This application claims priority of German patent application no. 10 2015 203 844.0, filed Mar. 4, 2015, the entire content of which is incorporated herein by reference.
The invention relates to an optics system for imaging an object region with an optical beam path in an image plane of an image acquisition system, with a first optical assembly, through which the optical beam path passes, and with a second optical assembly arranged in the optical beam path on the side of the first optical assembly facing away from the object region. Moreover, the invention relates to a surgical microscope with such an optics system.
In the present case, a surgical microscope is understood to mean a system with a microscope unit, preferably embodied as a stereo microscope, which is received at a stand and which enables an observing person to observe an operating region with magnification. The microscope unit can be configured for visualizing the operating region with an optical observation beam path. However, it is also possible to provide a microscope unit which brings digitally acquired images to the display for an observing person. An example of a surgical microscope within the meaning of the invention is the OPMI® Pentem® system, manufactured and distributed by Carl Zeiss Meditec AG. U.S. Pat. No. 4,786,155 has disclosed an optics system of the type set forth at the outset. This optics system is arranged in an operating microscope, which has a device for visualizing structures in the object region by means of light with a wavelength λ≤620 nm. The human eye has comparatively low sensitivity for light at this wavelength. However, this light is only scattered or absorbed a little by the arterial blood in the human body. The operating microscope contains an illumination device, by means of which it is possible to provide light lying in the red and infrared spectral range. In the operating microscope, there is a beam splitter on the side of an afocal magnification system facing away from the object region, above the microscope main objective in the left-hand and right-hand observation beam path, which beam splitter guides the observation light to a camera, by means of which light in the red and infrared spectral range can be detected. The optics system in the operating microscope contains a first optical assembly with an afocal magnification system. This optics system has a second optical assembly, which has the function of an objective and which guides a beam path, which passes through the first optical assembly, from an object region to the image sensor of the camera.
In surgical or operating microscopes, it is desirable, in particular for examining structures in an object region with fluorescing dyes, for an image acquisition system to be able to register not only the visible light but also light from the infrared spectral range.
To this end, conventional operating microscopes have an image acquisition system with different cameras, which are tuned to the visible and infrared spectral ranges (see, for example, DE 10 2006 006 014 A1).
It is an object of the invention to provide an optics system which is suitable for use in a surgical microscope and with which the image of the object region can be guided to an image acquisition system with good imaging quality not only in the visible but also in the infrared spectral range in the case of the same object distance, that is, in the case of one and the same distance between the optics system and the object region.
The optical system of the invention is for imaging an object region via an optical beam path in an image plane of an image acquisition system. The optical system includes: a first optical assembly configured to pass the optical beam path therethrough; the first optical assembly having an end facing away from the object region; a second optical assembly arranged in the optical beam path at the end of the first optical assembly; and, the second optical assembly defining a system configured to at least partially compensate chromatic longitudinal aberrations of the first optical assembly occurring in a wavelength range of light of 625 nm≤λ≤850 nm.
The invention rests on the concept of the optical assemblies used in surgical microscopes, especially optical assemblies with a microscope main objective and with a zoom system, generally being achromats. What this ensures is that the focal deviation for light with a wavelength lying in the red wavelength range (λ≈640 nm) and for light with a wavelength lying in the blue wavelength range (λ≈480 nm) is less than or equal to the depth of field δ=nλ/2NA2 of the optical assembly pursuant to the standard ISO/FDIS 19012-2, where n is a refractive index of the medium in the object space (in air, n=1 applies), NA is the object-side numerical aperture and λ=480 nm or λ=640 nm.
However, such achromats have a significant longitudinal and transverse chromatic aberration in respect of the wavelengths, specified above, for the light lying in the infrared spectral region, for example, for light with a wavelength λ=850 nm.
In order to reduce this longitudinal and transverse chromatic aberration, the invention proposes that the second optical assembly in the optics system is embodied as a system at least partly compensating longitudinal chromatic aberrations of the first optical assembly occurring in the wavelength range 625 nm≤λ≤850 nm of the light. What can be achieved by this measure is that the object region can also be examined by means of the optics system using light lying in the near infrared and in the infrared spectral range, without optical components in the optics system needing to be adjusted on long displacement paths for this purpose. In particular, what can be achieved by this measure is that changing the distance between the optics system and the object region or refocusing the optics system does not lead to the image of the object region supplied to the image acquisition system losing sharpness in the wavelength range 625 nm≤λ≤850 nm of the light in relation to an image of the object region with light lying in the visible spectral range.
