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Millimetre and Submillimetre Wave Components for Future Diagnostic Instrumentation
Published online by Cambridge University Press: 17 March 2011
Abstract
Contrary to common belief the technology associated with components and systems for operation in the millimetre and submillimetre or Terahertz (THz) region of the electromagnetic spectrum is mature. However, it has largely been developed for use in the fields of radio astronomy and remote sensing, two areas where size and cost have not been the driving issues. This is changing, both fields now have ambitious plans to put large complex systems into space in experiments such as NASA'a EOS MLS and ESA'a FIRST amongst others. Also, ground based systems such as ALMA are planned where the total number of receivers exceeds 1000. For such instruments cost and size now becomes important. Taking these factors into account for the last decade or so there has been a concerted drive towards smaller and cheaper instrumentation. Initially, the use of quasi-optical systems was implemented in place of waveguide mainly because of its prohibitive manufacturing cost. Quas-ioptical systems are still being developed but waveguide has recently seen a revival due to the use of new micromachining techniques for its fabrication. Planar or integrated circuitry mounted in waveguide has now demonstrated state of the art performance to 2.5THz. Combining these factors means that for the first time the cost of manufacturing high performance RF electronics in the THz region has finally become affordable thereby making it available to new areas of research, material science is one of many. This paper describes how new devices and systems may be implemented to realise the basic building blocks of such instrumentation, namely, detectors and sources.
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- Research Article
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- Copyright © Materials Research Society 2000
References
REFERENCES
1
Applications of Terahertz Technology to Medical Imaging”, Arnone, D D, Ciesla, CM, Corchia, A, Egusa, S, Pepper, M, Chamberlain, J M, Bezant, C, Linfield, E H, Clothier, R and Khammo, N. Terahertz Spectroscopy and Applications II, June 1999. SPIE Proceedings Volume #3828 pp209–219 Editor: Chamberlain, J M.. ISBN: 0 8194 3314 4.Google Scholar
2‘Compact Video Rate Passive Millimetre Wave-Imager’, Price, S, Anderson, R, Borrill, J, Coward, P, Roberts, M, Salmon, N, Sinclair, G, Wasley, M, Murphy, K, Appleby, R, pp295–296, 23rd International Conference on Infrared and Millimetre Waves, Sept, Colchester UK, 1998
Google Scholar
3
‘Broadband Space-Qualified Subharmonic Mixers at 183GHz With Low Local Oscillator Power Requirement, Moyna, B. P., Mann, C. M., Ellison, B. N., Oldfield, M. L., Matheson, D. N., Crowe, T. W., Proc. Of 2nd ESA Workshop on Millimetre Wave Technology and Applications, Espoo, Finland, May 1998
Google Scholar
4
A Compact 500GHz Schottky Diode Receiver with Wide Instantaneous Bandwidth’, Maddison, B., Martin, R., Oldfield, M., Mann, C. M., Matheson, D. N., Ellison, B., Thornton, J., Hall, W., Lamarre, D., 9th International Conference on Space THz Technology, Pasadena, CA, March 1998
Google Scholar
5
‘On The Design and Measurement Of A 2.5THz Waveguide Mixer’. Mann, C. M., Matheson, D. N., Ellison, B. N., Oldfield, M. L., Moyna, B. P., Spencer, J. J., Wilsher, D. S., and Maddison, B. J., 9th International Conference on Space THz Technology, Pasadena, CA, March 1998
Google Scholar
6‘2.5-THz GaAs Monolithic Membrane-Diode Mixer’, Siegel, Peter H., IEEE, Smith, R. Peter, Gaidis, Michael C., Martin, Suzanne C., 596 IEEE Transactions On Microwave Theory And Techniques, Vol. 47, No. 5, May 1999
Google Scholar
7“Quantum-barrier-varactor diode for high efficiency millimetre-wave multipliers,” Kollberg, E. L. and Rydberg, A., Electron. Lett., vol. 25, pp. 1696–1697, 1989
Google Scholar
8“12 % efficiency and 9.5 dBm output power from InP based heterostructure barrier varactor triplers at 250GHz,”, Mélique, X., Maestrini, A., Lheurette, E., Mounaix, P., Favreau, M., Vanbésien, O., Goutoule, M., Beaudin, G., Nähri, T., and Lippens, D., ’presented at IEEE-MTT-S, Anaheim, June 1999
Google Scholar
9‘Effects of Self-Heating on Planar Heterostructure Barrier Varactor Diodes’, Stake, J., Dillner, L., Jones, S. H., Mann, C., Thornton, J., Jones, J. R., Bishop, W. L., Kollberg, E., IEEE Transactions On Electron Devices, Vol.45, No.11, November 1998
Google Scholar
10‘Heterostructure Barrier Varactors on Copper Substrate for Generation of Millimetre and submillimetre-Waves’, Dillner, L, Stake, J, Hollung, S, Mann, C, Kollberg, E, 10th International Conference on Space THz Technology, Charlottesville, VA, March 1999
Google Scholar
11‘A Broadband Frequency Tripler For SIS Receivers’, Mahieu, S., Mann, C. M., Stake, J., Dillner, L., Jones, S. H., Tong, E., Thornton, J., 9th International Conference on Space THz Technology, Pasadena, CA, March 1998
Google Scholar
12
‘The Complete Analytical Simulation of Heterostructure Barrier Varactor Frequency Multipliers’ Dillner, L, Oldfield, M L, Mann, C M, Alderman, B E J, 10th International Conference on Space THz Technology, Charlottesville, VA, March 1999
Google Scholar
13‘A Versatile Micromachined Horn Antenna’,Mann, C.M., Hesler, J.L., Koh, P.J., Crowe, T.W., Bishop, W.L., Weikle, R.M., Matheson, D.N.
20TH ESTEC Antenna Workshop on Millimetre Wave Antenna Technology and Antenna Measurements, 18-20th June 1997
Google Scholar
14‘A Simple Micromachining Technique for Millimetre and Submillimetre Wavelengths’, Mann, C M, Matheson, D N, Oldfield, M L, Koh, P J, Crowe, T W, Bishop, W L, Weikle, R M, Hesler, J L, Proc. Of 2nd ESA Workshop on Millimetre Wave Technology and Applications, Espoo, Finland, May 1998
Google Scholar