A light emitting device includes: a substrate including a main surface; a first projection positioned on the main surface, the first projection including an upper surface and first and second lateral surfaces, wherein the first lateral surface of the first projection comprises a first reflective part, and the second lateral surface of the first projection comprises a second reflective part; a first laser element configured to irradiate laser light to the first reflective part; a second laser element configured to irradiate laser light to the second reflective part; and a first optical member fixed to the upper surface of the first projection, wherein the first optical member comprises a first lens part positioned above the first reflective part, and a second lens part positioned above the second reflective part.

A low numerical aperture fiber output diode laser module, which having several independent diode lasers, and collimated and converged the light beam, for the coupling the light to the core optical fiber with a core diameter of 105 um and a numerical aperture of 0.12. Compared with general products with a numerical aperture of 0.22, the light output angle is reduced to 55%, and use a general blue laser diode for verification. Use an optical software for facilitating the design and optimization of the parameters of the optical lens module.

A low numerical aperture fiber output diode laser module, which having several independent diode lasers, and collimated and converged the light beam, for the coupling the light to the core optical fiber with a core diameter of 105 um and a numerical aperture of 0.12. Compared with general products with a numerical aperture of 0.22, the light output angle is reduced to 55%, and use a general blue laser diode for verification. Use an optical software for facilitating the design and optimization of the parameters of the optical lens module.

An optoelectronic semiconductor chip comprises a semiconductor body including a plurality of active regions configured to generate electromagnetic radiation, the plurality of active regions being arranged in a horizontal plane. The optoelectronic semiconductor chip further comprises a conductive member configured to electrically connect at least two adjacent ones of the active regions with each other, the conductive member being arranged over a first main surface of the semiconductor body. The optoelectronic semiconductor chip further comprises a contact element extending from the first main surface to a second main surface of the semiconductor body and being electrically connected to at least one of the active regions via a contact material over the first main surface, and an optical element arranged over the first main surface of the semiconductor body.

An optoelectronic semiconductor chip comprises a semiconductor body including a plurality of active regions configured to generate electromagnetic radiation, the plurality of active regions being arranged in a horizontal plane. The optoelectronic semiconductor chip further comprises a conductive member configured to electrically connect at least two adjacent ones of the active regions with each other, the conductive member being arranged over a first main surface of the semiconductor body. The optoelectronic semiconductor chip further comprises a contact element extending from the first main surface to a second main surface of the semiconductor body and being electrically connected to at least one of the active regions via a contact material over the first main surface, and an optical element arranged over the first main surface of the semiconductor body.

The laser module includes a QCL element, a diffraction grating unit, a first lens holder, a second lens holder, and a mount member. The fourth mounting portion of the mount member is provided with a placement hole into which the protruding portion of the diffraction grating unit is inserted. The placement hole is longer than the protruding portion so that the protruding portion can be slid in the X-axis direction relative to the placement hole. A wall surface for positioning the diffraction grating unit is provided between the third mounting portion and the fourth mounting portion. The diffraction grating unit includes a positioning surface facing the wall surface. The diffraction grating unit is fixed to the fourth mounting portion in a state where the protruding portion is inserted into the placement hole and the positioning surface is in surface contact with the wall surface.

A three-dimensional optoelectronic device package is disclosed. The three-dimensional optoelectronic device package comprises a first board having at least one surface on which one or more optoelectronic devices is disposed, and a second board having at least one surface on which a plurality of optoelectronic devices is disposed. A side of the second board is attached to the surface of the first board on which one or more optoelectronic devices is disposed to form an angle between the surface of the first board on which one or more optoelectronic devices is disposed and the surface of the second board on which one or more optoelectronic devices is disposed. A method for manufacturing a three-dimensional optoelectronic device package is also disclosed.

A three-dimensional optoelectronic device package is disclosed. The three-dimensional optoelectronic device package comprises a first board having at least one surface on which one or more optoelectronic devices is disposed, and a second board having at least one surface on which a plurality of optoelectronic devices is disposed. A side of the second board is attached to the surface of the first board on which one or more optoelectronic devices is disposed to form an angle between the surface of the first board on which one or more optoelectronic devices is disposed and the surface of the second board on which one or more optoelectronic devices is disposed. A method for manufacturing a three-dimensional optoelectronic device package is also disclosed.

The laser module includes a QCL element, a diffraction grating unit, a first lens holder, a second lens holder, and a mount member. The first mounting portion has a first top surface on which the first lens holder is mounted via an adhesive layer. The third mounting portion has a third top surface on which the second lens holder is mounted via an adhesive layer. The second mounting portion has a second top surface located higher than the first top surface and the third top surface, a first side surface connecting the second top surface and the first top surface, and a second side surface connecting the second top surface and the third top surface. A notch extending from the second top surface to the first top surface or the third top surface is formed in at least one of the first side surface and the second side surface.

The laser module includes a QCL element, a diffraction grating unit, a first lens holder, a second lens holder, and a mount member. The first mounting portion has a first top surface on which the first lens holder is mounted via an adhesive layer. The third mounting portion has a third top surface on which the second lens holder is mounted via an adhesive layer. The second mounting portion has a second top surface located higher than the first top surface and the third top surface, a first side surface connecting the second top surface and the first top surface, and a second side surface connecting the second top surface and the third top surface. A notch extending from the second top surface to the first top surface or the third top surface is formed in at least one of the first side surface and the second side surface.