USRE33883E

USRE33883E - Split-image multi-power microscopic image display system and method

Info

Publication number: USRE33883E
Application number: US07/367,300
Authority: US
Inventors: Robert S. Ledley
Original assignee: National Biomedical Res Foundation
Current assignee: National Biomedical Res Foundation
Priority date: 1985-02-04
Filing date: 1989-06-16
Publication date: 1992-04-14
Anticipated expiration: 2005-02-04

Abstract

A split-image, multi-power microscopic image display system and method wherein the image of an object positioned on a slide is split into two optical paths, and is magnified to a varying degree in each optical path, the resulting respective magnifications being displayed on respective monitor devices. The initial optical path includes an objective and a splitter; the path of lower magnification includes a converging lens, diverging lens, reduction lens, bending prism, TV camera and TV monitor; the path of higher magnification includes a trinocular microscope head, TV camera, and TV monitor. Further features of the invention includes the following: provision of a microcomputer with data entry means, and respective mixers disposed between the TV cameras and their monitors for insertion of identifying information into the video signal and subsequent display on the monitors of the identifying information and the image of the object being microscopically viewed; provision of a photographic printer for producing a hardcopy record of the image viewed; and provision of a lens switching arrangement for selection of various objectives without the necessity of refocusing after a lens is switched into position.

Description

TECHNICAL FIELD

The present invention relates to a split-image, multi-power microscopic image display system for use in viewing simultaneously two images of the same object or specimen, each image having a different magnification with respect to the other.

BACKGROUND ART

In certain microscopic viewing applications, such as microscopic examination of chromosomes, it is necessary for the technician to view a relatively large area of the specimen under a lower magnification power in order to locate a particular smaller area to be viewed, and then to switch magnifications and refocus in order to view the smaller area of concern under a larger magnification. Much time is wasted performing these manipulations, and it is quite inefficient and inconvenient for the technician to have to refocus the microscope after switching to a higher magnification.

Accordingly, it would be considered highly desirable to provide a split-image microscopic image display system and method having multiple magnification powers, and it would especially be desirable to provide such a system with the capability of simultaneously viewing and displaying on two monitors both the larger area of general interest and the smaller area of specific interest. Moreover, it would also be considered desirable to provide such a system with the capability of producing, on operator command, a hardcopy of the images displayed on either of the monitors (the high-power monitor or the low-power monitor).

In some applications, it might be desirable to provide such a split-image, multi-power microscopic image display system and method with a type of lens switching apparatus whereby lenses of varying physical characteristics can be manually and yet easily employed as the objective lens in the microscopic image display system and method. However, as mentioned previously, the technology of the prior art is such as to require a refocusing of the microscope each time a new lens is switched into place for use as the objective. Therefore, it is considered desirable to provide a lens switching arrangement wherein refocusing is not required each time a new lens is switched into position.

The following patents are generally pertinent to the present invention: U.S. Pat. Nos. 2,527,719; 2,699,092; 2,950,649; 3,030,861; 3,057,259; 3,353,891; 3,459,464; 3,488,104; 3,503,684; 3,871,741; 3,895,854; 4,218,112; and 4,440,475.

DISCLOSURE OF INVENTION

The present invention relates to a split-image, multi-power microscopic image display system and method.

Specifically, the present invention relates to a microscopic image display system and method wherein the optical image of a specimen is, as a result of the employment of a splitter, directed along two optical paths. A first optical path includes a trinocular microscope head for operator viewing of the specimen during initial microscopic setup, in combination with a first TV camera to which the image is presented as an optical input and a first TV monitor connected to the first camera for producing a visual image of the specimen magnified in accordance with a first magnification power. The second optical path includes a combination of lenses and a bending prism for presenting to a second TV camera, as an optical input thereto, an image of the specimen magnified in accordance with a second magnification power, and a second TV monitor connected to the second TV camera for presenting a visual image thereof.

