Method of and apparatus for optically detecting anomalous subsurface structure in translucent articles

US 4,184,175 A
Filed: 02/09/1977
Issued: 01/15/1980
Est. Priority Date: 02/09/1977
Status: Expired due to Term

First Claim

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1. A nondestructive method of determining the degree of anomalous subsurface structure of a solid translucent article which method comprises the steps of:

illuminating a surface area of said article with a beam of incident light of predetermined intensity;

imposing a predetermined pattern of shaded regions on said incident light beam so that said surface area comprises at least one directly illuminated portion and at least one intervening shaded portion; and

detecting and quantifying the difference between the intensity of subsurface diverted light emanating from subjacent said directly illuminated portion and the intensity of subsurface diverted said light emanating from subjacent a shaded portion.

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Abstract

A nondestructive method of and apparatus for optically detecting the presence of and inferentially determining the relative degree of anomalous subsurface structure in translucent articles: for instance, such anomalous subsurface structural phenomena as pre-carious lesions in in vivo teeth. Moreover, dynamic changes in the degree of such anomalous subsurface structure can be identified and relatively quantified. Thus, for instance, progressive subsurface deterioration of teeth can be monitored, and the efficacy of products directed towards arresting or reversing the development of pre-carious lesions in teeth can be evaluated through the use of the present invention. The method and apparatus of the present invention provide for illuminating a surface area of a translucent article with incident light, and detecting whether a sufficient portion of the light is internally diverted by being refracted or diffusely reflected or the like by the internal structure of the article to indicate whether the subsurface structure of the article is anomalous. Both in vivo and in vitro apparatuses are disclosed. Several species of hand-held probes for such applications as dental examinations are also disclosed. Manipulation of the hand-held probes is facilitated by flexible fiber optic cables. The apparatus may include closed circuit video and automatic data processing equipment to facilitate the use of the apparatus, and to facilitate the reduction and interpretation of the data derived from operating the apparatus. As used herein, the term light is not intended to be limited to the visible spectrum.

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31 Claims

1. A nondestructive method of determining the degree of anomalous subsurface structure of a solid translucent article which method comprises the steps of:
- illuminating a surface area of said article with a beam of incident light of predetermined intensity;
  
  imposing a predetermined pattern of shaded regions on said incident light beam so that said surface area comprises at least one directly illuminated portion and at least one intervening shaded portion; and
  
  detecting and quantifying the difference between the intensity of subsurface diverted light emanating from subjacent said directly illuminated portion and the intensity of subsurface diverted said light emanating from subjacent a shaded portion.
- View Dependent Claims (2, 3)
- - 2. The method of claim 1 wherein said detecting and quantifying are effected along a scan line extending across said surface area so that said scan line crosses at least one said directly illuminated portion and at least one said shaded portion.
  - 3. The method of claim 2 further comprising the step of inferring from said difference between said intensities the relative degree of subsurface anomalous structure subjacent said illuminated area through the use of an empirical relation between such intensity and the relative degree of subsurface anomalous structure which relation has been derived by making corresponding intensity determinations on a plurality pf graded standards covering a predetermined range of degrees of anomalous subsurface structure.

4. An apparatus for detecting and determining the presence and relative degree of anomalous subsurface structure in a solid translucent article, said apparatus comprising:
- means for illuminating a surface area of said article with a beam of incident light of predetermined intensity;
  
  means for detecting and quantifying the intensity of a portion of said light which is being internally diverted and emerging outwardly from subjacent said surface area of said article;
  
  means for inferring from said intensity of said internally diverted light the relative degree of subsurface anomalous structure subjacent said illuminated area through the use of an empirical relation between such intensity and the relative degree of subsurface anomalous structure which relation has been derived by making corresponding intensity determinations on a plurality of graded standards covering a predetermined range of degrees of anomalous subsurface structure; and
  
