DE102005036397A1 - Lighting device for a light microscope - Google Patents

Abstract

An illumination device for optical light microscope with object carrier, with the illumination device embodied by the objective carrier which consists of a mainly rigid flat substrate with at least one organic light-emitting diode (OLED) mounted on it.

Description

For the consideration of an object by means of a microscope is generally the illumination of the Object with optical aids required. In weak enlargements It may be sufficient to use the natural light or light of an artificial one Radiation source over to direct a deflection mirror in the optical beam path. At higher magnification are however special lighting systems with an optimal coupling required to the imaging beam path. This will also special Microscopy possible by different object images due to different illuminations be effected.

For an optimal Object illumination and optimal utilization of the light source Microscope lights regularly after the Köhler's Lighting principle built. This lighting principle allows in particular first, a uniform illumination the object field, secondly the adjustment of the illumination aperture to the imaging aperture and third, the adaptation of the illuminated Object field to the size of the object. For microscopes with interchangeable lenses of different aperture and object field diameter would have to Change of the objective also the condenser be exchanged, to optimally exploit the light source. this Effort is usually saved, by illuminating the aperture with an aperture stop and the illuminated Object field can be set with a field stop.

There the picture quality the microscope is a complex function, in which also the parameters of the Lighting system is a correct adjustment of the on The lighting involved optically active elements of particular Importance. defects here you can reduce image intensity, resolution, and / or contrast. The therefore required time-consuming adjustment and adjustment of the lighting system by an experienced fitter are an essential cost-driving Factor in the production of high quality microscopes.

The Need of optical components, such as collector, condenser and possibly adjustable diaphragms and filter systems also increase the production price. About that In addition, these components and their predetermined arrangement to each other for the Total size of the microscope mitbestimmend.

Of the Production costs for conventional sophisticated Microscope lighting and the space required for this In the microscope, therefore, can be reduced only very limited.

In the US 5,734,498 Lighting elements for a light microscope are presented, which promise the illumination of an object equivalent to Köhler illumination without the use of a condenser. In particular, the Justageaufwand and the space required for the lighting device, which consists only of a light source and one lighting element, thereby significantly reduced. A lighting element is mounted immediately below the transparent slide. Due to its surface area parallel to the slide, the size of the illuminated object field is determined. When viewing the object via the optical imaging system of the microscope, the object appears evenly isotropically illuminated by a homogeneous bright light source of high numerical aperture. Different lighting elements allow lighting to be realized with different colors. For this purpose, lighting elements of a first type proposed according to fluorescent chemicals. These chemicals within the lighting element are excited by the illumination with a simple light source for fluorescence and emit light of one or more frequencies by the absorption of light energy. Other proposed types of lighting elements include light scattering particles or both fluorescent and light scattering particles.

By a required minimum distance of the light source to the lighting element is synonymous with this solution the reduction of the height limited.

It the object of the invention is to provide a lighting device, with a relatively small one and cheap Microscope can be created.

These Task is with a lighting device according to claim 1 solved.

advantageous versions are in the subclaims specified.

The Invention will be described below with reference to exemplary embodiments become.

As is known, OLEDs are formed from a thin-film system consisting of a first transparent electrode, a thin organic layer or layer sequence and a second electrode. If electricity flows through this thin-film system, then the organic layer or Layer sequence. The color in which the organic layer or layer sequence shines is determined by the substance of the organic layer and its possible doping. OLEDs can be produced in virtually any color. In order to produce white radiating OLEDs, short-wave emitting substances are selected for the organic layers. A fluorescent dye layer applied to the OLED with a mixture of color pigments converts the short wavelength light into a mixture of long wavelength light which appears as white light. For the purposes of the invention, an OLED with an applied dye layer, as described, is to be understood as a white OLED.

known manner can white Light can also be generated with an OLED matrix, consisting of red, green and blue-emitting single-OLEDs, the same time or almost simultaneously be controlled.