Preferably, the microscopic image display system and method of the present invention includes a microcomputer having an operator input means (such as a keyboard) for inputting information pertaining to the specimen being viewed, in combination with a mixer connected between the microcomputer and the TV camera(s), on the one hand, and the TV monitor(s), on the other hand, for displaying on the TV screen, as an inset, the information pertinent to the particular specimen being viewed. As a further preference, the microscopic image display system and method includes a slave monitor or monitors, each slave monitor being connected to an output of a respective one of the TV monitors, the system and method further including one or more respective photographic printers, each photographic printer being connected to a respective one of the slave monitors for producing a hardcopy record of the image being displayed at a particular time.

In accordance with a further feature of the invention, the microscopic image display system and method is provided with an objective lens switching apparatus by means of which the operator can switchably employ two or more lenses of varying characteristics as the objective lens of the microscopic image display system and method. However, in accordance with this feature of the present invention, each time the operator switches the lens into position, it is not necessary for the operator to refocus the microscope.

Therefore, it is a primary object of the present invention to provide a split-image, multi-power microscopic image display system and method.

It is an additional object of the present invention to provide a microscopic image display system and method having at least two optical paths, each optical path providing a visual image of a specimen magnified in accordance with a respective magnification power.

It is an additional object of the present invention to provide a microscopic image display system and method employing at least two TV cameras and at least two respectively associated TV monitors for viewing the respective magnified images of the specimen.

It is an additional object of the present invention to provide a microscopic image display system and method having the capability of producing a hardcopy record of the specimen being viewed.

It is an additional object of the present invention to provide a microscopic image display system and method wherein information relevant to the particular specimen being viewed can be electronically inserted into the TV signals so that it can be viewed simultaneously with the magnified image of the specimen.

It is an additional object of the present invention to provide a microscopic image display screen and method having a lens switching apparatus for providing the operator with the capability of switching various lenses into place without the need for refocusing after each lens switching operation.

The manner in which these and other objects are accomplished by the present invention will become clear from the following detailed description of a preferred embodiment.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a front view of the microscopic image display system of the present invention.

FIG. 2 is a top view of the microscopic image display system of the present invention.

FIG. 3 is a side view of a portion of the microscopic image display system of FIG. 1, as viewed along the arrow D in FIG. 1.

FIG. 4 is a block diagram further disclosing the microscopic image display system of the present invention.

FIGS. 5A and 5B are a top view and a section view (along line B--B' of FIG. 5A), respectively, of a lens switching arrangement employed in accordance with the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

The invention will now be described in more detail with reference to the figures of the drawings.

FIG. 1 is a front view of the microscopic image display system of the present invention, while FIG. 2 is a top view of the microscopic image display system. As seen therein, the system 10 comprises a stage 12, specimen slide 14, objective lens 16, splitter 18, trinocular microscopic head 20, first camera 22, first TV monitor 24, converging lens 26, diverging lens 28, reduction lens 30, bending prism 32, neutral density filter 33, second TV camera 34, and second TV monitor 36.

The objective 16 is preferably a 100X microscope objective having a high numerical aperture (1.3-1.4). Moreover, the optical output of the objective 16 must be characterized by a 15° divergence.

In accordance with a preferred embodiment of the invention, the amount of image provided as an optical output of the objective 16 covers an area of approximately 700 microns, but an image area of only 350 microns is desired for display on the monitor 36; moreover, the image area of 350 microns preferably fills the entire display area of the monitor 36. This is accomplished by proper design choice of the following parameters: (1) the distance between the objective 16 and the converging lens 26; (2) the distance between the converging lens 26 and the lens 38 of camera 22; and (3) the reduction factor, that is, the ratio of the focal length of reduction lens 30 to the focal length of diverging lens 28.

Converging lens 26 is preferably a 61 mm. double-convex lens measuring 16 (±5) diopters. As is well-known, a diopter is the inverse of the focal length.

Diverging lens 28 is preferably a 102 mm. compound lens, such as a projection lens, which takes converging light (emanating from the converging lens 26) and converts it to parallel light.

Reduction lens 30 is preferably a 28 mm. lens, such as is typically employed in a 35 mm. camera, for reducing the parallel light image coming from the diverging lens 28.