  ,means for imposing a shadow pattern image on said beam of incident light and for focusing said image on said surface area to provide at least one directly illuminated portion of said surface area and at least one shaded portion of said surface area, and wherein said means for detecting and quantifying comprises optical viewing means for viewing said surface area and means for scanning said surface area along a scan line which extends across at least one said directly illuminated portion of said surface area and at least one said shaded portion of said surface area, said means for detecting and quantifying further comprising computing means for determining the intensity difference between outwardly directed internally diverted light emerging from said article along the portion of said scan line extending across said directly illuminated portion and the outwardly directed internally diverted light emerging from said article along the portion of said scan line extending across said shaded portion and means for comparing said intensity difference with said empirical relation whereby the relative degree of anomalous subsurface structure in the article can be inferred.
- View Dependent Claims (5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27)
- - 5. The apparatus of claim 4 further comprising means for inferring from said difference the relative degree of subsurface anomalous structure subjacent said illuminated area through the use of an empirical relation between such intensity difference and the relative degree of subsurface anomalous structure which relation has been derived by making corresponding intensity difference determinations on a plurality of graded standards covering a predetermined range of degrees of anomalous subsurface structure.
  - 6. The apparatus of claim 5 further comprising output means for identifying said inferred relative degree of anomalous subsurface structure to an operator of said apparatus.
  - 7. The apparatus of claim 4 further comprising a hand-held optical probe which comprises at least in part said means for illuminating said surface area with a focused image, and said optical viewing means for viewing said focused image.
  - 8. The apparatus of claim 7 wherein said probe further comprises means for obviating from said optical viewing means substantially all of said light which is specularly reflected from said surface area.
  - 9. The apparatus of claim 8 wherein said means for obviating said specularly reflected light comprises means for providing a predetermined incident angle for said incident light which is so related to the angle of acceptance of said viewing means that said specularly reflected light is not received by said viewing means.
  - 10. The apparatus of claim 8 wherein said means for obviating said specularly reflected light comprises means for providing an incident angle for said beam in the range of from about thirty degrees to about sixty degrees, and means for obviating light from said optical viewing means which light has an angle of reflection in the range of from about thirty degrees to about sixty degrees.
  - 11. The apparatus of claim 10 wherein said incident angle is about forty-five degrees, and said optical viewing means has a line of sight which is substantially normal to said illuminated surface area.
  - 12. The apparatus of claim 11 further comprising filter means for obviating diffusely reflected light from said illuminated surface from reaching said optical viewing means which filter means comprises an optical filter for circularly polarizing said incident light, said filter being so disposed that light directed from said illuminated surface towards said optical viewing means must impinge on said filter whereby surface reflections are substantially obviated from reaching said optical viewing means and whereby internally diverted light is not obviated from reaching said optical viewing means.
  - 13. The apparatus of claim 7 wherein said probe further comprises means for obviating from said optical viewing means substantially all of said light which is reflected from said surface area.
  - 14. The apparatus of claim 13 wherein said means for obviating surface reflected light comprises an optical filter for circularly polarizing light which is so disposed that said incident light beam passes through it and upon which filter said surface reflected light directed towards said optical viewing means must impinge.
  - 15. The apparatus of claim 7 wherein said means for focusing said incident light beam on said illuminated surface area comprises a resilient member secured to the nose of said probe so that it can be sufficiently compressed by pressing the nose of said probe against said article to so space said probe from said article that said surface area is in the image plane of said incident light beam.
  - 16. The apparatus of claim 15 wherein said resilient member further comprises a means for obviating ambient light from said illuminated surface area.
  - 17. The apparatus of claim 16 wherein said resilient member further comprises means for conducting a flow of gas across said illuminated surface area.
  - 18. The apparatus of claim 7 wherein said probe further comprises means for directing a flow of gas across said illuminated surface area whereby said surface area can be dried.
  - 19. The apparatus of claim 4 wherein said optical viewing means comprises a closed circuit video system comprising a video camera, optical coupling means therefore, and a video monitor whereby said focused image on said illuminated surface area can be enlarged and remotely displayed.
  - 20. The apparatus of claim 19 wherein said scanning means comprises means for positioning said scan line with respect to said focused image so that it will extend across any selected portion of said focused image.
  - 21. The apparatus of claim 20 further comprising a hand-held optical probe which comprises at least in part said means for illuminating said surface area with a focused image, and said optical viewing means for viewing said focused image.
  - 22. The apparatus of claim 21 wherein said probe comprises means for providing an angle of incidence of about forty-five degrees, and for providing said optical viewing means having a line-of-sight which is substantially normal to said surface area.
  - 23. The apparatus of claim 21 further comprising means for computing an inferred degree of anomalous subsurface structure in said article, and output means for identifying said inferred degree of anomalous subsurface structure to an operator of said apparatus.
  - 24. The apparatus of claim 23 wherein said incident angle is about forty-five degrees, and said optical viewing means has a line-of-sight which is substantially normal to said illuminated surface area.
  - 25. The apparatus of claim 24 wherein said probe further comprises a member of resilient material attached to the nose of said probe and so configured that said member comprises means for obviating ambient light from said illuminated surface area, and means for enabling positioning said probe with respect to the surface area of interest of said article so that the image plane of said incident beam is coincident with said surface.
  - 26. The apparatus of claim 24 wherein said probe further comprises means for directing a flow of gas across said illuminated surface area whereby said surface area can be dried.
  - 27. The apparatus of claim 26 wherein said probe further comprises a member of resilient material attached to the nose of said probe and so configured that said member comprises means for obviating ambient light from said illuminated surface area, and in which member said means for directing said flow of gas across said illuminated surface area comprises interconnected passageways and ports.

