Search Results - (syntactic OR (synthetic OR synthesis)) (structures OR structure)

Enzymatic Synthesis of Structured Triglycerides From Laboratory to Industry / by Ferreira, María Luján, Tonetto, Gabriela Marta

Table of Contents: “…Chapter 1: Introduction: What´s the importance of structured triglycerides and diglycerides -- Chapter 2: Literature Review: What has been explored about enzymatic synthesis of ST and SD -- Chapter 3: Drawbacks: What problems arise when enzymatic synthesis of ST is performed -- Chapter 4: Potential Solutions: What can be done about the drawbacks in ST enzymatic synthesis -- Chapter 5: Industry perspective: What has to be taken into account when scaling-up from the lab to the industry -- Chapter 6: Examples of successful industrial synthesis or potential industrial scaling of SD and ST -- Chapter 7: Conclusion: What does the future look like.…”
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DNA microarrays, synthesis, and synthetic DNA /

Table of Contents: “…Macromolecular synthesis in mitochondria in the adrenal glands of aging mice as observed by electron microscopic radioautography / Tetsuji Nagata -- 3-Synthetic DNA as observed by microscopic radioautography / T. …”
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Synthesis, Structure and Properties of Poly(lactic acid)

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Quinoxalines Synthesis, Reactions, Mechanisms and Structure / by Mamedov, Vakhid A.

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New Data Structures and Algorithms for Logic Synthesis and Verification by Amaru, Luca Gaetano

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Advanced HDL Synthesis and SOC Prototyping RTL Design Using Verilog / by Taraate, Vaibbhav

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Magnetic Perovskites Synthesis, Structure and Physical Properties / by Kundu, Asish K.

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Insights into the Chemistry of Organic Structure-Directing Agents in the Synthesis of Zeolitic Materials

Table of Contents: “…Introduction of structure-directing phenomenon by organic molecules: general aspects -- Location of organic structure-directing agents by diffraction techniques -- Molecular modelling of organic structure-direction phenomena -- Beyond nitrogen organic structure-directing agents -- Role of supramolecular chemistry during templating phenomenon in zeolite synthesis -- Metal Complexes as structure directing agents for zeolites and related microporous materials -- Chiral organic structure-directing agents.…”
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Cellulose Derivatives Synthesis, Structure, and Properties / by Heinze, Thomas, El Seoud, Omar A., Koschella, Andreas

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PLD Based Design with VHDL RTL Design, Synthesis and Implementation / by Taraate, Vaibbhav

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Poly(lactic acid) : synthesis, structures, properties, processing, and applications /

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Analysis and Synthesis of Positive Systems Under ℓ1 and L1 Performance by Chen, Xiaoming

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Separation Logic for High-level Synthesis by Winterstein, Felix

Table of Contents: “…Introduction -- 2. High-level Synthesis of Dynamic Data Structures -- 3. Background -- 4. …”
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Metallic Microlattice Structures Manufacture, Materials and Application / by Mines, Robert

Table of Contents: “…Theory, simulation, analysis and synthesis for metallic micro-lattice structures -- 5.1. …”
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The Electronic Transitions of Molecular Oxygen by Bregnhøj, Mikkel

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Language Structure, Variation and Change The Case of Old Spanish Syntax / by Mackenzie, Ian E.

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Hierarchically structured porous materials : from nanoscience to catalysis, separation, optics, energy, and life science / by Su, Bao-Lian

Table of Contents: “…Insights into Hierarchically Structured Porous Materials: From Nanoscience to Catalysis, Separation, Optics, Energy, and Life Science / Bao-Lian Su, Cľment Sanchez, Xiao-Yu Yang -- Hierarchy in Natural Materials / Peter Fratzl, Marie Madeleine Giraud Guille -- Synthesis Strategies to Hierarchically Structured Porous Materials. …”
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High Performance Structural Materials Proceedings of Chinese Materials Conference 2017 /

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Vibration Control of Active Structures An Introduction / by Preumont, André

