Optical: systems and elements – Compound lens system – Microscope
Reexamination Certificate
1998-07-24
2001-06-05
Nguyen, Thong (Department: 2872)
Optical: systems and elements
Compound lens system
Microscope
C359S368000, C359S370000, C359S387000
Reexamination Certificate
active
06243197
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of Invention
The invention relates to an illuminating device for a microscope.
In the illuminating beam path, the illuminating device for a microscope contains a lamp, an illuminating optical system and mechanical diaphragms. The size and shape of the diaphragms must be respectively matched to the objective used and to the desired type of illumination. The practice of automatically driving the variable quantities has been adopted for this reason. The mechanical diaphragms and filters in the microscope have therefore being equipped in each case with an electric drive or actuator and with a control device. This type of drive involves a high mechanical and electrical outlay because of the multiplicity of the diaphragms and filters used in connection with the most varied types of microscopic illumination.
2. Description of Related Art
DE 31 08 389 A1 has disclosed an illuminating device for a microscope in which a drivable liquid crystal cell with defined structure is used as a mechanical diaphragm. Differently instructed liquid crystal cells are used in each case for the various types of illumination, such as reflected-light/transmitted-light illumination, oblique illumination, dark-field illumination, phase-contrast illumination and polarization illumination.
Because the electrodes of the respective cell have definitively prescribed structures, they can be used only for prescribed magnification ratios in the microscope. In the event of a change in magnification owing to the use of a different microscope objective, it is necessary to install in the microscope a different liquid crystal cell matched thereto. Moreover, setting various types of illumination requires the various liquid crystal cells to be interchanged with one another. The defined structures mean that the type of illumination can be changed only with a change in hardware.
The drive specified in this document is a computer which is connected to the liquid crystal cell via a special control circuit and through which current can be applied to the prescribed structures of the cell.
A planar light source made from individual LEDs arranged next to one another is disclosed in DE 37 34 691 A1. The LEDs are constructed to be drivable individually and replace the halogen lamp normally used. A disadvantage of this arrangement is that the relatively weakly shining LEDs provide only a limited quantity of light for the microscope illumination. Moreover, such self-illuminating LEDs are relatively large, with the result that only a relatively coarse resolution can be achieved by various diaphragms in the representation.
SUMMARY OF THE INVENTION
It is therefore the object of the invention to develop the known prior art such that the most varied types of illumination can be realized using a single controllable cell.
This object is achieved according to the invention by means of the features specified herein. Advantageous developments of the invention are the subject matter described below.
Either Köhler or critical illumination is realized by the arrangement of a liquid crystal display (hereafter LCD), which has a planar matrix with individually drivable pixels, in a plane which is conjugate with respect to the field diaphragm or aperture diaphragm. The most varied transparent/opaque patterns, and thus the most varied diaphragm shapes and diaphragm sizes, can be generated by means of the individually drivable pixels, for example using a computer.
In this case, the diaphragm generated can be represented simultaneously on a monitor connected to the computer. It has also proved to be advantageous if the computer is connected to the control device of the microscope for the purpose of data exchange. It is then thereby possible, for example, to relay the data for the control program via the objective just used, and to determine the required diaphragm size and diaphragm shape by means of the control program loaded in the computer.
Using a commercially available video projector with LCD or DLP (Digital Light Technology) as illuminating device on the microscope means that the most varied types of illumination can be implemented without the need for the previously customary mechanical matching of diaphragms, filters or the like. The mechanical diaphragms, filters, phase rings and the like previously used in the microscope can therefore be completely eliminated.
The commercially available video projectors, for example Sony CPJ-PC200E or InFocus SYSTEMS LitePro620, can be flanged to the microscope stand via a simple illuminating optical system, and can replace both the customary light source and the diaphragms and filters. The video projector can be driven by connecting the existing standardized video input, for example VGA, SVGA, PAL, SECAM, NTSC, RGB to the corresponding output of a video card of a computer.
When using a video projector for color LCD, the color of the illuminating light can be set via the video signal. In this case, it is even possible in a simple way to produce simultaneously differing colors at different points of the LCD, or to arrange for the brightness of the illuminating light in the microscope to differ at the various points.
Commercially available equipment can be used in this case as the video card and computer. A PC or portable computer with built-in video card suffices to drive the video projector. In this case, the video card can be connected both to the video projector and to a further monitor for representing the transparent/opaque pattern set.
Owing to the representation of the microscopic image of the object via a TV camera and a connected TV monitor, with the change in the image on the LCD the resulting change in the microscope image is advantageously visible on the TV monitor. The desired representation of the object image can therefore be set by a stepwise change to the illumination via the LCD image.
In the case of such TV adapters or TV cameras for observing the microscopic image, color shading is produced at the image edge with 3-chip video cameras. The shading results from the dispersion at the prisms inside the cameras. When the LCD image is generated, said color shading is already taken into account for the illumination. In this case, the LCD generates an image appropriately color-corrected at the edge, or in the case of critical illumination an appropriate limitation of the aperture is undertaken. Positionally dependent color shading in the illumination can thus be corrected appropriately in a relatively simple way. In the case of Köhler illumination, the light intensity decreases towards the edge for large fields. The LCD illumination device can be used to compensate this decreasing light intensity by means of an “inverse” diaphragm image on the LCD. The brightness then increases towards the edge in the case of such a diaphragm image on the LCD.
This function can, of course, be fully automated in a further refinement of the invention. A TV camera is then used, for example, to generate a video signal in which the drop in brightness towards the image edge is contained. The appropriate computer regulating device is used to measure the drop in brightness, and the inverse image signal is correspondingly generated. This correction can advantageously always be performed automatically when, for example, there is a need to change the illuminating aperture.
In a further refinement of the invention, the computer is connected to further computers via a network, as a result of which the illumination conditions can be remotely controlled. This is useful, in particular, in seminar rooms with several microscopes, for example in order to create the same illumination conditions overall during a teaching session. Said network can then also be used, of course, for remote control of the further microscope functions.
It has also proved to be advantageous if additional orientation and/or graphic characters can be faded into the microscopic beam path via the LCD. Said fading-in can also be performed together with the representation of the diaphragms for the illumination on the LCD.
Owing
Foley & Lardner
Leica Mikroskopie und Systeme GmbH
Nguyen Thong
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