Method and apparatus for optical interactance and transmittance measurements

US 7,142,307 B1
Filed: 03/14/1997
Issued: 11/28/2006
Est. Priority Date: 03/01/1991
Status: Expired due to Fees

First Claim

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1. A method for improving optical interactance measurements comprising the steps of:

passing illumination along a plurality of different transmission paths through an interior portion of a material having a characteristic to be measured;

defining each of said paths by corresponding and separated surface areas on said material, one of said surface areas for passing illumination into said material and the second of said surface areas for passing transmitted illumination from said material for detection, at least one of said surface areas of each of said paths being extended in length at substantially constant spacing from the other surface area of said each of said paths, the total length of said extended surface area of said each of said paths being substantially greater than the distance separating said corresponding and separated surface areas defining said each of said paths;

providing optical directionality for radiation passing through at least one of said extended surface areas by orienting the optical axes at the respective probe surface area at an angle with respect to the surface of said material and generally towards the said corresponding and separated surface area on said material;

sensing a plurality of independent signals developed at the same time or in rapid sequence representing optical information obtained from within said material in response to said illumination passing along said different paths, each independent signal corresponding to a particular path; and

processing said signals in accordance with appropriate modeling techniques to determine qualitative or quantitative characteristics of the material.

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Abstract

Apparatus and a method are disclosed for the simultaneous or rapid sequential use of two or more different separations between the source and detector of the measuring apparatus to obtain spectral measurement data in diffuse transmission or “interaction” modes of collecting optical information from a specimen. The method and apparatus subsequently combine separate data taken from two or more different pathlengths to provide discrimination against undesired information while preserving or enhancing desired information. Additional reference information to normalize the optical signal is also provided. The optical and mechanical design of the optical probe also provides for transmittance, reflectance and interactance measurements on small amounts of specimen.

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45 Claims

1. A method for improving optical interactance measurements comprising the steps of:
- passing illumination along a plurality of different transmission paths through an interior portion of a material having a characteristic to be measured;
  
  defining each of said paths by corresponding and separated surface areas on said material, one of said surface areas for passing illumination into said material and the second of said surface areas for passing transmitted illumination from said material for detection, at least one of said surface areas of each of said paths being extended in length at substantially constant spacing from the other surface area of said each of said paths, the total length of said extended surface area of said each of said paths being substantially greater than the distance separating said corresponding and separated surface areas defining said each of said paths;
  
  providing optical directionality for radiation passing through at least one of said extended surface areas by orienting the optical axes at the respective probe surface area at an angle with respect to the surface of said material and generally towards the said corresponding and separated surface area on said material;
  
  sensing a plurality of independent signals developed at the same time or in rapid sequence representing optical information obtained from within said material in response to said illumination passing along said different paths, each independent signal corresponding to a particular path; and
  
  processing said signals in accordance with appropriate modeling techniques to determine qualitative or quantitative characteristics of the material.

2. Apparatus for improving optical interactance, transmittance and reflectance measurements comprising:
- an elongated probe having a body portion and a tip portion, the body portion comprising a central tubular element surrounded by an annular outer element;
  
  the tip portion having a central aperture which communicates with said central tubular element and a plurality of rings which communicate with said annular outer element;
  
  the rings in said tip portion being angled with respect to the longitudinal axis of the probe;
  
  a number of fiber optic bundles whose number corresponds to said plurality of rings being disposed within said outer element, each bundle being arranged at one end to exit at a respective ring and, at the other end, at least one such bundle being connected to a source of illumination; and
  
