Abstract: Doppler lidar for detecting wind speeds, comprising a device (MO) for generating pulsed coherent laser light on N wavelength channels, amplitude modulation (AM) being performed separately for each individual wavelength channel for shaping the pulse individually for each channel, a device (TK, SC) for transmitting generated, frequency-shifted and amplified pulses of the laser light in predetermined spatial directions, a detector (n×Det.) for receiving the generated and the backscattered laser light on N wavelength channels, and an electronic evaluation device (n×SV) for determining a Doppler shift amount between the transmitted light and the received light on N wavelength channels, wherein a timing modulator (TM) is assigned to the N wavelength channels for individual control of a pulse repetition frequency (PRF) and/or pulse repetition period (PRT) in addition to the pulse shape for wavelength channels.

Abstract: The invention relates to a multichannel radio-frequency receiver for electromagnetic waves, having a radio-frequency analogue section, which has an input for an electrical signal from a reception device, and having a lower-frequency section, which is connected downstream of the radiofrequency analogue section and has a plurality of parallel channels (6b, 6c; 7b, 7c) for in each case different signal levels and an evaluation circuit, in which, in the radiofrequency analogue section in order to split the signal in accordance with a predeterminable division ratio into signal elements which can be supplied to radio-frequency analogue channels (6a, 7a), downstream from which the channels (6b, 6c; 7b, 7c) of the lower-frequency section are respectively connected, and the channels (6b, 6c; 7b, 7c) of the lower-frequency section each have an evaluation circuit for detection of the phase and amplitude of the respective signal element.

Abstract: The invention relates to a multichannel radio-frequency receiver (1) for electromagnetic waves, having a radio-frequency analogue section (2) which has an input (3) for an electrical signal of a receiving device (4), and having an lower-frequency section (8, 9) which is connected downstream from the radio-frequency analogue section (2) and has a plurality of parallel channels (6b, 6c; 7b, 7c) for respectively different signal strengths and an evaluation circuit, in which a signal divider (5) is provided in the radio-frequency analogue section (2) in order to split the signal in accordance with a predeterminable division ratio into signal elements which can be supplied to radio-frequency analogue channels (6a, 7a), downstream from which the channels (6b, 6c; 7b, 7c) of the lower-frequency section (8, 9) are respectively connected, and the channels (6b, 6c; 7b, 7c) of the lower-frequency section (8, 9) each have an evaluation circuit for detection of the phase and amplitude of the respective signal element.

Abstract: The invention relates to a multichannel radio-frequency receiver for electromagnetic waves, having a radio-frequency analogue section, which has an input for an electrical signal from a reception device, and having a lower-frequency section, which is connected downstream of the radiofrequency analogue section and has a plurality of parallel channels (6b, 6c; 7b, 7c) for in each case different signal levels and an evaluation circuit, in which, in the radiofrequency analogue section in order to split the signal in accordance with a predeterminable division ratio into signal elements which can be supplied to radio-frequency analogue channels (6a, 7a), downstream from which the channels (6b, 6c; 7b, 7c) of the lower-frequency section are respectively connected, and the channels (6b, 6c; 7b, 7c) of the lower-frequency section each have an evaluation circuit for detection of the phase and amplitude of the respective signal element.

Abstract: Polarization modulated transmitter, in particular for a weather radar, with at least two signal paths (3, 4) to which a radio frequency signal can be fed, and which are connected to a coupler (8), and with a phase modulation of the signal to be emitted via the antenna (1), it being possible to feed the same radio frequency signal to the at least two signal paths (3, 4) respectively having at least one transmit amplifier (5, 6), and a polarization modulator (7) is arranged for the phase modulation in one of the at least two signal paths (3, 4) in such a way that a radio frequency signal can first be phase modulated and then amplified.

Abstract: Polarization modulated transmitter, in particular for a weather radar, with at least two signal paths (3, 4) to which a radio frequency signal can be fed, and which are connected to a coupler (8), and with a phase modulation of the signal to be emitted via the antenna (1), it being possible to feed the same radio frequency signal to the at least two signal paths (3, 4) respectively having at least one transmit amplifier (5, 6), and a polarization modulator (7) is arranged for the phase modulation in one of the at least two signal paths (3, 4) in such a way that a radio frequency signal can first be phase modulated and then amplified.

