Abstract: In an embodiment a laser diode includes a surface emitting semiconductor laser configured to emit electromagnetic radiation and an optical element arranged downstream of the semiconductor laser in a radiation direction, wherein the optical element includes a diffractive structure or a meta-optical structure or a lens structure, wherein the optical element and the semiconductor laser are cohesively connected to each other, and wherein the semiconductor laser and the optical element are integrated with the laser diode.

Abstract: A semiconductor device includes a first semiconductor body including a substrate having a first thickness, wherein the first semiconductor body includes a first active zone that generates or receives radiation, and a second semiconductor body having a second thickness smaller than the first thickness and including a tear-off point is arranged on the substrate and connected in an electrically conducting manner to the first semiconductor body, wherein the second semiconductor body includes a second active zone that generates or receives radiation, and the second active zone generates radiation and the first active zone detects the radiation, and the first semiconductor body includes contacts on its underside for connection to the semiconductor device.

Abstract: A semiconductor laser includes a horizontal laser element including a first semiconductor layer arrangement having a first active zone for generating radiation. The horizontal laser element furthermore includes a first optical resonator extending in a direction parallel to a first main surface of the first semiconductor layer arrangement. Lateral boundaries of the first semiconductor layer arrangement run obliquely, such that electromagnetic radiation generated is reflectable in a direction of the first main surface of the first semiconductor layer arrangement. The semiconductor laser furthermore includes a vertical laser element having a second optical resonator extending in a direction perpendicular to the first main surface of the first semiconductor layer arrangement.

Abstract: According to embodiments, a semiconductor laser comprises a semiconductor layer stack, which comprises an active zone for generating radiation. The semiconductor laser also comprises a first resonator mirror, a second resonator mirror, and an optical resonator, which is arranged between the first and second resonator mirrors and extends in a direction parallel to a main surface of the semiconductor layer stack. A reflectance R1 of the first resonator mirror is wavelength-dependent, so that R1 or a product R of R1 and the reflectance R2 of the second resonator mirror in a wavelength range decreases from a target wavelength ?0 of the laser to ?0+?? from a value R0, wherein ?? is selected as a function of a temperature-dependent shift in an emission wavelength.

Abstract: A sensor that detects a heart rate and/or a blood oxygen content includes a radiation source and a photodetector, wherein the radiation source includes a light-emitting diode array, the light-emitting diode array includes a plurality of emission regions, the emission regions each include a first light-emitting diode and a second light-emitting diode, the first light-emitting diode includes a first wavelength, the second light-emitting diode includes a second wavelength, and a distance between the first light-emitting diode and the second light-emitting diode within the emission regions is 100 micrometers or less.

Abstract: The invention relates to a radiation-emitting semiconductor component comprising a semiconductor body which has an active zone for generating radiation and a radiation exit surface, a contact element which is arranged on the radiation exit surface at a first lateral distance from a first edge piece of the radiation exit surface and at a second lateral distance from a second edge piece of the radiation exit surface, and a decoupling structure for improving the decoupling of the radiation generated by the active zone, which decoupling structure is arranged on the radiation exit surface and has structural elements, wherein the structural elements vary in such a way that the radiation decoupling increases from the contact element to the first and/or second edge piece. Furthermore, a method is specified for producing a such a radiation-emitting semiconductor element.

Abstract: The invention relates to a semiconductor laser comprising a semiconductor layer arrangement, having an active zone for radiation generation, as well as comprising a first resonator mirror, a second resonator mirror and a resonator arranged between the first and the second resonator mirror, which ends in a direction parallel to a main surface of the semiconductor layer arrangement. The semiconductor laser also comprises a first wavelength-selective absorption element which is arranged between the semiconductor layer arrangement and the first resonator mirror.

Abstract: An optoelectronic semiconductor laser component may include at least two laser units. The semiconductor laser component may have an output coupling surface configured to generate electromagnetic radiation in the semiconductor laser component. Each laser unit may include a laser resonator having a resonator axis, an output coupling mirror and a first and a second resonator mirror with a primary section of the resonator axis running laterally therebetween. The output coupling mirror may be formed by a partial region of the output coupling surface. Along the primary section of the resonator axis at least one contact strip is arranged on the output coupling surface, and extends to a metallic connection surface. The laser units may be aligned in such a way that the primary sections of the resonator axes run parallel to one another and the output coupling mirrors face one another.

Abstract: A picture element for a display device includes a first and a second supply connection, a light-emitting semiconductor device arranged between the first and the second supply terminal, and a comparison unit having a first and a second input and an output. The comparison unit is configured to adjust a voltage at the output in dependence on a comparison of a voltage applied to the first input and a voltage applied to the second input. The picture element also includes a supply switch-configured to control a current flow between the first and the second supply terminal via the light-emitting semiconductor device depending on the voltage applied at the output of the comparison unit. The picture element further includes a selection input, a data input, a memory element and a control switch.

Abstract: The invention relates to various aspects of a ?-LED or a ?-LED array for augmented reality or lighting applications, in particular in the automotive field. The ?-LED is characterized by particularly small dimensions in the range of a few ?m.

