Angebote zu "Analytical" (5 Treffer)

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Contemporary Topics in Analytical and Clinical ...
168,00 CHF *
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1. Polychromatic Analysis Using the Technicon STAC¿ Analyzer.- 1. Introduction.- 2. The STAC Analyzer.- 2.1. Diluter/Dispenser Module.- 2.2. Analytical Module.- 2.3. Electronics Module.- 3. General Theory.- 4. Selection of Primary and Secondary Wavelengths.- 5. Classification of Polychromatic Analysis.- 5.1. Correction for Nonreactive (Static or Time Invariant Interferences).- 5.2. Correction for Reactive (Kinetic) Interferences.- 5.3. Correction for a Combination of Both Reactive and Nonreactive Interferences.- 5.4. Detection of Substrate Depletion.- 6. STAC Assays.- 7. Examples of Polychromatic Analysis.- 7.1. Calcium.- 7.2. Total Bilirubin.- 7.3. Uric Acid.- 7.4. Triglycerides.- 7.5. AST.- 8. Conclusion.- References.- 2. Introduction to Multiple-Wavelength Spectrophotometric Measurements in Analytical and Clinical Chemistry.- 1. Introduction.- 2. Definitions.- 3. Applications in Analytical Chemistry.- 4. Applications in Clinical Chemistry.- 5. Epilogue.- References.- 3. Bichromatic Analysis: The Design and Function of the ABA-100.- 1. Introduction.- 2. Design Principles.- 3. Performance of Individual Instrument Functions.- 3.1. Photometric Uncertainty and Linearity.- 3.2. Control of Reaction Temperature.- 3.3. Sample Evaporation.- 3.4. Volume Measurement.- 3.5. Performance Characteristics Unique to Bichromatic Measurements.- 4. Automation of a Specific Method with the ABA.- 5. Quality Control.- 6. Special Applications.- 7. Epilogue.- References.- 4. Bichromatic Analysis as Performed in the Du Pont Automatic Clinical Analyzer (¿aca¿).- 1. Introduction.- 2. Analytical Test Pack.- 2.1. Header.- 2.2. Pack Envelope.- 3. Instrument.- 3.1. Sample Handling/Pack Filling.- 3.2. Timing, Temperature, Reagent Addition/Mixing, and Incubation.- 4. Measurement System.- 4.1. Measurement Techniques.- 4.2. Electro-Optical System Description.- 4.3. Zero Absorbance Requirement.- 4.4. Output Result Performance and Calibration.- 5. Measurement Principles.- 5.1. Implementation.- 5.2. Representative Examples.- 5.3. Reaction Time Courses.- 5.4. Chromophore Spectra.- 5.5. Performance.- 6. Advantages.- 6.1. Disadvantages.- 6.2. Future Applications.- References.- 5. The Analysis of Matrix Formatted Multicomponent Data.- 1. Introduction.- 1.1. Data Reduction Strategies in Analytical Chemistry.- 1.2. Description of MFMDT.- 2. Linear Algebra Review.- 2.1. Vectors and Matrices.- 2.2. Arithmetic of Matrices.- 2.3. Matrix Solution of a System of Linear Equations.- 2.4. Basis and Rank.- 2.5. Identity and Inverse Matrices.- 2.6. Eigenvalues and Eigenvectors.- 2.7. Glossary.- 3. Theory and Application of MFMDT in Qualitative Analysis of the Fluorescence Emission-Excitation Matrix (FEEM).- 3.1. Properties of Fluorescence Emission.- 3.2. Principles of Qualitative Analysis of the FEEM by MFMDT.- 3.3. Qualitative Analysis of Simulated Fluorescence Data.- 3.4. Qualitative Analysis of Experimental Fluorescence Data.- 4. Theory and Application of MFMDT in Quantitative Analysis of the FEEM.- 4.1. Theory of Least Squares Analysis of the FEEM.- 4.2. Theory of Linear Programming Analyses (Simplex Method) of the FEEM.- 4.3. Quantitative Analysis of Simulated Fluorescence Data.- 4.4. Quantitative Analysis of Experimental Fluorescence Data.- 5. Summary and Conclusion.- 5.1. Effectiveness of MFMDT for Analysis of Multicomponent Fluorescence Data.- 5.2. Expansion and Future Applications of MFMDT.- 6. Appendices.- 6.1. Fortran Subroutines for Qualitative Analysis.- 6.2. Fortran Subroutines for Quantitative Analysis.- References.- 6. Nonlinear Parameter Estimation of Convolved Excitation and Multiple Emission Response Functions.- 1. Introduction.- 1.1. Luminescence Processes.- 1.2. Modern Instrumentation.- 1.3. Algorithms for Nonlinear Data Analysis.- 2. Instrumentation and Analytical Parameters.- 2.1. Time Correlated Single-Photon Method.- 2.2. Theory.- 2.3. Pile-Up.- 2.4. Time-to-Amplitude Converter.- 2.5. Excitation Source.- 2.6. Optics.- 2.7. Photomultiplier Tube.- 2.8. Start and Stop Lines.- 2.9. Timing Filter Amplifier (TFA).- 2.10. Analytical Considerations¿ Intensity versus Concentration.- 2.11. Scattered Excitation Radiation.- 2.12. Analytical Wavelength and Bandpass Selection.- 2.13. Linearity versus Concentration.- 3. Data Handling.- 3.1. Theory and