The structure as a thin-film system makes it possible to produce OLEDs of very different surface areas of a few μm ² (eg 350 μm × 350 μm) up to a few cm ² (eg 10 cm × 10 cm) and various surface shapes such as circles or rings.

Around the thin-film system before environmental influences to protect, is it with a for the emitting radiation transparent layer sealed. This layer can be made of glass or ceramic. For the purposes of the invention is intended the Versieglungsschicht also understood as belonging to the OLED become.

The previous explanations are intended for the average person skilled in the field of optical device development for understanding the one for the Invention significant properties of OLEDs serve, so far are only in a few applications on the market.

Neither The construction of OLEDs or their production are the subject of this Invention. The invention relates to the use of OLEDs as such and special designs for one Microscope illumination, which is embodied by a slide.

There OLEDs in contrast to the illuminated described in the prior art Lighting element (secondary radiator) even emitting light, no light is generated, which is not to Lighting contributes. Accordingly, with the same radiation efficiency of the primary radiator a comparably bright illumination of the object to be microscoped be achieved by OLEDs with less electrical energy than by a conventional Köhlersche Lighting or a secondary radiator.

Basically exists a lighting device according to the invention, through a slide personified is made of a rigid substrate carrier and one applied thereto OLED or an OLED matrix.

In a first embodiment is on the substrate, in a conventional form for slides as a rectangular plan plate is formed, a single OLED applied substantially emitted from the substrate away. The areal extent of the OLED is determined by the size of the desired Illuminated field for a respective microscope, for the slide should be used. Depending on what color the object was to be illuminated, an OLED was selected in the desired Wavelength band Emitted radiation. For an irradiation of the object with white light became an OLED, as described above, with an additional fluorescent layer used.

The Substrate is for the emission radiation is not transparent or beneficial to you too on the substrate incident radiation components for object illumination to use, transparent and mirrored on its surface facing away from the OLED.

One slides according to the first embodiment has a predefined luminous field size and a fixed preset Emission band and is positioned as intended in the light microscope so that the substrate on the side facing away from the microscope objective Side of the slide located.

There the OLED itself is a primary emitter is and therefore does not need lighting and beyond extremely thin running can claimed a lighting device by a slides personified consisting of a substrate with an applied OLED, just the space required for a slide anyway is. A equipped with such a lighting device Microscope can be correspondingly smaller, handier, lighter and too cheaper getting produced.

Especially Advantageously, the illumination device according to the invention for a Pocket microscope can be used, which is light in weight and a small size of special Interest are. Therefor It is also advantageous that the operation of OLEDs no mains voltage is required.

As a power source, a low voltage source is sufficient. It can be connected internally in the form of a battery to the electrodes of the OLEDs, or as an external voltage source via a low-voltage present on the microscope Connection to feed the OLED. For occasional microscopy in the wild, the microscope can also be connected to a mobile phone commonly carried today to power the OLEDs with the battery of the mobile phone. Still, the production of OLEDs is relatively expensive compared to the preparation of simple glass slides conventionally used as slides. However, it can be foreseen that their production costs will decline significantly in the future. The luminescent slides according to the invention could then become disposable, ie cleaning or disinfecting after use could be eliminated.

Around Slide according to the invention with OLEDs different emission wavelengths, surface shapes and size to one same microscope, they have a standardized Low-voltage connection on, which is also part of an object movement system can be and have a same substrate size and shape.

1 schematically shows such a microscope with a lens 1 which is that of a sample 2 coming light on a CCD receiver 3 projected. Instead of a conventional slide, an OLED 4 used on which the sample 2 fixed and with a coverslip 5 is covered. Power is supplied by a voltage source 6 which via cable 7 with the OLED slide 4 connected is.

Instead of a single OLED according to a second embodiment ( 2 ) also an OLED matrix are applied to the substrate. Due to the differentiated control of the individual single OLEDs 8.1 . 8.2 . 8.3 , ..., 8.n. Different emission spectra and different light field sizes and shapes can be realized.