Bending prism 32 is any conventional light-bending prism employed for the purpose of bending the light coming from reduction lens 30 so as to direct it toward camera 34. In this regard, it is to be noted that a first inversion of the image of the specimen takes place as a result of bending by the splitter 18, whereas a second inversion of the image takes place as a result of bending by the prism 32. It is to be further noted that the camera 34 is disposed in an inverted manner, with its top facing downward (in FIG. 1), whereas the monitor 36 is disposed on its side (as also shown in FIG. 1).

As a result of the latter arrangement, the image viewed on monitor 36 corresponds precisely, in orientation, to that viewed through the microscope directly (via the trinocular microscope head 20). Moreover, the arrangement is such that movement of the slide 14 (and its specimen) in a given direction will result in a movement of the image on monitor 36 in the corresponding direction on monitor 36. Finally, the placement of monitor 36 on its side results in vertical orientation of the scan lines of the monitor, thus facilitating viewing by the user.

Neutral density filter 33 (preferably, a Kodak Wratten No. 96) is disposed at some point in the optical path to the camera 34, preferably between prism 32 and camera 34 (FIG. 2), to compensate for an increase in light intensity occurring due to reduction in the second optical path.

FIG. 3 is a side view of a portion of the system of the present invention, as viewed along the line D in FIG. 1. As seen in FIG. 1, and as confirmed in FIG. 3, the camera 22 is preferably oriented with its top facing to the left in FIG. 1, while the monitor 24 is disposed on its side. As a result, the specimen as viewed through the trinocular microscope head 20 will correspond precisely in orientation to the view of the specimen displayed on the monitor 24 and viewing is facilitated. As best seen in FIG. 3, the trinocular microscope head 20 provides the user with the capability of viewing the fully magnified (100X) image of the specimen directly, that image being conveyed via the objective 16, splitter 18, further splitter 40 in the trinocular microscope head 20, and binocular viewing arrangement 42. The trinocular microscope head 20 is a conventional item available in the marketplace; for example, such a trinocular microscope head is manufactured by Olympus of Japan.

In order to provide the system with the aforementioned viewing capability, the present invention calls for the mounting of the trinocular microscope head 20, by suitable means, on the end of the camera 22 such that the distance B+C from the objective 16 to the binocular viewing arrangement 42 equals the distance A from the objective 16 to the camera 22 (specifically, the input lens 38 thereof).

Referring to FIGS. 1, 2 and 3, the operation of the system is as follows. The specimen to be viewed is placed on the slide 14, and the slide 14 is placed on the stage 12. The technician then adjusts the slide 14, using the trinocular microscope head 20 or the monitor 36 to view the specimen on slide 14. As mentioned previously, the arrangement is such that movement of the slide 14 in a given direction will result in precisely the same movement of the specimen on the monitor 36.

Once the specimen is properly positioned, the technician views the specimen under a lower magnification power (for example, 20X) on monitor 36 and under a higher magnification power (for example, 100X) on monitor 24. This simultaneous viewing of the specimen under lower and higher magnification powers is achieved without the need for switching of lenses and without any need for refocusing.

FIG. 4 is a block diagram further disclosing the system of the present invention. As seen therein, the system comprises the previously discussed

cameras

22 and 34 and monitors 24 and 36, and further comprises a microcomputer 50, keyboard (or other input means) 52,

mixers

54 and 60, slave monitors 56 and 62, and

photographic printers

58 and 64.

In operation, in the course of positioning a specimen on the slide 14 (FIG. 1), the technician uses the keyboard 52 to enter information relevant to the specimen into the microcomputer 50, the microcomputer 50 being appropriately programmed and configured to provide analog representations of the entered information to the

mixers

54 and 60. As an example, the microcomputer 50 can be configured to include a Video Memory Board MFB-512-8-4-M and an A/D, D/A board MFB-512-8-1-M, manufactured by Imaging Technology, Inc. of Woburn, Mass., for the purpose of generating analog representations of information entered via keyboard 52.