Here, the second optical assembly in the optics system can have positive refractive power. In particular, the second optical assembly can be an objective, for example an objective for a color camera, which brings about imaging of the object region in the image plane of the image acquisition system.
By virtue of the second optical assembly containing at least one lens displaceable in the optical beam path relative to the image plane of the image acquisition system, it is possible to compensate errors of the imaging in the image plane of the image acquisition system, which errors are dependent on the wavelength of the light used to observe the object region.
In order to compensate errors of the imaging in the image plane of the image acquisition system, which errors are dependent on the wavelength of the light used to observe the object region, it is also possible, within the optics system, to provide a displaceability of the second optical assembly as a whole for the purposes of setting the optical path length of the optical beam path from the object region into the image plane of the image acquisition system.
According to the invention, the second optical assembly can have a first lens with positive refractive power and a second lens with negative refractive power and a third lens with positive refractive power. Here, the first lens with positive refractive power and the second lens with negative refractive power can be combined to form a cemented member. The first lens of the second optical assembly then faces, where possible, the first optical assembly in the optical beam path. Here, the third lens of the second optical assembly is preferably arranged in the optical beam path on the side facing the image plane of the image acquisition system. Here, the two lenses with positive refractive power preferably consist of a material with anomalous partial dispersion.
The glasses of the lenses with positive refractive power in the second optical assembly of an optics system according to the invention respectively lie away from the so-called normal line.
According to the invention, the two lenses with positive refractive power, in particular, can consist of the glasses N-FK58, N-FK51A, N-PK52A, N-PK51 from Schott, the glasses S-FPL53, S-FPL-51, S-FPL51Y, S-FPM3 or else S-FPM2 from Ohara, or glasses which have optical properties corresponding to the optical properties of the aforementioned glasses and an anomalous relative partial dispersion.
The lens with negative refractive power in the second optical assembly advantageously consists of a material with a lower Abbe number but with a relative partial dispersion which is as similar as possible to the one occurring in the positive lenses. In an optics system according to the invention, the lens with a negative refractive power in the second optical assembly can consist, in particular, of the glass N-KZFS2, N-BK7 or N-SK11.
Advantageous glass combinations, in the second optical assembly, for the two lenses with positive refractive power on the one hand and the lens with negative refractive power on the other hand are in particular: S-FPL51/N-KZFS2, S-FPL53/N-BK7 or N-PK51/N-SK11. The glasses of the lens with negative refractive power in the second optical assembly in an optics system according to the invention can have anomalous partial dispersion, but this is not mandatory. The glasses of the lens with negative refractive power in the second optical assembly in an optics system according to the invention can therefore also lie in the vicinity of the normal line.
In particular, the invention proposes that the differences of the partial dispersions of the two glass types ΔPdC and the differences of the Abbe numbers of the two glass types Δv are related to one another in a ratio |ΔPdC/Δv|, for which |ΔPdC/Δv|≤0.1‰, preferably |ΔPdC/Δv|≤0.03‰ applies.
The first optical assembly in the optics system is an achromatic system preferably corrected for the light with the wavelength λ≈656 nm and the light with the wavelength λ≈486 nm. However, the first optical assembly can also be an apochromatic system, which is preferably corrected for the light with the wavelength λ≈656 nm and the light with the wavelength λ≈486 nm and the light with the wavelength λ≈588 nm. In particular, the first optical assembly can contain an afocal zoom system.
According to the invention, the second optical assembly in the optics system is an apochromat preferably corrected for the light with the wavelength λ≈486 nm, λ≈588 nm and λ≈656 nm or a semi-apochromat.
The invention understands a semi-apochromat to be an optics system with a positive refractive power, in which the focal deviation for light with a wavelength lying in the red wavelength range (λ≈640 nm) and for light with a wavelength lying in the blue wavelength range (λ≈480 nm) and for light with a wavelength lying in the green wavelength range (λ≈546 nm) is less than or equal to 2.5-times the depth of field δ=nλ/2NA2 pursuant to the standard ISO/FDIS 19012-2, where n is the refractive index of the medium in the object space, NA is the object-side numerical aperture and λ≈480 nm or λ≈546 nm or λ≈640 nm.