Abstract: The invention relates to a multichannel radio-frequency receiver (1) for electromagnetic waves, having a radio-frequency analogue section (2) which has an input (3) for an electrical signal of a receiving device (4), and having an lower-frequency section (8, 9) which is connected downstream from the radio-frequency analogue section (2) and has a plurality of parallel channels (6b, 6c; 7b, 7c) for respectively different signal strengths and an evaluation circuit, in which a signal divider (5) is provided in the radio-frequency analogue section (2) in order to split the signal in accordance with a predeterminable division ratio into signal elements which can be supplied to radio-frequency analogue channels (6a, 7a), downstream from which the channels (6b, 6c; 7b, 7c) of the lower-frequency section (8, 9) are respectively connected, and the channels (6b, 6c; 7b, 7c) of the lower-frequency section (8, 9) each have an evaluation circuit for detection of the phase and amplitude of the respective signal element.

Abstract: To provide a pulsed gas-discharge laser system, in particular a pulsed excimer laser system, comprising a resonator and a gas volume filled with laser gas in which a gas discharge is ignitable, a microwave discharge structure surrounding the gas volume at least partially for maintaining the gas discharge, a microwave source for generating a microwave pulse and a microwave line leading from the microwave source to the microwave discharge structure, in which the laser pulse power behaves overproportionally to the pumping power, it is proposed that there be coupled to the microwave line by a coupling element a resonant microwave storage structure which leads to the gas volume and extends with at least a partial section thereof between the microwave discharge structure and the microwave line, and that the microwave storage structure be of such design and coupled to the microwave line by the coupling element in such a way that it stores the energy from the microwave pulse emitted by the microwave source until the

Abstract: To provide more economical excitation of a high-power laser comprising a resonator having mirrors arranged in spaced, opposite relation to each other in the direction of a resonator axis and a beam path extending in both the direction of the resonator axis and a transverse direction perpendicular thereto, a gas-discharge volume permeated by the beam path and containing laser gas, and two facing wall surfaces extending substantially parallel to the resonator axis and to the transverse direction and enclosing between them and thereby delimiting the gas-discharge volume, it is propsoed that at least one wall surface be formed by a dielectric wall, that a microwave resonance structure separate from the laser gas in the gas-discharge volume be placed on the dielectric wall and have an opening facing the dielectric wall and bring about in an area of volume of the gas-discharge volume opposite the opening a microwave excitation of the laser gas, and that microwaves be introducible into the microwave resonance struct

Abstract: To provide more economical excitation of the laser gas in a waveguide laser comprising a resonator having a resonator axis, an optical waveguide extending with a waveguide longitudinal direction essentially in the direction of the resonator axis and a gas-discharge volume located between the optical waveguide surfaces and containing a laser gas, it is proposed that a microwave source be provided, that an overcoupling structure separate from the laser gas in the gas-discharge volume be arranged on a side of one of the optical waveguide surfaces opposite the gas-discharge volume, the overcoupling structure being connected via a waveguide to a microwave source, extending in an overcoupling direction parallel to the optical waveguide surface and bringing about in a strip region in the gas-discharge volume along the overcoupling direction a substantially constant coupling-in of the microwave power.

Abstract: In order to so improve a microwave-pumped, high-pressure, gas-discharge laser, in particular, excimer laser, with an optical resonator, with a resonator gas volume arranged therein and extending along an optical axis thereof, with a microwave coupling structure enclosing the resonator gas volume within it and with a microwave generator connected to the microwave coupling structure, that a wall breakdown is substantially suppressed, it is proposed that a central area with an electric field intensity lying above a threshold value for a high-pressure gas discharge be disposed within the resonator gas volume in a transverse direction to the optical axis and be adjoined on both sides thereof by outer areas with a field intensity lying below the threshold value for the high-pressure gas discharge.