The

mixers

54 and 60 are conventional analog mixing devices, available in the marketplace, for mixing the analog video signals from the

cameras

22 and 34, respectively, with the analog representations of operator-entered information provided by microcomputer 50, so as to generate a mixed video signal for provision to the

monitors

24 and 36, respectively. As a result, monitors 24 and 36 display both the operator-entered information and the image of the specimen.

The system further provides the capability, via

photographic printers

58 and 64, of producing a hardcopy record of the image displayed on the

monitors

24 and 36, respectively. This can be accomplished in either one of two alternate ways: first, the

cameras

22 and 34 can provide a direct optical output to the

photographic printers

58 and 64, respectively; or second, slave monitors 56 and 62 can be connected to the output of

monitors

24 and 36, respectively, so as to produce appropriate inputs to the

photographic printers

58 and 64, respectively. The

photographic printers

58 and 64 are, by way of example, implemented by an automatic print processor such as the "47th Street Photo Speed Printer" manufactured by the 47th Street Darkroom Center of New York, N.Y.

FIGS. 5A and 5B are top and sectional views, respectively, of a lens switching arrangement which can be employed with the system of the present invention. As seen in the figures, the lens switching arrangement comprises a frame member 160 in which a rotatable, circular disclike member 162 is positioned, member 162 being rotatable within the member 160. The member 162 includes receptacles in which are disposed

respective lens arrangements

164, 165 and 166.

More specifically, each of the

lens arrangements

164, 165 and 166 has a different magnification power so that, by rotating the member 162 within the frame member 160, lens arrangements of different magnification powers can be moved into position in the optical path, thus providing variable magnification of the object being viewed.

In the prior art, it is well-known to provide a lens switching arrangement wherein lenses of differing magnification may be rotated into position in the optical path. However, a significant drawback to such prior art arrangements resides in the fact that, after rotating each lens into position, it is necessary to refocus the microscope with which the lens switching arrangement is being used.

In accordance with a feature of the present invention, there is no necessity to refocus the microscope when a new lens is switched into position in the optical path. This is due to the fact that, in accordance with the invention, and as seen in FIG. 5B, each

lens arrangement

164, 165 and 166 includes a pair of

lenses

164a and 164b, 165a and 165b, and 166a and 166b, respectively. More specifically, the present inventor has discovered that, by superimposing

positive diopter lenses

164b, 165b and 166b on top of the negative diopter lenses 164a, 165a and 166a, respectively, and by arranging for a predetermined distance to be established between the negative diopter lens and its superimposed positive diopter lens, refocusing of the microscope after each switch to a new lens arrangement is unnecessary.

Accordingly, referring to FIGS. 1, 5A and 5B, in accordance with a further feature of the invention, a lens switching arrangement as shown in FIGS. 5A and 5B can be substituted for the objective lens 16 of FIG. 1. This will provide the microscopic image display system with the capability of switching objective lenses, thus providing the user with further flexibility in the establishment of split-image, multi-power displays.

It is to be understood that the split-image, multi-power microscopic image display system and method of the present invention must comply with the Koler technique (well-known in the art) in order to avoid focusing of the filament. In brief, every microscope has a filament which generates light which passes through the objective and is focused by one or more lenses in an objective plane. It is possible, in certain arrangements, to obtain a spurious image resulting from focusing of the filament. In order to avoid this problem, Koler developed lens arrangements and procedures so that the filament image was positioned quite a distance away, and thus was out of focus insofar as the microscopic viewer was concerned.

While preferred forms and arrangements have been shown in illustrating the invention, it is to be understood that various modifications can be made without departing from the spirit and scope of this disclosure.

Claims

I claim:

1. A method for displaying magnified images of an object having different respective magnifications, comprising:

providing an objective, characterized by a given magnification, through which the image of the object passes to produce an objective optical output having the given magnification;

splitting the objective optical output into first and second optical outputs for passage through respective first and second optical paths;

providing said first optical output to a first camera in said first optical path, said first camera producing a first video output;

.[.bending.]. .Iadd.providing .Iaddend.said second optical output to .[.direct it toward.]. a second camera in said second optical path, said second camera producing a second video output; and

processing said first and second video outputs to display first and second images, respectively, of the object;

wherein the method comprises the further step of adjusting the magnification of at least one of the first optical output in said first optical path and the second optical output in said second optical path so that the magnification of the object in the first .Iadd.optical .Iaddend.path differs from the magnification of the object in the second optical path;

whereby to display the first and second images of the object magnified in accordance with the different respective magnifications.

