Method and system of compensating for signal artifacts in a fiber-optic sensing system

US 5,300,769 A
Filed: 12/29/1992
Issued: 04/05/1994
Est. Priority Date: 12/29/1992
Status: Expired due to Fees

First Claim

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1. A method of compensating for signal artifacts in a sensor for monitoring parameters that includes a distal probe, a source of light signals of a first wavelength, a source of light signals of a second wavelength, at least one optical waveguide for transmitting primary light signals from the source of light signals of a first wavelength and the source of light signals of a second wavelength to the distal probe and for transmitting secondary light signals from the distal probe to at least one sensor for detecting the secondary light signals, respective secondary light signals being derived from respective primary light signals transmitted to the distal probe, wherein the signal artifacts result from changes in the transmission characteristics of the optical waveguide caused by displacement of the optical waveguide, the method comprising:

sampling the primary light signal from the source of light signals of a first wavelength over a first interval; and

sampling the primary light signal from the source of light signals of a second wavelength over a second interval, wherein the sum of the first interval and the second interval is less than intervals over which displacement of the optical waveguide occurs.

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Abstract

A method and system for controlling the intervals during which light signals are sampled in a fiber-optic sensing system compensates for signal artifacts that are caused by movement of the fiber-optic waveguide during the sampling. The method and system sample the light signals at intervals that are shorter than the intervals during which displacement of the optical waveguide occurs in normal use. The short-sampling intervals result in the individual sampling of different wavelengths of light being exposed to the same changes in transmission characteristics of the optical waveguide which causes signal artifacts. Accordingly, when subsequent processing of the collected signals occurs, the effects of the signal artifacts are compensated for.

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22 Claims

1. A method of compensating for signal artifacts in a sensor for monitoring parameters that includes a distal probe, a source of light signals of a first wavelength, a source of light signals of a second wavelength, at least one optical waveguide for transmitting primary light signals from the source of light signals of a first wavelength and the source of light signals of a second wavelength to the distal probe and for transmitting secondary light signals from the distal probe to at least one sensor for detecting the secondary light signals, respective secondary light signals being derived from respective primary light signals transmitted to the distal probe, wherein the signal artifacts result from changes in the transmission characteristics of the optical waveguide caused by displacement of the optical waveguide, the method comprising:
- sampling the primary light signal from the source of light signals of a first wavelength over a first interval; and
  
  sampling the primary light signal from the source of light signals of a second wavelength over a second interval, wherein the sum of the first interval and the second interval is less than intervals over which displacement of the optical waveguide occurs.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The method of claim 1, wherein the first interval is less than or equal to about 4 milliseconds and the second interval is less than or equal to about 4 milliseconds.
  - 3. The method of claim 1, further comprising the step of digitally demodulating the primary light signals from the sampling steps.
  - 4. The method of claim 3, further comprising the step of using the primary and secondary light signals from the digital demodulation step to determine pH and carbon dioxide levels of blood.
  - 5. The method of claim 1, further comprising sampling the secondary light signals derived from the primary light signal of the first wavelength during the first interval and sampling the secondary light signal derived from the primary light signal of the second wavelength during the second interval.
  - 6. The method of claim 5, further comprising the step of digitally demodulating the secondary light signals from the step of sampling the secondary light signals.
  - 7. The method of claim 6, further comprising the step of using the primary and secondary light signals from the digital demodulation step to determine pH and carbon dioxide levels of blood.
  - 8. The method of claim 1, wherein the primary light signal from the source of light signals of a first wavelength includes light signals of a wavelength in the green region of the visible spectrum and the primary light signal from the source of light signals of a second wavelength includes light signals of a wavelength in the near infrared region of the electromagnetic spectrum.
  - 9. The method of claim 1, further comprising sampling a signal during a third interval on the optical waveguide when the source of light signals of a first wavelength and the source of light signals of a second wavelength are not emitting.
  - 10. The method of claim 9, wherein the third interval is less than or equal to about 4 milliseconds.
  - 11. The method of claim 1, wherein the signal artifacts result from ambient light incident on the probe.

12. A method of compensating for signal artifacts in a system for monitoring parameters that includes a distal probe, a source of light signals of a first wavelength, a source of light signals of a second wavelength, at least one optical waveguide for transmitting primary light signals from the source of light signals of a first wavelength and the source of light signals of a second wavelength to the distal probe and for transmitting secondary light signals from the distal probe to at least one sensor for detecting the secondary light signals, respective secondary light signals being derived from respective primary light signals transmitted to the distal probe, wherein the signal artifacts result from changes in the transmission characteristics of the optical waveguide caused by displacement of the optical waveguide, the method comprising:
- sampling the secondary light signal derived from the primary light signal from the source of light signals of a first wavelength over a first interval; and
  