Abstract: A laser system may include a semiconductor laser configured to emit laser radiation in continuous wave operation at M modes having differing angular frequencies, where 2 ? M and where n ? [1; M]?. A tuning apparatus may periodically modify the angular frequencies where a variation of each angular frequency is smaller by at least a factor of 2 than a mode distance between the relevant adjacent angular frequencies. A detector has an upper cutoff frequency which is smaller by at least a factor of 10 than the smallest of the mode distances. A beam splitter may guide the M modes each to the detector and to an object, such that the detector may detect, for each of the M modes, portions of the laser radiation reflected by the object and portions of the laser radiation which come optically directly from the semiconductor laser.

Abstract: In one embodiment, an apparatus may include a light source. The apparatus also includes a measuring laser, such as a semiconductor laser. The measuring laser is configured to generate pulses with a maximum pulse duration of 10 ns. A wavelength of maximum intensity of the measuring laser radiation generated by the measuring laser ranges from 400 nm to 485 nm inclusive. The measuring laser radiation is used for distance measurement by means of LIDAR, for example in a car headlight.

Abstract: In an embodiment an apparatus includes at least one optoelectronic laser configured to provide excitation radiation to a sample, the excitation radiation being generated by an electric current flowing through the at least one optoelectronic laser, a transistor configured to modulate the electric current flowing through the at least one optoelectronic laser in order to switch on and off generation of the excitation radiation and a spectrometer configured to analyze Raman light scattered from the sample in response to exposing the sample to the excitation radiation, wherein the Raman light includes one or more spectral components, wherein the spectrometer includes a diffraction element configured to split the Raman light into the spectral components, and wherein the diffraction element includes at least a photonic crystal or a plasmonic Fabry Perot filter.

Abstract: The invention relates to a laser light source (10), comprising an arrangement (120) of surface-emitting semiconductor lasers (1251, 1252, . . . 125n) to which a voltage is applied such that an operating current is below the threshold current and an intrinsic emission of the surface-emitting semiconductor laser is prevented. The laser light source also comprises a first semiconductor laser (100) which emits radiation (110) that enters the surface-emitting semiconductor laser such that induced emission takes place via the injection locking mechanism and the individual surface-emitting semiconductor lasers emit laser light having the same wavelength and polarisation direction as the irradiated radiation (110). The emission frequency of the first semiconductor laser can be changed by changing the operating current.

Abstract: An optoelectronic component and a method for manufacturing an optoelectronic component are disclosed. In an embodiment an optoelectronic component includes a diffractive optical element comprising at least one conversion material and a light source configured to emit primary radiation, wherein the conversion material is encapsulated in the diffractive optical element, and wherein the conversion material is arranged in a beam path of the primary radiation and is configured to convert the primary radiation at least partially into secondary radiation.

Abstract: A semiconductor radiation source includes at least one semiconductor chip that generates radiation; and at least one capacitor body, wherein the semiconductor chip and the capacitor body are stacked on top of each other, the semiconductor chip directly electrically connects in a planar manner to the capacitor body, the semiconductor chip is a ridge waveguide laser, and a ridge waveguide of the semiconductor chip is arranged on a side of the semiconductor chip facing away from the capacitor body.

Abstract: A PWM controlled current source includes a selection input, a modulation input, a switchable current source which can be switched by means of a signal at a control terminal and whose current output is configured for connection to a load, and an inverter circuit including an input node and an output coupled to the control terminal. The inverter circuit has a capacitance conditioned by elements of the inverter circuit. A start signal can be supplied to the input node in dependence on a selection signal at the selection input, which controls the switchable current source via the inverter circuit. The PWM controlled current source also includes a voltage-to-current converter that generates a current derived from a modulation signal at the modulation input and supplies it to the input node. The supplied current disconnects the switchable current source after a time period predetermined by the conditioned capacitance.

Abstract: The invention relates to a semiconductor laser apparatus having a layer stack which comprises a first resonator mirror, a second resonator mirror and an active zone which is arranged between the first and second resonator mirrors and which is suitable for emitting electromagnetic radiation. A charge carrier barrier is arranged around a central region of the active zone.

Abstract: The invention relates to various aspects of a ?-LED or a ?-LED array for augmented reality or lighting applications, in particular in the automotive field. The ?-LED is characterized by particularly small dimensions in the range of a few ?m.

Abstract: A radiation source for emitting terahertz radiation (6) is specified, comprising at least two laser light sources emitting laser radiation (11, 12) of different frequencies, and a photomixer (5) comprising a photoconductive semiconductor material (51) and an antenna structure (52), the photomixer (5) being configured to emit the laser radiation (11, 12) of the laser light sources (1, 2) and emitting terahertz radiation (6) with at least one beat frequency of the laser light sources, and wherein the at least two laser light sources are surface-emitting semiconductor lasers (1, 2) which are arranged in a one-dimensional or two-dimensional array on a common carrier (10).