Resonant spectrophone system noise elimination
First Claim
1. In a spectrophone system wherein radiant energy from a radiant energy source is directed into a chamber containing a fluent sample with respect to which certain absorption data is to be obtained in the presence of background noise by detecting pressure variations within the chamber and generating a signal containing both absorption data and noise components, the radiant energy having a component corresponding to an absorption characteristic of the fluent sample which is being investigated and said chamber having a geometry allowing a resonant wave to be established in the chamber, the improvement for significantly attenuating the noise component relative to the absorption data component which comprises means of creating a resonant wave in the chamber by excitation from the radiant energy source, means for monitoring pressure variations at a location within the chamber corresponding to a peak of the resonant wave to develop a corresponding peak signal containing both true absorption data and noise components, means for monitoring pressure variations at a location within the chamber corresponding to a nodal point of the resonant wave and generating a corresponding nodal signal representing background noise, and means for modifying the peak signal by the nodal signal to remove the noise component from the peak signal and yield a true absorption data signal.
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Abstract
A resonant spectrophone system has a laser arranged to direct a laser beam into a chamber containing gas to be analyzed wherein absorption data relative to the gas constituents is obtained by detecting pressure variations within the chamber. The laser is operated such that the laser beam passing through the chamber generates a resonant wave therein. Pressure variations within the chamber are monitored at locations corresponding to nodal and/or peak points of the resonant wave. The nodal point signals represent background noise and are subtracted from the peak point signals to remove noise components from the peak point signals or out-of-phase nodal signals are subtracted to perform this function and thereby yield signals which more accurately represent the absorption data relative to the gas constituents.
27 Citations
8 Claims
- 1. In a spectrophone system wherein radiant energy from a radiant energy source is directed into a chamber containing a fluent sample with respect to which certain absorption data is to be obtained in the presence of background noise by detecting pressure variations within the chamber and generating a signal containing both absorption data and noise components, the radiant energy having a component corresponding to an absorption characteristic of the fluent sample which is being investigated and said chamber having a geometry allowing a resonant wave to be established in the chamber, the improvement for significantly attenuating the noise component relative to the absorption data component which comprises means of creating a resonant wave in the chamber by excitation from the radiant energy source, means for monitoring pressure variations at a location within the chamber corresponding to a peak of the resonant wave to develop a corresponding peak signal containing both true absorption data and noise components, means for monitoring pressure variations at a location within the chamber corresponding to a nodal point of the resonant wave and generating a corresponding nodal signal representing background noise, and means for modifying the peak signal by the nodal signal to remove the noise component from the peak signal and yield a true absorption data signal.
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6. In a spectrophone system wherein radiant energy from a radiant energy source is directed into a chamber containing a fluent sample with respect to which certain absorption data is to be obtained in the presence of background noise by detecting pressure variations within the chamber and generating a signal containing both absorption data and noise components, the radiant energy having a component corresponding to an absorption characteristic of the fluent sample which is being investigated and said chamber having a geometry allowing a resonant wave to be established in the chamber, an improved method for significantly attenuating the noise component relative to the absorption data component which comprises creating a resonant wave in the chamber, monitoring pressure variations at a location within the chamber corresponding to a peak of the resonant wave to develop a corresponding peak signal containing both true absorption data and noise components, monitoring pressure variations at a location within the chamber corresponding to a nodal point of the resonant wave and generating a corresponding nodal signal representing background noise, and modifying the peak signal by the nodal signal to remove the noise component from the peak signal and yield a true absorption data signal.
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7. In a spectrophone system wherein radiant energy from a radiant energy source is directed into a chamber containing a fluent sample with respect to which certain absorption data is to be obtained in the presence of background noise by detecting pressure variations within the chamber and generating signals containing both absorption data and noise components, the radiant energy having a component corresponding to an absorption characteristic of the fluent sample which is being investigated and said chamber having a geometry allowing a resonant wave to be established in the chamber, the improvement for significantly attenuating the noise component relative to the absorption data component so as to yield a true absorption data signal comprising means creating a state of resonance in the chamber by excitation from the radiant energy source wherein a half wave or integral multiple thereof is established in the chamber, means for monitoring pressure variations at a location within the chamber corresponding to a peak point of the resonant half wave or multiple thereof and generating a peak signal containing absorption data and noise components, means for monitoring pressure variations at another location within the chamber corresponding to a point of the half wave or multiple thereof where the resultant signal when processed with the peak signal will yield a true absorption data signal, and means for processing said resultant signal with said peak signal to yield such a true absorption data signal.
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8. In a spectrophone system wherein radiant energy from a radiant energy source is directed into a chamber containing a fluent sample with respect to which certain absorption data is to be obtained in the presence of background noise by detecting pressure variations within the chamber and generating signals containing both absorption data and noise components, the radiant energy having a component corresponding to an absorption characteristic of the fluent sample which is being investigated and said chamber having a geometry allowing a resonant wave to be established in the chamber, an improved method for significantly attenuating the noise component relative to the absorption data component so as to yield a true absorption data signal comprising creating a state of resonance in the chamber by excitation from the radiant energy source wherein a half wave or integral multiple thereof is established in the chamber, monitoring pressure variations at a location within the chamber corresponding to a peak point of the resonant half wave or multiple thereof and generating a peak signal containing absorption data and noise components, monitoring pressure variations at another location within the chamber corresponding to a point of the half wave or multiple thereof where the resultant signal when processed with the peak signal will yield a true absorption data signal, and processing said resultant signal with said peak signal to yield such a true absorption data signal.
Specification
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- Resources
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Current AssigneeOptimetrics, Inc (DCS Corporation)
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Original AssigneeOptimetrics, Inc (DCS Corporation)
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InventorsSpellicy, Robert L.
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Primary Examiner(s)Ciarlante, Anthony V.
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Application NumberUS06/296,774Time in Patent Office796 DaysField of Search73/24, 73/579US Class Current73/24.02CPC Class CodesG01N 2021/1704 in gasesG01N 21/1702 with opto-acoustic detectio...G01N 2291/015 Attenuation, scatteringG01N 2291/0421 Longitudinal wavesG01N 2291/103 one emitter, two or more re...G01N 29/036 by measuring frequency or r...G01N 29/223 Supports, positioning or al...G01N 29/2425 optoacoustic fluid cells th...G01N 29/46 by spectral analysis, e.g. ...