Anbieter: Orell Fuessli CH
Stand: 23.10.2020
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Liu, D: Environmental Engineers' Handbook
346,00 CHF *
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'Environmental Engineers' Handbook, Second Edition' covers in depth the interrelated factors and principles that affect our environment and how we have dealt with them in the past, are dealing with them today, and how we deal with them in the future. This stellar reference addresses the ongoing global transition in cleaning up the remains of abandoned technology, the prevention of pollution created by existing technology, and the design of future zero emission technology. The Handbook provides daily problem-solving tools and information on state-of-the-art technologies for the future. Chapters contain both introductory material and very specific technical answers to complex questions. Because analytical results are an essential part of any environmental study, analytical methods used in environmental analysis are presented as well.

Anbieter: Orell Fuessli CH
Stand: 23.10.2020
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Contemporary Topics in Analytical and Clinical ...
89,99 € *
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1. Polychromatic Analysis Using the Technicon STAC¿ Analyzer.- 1. Introduction.- 2. The STAC Analyzer.- 2.1. Diluter/Dispenser Module.- 2.2. Analytical Module.- 2.3. Electronics Module.- 3. General Theory.- 4. Selection of Primary and Secondary Wavelengths.- 5. Classification of Polychromatic Analysis.- 5.1. Correction for Nonreactive (Static or Time Invariant Interferences).- 5.2. Correction for Reactive (Kinetic) Interferences.- 5.3. Correction for a Combination of Both Reactive and Nonreactive Interferences.- 5.4. Detection of Substrate Depletion.- 6. STAC Assays.- 7. Examples of Polychromatic Analysis.- 7.1. Calcium.- 7.2. Total Bilirubin.- 7.3. Uric Acid.- 7.4. Triglycerides.- 7.5. AST.- 8. Conclusion.- References.- 2. Introduction to Multiple-Wavelength Spectrophotometric Measurements in Analytical and Clinical Chemistry.- 1. Introduction.- 2. Definitions.- 3. Applications in Analytical Chemistry.- 4. Applications in Clinical Chemistry.- 5. Epilogue.- References.- 3. Bichromatic Analysis: The Design and Function of the ABA-100.- 1. Introduction.- 2. Design Principles.- 3. Performance of Individual Instrument Functions.- 3.1. Photometric Uncertainty and Linearity.- 3.2. Control of Reaction Temperature.- 3.3. Sample Evaporation.- 3.4. Volume Measurement.- 3.5. Performance Characteristics Unique to Bichromatic Measurements.- 4. Automation of a Specific Method with the ABA.- 5. Quality Control.- 6. Special Applications.- 7. Epilogue.- References.- 4. Bichromatic Analysis as Performed in the Du Pont Automatic Clinical Analyzer (¿aca¿).- 1. Introduction.- 2. Analytical Test Pack.- 2.1. Header.- 2.2. Pack Envelope.- 3. Instrument.- 3.1. Sample Handling/Pack Filling.- 3.2. Timing, Temperature, Reagent Addition/Mixing, and Incubation.- 4. Measurement System.- 4.1. Measurement Techniques.- 4.2. Electro-Optical System Description.- 4.3. Zero Absorbance Requirement.- 4.4. Output Result Performance and Calibration.- 5. Measurement Principles.- 5.1. Implementation.- 5.2. Representative Examples.- 5.3. Reaction Time Courses.- 5.4. Chromophore Spectra.- 5.5. Performance.- 6. Advantages.- 6.1. Disadvantages.- 6.2. Future Applications.- References.- 5. The Analysis of Matrix Formatted Multicomponent Data.