Abstract: The invention relates to an optical pulse generator comprising an active optical component adapted to emit optical radiation and electronic components of a means for electronically driving the optical component to excite the optical component to a pulsed emission of optical radiation, wherein the electronic components are arranged on a first side of a first submount, contact surfaces of the means for electronically driving are arranged on an opposite second side of the first submount, and the electronic components are connected to the contact surfaces of the means for electronically driving using electrically conductive vias in the first submount.

Abstract: This invention concerns an optical pulse generator and a method for operating an optical pulse generator. In particular, this invention concerns an optical pulse generator for high frequency (HF) pulse width modulation in LiDAR systems. The optical pulse generator according to the invention comprises an active optical component (10) adapted to emit optical radiation, wherein the optical component (10) has contact surfaces (12, 14) for electrical contacting; means for electronically driving (20) the optical component (10) adapted to excite the optical component (10) to pulsed emission of optical radiation, wherein the means for electronically driving (20) has contact surfaces (22, 24) for electrical contacting; a first submount (30), wherein the means for electronically driving (20) is arranged on the first submount (30); a second submount (40), wherein the optical component (10) is arranged on the second submount.

Abstract: The invention discloses a device for selecting pulses comprising an optical waveguide for guiding the optical radiation along an axis; comprising a first electro-optical modulator designed to modulate the optical transparency of the waveguide; comprising a second electro-optical modulator designed to modulate the optical transparency of the waveguide, wherein the first modulator and the second modulator are arranged one after the other on the axis of the waveguide, and further comprising at least one control circuit designed to actuate the first modulator and the second modulator at offset times, and characterized in that a substrate of a semiconductive material is provided, the waveguide and the at least one control circuit are arranged on the substrate.

Abstract: The invention discloses a device for selecting pulses comprising an optical waveguide for guiding the optical radiation along an axis; comprising a first electro-optical modulator designed to modulate the optical transparency of the waveguide; comprising a second electro-optical modulator designed to modulate the optical transparency of the waveguide, wherein the first modulator and the second modulator are arranged one after the other on the axis of the waveguide, and further comprising at least one control circuit designed to actuate the first modulator and the second modulator at offset times, and characterized in that a substrate of a semiconductive material is provided, the waveguide and the at least one control circuit are arranged on the substrate.

Abstract: The present invention relates to a device and a method for selective transmission of an optical signal. It is an object of the present invention to provide a light modulator and a method for light modulation capable of selecting very short optical pulses of up to the femtosecond range with a low repetition frequency, wherein the repetition frequency can be variable in a range between several Hz up to the GHz range. To this end, the device has a first optical waveguide (3), a first drive circuit (14), a second optical waveguide (1, 2) and a second drive circuit (15), wherein the spacing between a switching element of the first drive circuit (14) and the first optical waveguide (3) is less than 3 mm, and the distance between a switching element of the second drive circuit (15) and the second optical waveguide (1, 2) is less than 3 mm, and the first optical waveguide (3) has a first absorber section (5), a pulse picker section (4) and a second absorber section (18).

Abstract: The present invention is directed to a self-adjusting gate bias network for field effect transistors in radio frequency applications. A bias network for field effect transistors is provided comprising a field effect transistor having a source electrode connected to ground and a drain electrode connected to a load; a radio frequency network connected to the gate electrode; a gate bias network connected to the gate electrode; wherein a device having a non-linear characteristic is provided in series between the gate electrode and the gate bias network such that a forward bias current at the gate electrode of the field effect transistor is reduced or prevented. The reduction or prevention of a forward bias current leads in overdrive conditions to a self-adjustment of the bias point of the field-effect transistor improving the reduction of distortions of an amplifier or changing the class of oscillators connected to the gate electrode.

Abstract: The present invention relates to a device and a method for selective transmission of an optical signal. It is an object of the present invention to provide a light modulator and a method for light modulation capable of selecting very short optical pulses of up to the femtosecond range with a low repetition frequency, wherein the repetition frequency can be variable in a range between several Hz up to the GHz range. To this end, the device has a first optical waveguide (3), a first drive circuit (14), a second optical waveguide (1, 2) and a second drive circuit (15), wherein the spacing between a switching element of the first drive circuit (14) and the first optical waveguide (3) is less than 3 mm, and the distance between a switching element of the second drive circuit (15) and the second optical waveguide (1, 2) is less than 3 mm, and the first optical waveguide (3) has a first absorber section (5), a pulse picker section (4) and a second absorber section (18).

Abstract: The present invention is directed to a self-adjusting gate bias network for field effect transistors in radio frequency applications. A bias network for field effect transistors is provided comprising a field effect transistor having a source electrode connected to ground and a drain electrode connected to a load; a radio frequency network connected to the gate electrode; a gate bias network connected to the gate electrode; wherein a device having a non-linear characteristic is provided in series between the gate electrode and the gate bias network such that a forward bias current at the gate electrode of the field effect transistor is reduced or prevented. The reduction or prevention of a forward bias current leads in overdrive conditions to a self-adjustment of the bias point of the field-effect transistor improving the reduction of distortions of an amplifier or changing the class of oscillators connected to the gate electrode.

Abstract: The invention relates to a device, a probe, and a method for the galvanically decoupling transmission of a measuring signal. A microwave signal is supplied by a transceiver (1) to a sensor (3) by means of a galvanically decoupled waveguide (2). The signal is partially reflected in the sensor (3), the amplitude, phase and/or polarization of the reflected microwave signal containing the information relating to the measuring value. The reflected microwave signal runs through the same waveguide (2) back to the transceiver (1) and is evaluated therein. The invention provides a more simple and economical structure than conventional devices of prior art, as a voltage supply is not required especially on the sensor side as a result of the reflection. In this way, the sensor (3) can also be produced in a very compact manner, minimizing the influence of the measuring signal through the sensor (3).

Abstract: The invention relates to a device, a probe, and a method for the galvanically decoupling transmission of a measuring signal. A microwave signal is supplied by a transceiver (1) to a sensor (3) by means of a galvanically decoupled waveguide (2). The signal is partially reflected in the sensor (3), the amplitude, phase and/or polarization of the reflected microwave signal containing the information relating to the measuring value. The reflected microwave signal runs through the same waveguide (2) back to the transceiver (1) and is evaluated therein. The invention provides a more simple and economical structure than conventional devices of prior art, as a voltage supply is not required especially on the sensor side as a result of the reflection. In this way, the sensor (3) can also be produced in a very compact manner, minimizing the influence of the measuring signal through the sensor (3).