The invention understands an apochromat to be an optics system with a positive refractive power, in which the focal deviation for light with a wavelength lying in the red wavelength range (λ≈640 nm) and for light with a wavelength lying in the blue wavelength range (λ≈480 nm) and for light with a wavelength lying in the green wavelength range (λ≈546 nm) is less than or equal to the depth of field δ=nλ/2NA2 pursuant to the standard ISO/FDIS 19012-2, where n is the refractive index of the medium in the object space, NA is the object-side numerical aperture and λ≈480 nm or λ≈546 nm or λ≈640 nm.
The invention also extends to a surgical microscope containing an optics system as specified above. It is advantageous if the surgical microscope has a color camera embodied as a 3-chip camera, with image sensors arranged in the image plane of the image acquisition system. This renders it possible to use the color camera to register the object region of the surgical microscope with light, the wavelength of which lies in the visible and infrared spectral range. The invention also extends to a surgical microscope with an illumination device, which provides an illumination beam path, which serves to excite the fluorescence of a dye in the object region and which can be guided through a filter system for filtering-out light, the wavelength of which corresponds to the wavelength of the fluorescent light of the fluorescing dye, which is then detected by the camera in the surgical microscope.
The invention will now be described with reference to the drawings wherein:
The surgical microscope 10 shown in
As an alternative to the above, it is also possible especially to configure the splitter prism arrangement 25 in such a way that the image sensor 29c, which is configured for registering light in the blue spectral range, can also register the light with wavelengths in the near infrared and infrared spectral ranges.
The observation beam path 16L in the surgical microscope passes through a zoom system 22L which corresponds to the configuration of the zoom system 22R.
The surgical microscope 10 is accommodated on a stand (not shown here), which has adjustable articulated arms. On the stand, the surgical microscope 10 can be displaced over the object region 12 by adjusting the articulated arms.
The surgical microscope 10 contains an illumination device 30 with a light source 32 and illumination optics 34, through which the light from the light source 32 can pass. The illumination optics provide an illumination beam path 36 via which the object region 12 can be illuminated.
The illumination device 30 is configured to excite one or more dyes, such as, for example, indocyanine green (ICG) dye, 5ALA dye or protoporphyrin IX dye, to fluoresce. To this end, light having a wavelength in the blue spectral range is provided by the light source 32 of the illumination device 30. In order to prevent light having a wavelength corresponding to the wavelength of the light of the dye, which is excited to fluoresce and arranged in the object region 12, from being guided in the illumination beam path 36 to the object region 12, there is a fluorescence excitation filter 40 in the illumination device 30. The fluorescence excitation filter can be introduced into the illumination beam path 36 in accordance with the double-headed arrow 38 so as to filter out the spectral range of the illumination light which is released when a dye in the object region 12, which is excited to fluoresce, fluoresces.
So that only the fluorescent light released by a fluorescing dye in the object region 12 can be guided to an observer and the color camera 26 in the fluorescence operating mode of the surgical microscope 10, the optics system in the surgical microscope 10 contains adjustable filter elements 42 which, in accordance with the double-headed arrow 44, can be arranged in the stereoscopic observation beam paths (16L, 16R) on the end of the zoom systems facing away from the object region. The filter elements 42 can ensure that the light with the wavelength of the light exciting the fluorescence does not reach the eyepieces (14L, 14R) of the binocular tube 15 and the color camera 26.
The optical assembly 18 is an achromat which completely compensates the longitudinal chromatic aberration CHL of the wavefront for the light with the wavelength λ=486 nm (F-line) in relation to the light with the wavelength λ=656 nm (C-line), that is, CHL18FC=0.
The configuration of the optics system in the surgical microscope 10 is based on the consideration that the longitudinal chromatic aberration CHL18xC, related to the C-line and dependent on any wavelength of the light (x-line), of the wavefront in relation to the C-line can be estimated to a good approximation as follows:
where αxC denotes the gradient of the normal line related to the C-line for the light with a wavelength x, βxC,i denotes the distance of a specific glass of a lens i from this normal line, yi denotes the marginal ray height, vi denotes the Abbe numbers of the materials v=(nd-1)/(nF-nC), and φi denotes the refractive powers of the lenses i.
The inventors discovered that, if only normal glasses are used in the optical assembly 18 for achromatization (that is, βxC,i=0), the chromatic longitudinal aberrations, related to the C-line, for the light with a wavelength λ=588 nm (d-line) and λ=850 nm (s-line), with
CHLdC18=αdC·Σi½yi2·φi αdC=+0.00046173
CHLsC18=αsC·Σi½yi2·φi αsC=−0.002304493
are related to one another as follows:
That is, the chromatic aberrations for the light in the near infrared and in the infrared are approximately 5-times larger than in the visible spectral range in the optical assembly 18; the sign of these chromatic aberrations is, however, opposite to the sign of the chromatic aberrations in the visible spectral range.