- 1. Introduction.- 1.1. Data Reduction Strategies in Analytical Chemistry.- 1.2. Description of MFMDT.- 2. Linear Algebra Review.- 2.1. Vectors and Matrices.- 2.2. Arithmetic of Matrices.- 2.3. Matrix Solution of a System of Linear Equations.- 2.4. Basis and Rank.- 2.5. Identity and Inverse Matrices.- 2.6. Eigenvalues and Eigenvectors.- 2.7. Glossary.- 3. Theory and Application of MFMDT in Qualitative Analysis of the Fluorescence Emission-Excitation Matrix (FEEM).- 3.1. Properties of Fluorescence Emission.- 3.2. Principles of Qualitative Analysis of the FEEM by MFMDT.- 3.3. Qualitative Analysis of Simulated Fluorescence Data.- 3.4. Qualitative Analysis of Experimental Fluorescence Data.- 4. Theory and Application of MFMDT in Quantitative Analysis of the FEEM.- 4.1. Theory of Least Squares Analysis of the FEEM.- 4.2. Theory of Linear Programming Analyses (Simplex Method) of the FEEM.- 4.3. Quantitative Analysis of Simulated Fluorescence Data.- 4.4. Quantitative Analysis of Experimental Fluorescence Data.- 5. Summary and Conclusion.- 5.1. Effectiveness of MFMDT for Analysis of Multicomponent Fluorescence Data.- 5.2. Expansion and Future Applications of MFMDT.- 6. Appendices.- 6.1. Fortran Subroutines for Qualitative Analysis.- 6.2. Fortran Subroutines for Quantitative Analysis.- References.- 6. Nonlinear Parameter Estimation of Convolved Excitation and Multiple Emission Response Functions.- 1. Introduction.- 1.1. Luminescence Processes.- 1.2. Modern Instrumentation.- 1.3. Algorithms for Nonlinear Data Analysis.- 2. Instrumentation and Analytical Parameters.- 2.1. Time Correlated Single-Photon Method.- 2.2. Theory.- 2.3. Pile-Up.- 2.4. Time-to-Amplitude Converter.- 2.5. Excitation Source.- 2.6. Optics.- 2.7. Photomultiplier Tube.- 2.8. Start and Stop Lines.- 2.9. Timing Filter Amplifier (TFA).- 2.10. Analytical Considerations¿ Intensity versus Concentration.- 2.11. Scattered Excitation Radiation.- 2.12. Analytical Wavelength and Bandpass Selection.- 2.13. Linearity versus Concentration.- 3. Data Handling.- 3.1. Theory and

Anbieter: Thalia AT
Stand: 23.10.2020
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Modeling, Analaysis and Control Of Effects Of T...
53,99 € *
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The planar solid-oxide fuel cells (PSOFCs) have emerged as one of the promising candidates for future energy system because of their high energy efficiency, fuel flexibility, zero emission, modularity and high tolerance to the fuel impurities. However, for large-scale commercialization of the PSOFC technology, there is a strong need of developing a reliable and highly efficient PSOFC power system. Development of such a reliable PSOFC based power system requires knowledge of the several feedback effects from the power electronics system and the application loads that may impact the PSOFC stack and the system as a whole. Therefore, it is important to develop analytical methodologies to investigate and mitigate the effects of these electrical feedbacks on the performance of PSOFC systems. On the whole, the dissertation focuses on i) the modeling and development of an effective PSOFC power- system design and system interaction analyses, ii) cost-constrained PES topology design for PSOFCS and iii) the design of cost effective optimal controller and controlling strategy for mitigation of electrical impacts with higher system efficiency.

Anbieter: Thalia AT
Stand: 23.10.2020
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