Abstract: A beam combiner for combining at least two light beams (1, 2) into one combined light beam (3), in particular in the beam path of an optical arrangement, preferably of a microscope, is with respect to a flexible beam combination with structurally simple means characterized by an acousto-optical element (4) in which a mechanical wave or sound wave for deflecting or bending light beams can be generated, so that a first light beam (1) entering the acousto-optical element (4) and at least a second light beam (2) entering the acousto-optical element (4) exit the acousto-optical element (4) in a collinear manner as a combined light beam (3). Further, a light source with such a beam combiner is specified.

Abstract: An optical evaluation method and an apparatus for performing said method are described. First laser pulses of a first type and second laser pulses of a second type that differs from the first type are sent onto a sample to be examined. The sample is hit with first incident light from the two laser pulses in at least one manner of simultaneously, within a very short time lag between the two laser pulses, and a time-correlated manner of the two laser pulses, thereby generating a first optical signal, and hit with second incident light from the two laser pulses, thereby generating a second optical signal. The generated first and second optical signals are detected with at least one detector; and an electronic difference between the first and second optical signals is generated.

Abstract: The invention relates to a laser system (20) for a microscope, comprising a laser module (22), a beam correction device (26), an optical fiber (31), a measuring element (34), and an external controller (37). The laser module (22) generates a light beam (24). The light beam (24) penetrates the beam correction device (26), which corrects a deviation of an actual value of at least one parameter of the light beam (24) from a target value of the parameter. The corrected light beam (24) is coupled into the optical fiber (31). The measuring element (34) is connected downstream of the optical fiber (31) and captures an actual value (36) of the intensity of at least one partial beam (32) of the corrected light beam (24). The external controller (37), regulates the actual value (36) of the intensity to a prescribed target value for the intensity.

Abstract: An acousto-optical filter element (114) is provided which has an acousto-optical crystal (118) having an acoustic signal transmitter (120) for generating acoustic signals in the acousto-optical crystal (118). The acousto-optical crystal (118) is designed to selectively spatially deflect light of a target wavelength from an input light beam (116) entering into the acousto-optical crystal (118), as a function of a high frequency applied to the acoustic signal transmitter (120), and to thereby produce a target light beam (126) having the target wavelength. In addition, the acousto-optical filter element (114) includes a spatial filter element (132) which is located in the target light beam (126) and is designed to selectively suppress the intensity of the target light beam (126) in a plane perpendicular to the propagation direction of the target light beam (126).

Abstract: The invention relates to a method and a system for central computer controlled execution of at least one test run in a scanning microscope, particularly a confocal microscope, wherein at least one first software module of an application software is tested. The invention achieves the aim by a network made of individual scanning microscope clients and a central server. The clients can be contacted via a network interface and are administered in a central directory in the server. The application software for the individual components of a scanning microscope is made of individual software modules, each associated with a potential test. In order to be able to perform the various tests, the scanning microscope clients have been equipped on the hardware side with additional sensors and components that allow various operating parameters to be determined.

Abstract: An acousto-optical system is described comprising at least one acousto-optical element having at least one transducer that is attached to a crystal, a driver unit for generating at least one acoustic signal for driving acousto-optical elements modifying light transmitted through the acousto-optical element and comprising at least one digital data processing unit, at least one digital-to-analog converter transforming the digital combination signal into an initial analog driver signal, and an amplifier for amplifying the initial analog driver signal to become said analog electronic driver signal. Further, a microscope and a method of operating the acousto-optical element is are described. Various objectives are achieved like more flexibility, real time compensation for non-linearity and reducing the number, size, costs and energy consumption of electronic components.

Abstract: An acousto-optical component is suggested, in particular for use in the beam path of an optical arrangement, preferably of a microscope, with a crystal for the passage of light. Sound waves are generated via an electrical transducer and passed through the crystal. The sound waves passing through the crystal affect the optical properties of the crystal and therefore the light passing through the crystal. For exerting a variable influence on the light passing through the crystal, the sound waves passing through the crystal, or the acoustic field in the crystal, are/is variable.

Abstract: The invention relates to a method and a device for illuminating or irradiating an object, a sample (8), or the like, for the purpose of imaging or analysis, particularly for use in a laser microscope (1), preferably in a confocal microscope having a laser light source (2) emitting the illuminating light, the laser light being coupled directly or by means of a glass fiber into an illumination light path (4), characterized in that the laser light source (2) is switched on rapidly upon a trigger signal directly prior to the actual need, for example, directly prior to imaging.

Abstract: A method for superimposing optical information in a scanning microscope includes determining a transformation matrix, and superimposing first optical information of a CCD image and second optical information of at least one piece of second image information using the transformation matrix.

Abstract: A device for generating a laser light beam includes a module. The module includes at least one laser light source, and a mechanical, an electrical and/or an optical interface defined towards an outside of the module.

