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Multiplexed diagram

Fig. 6.7. Block diagram of the differential mixed-signal architecture. AAF Anti-aliasing filter BF Buffer MUX Multiplexer... Fig. 6.7. Block diagram of the differential mixed-signal architecture. AAF Anti-aliasing filter BF Buffer MUX Multiplexer...
Figure 1. Schematic diagram for digital noise measurements using multiplexed electrodes. Figure 1. Schematic diagram for digital noise measurements using multiplexed electrodes.
Figure 24.1 Schematic diagram for a potential application of multiplexed diode-laser sensors for measurements of gas temperature, species concentrations, velocity, mass flux, and thrust at several locations in military- and industrial-scale gas turbines (e.g., aeropropulsion, incineration, power generation appheations)... Figure 24.1 Schematic diagram for a potential application of multiplexed diode-laser sensors for measurements of gas temperature, species concentrations, velocity, mass flux, and thrust at several locations in military- and industrial-scale gas turbines (e.g., aeropropulsion, incineration, power generation appheations)...
Figure 24.2 Schematic diagram of the setup used to measure and control H2O concentration and gas temperature in the combustion region (in situ) of a forced 5-kilowatt combustor at Stanford University 1 — steel duct 2 — quartz duct 3 — A1 duct 4 — multiplexed beam 5 — tunable diode lasers 6 — data acquisition and control computer 7 — control signals 8 — primary air driver Aair sin(27r/of) 9 — fuel drivers Afuei sin(27r/of-f dfuei) 10 — demultiplexing box 11 — Si detector (ND filter) and 12 — laser beam... Figure 24.2 Schematic diagram of the setup used to measure and control H2O concentration and gas temperature in the combustion region (in situ) of a forced 5-kilowatt combustor at Stanford University 1 — steel duct 2 — quartz duct 3 — A1 duct 4 — multiplexed beam 5 — tunable diode lasers 6 — data acquisition and control computer 7 — control signals 8 — primary air driver Aair sin(27r/of) 9 — fuel drivers Afuei sin(27r/of-f dfuei) 10 — demultiplexing box 11 — Si detector (ND filter) and 12 — laser beam...
Figure 24.10 Schematic diagram of the combustion-control experiment at China Lake 1 — primary air 2 — primary air driver sin(27r/ot) 3 — pyrolysis gases N2 -h C2H4 4 — secondary air 5 — secondary air drivers sin(27r/ot- -0) 6 — demultiplexing box 7 — sampling probe 8 — multipass fast-sample cell (36-meter path) 9 — InGaAs detector 10 — multiplexed beam and 11 — data acquisition and control computer... Figure 24.10 Schematic diagram of the combustion-control experiment at China Lake 1 — primary air 2 — primary air driver sin(27r/ot) 3 — pyrolysis gases N2 -h C2H4 4 — secondary air 5 — secondary air drivers sin(27r/ot- -0) 6 — demultiplexing box 7 — sampling probe 8 — multipass fast-sample cell (36-meter path) 9 — InGaAs detector 10 — multiplexed beam and 11 — data acquisition and control computer...
Fig. 6.8. A Principle of frequency-multiplexed CARS microspectroscopy A narrow-bandwidth pump pulse determines the inherent spectral resolution, while a broad-bandwidth Stokes pulse allows simultaneous detection over a wide range of Raman shifts. The multiplex CARS spectra shown originate from a 70 mM solution of cholesterol in CCI4 (solid line) and the nonresonant background of coverglass (dashed line) at a Raman shift centered at 2900 cm-1. B Energy level diagram for a multiplex CARS process. C Schematic of the multiplex CARS microscope (P polarizer HWP/QWP half/quarter-wave plate BC dichroic beam combiner Obj objective lens F filter A analyzer FM flip mirror L lens D detector S sample). D Measured normalized CARS spectrum of the cholesterol solution. E Maximum entropy method (MEM) phase spectrum (solid line) retrieved from (D) and the error background phase (dashed line) determined by a polynomial fit to those spectral regions without vibrational resonances. F Retrieved Raman response (solid line) calculated from the spectra shown in (E), directly reproducing the independently measured spontaneous Raman response (dashed line) of the same cholesterol sample... Fig. 6.8. A Principle of frequency-multiplexed CARS microspectroscopy A narrow-bandwidth pump pulse determines the inherent spectral resolution, while a broad-bandwidth Stokes pulse allows simultaneous detection over a wide range of Raman shifts. The multiplex CARS spectra shown originate from a 70 mM solution of cholesterol in CCI4 (solid line) and the nonresonant background of coverglass (dashed line) at a Raman shift centered at 2900 cm-1. B Energy level diagram for a multiplex CARS process. C Schematic of the multiplex CARS microscope (P polarizer HWP/QWP half/quarter-wave plate BC dichroic beam combiner Obj objective lens F filter A analyzer FM flip mirror L lens D detector S sample). D Measured normalized CARS spectrum of the cholesterol solution. E Maximum entropy method (MEM) phase spectrum (solid line) retrieved from (D) and the error background phase (dashed line) determined by a polynomial fit to those spectral regions without vibrational resonances. F Retrieved Raman response (solid line) calculated from the spectra shown in (E), directly reproducing the independently measured spontaneous Raman response (dashed line) of the same cholesterol sample...
Fig. 5. Schematic diagram of an eight-channel multiplexed electrospray source. At the current representation, only spray 1 can pass through the sampling rotor to the mass analyzer, whereas sprays 2-8 are blocked. Reprinted with permission from Micromass, UK... Fig. 5. Schematic diagram of an eight-channel multiplexed electrospray source. At the current representation, only spray 1 can pass through the sampling rotor to the mass analyzer, whereas sprays 2-8 are blocked. Reprinted with permission from Micromass, UK...
Figure 3.5. Block diagrams for multichannel and multiplex Raman spectrometers. FT indicates computer for performing a Fourier transform. Figure 3.5. Block diagrams for multichannel and multiplex Raman spectrometers. FT indicates computer for performing a Fourier transform.
Figure 16. (a) Schematic diagram of the balloon-borne IR spectrometer. Key SSI-6, sun sensor W, attenuator CMcont., command controller RL, relay HV, high voltage power supply and MPX, multiplexer. [Pg.315]