  optical means disposed in the central tubular element for receiving optical information resulting from applied illumination to a specimen from said central aperture from different paths through a specimen and for conveying said information to a sensing device so as to develop signals representing said specimen optical information.
- View Dependent Claims (3, 4, 5, 6, 7, 8, 9)
- - 3. The apparatus of claim 2 wherein each fiber optic bundle is arranged at the other end to be connected to a source of illumination.
  - 4. The apparatus of claim 2 also including means to process said signals in accordance with appropriate modeling techniques to minimize inaccuracies in spectroscopic determination of qualitative or quantitative characteristics of the specimen.
  - 5. The apparatus of claim 2 wherein said tip portion and fiber optic elements at the tip portion are angled at approximately 26E with respect to the longitudinal axis of the probe.
  - 6. The apparatus of claim 2 including at least one lens disposed in said central tubular element for focusing the optical information received in said central aperture and means responsive to the focused information for forming a signal representing said information.
  - 7. The apparatus of claim 6 wherein said means responsive to the focused information includes a fiber optic element for conveying the focused optical information to a detector responsive to the optical information conveyed by the fiber optic element.
  - 8. The apparatus of claim 6 including means for allowing the focusing of said lenses to be changed.
  - 9. The apparatus of claim 2 also including fiber optic means and a detector for providing a signal representative of the illumination received by the specimen.

10. In a method of using apparatus for improving optical transmittance and reflectance measurements comprising means for providing illumination to a specimen having a characteristic to be measured along a plurality of different paths, at a probe tip of said apparatus, means for sensing optical information, at a central aperture of said probe tip, developed by said illumination provided from an illuminated specimen, means, responsive to said sensed optical information, for developing a plurality of independent signals corresponding in number to said plurality of paths, said signals representing said optical information obtained from said specimen, and means for processing said signals in accordance with appropriate modeling techniques to minimize inaccuracies in spectroscopic determination of quantitative or qualitative characteristics of the specimen, said method including the step of providing a further source of illumination, arranging said probe tip adjacent a near side of a specimen of small size, arranging the further source of illumination on a far side of said specimen, and using said probe tip so that reflected energy from said specimen is directed to said central aperture and/or energy transmitted by said further source through said specimen is directed to said central aperture.
- View Dependent Claims (11)
- - 11. In a method as in claim 10 including the step of selectively choosing an operational mode of reflectance, transmittance or combined reflectance and transmittance by selectively applying said illumination and selectively sensing reflected or transmitted illumination.

12. In a method of using apparatus for improving optical transmittance and reflectance measurements comprising means for providing illumination to a specimen having a characteristic to be measured along a plurality of different paths at a probe tip of said apparatus, means for sensing optical information, at a central aperture of said probe tip, developed by said illumination provided from an illuminated specimen, means, responsive to said sensed optical information, for developing a plurality of independent signals corresponding in number to said plurality of paths, said signals representing said optical information obtained from said specimen, and means for processing said signals in accordance with appropriate modeling techniques to minimize inaccuracies in spectroscopic determination of quantitative or qualitative characteristics of the specimen, said method including the steps of providing a further detector for developing an electrical signal responsive to illumination, arranging said probe tip adjacent a near side of a specimen of small size, arranging said further detector on a far side of said specimen, and using said probe tip so that reflected energy from said specimen is directed to said central aperture and/or energy transmitted by said probe is detected by said further detector.
- View Dependent Claims (13)
- - 13. In a method as in claim 12 including the step of selectively choosing an operational mode of reflectance, transmittance or combined reflectance and transmittance by selectively applying said illumination and selectively sensing reflected or transmitted illumination.

14. Apparatus for improving optical interactance, and transmittance measurements comprising:
- an elongated probe having a body portion and a tip portion, the body portion comprising a central tubular element surrounded by an annular outer element;
  
  the tip portion having a central aperture which communicates with said central tubular element and a plurality of rings which communicate with said annular outer element;
  
  a plurality of fiber optic bundles whose number corresponds to said plurality of rings being disposed within said outer element, each bundle being arranged annularly within a respective ring at said tip end for receiving optical information from within a particular material and, at the other end, each bundle being adapted to be connected to a detector for developing an independent signal corresponding to an illumination path through said material; and
  
  said central tubular element containing optical elements connected with a source of illumination, which illumination will exit at the central aperture.

15. The apparatus of claim wherein 14 said rings in said tip portion are angled with respect to the longitudinal axis of the probe.

