Photosensing optical cavity output light
First Claim
1. A device comprising:
- an optical cavity component that includes at least one optical cavity that can contain analyte;
with analyte absent, the optical cavity providing output light with a first intensity-energy function;
with an analyte present in the cavity, the optical cavity providing analyte-affected output light from the cavity, the analyte-affected output light having a second intensity-energy function different than the first intensity-energy function;
a photosensing IC component; and
a laterally varying transmission component that, in response to the first and second intensity-energy functions, provides first and second laterally varying photon energy distributions, respectively, on the photosensing IC component, the first and second distributions being different;
in response to the first and second distributions, the photosensing IC component providing first and second sensing results, respectively;
the first and second sensing results each including at least one of position, size, and intensity information about the respective distribution, the first and second sensing results being different.
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Abstract
An optical cavity, such as a laser or transmissive cavity, that can contain an analyte provides a different intensity-energy function with analyte present than when absent. The intensity-energy functions can, for example, include respective peaks that are different in at least one of central energy, amplitude, contrast, and full width half maximum (FWHM) (or other intermediate intensity width). Each intensity-energy function can include a set of modes in which the optical cavity provides output light. A laterally varying transmission component, such as a layered linearly varying filter, responds to the intensity-energy functions by providing different laterally varying energy distributions to a photosensing IC, and the distributions are also different, such as in position, size, or intensity. In response, the photosensing IC provides sensing results that are also different. The sensing results can be used to obtain information about the analyte, such as its refractive index or absorption coefficient.
78 Citations
24 Claims
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1. A device comprising:
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an optical cavity component that includes at least one optical cavity that can contain analyte;
with analyte absent, the optical cavity providing output light with a first intensity-energy function;
with an analyte present in the cavity, the optical cavity providing analyte-affected output light from the cavity, the analyte-affected output light having a second intensity-energy function different than the first intensity-energy function;a photosensing IC component; and a laterally varying transmission component that, in response to the first and second intensity-energy functions, provides first and second laterally varying photon energy distributions, respectively, on the photosensing IC component, the first and second distributions being different;
in response to the first and second distributions, the photosensing IC component providing first and second sensing results, respectively;
the first and second sensing results each including at least one of position, size, and intensity information about the respective distribution, the first and second sensing results being different. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
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9. A system comprising:
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an optical cavity component that includes at least one optical cavity that can contain analyte;
with analyte absent, the optical cavity providing output light with a first intensity-energy function;
with an analyte present in the cavity, the optical cavity providing analyte-affected output light from the cavity, the analyte-affected output light having a second intensity-energy function different than the first intensity-energy function;a photosensing IC component; a laterally varying transmission component that, in response to the first and second intensity-energy functions, provides first and second laterally varying photon energy distributions, respectively, on the photosensing IC component, the first and second distributions being different;
in response to the first and second distributions, the photosensing IC component providing first and second sensing results, respectively;
the first and second sensing results each including at least one of position, size, and intensity information about the respective distribution, the first and second sensing results being different; andcontrol circuitry that controls at least one of the optical cavity component, the photosensing IC component, and the laterally varying transmission component. - View Dependent Claims (10, 11)
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12. A method of using an optical cavity that can contain analyte;
- with analyte absent, the optical cavity providing output light with a first intensity-energy function;
the method comprising;with an analyte present in the cavity, providing analyte-affected output light from the cavity;
as a result of the analyte'"'"'s presence, the analyte-affected output light having a second intensity-energy function different than the first intensity-energy function; andtransmitting the analyte-affected output light from the optical cavity through a layered transmission structure that provides light with laterally varying photon energy distributions on a photosensing IC;
in response, the photosensing IC providing sensing results that depend on at least one of position, size, and intensity. - View Dependent Claims (13, 14, 15, 16)
- with analyte absent, the optical cavity providing output light with a first intensity-energy function;
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17. A method of obtaining information about analytes using a Fabry-Perot cavity that provides output light in a set of two or more modes;
- when illuminated at first and second transmission modes in the set with analyte absent, the cavity providing output light with first and second intensity-energy peaks, respectively;
the method comprising;with an analyte present in the cavity, illuminating the cavity at the first and second transmission modes;
in response, the cavity providing analyte-affected output light in the first and second transmission modes with third and fourth intensity-energy peaks, respectively;
the third and fourth intensity-energy peaks being different than the first and second peaks, respectively;transmitting the analyte-affected output light from the cavity through a layered transmission structure that provides light with a laterally varying photon energy distribution to an IC with one or more photosensing components, the laterally varying photon energy distribution including respective light spots on the photosensing components for the first and second modes;
the first mode'"'"'s light spot having at least one of a different position, a different size, and a different intensity in response to the third peak than to the first peak and the second mode'"'"'s light spot having at least one of a different position, a different size, and a different intensity in response to the fourth peak than to the second peak;
the photosensing components producing first sensing results that depend on at least one of position, size, and intensity of the first mode'"'"'s light spot and second sensing results that depend on at least one of position, size, and intensity of the second mode'"'"'s light spot; andusing the first and second sensing results to obtain information about the analyte. - View Dependent Claims (18, 19, 20, 21)
- when illuminated at first and second transmission modes in the set with analyte absent, the cavity providing output light with first and second intensity-energy peaks, respectively;
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22. A method of obtaining information about analytes using a laser cavity;
- when stimulated with analyte absent, the laser cavity providing output light within a first subrange of photon energies;
the method comprising;with an analyte present in the laser cavity, stimulating the laser cavity so that it provides analyte-affected output light within a second subrange of photon energies different than the first subrange; transmitting the analyte-affected output light from the laser cavity through a layered transmission structure that provides light with laterally varying photon energy distributions to a photosensing IC;
in response to the analyte-affected output light in the second subrange, the layered transmission structure providing a light spot on the photosensing IC;
in response, the photosensing IC providing sensing results that depend on the light spot'"'"'s position; andusing the sensing results to obtain information about the analyte. - View Dependent Claims (23, 24)
- when stimulated with analyte absent, the laser cavity providing output light within a first subrange of photon energies;
Specification