Liquid crystal tunable filter

LCTFs circa 2014 with integrated circuitry for control and power (left), or an older model with a separate electronics controller box and thick, shielded cable (right).

Liquid crystal tunable filters (LCTFs) are optical filters that use electronically controlled liquid crystal (LC) elements to transmit a selectable wavelength of light and exclude others. Often, the basic working principle is based on the Lyot filter but many other designs can be used.[1] The main difference with the original Lyot filter is that the fixed wave plates are replaced by switchable liquid crystal wave plates.

LCTFs are known for enabling very high image quality and allowing relatively easy integration with regard to optical system design and software control but having lower peak transmission values in comparison with conventional fixed-wavelength optical filters due to the use of multiple polarizing elements. This can be mitigated in some instances by using wider bandpass designs, since a wider bandpass results in more light traveling through the filter. Some LCTFs are designed to tune to a limited number of fixed wavelengths such as the red, green, and blue (RGB) colors while others can be tuned in small increments over a wide range of wavelengths such as the visible or near-infrared spectrum from 400 to the current limit of 2450 nm. The tuning speed of LCTFs varies by manufacturer and design, but is generally several tens of milliseconds, mainly determined by the switching speed of the liquid crystal elements. Higher temperatures can decrease the transition time for the molecules of the liquid crystal material to align themselves and for the filter to tune to a particular wavelength. Lower temperatures increase the viscosity of the liquid crystal material and increase the tuning time of the filter from one wavelength to another.

LCTFs are often used in multispectral imaging or hyperspectral imaging systems because of their high image quality and rapid tuning over a broad spectral range.[2][3][4] Multiple LCTFs in separate imaging paths can be used in optical designs when the required wavelength range exceeds the capabilities of a single filter, such as in astronomy applications.[5]

Another type of solid-state tunable filter is the Acousto Optic Tunable Filter (AOTF), based on the principles of the acousto-optic modulator. Compared with LCTFs, AOTFs enjoy a much faster tuning speed (microseconds versus milliseconds) and broader wavelength ranges. However, since they rely on the acousto-optic effect of sound waves to diffract and shift the frequency of light, imaging quality is comparatively poor, and the optical design requirements are more stringent. Indeed, LCTFs are capable of diffraction-limited imaging onto high-resolution imaging sensors. AOTFs have smaller apertures and have narrower angle-of-acceptance specifications compared with LCTFs that can have working aperture sizes up to 35mm and can be placed into positions where light rays travel through the filter at angles of over 7 degrees from the normal.[6][7]

LCTFs have been utilized for aerospace imaging.[4][8] Their light weight and low power requirements make them good candidates for remote-sensing applications. They can be found integrated into compact but high-performance scientific digital imaging cameras as well as industrial- and military-grade instruments (multispectral and high-resolution color imaging systems).[9] LCTFs can have a long lifespan, usually many years. Environmental factors that can cause degradation of filters are extended exposure to high heat and humidity, thermal and/or mechanical shock (most, but not all, LCTFs utilize glass as the principal base material), and long-term exposure to high photonic energy such as ultraviolet light which can photobleach some of the materials used to construct the filters.

Recent advances in miniaturized electronic driver circuitry have reduced the size requirement of LCTF enclosures without sacrificing large working aperture sizes. In addition, new materials have allowed the effective wavelength range to be extended to 2450 nm.

Applications

References

  1. Beeckman, J; Neyts, K & Vanbrabant, P (2011). "Liquid-Crystal Photonic Applications". Optical Engineering. 50 (081202). doi:10.1117/1.3565046.
  2. Peng, Yankun & Lu, Renfu. "An LCTF-Based Multispectral Imaging System for Estimation of Apple Fruit Firmness: Part II: Selection of Optimal Wavelengths and Development of Prediction Models". United States Department of Agriculture. Retrieved 2010-07-06.
  3. Morris, H; Hoyt, C & Treado, P. "Imaging Spectrometers for Fluorescence and Raman Microscopy: Acousto-Optic and Liquid Crystal Tunable Filters". Optical Society of America. Retrieved 2010-07-06.
  4. 1 2 Yasuhiro, Shoji; Takashi, Yoshikawa; Yuji, Sakamoto; Yukihiro, Takahashi & Kazuya, Yoshida. "Development of a Multi-Spectrum Imager for the S-520 Sounding Rocket". Japan Society for Aeronautical and Space Sciences. Retrieved 2010-07-06.
  5. Jerkatis, Kanneth. "The AEOS Spectral Imaging System" (PDF). Boeing-SVS, Inc., Suite 350, 4411 The 25 Way NE, Albuquerque, NM 87109. Retrieved 2013-05-30.
  6. Dimitra N. Stratis; Kristine L. Eland; J. Chance Carter; Samuel J. Tomlinson & S. Michael Angel. "Comparison of Acousto-optic and Liquid Crystal Tunable Filters for Laser-Induced Breakdown Spectroscopy". Applied Spectroscopy, Vol. 55, Issue 8, pp. 999-1004 (2001). Retrieved 2010-07-06.
  7. Gebhart, Steven C.; Stokes, David L.; Vo-Dinh, Tuan; Mahadevan-Jansen, Anita (2005). "Instrumentation considerations in spectral imaging for tissue demarcation: comparing three methods of spectral resolution". Proceedings of SPIE. 5694: 41. doi:10.1117/12.611351.
  8. Michael P. Doherty; Susan M. Motil; John H. Snead & Diane C. Malarik. "Microscope-Based Fluid Physics Experiments in the Fluids and Combustion Facility on ISS" (PDF). NASA/TM—2000-210248. Archived from the original (PDF) on October 14, 2006. Retrieved 2010-07-06.
  9. Richard M. Levenson; David T. Lynch; Hisataka Kobayashi; Joseph M. Backer; Marina V. Backer. "Multiplexing with Multispectral Imaging: From Mice to Microscopy" (PDF). ILAR Journal partially supported by a Bioengineering Re- search Grant (1RO1 CA108468-01) and by the SBIR mechanism (1R44 CA88684), both through the National Institutes of Health. Archived from the original (PDF) on July 18, 2011. Retrieved 2010-07-06.

External links

Informative sites or links

This article is issued from Wikipedia - version of the 9/13/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.