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Output grating coupler

Clerc D., Lukosz W., Integrated optical output grating coupler as biochemical sensor, Sensors and Actuators B 1994 19 581-586. [Pg.191]

D. Clerc and W. Lukosz, "Integrated Optical Output Grating Coupler as Biochemical Sensor," Sensors and Actuators B19, 581-586 (1994). [Pg.116]

Lukosz W, Clerc D, Nellen PM, Stamm C, Weiss P (1991) Output grating couplers on planar optical waveguides as direct immunosensors. Biosens Bioelectron 6 227-232... [Pg.52]

An electro-active integrated optical waveguide (EA-lOW) with a separation of 8 mm between the input and output grating couplers was used to experimentally assess the sensitivity of EA-lOW-based measurements on surface-confined films. Measurements performed on adsorbed MB (e = 7,800 M cm at 633 nm) at a... [Pg.123]

Figure B2.1.1 Femtosecond light source based on an amplified titanium-sapphire laser and an optical parametric amplifier. Symbols used P, Brewster dispersing prism X, titanium-sapphire crystal OC, output coupler B, acousto-optic pulse selector (Bragg cell) FR, Faraday rotator and polarizer assembly DG, diffraction grating BBO, p-barium borate nonlinear crystal. Figure B2.1.1 Femtosecond light source based on an amplified titanium-sapphire laser and an optical parametric amplifier. Symbols used P, Brewster dispersing prism X, titanium-sapphire crystal OC, output coupler B, acousto-optic pulse selector (Bragg cell) FR, Faraday rotator and polarizer assembly DG, diffraction grating BBO, p-barium borate nonlinear crystal.
D. Mehuys, A. Hardy, D. F. Welch, R. G. Waarts, and R. Parke, Analysis of detuned second-order grating output couplers with an integrated superlattice reflector, IEEE Photon. Tech. Lett. 3, 342-344 (1991). [Pg.244]

Figure 6. Instrumental schematic for vacuum UV photofragmentation-laser induced fluorescence measurement of ammonia SHGC, second harmonic generation crystal SFMC, sum frequency mixing crystal BS, beam splitter BD, beam dump TP, turning prism CL, cylindrical lens R, reflector TD, trigger diode OSC, oscillator cell AMP, amplifier cell BE, beam expander G, grating OC, output coupler M, mirror BC, beam combiner L, lens A, aperture PD, photodiode SC, sample cell RC, reference cell FP, filter pack SAM.PMT, sample cell photomultiplier REF.PMT, reference cell photomultiplier PP, additional photomultiplier port EX, exhaust and CGI, calibration gas inlet to flow line. (Reproduced with permission from reference 15. Copyright 1990 Optical Society of America.)... Figure 6. Instrumental schematic for vacuum UV photofragmentation-laser induced fluorescence measurement of ammonia SHGC, second harmonic generation crystal SFMC, sum frequency mixing crystal BS, beam splitter BD, beam dump TP, turning prism CL, cylindrical lens R, reflector TD, trigger diode OSC, oscillator cell AMP, amplifier cell BE, beam expander G, grating OC, output coupler M, mirror BC, beam combiner L, lens A, aperture PD, photodiode SC, sample cell RC, reference cell FP, filter pack SAM.PMT, sample cell photomultiplier REF.PMT, reference cell photomultiplier PP, additional photomultiplier port EX, exhaust and CGI, calibration gas inlet to flow line. (Reproduced with permission from reference 15. Copyright 1990 Optical Society of America.)...
Figure 7. A number of all-optical guided wave devices and their responses to increasing power. (a) Half beat length directional coupler. (b) One beat length directional coupler. (c) Distributed feedback grating relector. (d) Nonlinear Mach-Zehnder interferometer. (e) Nonlinear mode mixer. (f) Nonlinear X-switch. For nonlinear media (n2 0), the input power determines the output state. Figure 7. A number of all-optical guided wave devices and their responses to increasing power. (a) Half beat length directional coupler. (b) One beat length directional coupler. (c) Distributed feedback grating relector. (d) Nonlinear Mach-Zehnder interferometer. (e) Nonlinear mode mixer. (f) Nonlinear X-switch. For nonlinear media (n2 0), the input power determines the output state.
In SPR sensors with angular modulation, the sensor output is the coupling wavelength kt and therefore the instrumental contribution to sensor sensitivity Srii is equal to Skr/Suef. By differentiating the coupling conditions for the prism, grating, and waveguide coupler (see Chap. 1 of this volume [1]) in ef and k, we obtain ... [Pg.56]

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