Monolithic band-limited integrated computational elements

What is claimed is: 1. An optical analysis tool comprising: an integrated computational element (ICE) comprising an ICE core to process light received by the ICE from a sample, when the tool is operated, such that the processed light is related, over a wavelength range, to a characteristic of the sample, and a filter monolithically coupled to the ICE core, the filter to block light at wavelengths that are either shorter than the wavelength range or longer than the wavelength range, or both, such that the ICE outputs, when the tool is operated, the processed light that is passed by the filter, wherein each of (i) a mismatch of refractive index for the processed light across an optical interface between the ICE core and the filter and (ii) a mismatch of refractive index for the processed light across an output optical interface between the filter and an output medium downstream from the ICE is smaller than a mismatch of refractive index for the processed light if the output optical interface is between the ICE core and the output medium. 2. The optical analysis tool of claim 1 , wherein the filter is a band-pass filter to block the light at the wavelengths that are shorter and longer than the wavelength range, such that the ICE outputs, when the tool is operated, the processed light within the wavelength range. 3. The optical analysis tool of claim 1 , wherein the filter is a long-pass filter to block the light at the wavelengths that are shorter than the wavelength range, and the ICE further comprises a short-pass filter monolithically coupled to the ICE core, the short-pass filter to block light at the wavelengths that are longer than the wavelength range, such that the ICE outputs, when the tool is operated, the processed light within the wavelength range. 4. The optical analysis tool of claim 3 , wherein each of (i) a mismatch of refractive index for the received light across an input optical interface between the short-pass filter and an input medium upstream from the ICE and (ii) a mismatch of refractive index for the short-pass filtered light across an optical interface between the ICE core and the short-pass filter is smaller than a mismatch of refractive index for the received light if the input optical interface were between the ICE core and the input medium. 5. The optical analysis tool of claim 1 , further comprising: a light source positioned to illuminate the sample with light having a first spectrum over the wavelength range, wherein the ICE is positioned to receive the light provided by the sample in response to the illumination, such that the light received from the sample has a second spectrum over the wavelength range, the second spectrum corresponding to the first spectrum modified by the sample; and an optical transducer positioned to receive the processed light from the ICE and produce a signal having a value related to an integrated intensity of the processed light across the wavelength range, wherein the signal value corresponds to a value of the characteristic of the sample. 6. The optical analysis tool of claim 5 , wherein the optical transducer is spaced apart from the ICE, such that the output medium downstream from the ICE is ambient between the ICE and the optical transducer. 7. The optical analysis tool of claim 5 , wherein the optical transducer is monolithically coupled to the filter of the ICE, such that the output medium downstream from the ICE is a constituent material of the optical transducer. 8. The optical analysis tool of claim 5 , wherein the ICE is spaced apart from the sample, such that the input medium upstream from the ICE is ambient between the sample and the ICE. 9. The optical analysis tool of claim 5 , wherein the short-pass filter of the ICE is adjacent the sample, such that the input medium upstream from the ICE is a constituent material of the sample. 10. The optical analysis tool of claim 1 , wherein the ICE core comprises a substrate having a first surface and a second surface, wherein the substrate comprises a substrate material with a substrate material refractive index, and a layer of material patterned on the first surface of the substrate such that the processed light is related, over the wavelength range, to the characteristic of the sample, the layer of patterned material comprising a plurality of identical features arranged in an array, and the features each comprising one or more geometric shapes selected from the group consisting of triangles, quadrilaterals, hexagons, and circles. 11. The optical analysis tool of claim 10 , wherein constituent material of the filter is stacked on the second surface of the substrate. 12. The optical analysis tool of claim 10 , wherein constituent material of the filter is included within the substrate between the first and second surfaces thereof. 13. The optical analysis tool of claim 1 , wherein the ICE core comprises a substrate having a first surface and a second surface, wherein the substrate comprises a substrate material with a substrate material refractive index, and a plurality of spectral filters supported by the substrate adjacent to the first surface and arranged at different lateral positions with respect to a path of the light received from the sample, each spectral filter formed to transmit or reflect a different subset of wavelengths in the wavelength range, and each spectral filter having a respective area exposed to the light from the sample, the respective areas being related to a property of the sample. 14. The optical analysis tool of claim 13 , wherein constituent material of the filter is stacked on the second surface of the substrate. 15. The optical analysis tool of claim 13 , wherein a constituent material of the filter is included within the substrate between the first and second surfaces thereof. 16. The optical analysis tool of claim 1 , wherein the wavelength range comprises wavelengths in a range from about 0.2 μm to about 25 μm. 17. An optical analysis tool comprising: an integrated computational element (ICE) comprising an ICE core to process light received by the ICE from a sample, when the tool is operated, such that the processed light is related, over a wavelength range, to a characteristic of the sample, a long-pass filter monolithically coupled to the ICE core, the filter is a long-pass filter to block light at wavelengths that are shorter than the wavelength range, wherein a value of an effective refractive index n F associated with the long-pass filter is bound by a value of an effective refractive index associated with the ICE core and a value of a refractive index of an output medium downstream from the ICE, and a short-pass filter monolithically coupled to the ICE core, the short-pass filter to block light at the wavelengths that are longer than the wavelength range, such that the ICE outputs, when the tool is operated, processed light within the wavelength range, wherein a value of an effective refractive index associated with the short-pass filter is bound by a value of the effective refractive index associated with the ICE core and a value of a refractive index of an input medium upstream from the ICE. 18. The optical analysis tool of claim 17 , wherein the wavelength range comprises wavelengths in a range from about 0.2 μm to about 2.5 μm. 19. The optical analysis tool of claim 17 , wherein the wavelength range comprises wavelengths in a range from about 2.5 μm to about 25 μm. 20. A well logging system comprising: an optical analysis tool that comprises an inte