  sampling the secondary light signal derived from the primary light signal from the source of light signals of a second wavelength over a second interval, wherein the sum of the first interval and the second interval is less than intervals over which displacement of the optical waveguide occurs.
- View Dependent Claims (13, 14, 15, 16, 17, 18)
- - 13. The method of claim 12, wherein the first interval is less than or equal to about 4 milliseconds and the second interval is less than or equal to about 4 milliseconds.
  - 14. The method of claim 12, further comprising the step of digitally demodulating the secondary light signals from the sampling steps.
  - 15. The method of claim 12, or in the secondary light signal from the source of light signals of a first wavelength includes light signals of a wavelength in the green region of the visible spectrum in the secondary light signal from the source of light signals of a second wavelength include light signals of a wavelength in the near infrared region of the electrical magnetic spectrum.
  - 16. The method of claim 15, further comprising sampling a signal during a third interval on the optical waveguide, when the source of light signals of a first wavelength and the source of light signals of a second wavelength are not emitting.
  - 17. The method of claim 16, wherein the third interval is less than or equal to about 4 milliseconds.
  - 18. The method of claim 12, wherein the signal artifacts result from ambient light incident on the probe.

19. A system for controlling the sampling of light signals utilized by a sensor for a monitoring an unknown parameter, the sensor including a distal probe including an optical waveguide, light signals of a first wavelength being absorbed by the probe to an extent dependent upon the unknown parameter, light signals of a second wavelength being transmitted by the probe independent of the amount of the unknown parameter, source of light signals of the first wavelength optically coupled to the probe through a first optical pathway, first photodetector provided in the first optical pathway for detecting the amount of the light signal of the first wavelength emitted by the source of light signals of the first wavelength and producing a first electric signal dependent upon the amount of the light signal of a first wavelength emitted by the light source, second photodetector provided in the first optical pathway for detecting the light signals of the first wavelength attenuated by the probe and producing a second electric signal dependent upon the attenuated light signal of the first wavelength, source of light signals of the second wavelength optically coupled to the probe through the first optical pathway, the first photodetector detecting the amount of the light signal of the second wavelength emitted by the light source and producing a third electric signal dependent upon the amount of the light signal of the second wavelength emitted by the light source, the second photodetector detecting the light signal of the second wavelength transmitted by the probe and producing a fourth electric signal dependent upon the amount of the light signal of the second wavelength transmitted by the probe, the first photodetector also detecting light signals in the first optical pathway when the source of light signals of the first and second wavelengths are not emitting and producing a fifth electronic signal that depends on the detected light signals, and the second photodetector also detecting light signals in the first optical pathways when the source of light signals of the first and second wavelengths are not emitting and producing a sixth electric signal that depends on the detected light signals the system comprising:
- first signal-frequency converter connected to the first photodetector for producing a first, third, and fifth frequency signal dependent upon the first, third, and fifth electric signal from the first photodetector;
  
  second signal-frequency converter connected to the second photodetector for producing a second, fourth, and sixth frequency signal dependent upon the second, fourth, and sixth electric signal from the second photodetector;
  
  first counter for sampling the first frequency signal produced by the first signal-to-frequency converter over a first interval and the fifth frequency signal over a third interval;
  
  third counter for sampling the second frequency signal produced by the second signal-frequency converter over a first interval and the sixth frequency signal over the third interval;
  
  second counter for sampling the third frequency signal produced by the first signal-to-frequency converter over a second interval and the fifth frequency signal over the third interval;
  
  fourth counter for sampling the fourth frequency signal produced by the second frequency converter over a second interval and the sixth frequency signal over the third interval, wherein the sum of the first interval, second interval, and third interval is less than intervals during which the optical waveguide is displaced; and
  
  timer connected to the first, second, third, and fourth counters and the sources of light signals for controlling the length of the first interval, second interval, and the third interval.
- View Dependent Claims (20, 21, 22)
- - 20. The system of claim 19, wherein the sum of the first interval, second interval, and third interval is less than or equal to about 12 milliseconds.
  - 21. The system of claim 19, further comprising a first amplifier intermediate the first photodetector and the first signal-frequency converter and a second amplifier intermediate the second photodetector and the second signal-frequency converter.
  - 22. The system of claim 19, wherein the first and second photodetectors produce a voltage dependent upon the amount of the light signal detected.

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Current Assignee
Abbott Laboratories Incorporated
Original Assignee
Abbott Laboratories Incorporated
Inventors
Dahlin, Jeffrey J., Yim, Jeffrey B., Holic, John F. Jr., Duke, Steven B., Lundell, William G.
Primary Examiner(s)
Nelms, David C.
Assistant Examiner(s)
Lee, John R.

Application Number

US07/999,495
Time in Patent Office

462 Days
Field of Search

250/227.21, 250/227.23, 250/226, 356/39, 356/40, 356/41, 128/634, 128/637, 385/12, 385/13
US Class Current

250/227.23
CPC Class Codes

G01D 5/268   using optical fibres G01D5/...

G01N 2021/772   Tip coated light guide

G01N 21/7703   using reagent-clad optical ...

Method and system of compensating for signal artifacts in a fiber-optic sensing system

First Claim

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Abstract

20 Citations

22 Claims

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Method and system of compensating for signal artifacts in a fiber-optic sensing system

First Claim

1 Assignment

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Accused Products

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Abstract

20 Citations

22 Claims

Specification

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Solutions

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