Methods and systems using photonic crystal-based integrated computational elements

The invention claimed is: 1. A method, comprising: selecting a photonic crystal (PhC) structure with a design suite stored in a non-transitory, computer-readable medium; obtaining a transmission spectrum for the PhC structure; determining a predictive power of a PhC-based integrated computational element (ICE) for a characteristic of a sample with the transmission spectrum and a database of spectra for calibrated samples; adjusting the transmission spectrum to improve the predictive power; and fabricating the PhC structure for the PhC-based ICE when the predictive power surpasses a pre-selected threshold. 2. The method of claim 1 , wherein said selected PhC structure has a transmission function of light propagating through the PhC structure, said adjusting the transmission spectrum including adjusting the transmission function of the selected PhC structure, and wherein fabricating the PhC structure further comprises finding a PhC structure having a transmission function similar to the adjusted transmission function. 3. The method of claim 1 , wherein adjusting the transmission spectrum to improve the predictive power comprises one of reducing a prediction error, reducing a standard error of calibration, reducing a standard error of prediction, increasing a sensitivity, increasing a slope of a calibration curve, increasing a signal-to-noise ratio, and increasing a mean optical transmission value as tested against a known value for the characteristic of the sample. 4. The method of claim 1 , wherein adjusting the transmission spectrum to improve the predictive power comprises one of displacing a center wavelength of a band-pass of an electromagnetic radiation transmitted through the PhC structure, increasing a transmission dynamic range of the band-pass of the electromagnetic radiation transmitted through the PhC structure, and adjusting the bandwidth of the band-pass of the electromagnetic radiation transmitted through the PhC structure. 5. The method of claim 1 , wherein selecting a PhC structure further comprises: selecting an optical input side and an optical output side of the PhC structure; selecting a PhC medium having a first index of refraction; and selecting at least one geometric feature in a PhC substrate embedded in the medium, the PhC substrate having a second index of refraction, wherein selecting at least one geometric feature comprises comparing an output spectrum resulting at the optical output side of the PhC with a regression vector for a characteristic of a sample being analyzed. 6. The method of claim 5 , wherein the second index of refraction is different from the first index of refraction. 7. The method of claim 1 , further comprising configuring the PhC-based ICE for a sensor in one of a measurement-while-drilling tool or a logging-while-drilling tool. 8. The method of claim 1 , further comprising configuring the PhC-based ICE for a sensor in a wireline tool. 9. A method, comprising: selecting a desired transmission spectrum for an integrated computational element (ICE); identifying a photonic crystal (PhC) structure having a transmission spectrum comparable to the desired transmission spectrum; obtaining the transmission spectrum for the PhC structure; determining a predictive power of a PhC-based ICE for a characteristic of a sample with the obtained transmission spectrum and a database of spectra for calibrated samples; adjusting the transmission spectrum of the PhC structure to improve the predictive power of the PhC-based ICE; and fabricating the PhC structure for the PhC-based ICE when the predictive power surpasses a pre-selected threshold. 10. The method of claim 9 , wherein said selected PhC structure has a transmission function of light propagating through the PhC structure, said adjusting the transmission spectrum including adjusting the transmission function of the selected PhC structure, and wherein fabricating the PhC structure further comprises finding a PhC structure having a transmission function similar to the adjusted transmission function. 11. The method of claim 9 , wherein adjusting the transmission spectrum of the PhC structure comprises at least one of modifying a geometric feature of the PhC structure, modifying an index of refraction of a medium in the PhC structure, and modifying an index of refraction of a substrate in the PhC structure. 12. The method of claim 9 , wherein the PhC structure comprises a 2D substrate, the method further comprising selecting a center-to-center distance in a plurality of apertures on the 2D substrate based on the corresponding power of prediction. 13. The method of claim 9 , further comprising estimating a detector signal from an interacted light transmitted through the PhC structure, wherein selecting a desired transmission spectrum comprises determining that the detector signal is proportional to a scalar product between the interacted light and a linear regression vector associated with the characteristic of the sample being analyzed. 14. The method of claim 9 , wherein fabricating the PhC structure for the PhC-based ICE comprises selecting at least one geometric feature in a PhC substrate embedded in a medium based on a comparison of an output spectrum resulting at an optical output side of the PhC with a regression vector for a characteristic of a sample being analyzed. 15. The method of claim 14 , wherein selecting the at least one geometric feature comprises selecting a diameter for an aperture in a plurality of apertures formed on the PhC substrate. 16. The method of claim 9 , further comprising configuring the PhC-based ICE for a sensor in one of a measurement-while-drilling tool or a logging-while-drilling tool. 17. The method of claim 9 , further comprising configuring the PhC-based ICE for a sensor in a wireline tool. 18. A computer system comprising: a processor; and a memory device that stores commands executed by the processor to perform a method comprising: selecting a photonic crystal (PhC) structure with a design suite stored in a non-transitory, computer-readable medium; obtaining a transmission spectrum for the PhC structure; determining a predictive power of a PhC-based integrated computational element (ICE) for a characteristic of a sample with the transmission spectrum and a database of spectra for calibrated samples; adjusting the transmission spectrum to improve the predictive power; and providing the PhC structure for the PhC-based ICE when the predictive power surpasses a pre-selected threshold. 19. The computer system of claim 18 , wherein adjusting the transmission spectrum to improve the predictive power comprises one of displacing a center wavelength of a band-pass of an electromagnetic radiation transmitted through the PhC structure, increasing a transmission dynamic range of the band-pass of the electromagnetic radiation transmitted through the PhC structure, and adjusting the bandwidth of the band-pass of the electromagnetic radiation transmitted through the PhC structure. 20. The computer system of claim 18 , wherein the method further includes: selecting an optical input side and an optical output side of the PhC structure; selecting a PhC medium having a first index of refraction; and selecting at least one geometric feature in a PhC substrate embedded in the medium, the PhC substrate having a second index of refraction, wherein selecting at least one geometric feature comprises comparing an output spectrum resulting at the optical output side of the PhC with a regression vector