Measurement of nitrate-nitrogen concentration in soil based on absorption spectroscopy

What is claimed is: 1. A device for measuring a nitrate-nitrogen concentration in soil based on attenuation over a spectral operating range, the device comprising: a light source that generates light that spans the spectral operating range, the spectral operating range including wavelengths at least as short as 230 nm; a detector having a sensitivity that spans the spectral operating range; a sample chamber configured to contain a soil-extractant mixture, the light propagating from the light source to the detector and attenuated by the soil-extractant mixture in the sample chamber, the detector generating a soil spectral signal that indicates the light received by the detector at different wavelengths across the spectral operating range; and a processor coupled to the detector, wherein the processor estimates an attenuation spectrum of the soil-extractant mixture over the spectral operating range based on the soil spectral signal, and estimates the nitrate-nitrogen concentration based on the attenuation spectrum, wherein the processor, when estimating the attenuation spectrum, removes interference in the soil-extractant mixture using one of spectral deconvolution and curve-fitting. 2. The device of claim 1 , wherein the spectral operating range includes wavelengths proximate a 200 nm nitrate-nitrogen absorption peak, and wherein the 200 nm nitrate-nitrogen absorption peak includes estimated attenuation values for wavelengths greater than 200 nm. 3. The device of claim 1 , wherein the sample chamber is optically positioned between the light source and the detector, the light propagating through the soil-extractant mixture in the sample chamber. 4. The device of claim 1 , wherein the processor estimates the attenuation spectrum based on the soil spectral signal, a reference spectral signal and a dark spectral signal, wherein the reference spectral signal is generated when the sample chamber contains extractant without soil and the dark spectral signal is generated without light from the light source incident on the detector. 5. The device of claim 1 , wherein, at different times, the sample chamber contains the soil-extractant mixture or extractant without soil, the detector generating the soil spectral signal when the sample chamber contains the soil-extractant mixture and the detector generating a reference spectral signal when the sample chamber contains extractant without soil, the processor estimating the attenuation spectrum based on the soil spectral signal and the reference spectral signal. 6. The device of claim 1 , further comprising: a second sample chamber configured to contain extractant without soil, wherein the processor estimates the attenuation spectrum based on the soil spectral signal and a reference spectral signal, wherein the reference spectral signal is generated from the second sample chamber containing extractant without soil. 7. The device of claim 1 , further comprising: a reference optical path from the light source to the detector but not attenuated by the soil-extractant mixture, wherein the processor estimates the attenuation spectrum based on the soil spectral signal and a reference spectral signal, wherein the reference spectral signal is generated based on the reference optical path. 8. The device of claim 1 wherein the processor curve fits the attenuation spectrum, at least one component of the curve fit based on a nitrate-nitrogen 200 nm absorption peak. 9. The device of claim 1 wherein the processor receives a soil type and estimates the nitrate-nitrogen concentration further based on the soil type. 10. The device of claim 1 wherein the processor receives a soil conductivity and estimates the nitrate-nitrogen concentration further based on the soil conductivity. 11. The device of claim 1 , wherein the processor applies a partial least squares regression to the attenuation spectrum to estimate the nitrate-nitrogen concentration. 12. The device of claim 1 , wherein the processor is trained based on a set of absorption spectra and their corresponding nitrate-nitrogen concentrations, and the processor estimates the nitrate-nitrogen concentration based on its training. 13. The device of claim 1 , wherein the processor curve fits the attenuation spectrum, at least one component of the curve fit based on a Gaussian background spectrum. 14. The device of claim 1 , wherein the processor estimates the nitrate-nitrogen concentration as a function of time of measurement and extrapolates the estimates to a final estimated nitrate-nitrogen concentration. 15. The device of claim 1 , wherein a UV spectrum of the light source can be controlled separately from a visible spectrum of the light source. 16. The device of claim 15 , wherein the light source includes two bulbs, one of which has a relatively stronger UV spectrum than the other, and which can be separately controlled. 17. The device of claim 1 , further comprising: a filter that filters the soil-extractant mixture, the light propagating through the filtered soil-extractant mixture. 18. The device of claim 1 , wherein the light propagates through unfiltered soil-extractant mixture. 19. The device of claim 1 , further comprising: a centrifuge for separating the soil-extractant mixture, the light propagating through the separated soil-extractant mixture. 20. A method for measuring the nitrate-nitrogen concentration in soil based on attenuation over a spectral operating range, the method comprising: generating light that spans the spectral operating range and includes wavelengths at least as short as 230 nm; providing a soil-extractant mixture that attenuates the light; detecting the attenuated light; generating a soil spectral signal that indicates the light detected at different wavelengths across the spectral operating range; estimating an attenuation spectrum of the soil-extractant mixture over the spectral operating range based on the soil spectral signal, wherein estimating the attenuation spectrum includes removing interference in the soil-extractant mixture using one of spectral deconvolution and curve-fitting; and estimating the nitrate-nitrogen concentration based on the attenuation spectrum. 21. A device for measuring the nitrate-nitrogen concentration in soil based on attenuation over a spectral operating range, the device comprising: a light source that generates light that spans the spectral operating range, wherein the spectral operating range includes wavelengths at least as short as 230 nm; a detector having a sensitivity that spans the spectral operating range; a sample chamber configured to contain a soil-extractant mixture, wherein the light propagates from the light source to the detector and is attenuated by the soil-extractant mixture in the sample chamber, wherein the detector generates a soil spectral signal that represents the light received by the detector at different wavelengths across the spectral operating range; and a processor coupled to the detector, wherein the processor estimates an attenuation spectrum of the soil-extractant mixture over the spectral operating range based on the soil spectral signal, a reference spectral signal and a dark spectral signal, wherein the processor estimates the nitrate-nitrogen concentration based on the attenuation spectrum. 22. A method for measuring the nitrate-nitrogen concentration in soil based on attenuation over a spectral operating range, the method comprising: generating light that spans the spectral operating r