Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Applied optics

R. Dorsch, G. Hausler, and J. Herrmaim, Laser Triangulation Fundamental Uncertainty in Distance Measurement, Applied Optics, Vol. 33, No. 7 (1994). [Pg.1067]

Here E(t) denotes the applied optical field, and-e andm represent, respectively, the electronic charge and mass. The (angular) frequency oIq defines the resonance of the hamionic component of the response, and y represents a phenomenological damping rate for the oscillator. The nonlinear restoring force has been written in a Taylor expansion the temis + ) correspond to tlie corrections to the hamionic... [Pg.1266]

Up to this point, we have calculated the linear response of the medium, a polarization oscillating at the frequency m of the applied field. This polarization produces its own radiation field that interferes with the applied optical field. Two familiar effects result a change in tlie speed of the light wave and its attenuation as it propagates. These properties may be related directly to the linear susceptibility The index of... [Pg.1267]

Baner]ee P P and Poon T C 1991 Principles of Applied Optics (Boston, MA Asken)... [Pg.1897]

N. J. Kreidl and J. Rood, in R. Kinglake, ed.. Optical Materials, Applied Optics and Optical Engineering, Academic Press, Inc., New York, 1965. [Pg.317]

Additional sources are the Journal of Applied Optics and the Journal of the Optical Society of America, particularly for surface properties the Jour nal of Quantitative Spectroscopy and Radiative Transfer for gas properties the Jour -nal of Heat Tr ansfer andthe Inter national Journal of Heat and Mass Tr ansfer lor broad coverage and the Jour nal of the Institute of Ener gy for applications to industrial furnaces. [Pg.569]

Edner, Hans, Anders Sunesson, Sune Svanberg, Leif Llneus, and. Svante Wallin. Differential Optical Absorption Spectroscopy System Used for Atmospheric Mercury Monitoring. Applied Optics 25 (1986), pp. 403-409. [Pg.1315]

D.N. Kumar, J.D. Bhawalkar, P.N. Prasad, Solid-state cavity lasing from poly(/>-phenylencvinyl-ene)-silica nanocompositc bulk. Applied Optics 1998, 37, 510. [Pg.178]

Stressed Mirror Polishing A Technique for Producing Non-axisymmetric Mirrors. Lubliner, J., Nelson, J., 1980,Applied Optics 19, 2332 Figure Control For a Fully Segmented Primary Mirror. Mast, T., Nelson, J., 1982, App. Optics 21, 2631... [Pg.72]

Control and alignment of segmented-mirror telescopes matrices, modes, and error propagation Chanan, G., MacMartin, D., Nelson, J., Mast, T., 2004, Applied Optics 43, 1223... [Pg.72]

Irwan, R., Lane, R.G., 1999, Analysis of optimal centroid estimation applied to Shack-Hartmann sensing. Applied Optics 38, 6737 Kay, S.M., 1993, Fundamentals of statistical signal processing estimation theory, Prentice-Hall, New Jersey, pp 27-81... [Pg.394]

Cronhjort, A., Wahlin, E, Segmentation Algorithm for Diesel Spray Image Analysis, Applied Optics, 43(32), 5971-5980, 2004. [Pg.196]

Maaroof, A.I., Cortie, M.B. and Smith, G.B. (2005) Optical properties of mesoporous gold films. Journal of Optics A Pure and Applied Optics, 7, 303-309. [Pg.349]

Delori, F. C. and K. P. Pflibsen (1989). Spectral reflectance of the human ocular fundus. Applied Optics 28 1061-1077. [Pg.84]

Lee S., Gin J., Nampoori V., Vallabhan C., Unnikrishnan N., Radhakrishnan P., A sensitive fibre optic pH sensor using multiple sol-gel coatings, Journal of Optics A Pure and Applied Optics 2003 3 355-359. [Pg.383]

Zou, L., Ferrier, G.A., Afshar, Sv Yu, Q., Chen, L., and Bao, X. Distributed Brillouin scattering sensor for discrimination of wall-thinning defects in steel pipe under internal pressure, Applied Optics, 43(7), 1583-1588,2004. [Pg.379]

EL Dereniak, DG Crowe. Optical Radiation Detectors. Wiley Series in Pure and Applied Optics. Chichester Wiley, 1984. [Pg.103]