Table of Contents: “….-   1.3 Smart materials and structures.-   1.4 Control strategies.-   1.4.1 Feedback.-   1.4.2 Feedforward.-   1.5 The various steps of the design.-   1.6 Plant description, error and control budget.-   1.7 Readership and Organization of the book.-   1.8 References.-   1.9 Problems.-   2 Some concepts in structural dynamics.-  2.1 Introduction.-   2.2 Equation of motion of a discrete system.-   2.3 Vibration modes.-   2.4 Modal decomposition.-   2.4.1 Structure without rigid body modes.-   2.4.2 Dynamic °exibility matrix.-   2.4.3 Structure with rigid body modes.-   2.4.4 Example.-  2.5 Collocated control system.-   2.5.1 Transmission zeros and constrained system.-  2.6 Continuous structures.-   2.7 Guyan reduction.-   2.8 Craig-Bampton reduction.-   2.9 References.-   2.10 Problems.-   3 Electromagnetic and piezoelectric transducers.-   3.1 Introduction.-   3.2 Voice coil transducer.-   3.2.1 Proof-mass actuator.-   3.2.2 Geophone.-   3.3 General electromechanical transducer.-   3.3.1 Constitutive equations.-   3.3.2 Self-sensing.-   3.4 Reaction wheels and gyrostabilizers.-   3.5 Smart materials.-   3.6 Piezoelectric transducer.-   3.6.1 Constitutive relations of a discrete transducer.-   3.6.2 Interpretation of k2.-   3.6.3 Admittance of the piezoelectric transducer.-   3.7 References.-   3.8 Problems.-   4 Piezoelectric beam, plate and truss.-   4.1 Piezoelectric material.-   4.1.1 Constitutive relations.-   4.1.2 Coenergy density function.-   4.2 Hamilton's principle.-   4.3 Piezoelectric beam actuator.-   4.3.1 Hamilton's principle.-   4.3.2 Piezoelectric loads.-   4.4 Laminar sensor.-   4.4.1 Current and charge amplifiers.-   4.4.2 Distributed sensor output.-   4.4.3 Charge amplifier dynamics.-   4.5 Spatial modalfilters.-   4.5.1 Modal actuator.-   4.5.2 Modal sensor.-   4.6 Active beam with collocated actuator-sensor.-   4.6.1 Frequency response function.-   4.6.2 Pole-zero pattern.-   4.6.3 Modal truncation.-   4.7 Admittance of a beam with a piezoelectric patch.-   4.8 Piezoelectric laminate.-   4.8.1 Two dimensional constitutive equations.-   4.8.2 Kirchhoff  theory.-   4.8.3 Stiffness matrix of a multi-layer elastic laminate.-   4.8.4 Multi-layer laminate with a piezoelectric layer.-   4.8.5 Equivalent piezoelectric loads.-   4.8.6 Sensor output.-   4.8.7 Beam model vs. plate model.-   4.8.8 Additional remarks.-   4.9 Active truss.-   4.9.1 Open-loop transfer function.-   4.9.2 Admittance function.-   4.10 Finite element formulation.-   4.11 References.-   4.12 Problems.-   5 Passive damping with piezoelectric transducers.-   5.1 Introduction.-   5.2 Resistive shunting.-   5.3 Inductive shunting.-   5.4 Switched shunt.-   5.4.1 Equivalent damping ratio.-   5.5 References.-   5.6 Problems.-   6 Collocated versus non-collocated control.-   6.1 Introduction.-  6.2 Pole-zero flipping.-   6.3 The two-mass problem.-   6.3.1 Collocated control.-   6.3.2 Non-collocated control.-   6.4 Notch filter.-   6.5 Effect of pole-zero flipping on the Bode plots.-   6.6 Nearly collocated control system.-   6.7 Non-collocated control systems.-   6.8 The role of damping.-   6.9 References --   6.10 Problems ..-   7 Active damping with collocated system.-   7.1 Introduction.-   7.2 Lead control.-   7.3 Direct velocity feedback (DVF).-   7.4 Positive Position Feedback (PPF).-   7.5 Integral Force Feedback(IFF).-   7.6 Duality between the Lead and the IFF controllers.-   7.6.1 Root-locus of a single mode.-   7.6.2 Open-loop poles and zeros.-   7.7 Actuator and sensor dynamics.-   7.8 Decentralized control with collocated pairs.-   7.8.1 Cross talk.