16. A process for improving optical interactance measurements comprising the steps of:
- passing illumination along a plurality of different transmission paths through an interior portion of a material having a characteristic to be measured;
  
  defining each of said transmission paths by corresponding and separated surface areas on said material, one of said corresponding and separated surface areas for passing transmitted illumination into said material as a beginning of a first transmission path and a second of said corresponding and separated surface areas for passing transmitted illumination from said material for detection as an end of the first transmission path, at least one of said corresponding and separated surface areas of each of said transmission paths being extended in length as a ring shape or slit shape on said surface at substantially constant spacing from the other corresponding and separated surface area of said each of said paths, the total length of said ring or slit surface area of said each of said transmission paths being substantially greater than the mean distance separating said corresponding and separated surface areas defining each of said transmission paths;
  
  sensing a plurality of independent signals developed at the same time or in rapid sequence representing optical information obtained from a spectrum related to analytes and interferences within said material in response to said illumination passing alone different transmission paths, each signal corresponding to a particular transmission path; and
  
  processing and combining said signals in accordance with appropriate chemometric modeling techniques and determination of model parameters during the calibration process to determine qualitative characteristics of the material, including the step of defining at least one of said paths and said surface areas by areas on opposite surfaces of said material.

17. A method for improving optical interactance measurements comprising the steps of:
- passing illumination along a plurality of different paths through an interior portion of a material having a characteristic to be measured;
  
  defining each of said paths by corresponding and separated surface areas on said material, at least one of said surface areas of one of said paths being extended in length at substantially constant spacing from the other surface area of said one path;
  
  sensing a plurality of independent signals developed at the same time or in rapid sequence representing optical information obtained from within said material in response to said illumination passing along said different paths, each independent signal corresponding to a particular path; and
  
  processing said signals in accordance with appropriate modeling techniques to determine qualitative or quantitative characteristics of the material;
  
  wherein said steps of passing illumination and sensing are provided by an instrument for said interactance measurement and said method further includes the steps of moving said instrument a predetermined distance away from said material and performing a reflectance measurement of said material.

18. Apparatus for optical interactance measurements of an interior portion of a material, said measurements being effected by passing illumination through portions of the material comprising:
- apertures for defining corresponding and separated surface areas on said material for defining each of a plurality of transmission paths through an interior portion of said material, one of said corresponding and separated surface areas for passing illumination into said material as beginning of a first transmission path and the second of said corresponding and separated surface areas for passing illumination from said material for detection as an end of the first transmission path, at least one of said corresponding and separated surface areas of each of said transmission paths being extended in length as a ring shape or slit shape on said surface and substantially constantly spaced from its corresponding surface area, the total length of said ring shape or slit shape area of each of said transmission paths being substantially greater than the mean distance separating said corresponding and separated surface areas defining said each of said transmission paths;
  
  illuminator for directing illumination onto said illumination surface areas and along said transmission paths;
  
  sensor for sensing optical information indicative of said interior portion of said material developed by illumination passing along said transmission paths to said detection surface areas of said transmission paths;
  
  signaler responsive to said sensing means, for developing a plurality of independent signals corresponding in number to said plurality of transmission paths, each of said signals representing said optical information obtained in a spectrum related to analytes and interferences within said material; and
  
  processor for combining and processing said signals in accordance with appropriate chemometric modeling techniques and determination of model parameters during the calibration process to determine quantitative or qualitative characteristics of said material, wherein said aperture means are operative to define one surface area of at least two of said paths to be common to said two paths, and wherein said aperture means are operative to define said common surface areas as the detection surface area.

19. Apparatus for optical interactance measurements of an interior portion of a material, said measurements being effected by passing illumination through portions of the material comprising;
- apertures for defining corresponding and separated surface areas on said material for defining each of a plurality of transmission paths through an interior portion of said material, one of said corresponding and separated surface areas for passing illumination into said material as beginning of a first transmission path and the second of said corresponding and separated surface areas for passing illumination from said material for detection as an end of the first transmission path, at least one of said corresponding and separated surface areas of each of said transmission paths being extended in length as a ring shape or slit shape on said surface and substantially constantly spaced from its corresponding surface area, the total length of said ring shape or slit shape area of each of said transmission paths being substantially greater than the mean distance separating said corresponding and separated surface areas defining said each of said transmission paths;
  