The second optical assembly 24 in the optics system of the surgical microscope 10 serves to reduce the chromatic aberration of the image of the object region, supplied to the color camera 26, in the near infrared and in the infrared.
This is achieved by virtue of the chromatic aberrations of the optics group 24 being completely compensated for simultaneously, preferably for light with the wavelength λ=656 nm (C-line), λ=588 nm (d-line) and λ=486 nm (F-line). This is because the chromatic aberration of the optical assembly 24 for the wavelength λ=850 nm (s-line) then has the opposite sign to the corresponding chromatic aberration of the optical assembly 18. As a consequence, the chromatic aberration in the near infrared and in the infrared of the optical assembly 18 is at least partly lifted by the chromatic aberration of the optical assembly 24 in the near infrared and infrared. Since the optical assembly 18 and the optical assembly 24 are in each case completely compensated for the light in the visible spectral range, the combination of the optical assembly 18 with the optical assembly 24 in the optics system of the surgical microscope 10 can supply the color camera 26 with an image which does not have any chromatic aberrations in the visible spectral range either.
The inventors have discovered that the residual error of the two-member apochromat into the near infrared in the case of light with the wavelength λ=852 nm (s-line) can be estimated to a good approximation as follows:
where y0 is the marginal ray height and φ is the refractive power of the two-member apochromat. The variable ΔPsC denotes the difference of the relative partial dispersions of the two employed glass types in the wavelength range between the s-line and the C-line, the variable Δv describes the difference in the Abbe numbers of the two glasses.
As can be gathered from the following table, the values of the variable ΔPsC/Δv vary between +0.00051 and +0.00042 for some of the aforementioned glass pairs.
The variations of the values of the variable ΔPsC/Δv for different glass types are used by the invention in order thereby to at least partly compensate the longitudinal chromatic aberration CHLxC of the first optical assembly 18 by way of a suitable selection of the glass types of the lenses (200, 202, 204) in the optical assembly 24. To this end, an allowance with a sign opposite to the sign of the longitudinal chromatic aberration of the first optical assembly is set for the longitudinal chromatic aberration of the second optical assembly in the infrared spectral range.
Therefore, in the optics system of the surgical microscope 10, the second optical assembly 24 compensates the longitudinal chromatic aberration of the first optical assembly 18 except for a residual error, which does not have an effect for the imaging of the object region 12 on the image sensor of the camera with light in the infrared spectral range.
A configuration example for the first optical assembly 18 and the second optical assembly 24 in the optics system of the surgical microscope 10 is reproduced in the following tables:
Here, the following applies:
It should be noted that, in principle, as lens material for the lenses with anomalous partial dispersion in the second optical assembly, use can also be made of glasses N-FK58, N-FK51A, N-PK52A, N-PK51 from Schott, the glasses S-FPL53, S-FPL-51, S-FPL51Y, S-FPM3 or else S-FPM2 from Ohara, or glasses which have optical properties corresponding to the optical properties of the aforementioned glasses and an anomalous partial dispersion.
It should be noted that, in principle, the microscope main objective system 20 in the above-described surgical microscope 10 can also be embodied as a focusable microscope main objective. The configuration of the optical assembly 24 according to the table reproduced above ensures that an image of the object region 12 is respectively generated even when focusing the microscope main objective in the image planes 27a, 27b and 27c, which image does not lose sharpness only for light in the visible spectral range but does not lose sharpness for the light in the near infrared either, without this requiring a displacement in the beam path 16R of the optical assembly 24 as a whole or of the lenses in this optical assembly.
In conclusion, the following, in particular, should be registered: The invention relates to an optics system for imaging an object region 12 with an optical beam path (16R, 16R′) in an image plane (27a, 27b, 27c) of an image acquisition system. The optics system contains a first optical assembly 18, through which the optical beam path 16R passes, and a second optical assembly 24 arranged in the optical beam path 16R on the side of the first optical assembly 18 facing away from the object region 12. The second optical assembly 24 is embodied as a system at least partly compensating longitudinal chromatic aberrations of the first optical assembly 18 occurring in the wavelength range 625 nm≤λ≤850 nm of the light.
It is understood that the foregoing description is that of the preferred embodiments of the invention and that various changes and modifications may be made thereto without departing from the spirit and scope of the invention as defined in the appended claims.
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