According to a third embodiment ( 3 ) should be an OLED or an OLED matrix 4 are used, which emits substantially towards the substrate. The substrate 9 is transparent to the emission radiation and in the form of a microtiter plate 10 formed on the bottom surface of the OLED or OLED matrix 4 borders. Such a slide is intended to be positioned in the light microscope so that the substrate is located on the side facing the microscope objective side of the slide.

According to one fourth embodiment the illumination source should be in the form of an OLED or OLED matrix not part of the slide or be the microtiter plate, but as part of the microscope be connected to the microscope stand. Advantageous to this embodiment is that the OLED is not over Electrode is electrically connected to the power source, but directly above Cable can be connected. Furthermore, previous slides and Microtiter plates are used.

Preferably the integrated OLED illumination source can be part of the microscope be the object movement unit. Usually, the to be examined Object on object movement unit through one or more clamps fixed, so that its position is clearly specified. The area The object movement unit below the object could be called OLED be formed so that the light emitted by the OLED through The object is coupled into the imaging optics of the microscope becomes.

This embodiment is in 4 shown schematically, wherein essentially only the parts are shown, the of the in 1 differed embodiment shown. Here is the object table 11 itself as OLED running, which over connections 7 with the power supply 6 connected is. The sample 2 is on a conventional slide 12 and is with a cover slip 5 covered.

Of the Advantage of the OLED to be a primary emitter itself and therefore extremely thin to be able to be, comes in this embodiment especially for carrying. Also let the other advantages mentioned above in this embodiment call.

According to a fifth embodiment ( 5 ) should also be the illumination source in the form of an OLED or OLED matrix not part of the slide or the microtiter plate, but the OLED 4 can also be part of the microscope below the condenser 13 to be appropriate. This makes it possible for the OLED 4 emitted light more efficient the object 2 to supply and to realize a Köhler illumination principle related form of microscope illumination.

An advantage of this invention is that the OLED can be made more compact. If the OLED is designed as an OLED microdisplay (see 2 ), it can be realized by suitable control for contrasting necessary lighting forms without the aid of mechanical components. For example, a dark field contrast can be generated by an annular illumination pattern. Furthermore, the color channels of the OLED microdisplay can be used to vary the spectral characteristics of the illumination according to the requirements of the application.

the A person skilled in the art will understand that that the invention is not illustrative of the details of the above mentioned embodiments limited is, but that the present invention in other special Forms forms may be without departing from the scope of the invention, which the appended claims is fixed.

Claims (11)

Lighting device for a light microscope with a slide, characterized in that the illumination device is embodied by the slide, which consists of a substantially rigid plate-shaped substrate having at least one organic light-emitting diode (OLED) applied thereto. Lighting device for a light microscope, thereby in that the illumination device is a component of the light microscope and from a substantially rigid plate-shaped substrate with at least one organic light emitting layer applied thereto Diode (OLED) exists. Lighting device according to claims 1 or 2, characterized in that exactly one OLED is present and this has a surface area, the same as the luminous field size for a light microscope is. Lighting device according to claims 1 or 2, characterized in that a plurality of individually controllable OLED is present, which form an OLED matrix and by a selected control the individual OLED variable the field size for a light microscope is. Lighting device according to claims 1, 2 or 4, characterized in that a plurality of individually controllable OLED is present, which form an OLED matrix and by a selected control the individual OLED the luminous field shape for a light microscope variable is. Lighting device according to claims 1 or 2, characterized in that at the OLED / OLED matrix a normalized Low-voltage connection is present, via which the OLED / OLED matrix can be connected to an external low voltage source. Lighting device according to claims 1 or 2, characterized in that the substrate is mirrored on its surface is. Lighting device according to claim 1, characterized in that the substrate is in the form of a microtiter plate is trained. Lighting device according to claim 2, characterized in that the lighting device is part of the Object movement device of the light microscope is. Lighting device according to claim 2, characterized in that the illumination device is below the condenser of the light microscope is arranged. Lighting device according to claim 10, characterized characterized in that the OLED lighting as OLED microdisplay accomplished is and thus a local and spectral variation of the lighting allowed.