2. The method of claim 1, wherein .Iadd.one of .Iaddend.the .[.bending step comprises passing.]. .Iadd.first optical output and the second optical output comprises an inverted image of the object, said method comprising the step of further inverting said one of the first optical output and .Iaddend.the second optical output .[.through a prism.]..

3. The method of claim 1, wherein the processing step comprises mixing at least one of said first and second video outputs with analog representations of operator-entered information so as to display the operator-entered information with corresponding at least one of the first and second images of the object.

4. The method of claim 1, comprising the additional step of producing a hardcopy record of at least one of the first and second images of the object.

5. The method of claim 1, wherein the step of providing an objective comprises selecting one of a plurality of objectives, and wherein each objective comprises a negative-diopter lens with a superimposed positive-diopter lens.

6. The method of claim 1, wherein said objective is a lithography lens.

7. The method of claim 1, wherein .[.said.]. .Iadd.the .Iaddend.adjusting step comprises reducing the magnification of the second optical output in said second optical path to produce a third optical output characterized by a magnification different from said given magnification.

8. The method of claim .[.7.]. .Iadd.1.Iaddend., wherein the .[.reducing.]. .Iadd.adjusting .Iaddend.step comprises converging the second optical output to produce a converged optical output, diverging the converged optical output to produce a diverged optical output, and passing the diverged optical output through a reducing lens.

9. A system for displaying magnified images of an object having different respective magnifications, comprising:

objective lens means for magnifying an image of the object passing therethrough to produce an objective optical output having a given magnification;

splitting means for splitting the objective optical output into first and second optical outputs for passage through respective first and second optical paths;

a first camera disposed in said first optical path for producing a first video output;

a second camera disposed in said second optical path.[.; bending means.]. for .[.bending the second optical output to direct it toward said second camera, said second camera.]. producing a second video output; and

display means responsive to said first and second video outputs for displaying first and second images, respectively, of the object;

said system further comprising adjusting means for adjusting the magnification of at least one of the first optical output in said first optical path and the second optical output in said second optical path so that the magnification of the object in the first optical path differs from the magnification of the object in the second optical path;

10. The system of claim 9, wherein .Iadd.one of .Iaddend.the .[.bending means comprises a prism disposed at an end of.]. .Iadd.first optical output and the second optical output comprises an inverted image of the object, said system comprising inverting means for further inverting said one of the first optical output and .Iaddend.the second optical .[.path and adjacent to said second camera.]. .Iadd.output.Iaddend..

11. The system of claim 9, wherein said objective lens .Iadd.means .Iaddend.comprises a lithography lens.

12. The system of claim 9, comprising photographic printer means operatively associated with said display means for producing a hardcopy record of at least one of the first and second images of the object.

13. The system .[.f.]. .Iadd.of .Iaddend.claim 9, comprising photographic printer means operatively associated with at least one of said first and second cameras for receiving a direct optical output therefrom, and for producing a hardcopy record of at least one of the first and second images of the object.

14. The system of claim 9, .[.furthr.]. .Iadd.further .Iaddend.comprising mixing means connected to at least one of said first and second cameras for mixing at least one of said first and second video outputs with analog representations of operator-entered information so as to display the operator-entered information with corresponding at least one of the first and second images of the object.

15. The system of claim 14, further comprising operator input means for inputting the operator-entered information, and processing means for processing the operator-entered information so as to provide the operator-entered information to said mixing means.

16. The system of claim 9, wherein said objective lens means comprises a plurality of objective lenses of varying magnifications, said system further comprising selecting means for selecting one of said plurality of objective lenses through which the image of the object passes.

17. The system of claim 16, wherein each of said plurality of objective lenses comprises a negative-diopter lens and a superimposed positive-diopter lens.