  illuminator for directing illumination onto said illumination surface areas and alone said transmission paths;
  
  sensor for sensing optical information indicative of said interior portion of said material developed by illumination passing along said transmission paths to said detection surface areas of said transmission paths;
  
  signaler responsive to said sensing means, for developing a plurality of independent signals corresponding in number to said plurality of transmission paths, each of said signals representing said optical information obtained in a spectrum related to analytes and interferences within said material; and
  
  processor for combining and processing said signals in accordance with appropriate chemometric modeling techniques and determination of model parameters during the calibration process to determine quantitative or qualitative characteristics of said material, wherein said aperture means are operative to define said illumination and sensing areas for at least one of said paths to be on opposite surfaces of said material.

20. A method for effecting optical interactance and reflectance measurements relative to a material, having a characteristic to be measured, comprising the steps of:
- providing optical means, at a first predetermined distance from a surface of said material, for defining on said material at least one illumination surface area and at least one detection surface area which are separated said surface areas on said material defining at least one transmission path through an interior portion of said material for performing interactance measurements, at least one of said surface areas of one of said paths being extended in length at substantially constant spacing from the other surface of said one path;
  
  providing said optical means at a second predetermined distance, relative to the surface of said material, for defining illumination and detection surface areas on said material which are at least partially superimposed thereby defining a surface area on said material for performing diffuse reflectance measurements;
  
  illuminating said illumination area and detecting optical information received from said detection area for developing signals representing said optical information obtained from said material in response to said illumination; and
  
  processing said signals detected by said optical means in accordance with appropriate modeling techniques to determine quantitative or qualitative characteristics of the material.
- View Dependent Claims (21, 22, 23, 24, 25, 26, 27, 28)
- - 21. The method as in claim 20 wherein said optical means, at said first distance, defines a plurality of distinct illumination surface areas and at least one detection surface area, whereby a plurality of different transmission paths are defined in said specimen.
  - 22. The method as in claim 21 herein said optical means, at said first distance, defines at least one of said illumination surface areas as a ring shape or slit shape.
  - 23. The method as in claim 21 wherein said optical means, at said first distance, defines said at least one detection surface area as extended in length as a ring shape or slit shape.
  - 24. The method as in claim 20 wherein said optical means, at said first distance, defines at least one of said illumination surface areas and said at least one detection areas as parallel ring shapes or slit shapes.
  - 25. The method as in claim 20 wherein said optical means, at said first distance, defines at least one of said surface areas to be extended as a ring shape or slit shape and to define another of said surface areas to be distinct and contained within a boundary defined by said ring shape or slit shape surface area.
  - 26. The method as in claim 20 wherein said optical means, at said first distance, defines said illumination and detection surface areas to be parallel.
  - 27. The method as in claim 20 wherein said optical means, at said first distance, defines said illumination and detection surface areas to be concentric.
  - 28. The method as in claim 20 wherein said optical means, at a plurality of said second distances, defines a plurality of illumination and detection surface areas which are at least partially superimposed corresponding to said plurality of said second distances.

29. A method for improving optical interactance measurements of a material comprising the steps of:
- (a) passing illumination along a plurality of different paths through an interior portion of a material having a characteristic to be measured;
  
  (b) said different paths of illumination each comprising a distribution of substantially equidistant illumination means surrounding a central detection aperture;
  
  (c) said central detection aperture comprising optical connections within said central detection aperture which are connected to a detection system;
  
  (d) sensing in said detection system a plurality of independent signals developed at the same time or in rapid sequence representing optical information obtained from within said material in response to said illumination passing along said different paths, each independent signal corresponding to a particular path; and
  
