Voltage-tunable optical filters for instrumentation applications

What is claimed is: 1. An optical-based imaging system including at least one voltage-controlled plasmonic tunable optical filter comprising a shortwave pass (SWP) plasmonic filter comprising a plurality of voltage-controlled transparent, conductive strips disposed above and insulated from a layer of transparent, conductive material, the SWP plasmonic filter defined as exhibiting a selected cut-off wavelength λ S ; and a longwave pass (LWP) plasmonic filter comprising a plurality of voltage-controlled transparent, conductive strips disposed above and insulated from a layer of transparent, conductive material, the LWP plasmonic filter defined as exhibiting a selected cut-on wavelength λ L , with λ L less than λ S , wherein at least one of the SWP plasmonic filter and the LWP plasmonic filter exhibits a voltage-controlled spectral response such that the combination of the SWP and LWP plasmonic filters creates a tunable optical filter defined by the wavelength range between the cut-on wavelength λ L and the cut-off wavelength λ S , providing a tunable center wavelength and an independently tunable bandwidth, depending on the selected values for λ L and λ S . 2. The optical-based imaging system as defined in claim 1 , wherein the imaging system includes an excitation filter for controlling an optical bandwidth used to illuminate a specimen and an emission filter for controlling an optical bandwidth received at a detector from the illuminated specimen, with at least one of the excitation and emission filters formed as a voltage-controlled plasmonic tunable filter. 3. The optical-based imaging system as defined in claim 2 wherein the excitation filter is formed as a voltage-controlled plasmonic tunable excitation filter. 4. The optical-based imaging system as defined in claim 3 wherein the voltage-controlled plasmonic tunable excitation filter is controlled by voltages applied to the SWP and LWP plasmonic filters to create a swept wavelength filter, sweeping across a plurality of different excitation wavelengths. 5. The optical-based imaging system as defined in claim 3 wherein the voltage-controlled plasmonic tunable excitation filter is controlled by voltages applied to the SWP and LWP plasmonic filters to create a blocking filter that prevents excitation wavelengths from passing through, providing a controlled shutter for the imaging system. 6. The optical-based imaging system as defined in claim 3 wherein the imaging system comprises a fluorescence spectrometer and the voltage-controlled plasmonic tunable excitation filter is tunable to excite a plurality of different dyes within a specimen, associated with a plurality of different excitation wavelengths. 7. The optical-based imaging system as defined in claim 3 wherein the imaging system comprises a Raman spectrometer and the voltage-controlled plasmonic tunable excitation filter is tunable to generate vibrational and rotational resonances within an illuminated specimen at a plurality of different excitation wavelengths. 8. The optical-imaging system as defined in claim 3 wherein the imaging system comprises a flow cytometer and the voltage-controlled plasmonic tunable excitation filter is tunable to control a wavelength range directed to a forward-scatter detector of the flow cytometer. 9. The optical-based imaging system as defined in claim 2 wherein the emission filter is formed as a voltage-controlled plasmonic tunable emission filter. 10. The optical-based imaging system as defined in claim 9 wherein the imaging system comprises a fluorescence spectrometer and the voltage-controlled plasmonic tunable emission filter is tunable to maximum signal strength at the associated optical detector. 11. The optical-based imaging system as defined in claim 9 wherein the imaging system comprises a Raman spectrometer and the voltage-controlled plasmonic tunable emission filter is configured as a deep notch filter, centered at the excitation wavelength, to minimize noise at the detector. 12. The optical-based imaging system as defined in claim 9 wherein the imaging system comprises a flow cytometer and the voltage-controlled plasmonic tunable emission filter is configured to sweep across a plurality of side-scattered wavelengths, associated with a plurality of different fluorophores. 13. The optical-based imaging system as defined in claim 2 wherein the optical-based imaging system further comprises a dichroic filter disposed to direct the excitation signal toward the specimen and the emission signal toward the detector, and also maintaining an angular separation between the excitation signal and the emission signal. 14. The optical-based imaging system as defined in claim 13 wherein the dichroic filter comprises a voltage-controlled plasmonic tunable dichroic filter. 15. The optical-based imaging system as defined in claim 13 wherein the voltage-controlled plasmonic tunable dichroic filter is tunable with respect to changes in excitation wavelength. 16. The optical-based imaging system as defined in claim 13 wherein the voltage-controlled plasmonic tunable dichroic filter is tunable with respect to changes in emission wavelength. 17. A voltage-controlled plasmonic tunable optical filter comprising a shortwave pass (SWP) plasmonic filter defined as exhibiting a selected cut-off wavelength λ S ; and a longwave pass (LWP) plasmonic filter defined as exhibiting a selected cut-on wavelength λ L , with λ L less than λ S , wherein at least one of the SWP plasmonic filter and the LWP plasmonic filter exhibits a voltage-controlled spectral response such that the combination of the SWP and LWP plasmonic filters creates a tunable optical filter defined by the wavelength range between the cut-on wavelength λ L and the cut-off wavelength λ S , providing a tunable center wavelength and an independently tunable bandwidth, depending on the selected values for λ L and λ S , wherein each plasmonic filter comprises a plurality of voltage-controlled transparent, conductive strips disposed above and insulated from a layer of transparent, conductive material, such that the adjustment of a voltage applied to the transparent, conductive strips adjust the spectral response of the associated plasmonic filter. 18. The voltage-controlled plasmonic tunable optical filter as defined in claim 17 wherein the SWP plasmonic filter is formed to exhibit a voltage-controlled spectral response such that the cut-off wavelength λ S is tunable by adjusting a voltage applied thereto. 19. The voltage-controlled plasmonic tunable optical filter as defined in claim 17 wherein the LWP plasmonic filter is formed to exhibit a voltage-controlled spectral response such that the cut-on wavelength λ L is tunable by adjusting a voltage applied thereto. 20. The voltage-controlled plasmonic tunable optical filter as defined in claim 17 wherein the SWP plasmonic filter is formed to exhibit a voltage-controlled spectral response such that the cut-off wavelength λ S is tunable by adjusting a voltage applied thereto and the LWP plasmonic filter is formed to exhibit a voltage-controlled spectral response such that the cut-on wavelength λ L is tunable by adjusting a voltage applied thereto. 21. The voltage-controlled plasmonic tunable optical filter as defined in claim 17 wherein either one or both of the cut-on wavelength λ L and the cut-off wavelength λ S are voltage controlled to create a tunable a center wavelength (CWL) of the optical filter. 22. The voltage-controlled plasmonic