-   7.8.2 Force actuator and displacement sensor.-   7.8.3 Displacement actuator and force sensor.-   7.9 References.-   7.10 Problems.-   8 Vibration isolation.-   8.1 Introduction.-   8.2 Relaxation isolator.-  8.2.1 Electromagnetic realization.-   8.3 Active isolation.-  8.3.1 Sky-hook damper.-   8.3.2 Integral Force Feedback.-   8.4 Flexible body.-   8.4.1 Free-free beam with isolator.-   8.5 Payload isolation in spacecraft.-   8.5.1 Interaction isolator/attitude control.-   8.5.2 Gough-Stewart platform.-   8.6 Six-axis isolator.-   8.6.1 Relaxation isolator.-   8.6.2 Integral Force Feedback.-   8.6.3 Spherical joints, modal spread.-   8.7 Active vs. passive.-   8.8 Car suspension.-   8.9 References.-   8.10 Problems.-   9 State space approach.-   9.1 Introduction.-   9.2 State space description.-   9.2.1 Single degree of freedom oscillator.-   9.2.2 Flexible structure.-   9.2.3 Inverted pendulum.-   9.3 System transfer function.-   9.3.1 Poles and zeros.-   9.4 Pole placement by state feedback.-   9.4.1 Example: oscillator.-   9.5 Linear Quadratic Regulator.-   9.5.1 Symmetric root locus.-   9.5.2 Inverted pendulum.-   9.6 Observer design.-   9.7 Kalman Filter.-   9.7.1 Inverted pendulum.-   9.8 Reduced order observer.-   9.8.1 Oscillator.-   9.8.2 Inverted pendulum.-   9.9 Separation principle.-   9.10 Transfer function of the compensator.-   9.10.1 The two-mass problem.-   9.11 References.-   9.12 Problems.-   10 Analysis and synthesis in the frequency domain.-   10.1 Gain and phase margins.-  10.2 Nyquist criterion.-   10.2.1 Cauchy's principle.-   10.2.2 Nyquist stability criterion.-  10.3 Nichols chart.-   10.4 Feedback specification for SISO systems.-   10.4.1 Sensitivity.-   10.4.2 Tracking error.-   10.4.3 Performance specification.-   10.4.4 Unstructured uncertainty.-   10.4.5 Robust performance and robust stability.-  10.5 Bode gain-phase relationships.-  10.6 The Bode Ideal Cutoff.-  10.7 Non-minimum phase systems.-   10.8 Usual compensators.-   10.8.1 System type.-   10.8.2 Lead compensator.-   10.8.3 PI compensator.-   10.8.4 Lag compensator.-   10.8.5 PID compensator.-   10.9 Multivariable systems.-   10.9.1 Performance specification.-   10.9.2 Small gaintheorem.-   10.9.3 Stability robustness tests.-   10.9.4 Residual dynamics.-   10.10References.-   10.11Problems.-   11 Optimal control.-   11.1 Introduction.-   11.2 Quadratic integral.-   11.3 Deterministic LQR.-   11.4 Stochastic response to a white noise.-   11.4.1 Remark.-   11.5 Stochastic LQR.-   11.6 Asymptotic behavior of the closed-loop.-   11.7 Prescribed degree of stability --   11.8 Gain and phase margins of the LQR.-   11.9 Full state observer.-   11.9.1 Covariance of the reconstruction error.-   11.10Kalman-Bucy Filter (KBF).-   11.11Linear Quadratic Gaussian (LQG).-  11.12Duality.-   11.13Spillover.-   11.13.1Spillover reduction.-   11.14Loop Transfer Recovery (LTR).-   11.15Integral control with state feedback.-   11.16Frequency shaping.-   11.16.1Frequency-shaped cost functionals.-   11.16.2Noise model ..-   11.17References.-   11.18Problems.-   12 Controllability and Observability.-   12.1 Introduction.-  12.1.1 Definitions.-   12.2 Controllability and observabilitymatrices.-   12.3 Examples.-   12.3.1 Cart with two inverted pendulums.-   12.3.2 Double inverted pendulum.-   12.3.3 Two d.o.f.…”
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Environmentally Friendly Zeolites Synthesis and Source Materials / by Chaves Lima, Rafael, Bieseki, Lindiane, Vinaches Melguizo, Paloma, Castellã Pergher, Sibele Berenice

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