  (e) processing said signals in accordance with modeling techniques to determine qualitative or quantitative characteristics of the material.
- View Dependent Claims (30, 31, 32, 33, 34, 35, 36, 37, 38)
- - 30. The process of claim 29 wherein said central detection aperture consists of optical connections within said central detection aperture.
  - 31. The process of claim 30 wherein said optical connections within said central aperture comprises fiber optics.
  - 32. The process of claim 31 wherein said central detection aperture consists of fiber optics which consist of a detection system.
  - 33. The process of claim 30 wherein said distribution of substantially equidistant illumination means comprises a circular distribution of illumination means.
  - 34. The process of claim 33 wherein substantially equidistant illumination means comprise fiber optics.
  - 35. The process of claim 34 wherein said fiber optics within each circular distribution of illumination means are within individual ring apertures surrounding a central detection aperture and are present within an aperture which is sloped towards said central detection aperture.
  - 36. The process of claim 34 wherein said fiber optics within individual ring apertures surrounding a central detection aperture are present within an aperture which is sloped towards said central detection aperture.
  - 37. The process of claim 30 wherein substantially equidistant illumination means comprise fiber optics.
  - 38. The process of claim 30 wherein fiber optics within individual ring apertures surrounding a central detection aperture are within apertures which are concentrically spaced around said central detection aperture.

39. Apparatus for improving optical interactance, transmittance and reflectance measurements comprising:
- (a) a probe comprising a body portion and a contacting portion;
  
  (b) said contacting portion comprising;
  
  (i) a central detection area comprising at least one optical connection to a detection system; and
  
  (ii) at least two outer illumination areas, each outer illumination area being connected to illumination means;
  
  (c) said at least two outer illumination areas being optically connected to at least one source of illumination which can provide different signals at the same time or in rapid sequence to each of said at least two outer illumination areas;
  
  (d) said at least two outer illumination areas and said central detection area forming at least two different paths of illumination between said at least two illumination areas and said central detection are, said different paths of illumination each comprising a distribution of substantially equidistant illumination means surrounding said central detection area.
- View Dependent Claims (40, 41, 42, 43, 44)
- - 40. The apparatus of claim 39 wherein said central detection area consists of optical connections to a detector system.
  - 41. The apparatus of claim 40 wherein said optical connection of said central detection area to said detection system comprises fiber optics.
  - 42. The apparatus of claim 41 wherein said optical connection of said at least two illumination areas and said at least one source of illumination comprises fiber optics.
  - 43. The apparatus of claim 41 wherein said central detection area consists of optical fibers which consist of a detection system.
  - 44. The apparatus of claim 40 wherein said optical connection of said at least two illumination areas and said at least one source of illumination comprises fiber optics.

45. A method for improving optical interactance measurements comprising the steps of:
- passing illumination along at least one transmission path through an interior portion of a material having a characteristic to be measured, said material having a surface;
  
  defining said at least one path by transmission path optically transmissively connecting corresponding and separated surface areas on said surface of said material, one of said surface areas optically transmissively connected to a first of said corresponding and separated areas for passing illumination into said material and the second of said surface areas optically transmissively connected to a second of said corresponding and separated areas for passing transmitted illumination from said material for detection, at least one of said surface areas of said at least one path having a dimension with a total length being extended in length at substantially constant spacing from a similar dimension of the other surface area of said at least one path, the total length of said extended surface area of said at least one path being substantially greater than the distance separating said corresponding and separated surface areas defining said at least one path;
  
  providing optical directionality for radiation passing through at least one of said extended surface areas by orienting the optical axes at the respective probe surface area at an angle with respect to the surface of said material and generally towards the said corresponding and separated surface area on said material;
  
  sensing a plurality of independent signals developed at the same time or in rapid sequence representing optical information obtained from within said material in response to said illumination passing along said at least one path, each independent signal corresponding to a particular path, and processing said signals in accordance with appropriate modeling techniques to determine qualitative or quantitative characteristics of the material.

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Current Assignee
Edward W. Stark
Original Assignee
Edward W. Stark
Inventors
Stark, Edward W.
Primary Examiner(s)
Rosenberger, Richard A.

Application Number

US08/818,289
Time in Patent Office

3,546 Days
Field of Search

356/446, 356/434, 356/445, 356/41, 356/239, 356/442, 356/239.1, 385/12, 385/115, 250/227.28
US Class Current

356/446
CPC Class Codes

G01N 21/255 Details, e.g. use of specia...

G01N 21/474 Details of optical heads th...

Method and apparatus for optical interactance and transmittance measurements

First Claim

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Method and apparatus for optical interactance and transmittance measurements

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