die is bonded to the bond ring. A molding layer is formed around the semiconductor die. The molding layer is laterally offset from a cavity between the semiconductor die and the substrate. A VCSEL structure is formed over the bond bump.

The present disclosure provides an apparatus for generating fiber delivered laser-induced white light. The apparatus includes a package case enclosing a board member with an electrical connector through a cover member and a laser module configured to the board member inside the package case. The laser module comprises a support member, at least one laser diode device configured to emit a laser light of a first wavelength, a set of optics to guide the laser light towards an output port. Additionally, the apparatus includes a fiber assembly configured to receive the laser light from the output port for further delivering to a light head member disposed in a remote destination. A phosphor material disposed in the light head member receives the laser light exited from the fiber assembly to induce a phosphor emission of a second wavelength for producing a white light emission substantially reflected therefrom for various applications.

A light emitting device includes first and second semiconductor laser elements, first and second light-reflective members, and a basal part. The light emitted from the first semiconductor laser element irradiates a first light-reflective surface of the first light-reflective member at a first position. The light emitted from the second semiconductor laser element irradiates a second light-reflective surface of the second light-reflective member at a second position. A height of the first position is different from a height of the second position. With respect to a virtual axis extending along the prescribed direction, the first position and the second position have the same coordinates. A mounting position of the first light-reflective member and a mounting position of the second light-reflective member are different with respect to the prescribed direction.

A light emitting device includes first and second semiconductor laser elements, first and second light-reflective members, and a basal part. The light emitted from the first semiconductor laser element irradiates a first light-reflective surface of the first light-reflective member at a first position. The light emitted from the second semiconductor laser element irradiates a second light-reflective surface of the second light-reflective member at a second position. A height of the first position is different from a height of the second position. With respect to a virtual axis extending along the prescribed direction, the first position and the second position have the same coordinates. A mounting position of the first light-reflective member and a mounting position of the second light-reflective member are different with respect to the prescribed direction.

A semiconductor laser device includes: a housing including: a first upper upward-facing surface, a mounting surface below the first upper upward-facing surface, inner lateral surfaces including a first inner lateral surface and a second inner lateral surface facing the first inner lateral surface, wherein the first upper upward-facing surface and the mounting surface are formed inward of the inner lateral surfaces, and a first wiring part disposed on the first upper upward-facing surface; a semiconductor laser element including: a light output surface, a first lateral surface extending from the light output surface and facing the first inner lateral surface, and a second lateral surface extending from the light output surface and opposite to the first lateral surface; and a first wire connected to the first wiring part for electrical connection of the semiconductor laser element.

A semiconductor laser device includes: a housing including: a first upper upward-facing surface, a mounting surface below the first upper upward-facing surface, inner lateral surfaces including a first inner lateral surface and a second inner lateral surface facing the first inner lateral surface, wherein the first upper upward-facing surface and the mounting surface are formed inward of the inner lateral surfaces, and a first wiring part disposed on the first upper upward-facing surface; a semiconductor laser element including: a light output surface, a first lateral surface extending from the light output surface and facing the first inner lateral surface, and a second lateral surface extending from the light output surface and opposite to the first lateral surface; and a first wire connected to the first wiring part for electrical connection of the semiconductor laser element.