Figure 4.16. (a) Pictures of an Eksigent Parallel LC system and (b) Waters 2488 eight-channel UV/Vis detector, (c) Schematic diagram of a multiplexed parallel LC/MS analysis. Diagrams courtesy of Eksigent and Waters Corporation. [Pg.100]

Bode diagram, 330-31, 334-37 frequency response, 323-24 interacting capacities, 197-200 noninteracting capacities, 194-96 pulse transfer function, 619 Multiple-input multiple-output system, 20 discrete-time model, 586 discrete transfer function, 612 input-output model, 83-85, 163-68 linearization, 121-26 transfer-function matrix, 164, 166 Multiple loop control systems, 394-409 Multiplexer, 560, 564 Multivariable control systems, 461-62 alternative configurations, 467-84 decoupling of loops, 503-8 design questions, 461-62 interaction of loops, 487-94 selection of loops, 494-503 Multivariable process (see Multiple-input multiple-output system)... [Pg.356]

Fig. 7. Diagram of a multiplexed SPT instrument using a multianode MCP detector. The signals from several channels (representing different wavelengths) can be measuretd in parallel. In the excitation beam the possibility of a pump-probe arrangement using two laser pulses for measuring the fluorescence kinetics of short-lived intermediates is indicated (see text). Fig. 7. Diagram of a multiplexed SPT instrument using a multianode MCP detector. The signals from several channels (representing different wavelengths) can be measuretd in parallel. In the excitation beam the possibility of a pump-probe arrangement using two laser pulses for measuring the fluorescence kinetics of short-lived intermediates is indicated (see text).
Figure 1.4 Schematic diagram of single-band UCNP fabrication for multiplexed detection. Surface amino modifications of the multilayer structure of green, blue, and red single-band UCNPs and conjugates with antibodies to the breast cancer biomarkers PR, ER, and HER2, respectively, for multiplexed in situ molecular mapping of breast cancer biomarkers. (Reproduced with permission from ref. 87.1... Figure 1.4 Schematic diagram of single-band UCNP fabrication for multiplexed detection. Surface amino modifications of the multilayer structure of green, blue, and red single-band UCNPs and conjugates with antibodies to the breast cancer biomarkers PR, ER, and HER2, respectively, for multiplexed in situ molecular mapping of breast cancer biomarkers. (Reproduced with permission from ref. 87.1...
Fig. 37. A simple diagram to explain the exposure time of each hologram in holographic multiplexing (A) condition with equivalent recording time (b) condition with decreased recording time... Fig. 37. A simple diagram to explain the exposure time of each hologram in holographic multiplexing (A) condition with equivalent recording time (b) condition with decreased recording time...
Figure 12. Diagram of multiplex detector (diode array) combined with a grating for spectral dispersion of while light a) Grating b) Diode anay... Figure 12. Diagram of multiplex detector (diode array) combined with a grating for spectral dispersion of while light a) Grating b) Diode anay...
Plasma Etching, Rgure 4 Schematic diagram of the STS Multiplex ICP etching system... [Pg.1677]

Figure 29. Diagram of a multiplex addressing for a 7-segment display, a to g Face electrodes h Back electrode... Figure 29. Diagram of a multiplex addressing for a 7-segment display, a to g Face electrodes h Back electrode...
FIGURE 5.5 Schematic diagram of the flow system developed for the multiplexed detection of glucose, fructose, and sucrose using enzyme bioelectrodes as ampero-metric biosensors. (Reprinted from Vargas, E. et al. 2013. Talanta 105 93-100. With permission.)... [Pg.110]

The 4-to-l multiplexer selects an output Y from one of four inputs A, B, C or D based on the state of the two select lines SO and SI. The logical fimc-tion of the circuit is shown in Table 4.3 and a top-level block diagram showing the inputs and output is illustrated in Figure 4.1. [Pg.45]

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