28. An optical probe for use in an optical instrumentation system comprising a remote light source, a flexible fiber optic cable for transmitting light from said source to said probe, a closed circuit video sub-system, and a flexible coherent fiber optic cable for conducting an image from said probe to said closed circuit video sub-system, said probe comprising means for being coupled to said fiber optic cables, means for projecting an image-carrying incident light beam from said probe and for focusing said beam to form said image on a solid surface of interest, and means for focusing light received from the direction of said surface of interest on the end of the flexible coherent fiber optic cable coupled to said probe whereby said video sub-system can view said surface of interest, and enlarge and remotely display a video image of said view of said surface of interest, said optical probe further comprising means for substantially obviating every portion of said incident light that is reflected from said surface from being transmitted to said video sub-system.
- View Dependent Claims (29)
- - 29. The optical probe of claim 28 wherein said means for obviating surface reflected light comprises an optical filter for circularly polarizing light which filter is so disposed that said incident light passes through it and so that any of said surface reflected incident light directed towards said means for focusing impinges on said filter whereby said surface reflected light is blocked from said video sub-system.

30. An optical probe for use in an optical instrumentation system comprising a remote light source, a flexible fiber optic cable for transmitting light from said source to said probe, a closed circuit video sub-system, and a flexible coherent fiber optic cable for conducting an image from said probe to said closed circuit video sub-system, said probe comprising means for being coupled to said fiber optic cables, means for projecting an image-carrying incident light beam from said probe and for focusing said beam to form said image on a solid surface of interest, and means for focusing light received from the direction of said surface of interest on the end of the flexible coherent fiber optic cable coupled to said probe whereby said video sub-system can view said surface of interest, and enlarge and remotely display a video image of said view of said surface of interest, said means for focusing said incident light beam comprising means for providing a fixed focal length for said beam so that said image is focused in an image plane, and means for spacing said probe so that said surface of interest is substantially coincident with said image plane, and said means for spacing comprises a resilient member disposed on the projection end of said probe which member has a length greater than the distance between the projection end of the probe and said image plane whereby said projection end of said probe can be pressed against said surface of interest to sufficiently deform said resilient member to cause said surface of interest and said image plane to be substantially coextensive.
- View Dependent Claims (31)
- - 31. The optical probe of claim 30 wherein said resilient member comprises means for obviating ambient light from said surface of interest, and means for conducting a flow of gas across said surface of interest.

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Current Assignee
The Procter & Gamble Company
Original Assignee
The Procter & Gamble Company
Inventors
Mullane, William I. Jr.
Primary Examiner(s)
Griffin, Robert L.
Assistant Examiner(s)
Orsino, Jr., Joseph A.

Application Number

US05/767,008
Time in Patent Office

1,070 Days
Field of Search

250/562, 250/563, 250/572, 356/237, 356/118, 356/119, 356/120, 356/204, 358/93, 358/106, 358/98
US Class Current

348/66
CPC Class Codes

A61B 2560/0233   Optical standards

A61B 5/0088   for oral or dental tissue

G01J 3/508   measuring the colour of teeth

G01N 2021/4735   Solid samples, e.g. paper, ...

G01N 2021/4742   comprising optical fibres

G01N 21/278   Constitution of standards

G01N 21/4738   Diffuse reflection preceden...

G01N 21/4785   Standardising light scatter...

Method of and apparatus for optically detecting anomalous subsurface structure in translucent articles

First Claim

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Abstract

161 Citations

31 Claims

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Method of and apparatus for optically detecting anomalous subsurface structure in translucent articles

First Claim

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0 Petitions

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Accused Products

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Abstract

161 Citations

31 Claims

Specification

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Solutions

Use Cases

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