K. R. Armstrong and F. J. Low. Far-Infrared Filters Utilizing Small Particle Scattering and Antireflection Coatings , Applied Optics, Vol. 13, No. 2, pp. 425-430, February 1974. [Pg.267]

S. R. Arridge. Photon measurement density functions, part 1 Analytical forms. Applied Optics, 34 7395-7409, 1995. [Pg.364]

M. Essenpreis, C. E. Elwell, M. Cope, and D. T. Delpy. Spectral dependence of temporal point spread functions in human tissues. Applied Optics, 32 418-425, 1993. [Pg.365]

S. J. Madsen, B. C. Wilson, M. S. Patterson, Y. D. Park, S. L. Jacques, and Y. Hefetz. Experimental tests of a simple diffusion model for the estimation of scattering and absorption coefficients of turbid media from time-resolved diffuse reflectance measurements. Applied Optics, 31 3509-3517, 1992. [Pg.368]

M. S. Patterson, B. Chance, and B. C. Wilson. Time resolved reflectance and transmittance for the non-invasive measurement of tissue optical properties. Applied Optics, 28(12) 2331-2336, 1989. [Pg.370]

F. V. Bright and G. M. Hieftje, Rapid-scanning frequency domain fluorometer with picosecond time resolution, Applied Optics 26, 3526-3529 (1987). [Pg.293]

K. Matsubara, S. Kawata, and S. Minami, "Optical Chemical Sensor based on Surface Plasmon Measurement," Applied Optics 27, 1160-1163 (1988). [Pg.116]

H. Schnitzler, U. Frohlich, T.K.W. Boley, A.E.M. Clemen, J. Mlynek, A. Peters, and S. Schiller, All-solid-state tunable continuous-wave ultraviolet source with high purity and frequency stability. Applied Optics 41(33), 7000-7005 (2002). [Pg.224]

Fraunhofer Institute for Applied Optics and Precision Engineering, Albert-Einstein-Strasse 7,... [Pg.245]

M. D. Felt, and J. A. Fleck, Light propagation in graded-index optical fibers, Applied Optics 17, 3990-3998 (1978). [Pg.276]

A. S. Sudbo, Improved formulation of the film mode matching method for mode field calculations in dielectric waveguides. Pure and Applied Optics 3, 381-388 (1993). [Pg.276]

I. Ichimura, S. Hayashi, and G. S. Kino, High-density optical recording using a solid immersion lens, Applied Optics 36, 4339-4348 (1997). [Pg.280]

Suzuko, T. and Horikawa, Y. (1986) Development of a real-time scanning laser microscope for biological use. Applied Optics 25,4115 121. [Pg.158]

Fig. 12, Photophoretic force data of Lin and Campillo (1985) for crystalline ammonium sulfate particles levitated in an electrodynamic balance. Reprinted with permission from Lin, H.-B., and Campillo, A. J., Applied Optics 24, 244, Copyright 1985, The Optical Society of America. Fig. 12, Photophoretic force data of Lin and Campillo (1985) for crystalline ammonium sulfate particles levitated in an electrodynamic balance. Reprinted with permission from Lin, H.-B., and Campillo, A. J., Applied Optics 24, 244, Copyright 1985, The Optical Society of America.
Fig. 19. The levitation power and backscatter intensity recorded by Ashkin and Dziedzic (1981) as a function of laser wavelength in nanometers for a silicone oil droplet with a diameter of 11.4/im and N = 1.47. Reprinted with permission from Ashkin, A., and Dziedzic, J. M., Applied Optics 20, 1803, Copyright 1981, The Optical Society of America. Fig. 19. The levitation power and backscatter intensity recorded by Ashkin and Dziedzic (1981) as a function of laser wavelength in nanometers for a silicone oil droplet with a diameter of 11.4/im and N = 1.47. Reprinted with permission from Ashkin, A., and Dziedzic, J. M., Applied Optics 20, 1803, Copyright 1981, The Optical Society of America.
See other pages where Applied optics is mentioned: [Pg.685]    [Pg.685]    [Pg.1263]    [Pg.1274]    [Pg.1274]    [Pg.709]    [Pg.760]    [Pg.112]    [Pg.112]    [Pg.13]    [Pg.211]    [Pg.350]    [Pg.146]    [Pg.166]    [Pg.442]    [Pg.686]    [Pg.251]    [Pg.310]   
See also in sourсe #XX -- [ Pg.257 ]



SEARCH



© 2024 chempedia.info