Abstract: A method for high spatial resolution examination of a sample, the sample to be examined including a substance that can be repeatedly converted from a first state into a second state, the first and the second states differing from one another in at least one optical property. The method includes: a) bringing the substance into the first state by means of a switching signal in a sample region to be recorded, b)inducing the second state by means of an optical signal, spatially delimited subregions being specifically excluded within the sample region to be recorded, c) reading out the remaining first states, and d) steps a) to c) are repeated, the optical signal being displaced upon each repetition in order to scan the sample, wherein the individual steps a) to d) are carried out in a sequence adapted to the respective measuring situation.

Abstract: The invention relates to a confocal microscope which illuminates a sample (15) by means of at least one light source. A detection light beam (17) is emitted from the sample (15). The detection light beam (17) is spectrally split up in a spatial manner by the dispersive element (20) and subsequently formed on a photosensor chip (19) by means of a detection optical system (22). At least one expanding optical system (23) is arranged in front of the dispersive element (20) in the direction of the detection light beam (17). The expanding optical system (23) is embodied in such a manner that the numerical aperture of the detection optical system (22) is independent from the numerical aperture of the detection light beam (17) on the detection apertured diaphragm (18).

Abstract: An apparatus for controlling an acousto-optical component influencing at least one of illumination light and detection light in a microscope is described. The apparatus comprises a radio-frequency generator for supplying the acousto-optical component with a radio frequency. The radio-frequency generator is configured to compensate deviations in the characteristics of the light due to temperature fluctuations in the acousto-optical component by adapting the radio frequency.

Abstract: A light detector for use in a line scanning microscope and a microscope comprising such a light detector are described. The light detector comprises—a line array of avalanche semiconductor detectors; and an electronic trigger circuit that is adapted to operate the avalanche semiconductor detectors in at least one of a Geiger mode with internal charge amplification and in a linear mode. The trigger circuit further comprises a parallel counter that is designed to read out in parallel light pulses detected by the avalanche semiconductor detectors. The parallel counter is adapted to accumulate the light pulses detected by the avalanche semiconductor detectors over a preset counting time.

Abstract: A beam combiner for combining at least two light beams (1, 2) into one combined light beam (3), in particular in the beam path of an optical arrangement, preferably of a microscope, is with respect to a flexible beam combination with structurally simple means characterized by an acousto-optical element (4) in which a mechanical wave or sound wave for deflecting or bending light beams can be generated, so that a first light beam (1) entering the acousto-optical element (4) and at least a second light beam (2) entering the acousto-optical element (4) exit the acousto-optical element (4) in a collinear manner as a combined light beam (3). Further, a light source with such a beam combiner is specified.

Abstract: A method for high spatial resolution stochastic examination of a biological sample structure labeled with a labeling substance is described. The method comprises providing a biological sample structure; choosing such a labeling substance that has molecules present in a first state and in a second state, and the first and second states differ from one another in at least one photophysical property such that there is sufficient probability that one portion of the molecules of the substance will be in the first state and another portion of the molecules will be in the second state and within which labeling substance a change of the state of the molecules can occur spontaneously between the two states in both directions; and labeling the biological sample structure with the substance.

Abstract: An optical evaluation method and an apparatus for performing said method are described. First laser pulses of a first type and second laser pulses of a second type that differs from the first type are sent onto a sample to be examined. The sample is hit with first incident light from the two laser pulses in at least one manner of simultaneously, within a very short time lag between the two laser pulses, and a time-correlated manner of the two laser pulses, thereby generating a first optical signal, and hit with second incident light from the two laser pulses, thereby generating a second optical signal. The generated first and second optical signals are detected with at least one detector; and an electronic difference between the first and second optical signals is generated.

Abstract: An acousto-optical filter element (114) is provided which has an acousto-optical crystal (118) having an acoustic signal transmitter (120) for generating acoustic signals in the acousto-optical crystal (118). The acousto-optical crystal (118) is designed to selectively spatially deflect light of a target wavelength from an input light beam (116) entering into the acousto-optical crystal (118), as a function of a high frequency applied to the acoustic signal transmitter (120), and to thereby produce a target light beam (126) having the target wavelength. In addition, the acousto-optical filter element (114) includes a spatial filter element (132) which is located in the target light beam (126) and is designed to selectively suppress the intensity of the target light beam (126) in a plane perpendicular to the propagation direction of the target light beam (126).

Abstract: A method and a device for providing a predeterminable concentration of at least one component in a microscopic sample liquid medium are described. The device includes a feeding device for the at least one component. Measurement data are determined, measuring a predeterminable parameter using a microscopic method. The concentration of the at least one component is adjusted or controlled via the feeding device based on the basis of measurement data.

Abstract: An optical arrangement and a related method for operating this optical arrangement are suggested, particularly in microscopes, for use as at least one of a main beam splitter and a beam combiner. One or more light beams can be coupled into the arrangement and at least one of the light beams that were coupled in can be coupled out again after having passed through the optical arrangement. In the path of the coupled in light beams at least one controllable microstructured element is provided, allowing to switch beam paths within the optical arrangement. This allows controlling or influencing the one or more light beams that are coupled out.