18. The system of claim 9, wherein said adjusting means comprises a reducing arrangement disposed in said second optical path for reducing the magnification of the second optical output so as to produce a third optical output characterized by a magnification different from the given magnification.

19. The system of claim .[.18.]. .Iadd.9.Iaddend., wherein .[.the reducing arrangement.]. .Iadd.said adjusting means .Iaddend.comprises a converging lens for converging the second optical output to produce a converged optical output, a diverging lens for diverging the converged optical output to produce a diverged optical output, and a reducing lens for reducing the diverged optical output. .Iadd.20. The method of claim 2, wherein said further inverting step comprises bending said one of the first optical output and the second optical output to direct it toward a corresponding one of said first and second cameras. .Iaddend. .Iadd.21. The system of claim 10, wherein said inverting means comprises bending means for bending said one of the first optical output and the second optical output to direct it toward a corresponding one of said first and second cameras. .Iaddend. .Iadd.22. The system of claim 21, wherein said bending means comprises a prism disposed at the end of a corresponding one of the first and second optical paths. .Iaddend. .Iadd.23. A method for interactively viewing in detail a selected portion of an object, comprising the steps of:

(a) providing an optical image input corresponding to the object to be viewed;

(b) splitting the optical image input into a first optical input and a second optical input;

(c) providing the first optical input to a first optical path, at an output end of which a first camera is disposed for receiving a first optical output, corresponding to a first image of the object, from the first optical path;

(d) providing the second optical input to a second optical path, at an output end of which a second camera is disposed for receiving a second optical output, corresponding to a second image of the object, from the second output path;

(e) operating the first camera to provide a first video output, corresponding to the first optical output, to a first display screen; and

(f) operating the second camera to provide a second video output, corresponding to the second optical output, to a second display screen;

wherein the method further comprises the step of providing at least one optical element in at least one of the first optical path and the second optical path for adjusting the magnification of at least one of the first image of the object in the first optical path and the second image of the object in the second optical path so that the second optical output from the second optical path represents an image of the object which appears magnified relative to the first image of the object. .Iaddend. .Iadd.24. The method of claim 23, wherein one of the first optical output and the second optical output comprises an inverted image of the object, said method comprises the step of further inverting said one of the first

optical output and the second optical output. .Iaddend. .Iadd.25. The method of claim 24, wherein said further inverting step comprises bending said one of the first optical output and the second optical output to direct it toward a corresponding one of said first and second cameras. .Iaddend. .Iadd.26. A system for interactively viewing in detail a selected portion of an object, comprising:

splitter means for splitting an optical image input into first and second optical inputs, and for providing the first optical input to a first optical path and the second optical input to a second optical path;

first camera means disposed at an output end of the first optical path for receiving a first optical output corresponding to a first image of the object in the first optical path, and for providing a first video output corresponding thereto;

second camera means disposed at an output end of the second optical path for receiving a second optical output corresponding to a second image of the object in the second optical path, and for providing a second video output corresponding thereto; and

displaying means connected to said first camera means for receiving said first video output and responsive thereto for displaying the first image of the object, and connected to said second camera means for receiving said second video output and responsive thereto for displaying the second image of the object;

wherein said system further comprises optical means disposed in at least one of the first optical path and the second optical path for adjusting the magnification of at least one of the first image of the object in the first optical path and the second image of the object in the second optical path so that the second optical output from the second optical path represents an image of the object which appears magnified relative to

the first image of the object. .Iaddend. .Iadd.27. The system of claim 26, wherein one of the outputs of the first optical path and the second optical path comprises an inverted image of the object, said system comprising inverting means for further inverting said one of the outputs of the first optical path and the second optical path. .Iaddend. .Iadd.28. The system of claim 27, wherein said inverting means comprises bending means for bending said one of the outputs of the first optical path and the second optical path to direct it toward a corresponding one of said first and second cameras. .Iaddend. .Iadd.29. The system of claim 28, wherein said bending means comprises a prism disposed at the end of a corresponding one of the first and second optical paths. .Iaddend.