(Ebook PDF) System Dynamics for Engineering Students Concepts and Applications 2nd Edition by Nicolae Lobontiu 0124172091 9780124172098 full chapters

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ISBN-10 :  0124172091

ISBN-13 :  9780124172098

Author : Nicolae Lobontiu  

Engineering system dynamics focuses on deriving mathematical models based on simplified physical representations of actual systems, such as mechanical, electrical, fluid, or thermal, and on solving these models for analysis or design purposes. System Dynamics for Engineering Students: Concepts and Applications features a classical approach to system dynamics and is designed to be utilized as a one-semester system dynamics text for upper-level undergraduate students with emphasis on mechanical, aerospace, or electrical engineering. It is the first system dynamics textbook to include examples from compliant (flexible) mechanisms and micro/nano electromechanical systems (MEMS/NEMS). This new second edition has been updated to provide more balance between analytical and computational approaches; introduces additional in-text coverage of Controls; and includes numerous fully solved examples and exercises.

System Dynamics for Engineering Students: Concepts and Applications 2nd Table of contents:

Chapter 1. Introduction
1.1. Engineering System Dynamics
1.2. Modeling Engineering System Dynamics
1.3. Elements, System, Input, and Output
1.4. Compliant Mechanisms and Microelectromechanical Systems
1.5. System Order
1.6. Coupled-Field (Multiple-Field) Systems
1.7. Linear and Nonlinear Dynamic Systems
1.8. Time- and Frequency-Domain System Dynamics
1.9. Feedback Control of Dynamic Systems
Chapter 2. Mechanical Elements
Introduction
2.1. Spring Elements
2.2. Inertia Elements
2.3. Viscous Damping Elements
2.4. Equivalent Mechanical Elements Through Gear and Lever Transfer
Summary
Chapter 3. Mechanical Systems
Introduction
3.1. Configuration, Degrees of Freedom
3.2. Single–DOF Systems
3.3. Multiple–DOF Systems
Summary
Chapter 4. Electrical Systems
Introduction
4.1. Electrical Elements: Voltage and Current Sources, Resistor, Capacitor, Inductor, and Operational Amplifier
4.2. Electrical Systems: Circuits or Networks
4.3. Mechanical–Electrical Analogy
Summary
Chapter 5. Fluid and Thermal Systems
Introduction
5.1. Liquid Systems Modeling
5.2. Pneumatic Systems Modeling
5.3. Thermal Systems Modeling
5.4. Electrical–Fluid–Thermal System Analogy
Summary
Chapter 6. The Laplace Transform
Introduction
6.1. Direct and Inverse Laplace Transformations
6.2. Laplace Transform Solution of Linear Ordinary Differential Equations (ODE)
6.3. Laplace Transform Solution of Integral and Integral–Differential Equations
6.4. Time-Domain System Identification From Laplace-Domain Information
Summary
Chapter 7. Transfer Function Approach
Introduction
7.1. The Transfer Function Concept and Definition
7.2. Transfer Function Model Formulation
7.3. Transfer Function and System Stability
7.4. Transfer Function and the Time Response
Summary
Chapter 8. State-Space Modeling
Introduction
8.1. The Concept and Model of the State-Space Approach
8.2. State-Space Model Formulation
8.3. State-Space Model and the Time-Domain Response
Summary
Chapter 9. Frequency-Domain Approach
Introduction
9.1. The Concept of Complex Transfer Function in Steady-State Response and Frequency-Domain Analysis
9.2. Steady-State Response of Dynamic Systems to Harmonic Input
9.3. Frequency-Domain Applications
Summary
Chapter 10. Coupled-Field Systems
Introduction
10.1. Concept of System Coupling
10.2. Thermomechanical and Electrothermomechanical Coupling
10.3. Electromechanical Coupling
Summary
Chapter 11. Block Diagrams and Feedback Control System Modeling
Introduction
11.1. Concept of Feedback Control of Dynamic Systems
11.2. Block Diagrams and SISO Feedback Systems
11.3. Block Diagrams and MIMO Feedback Systems
Summary
Chapter 12. Stability of Feedback Control Systems
Introduction
12.1. Concept of Stability Applied to Feedback Control Systems
12.2. The Routh–Hurwitz Stability Test
12.3. Stability of Feedback Systems by the Root Locus Method
12.4. Nyquist Plot and Bode Plots for Stability of Feedback Systems
Summary
Chapter 13. Time- and Frequency-Domain Controls of Feedback Systems
Introduction
13.1. Time-Domain Response of SISO Feedback Control Systems
13.2. Time-Domain Response of MIMO Feedback Control Systems
13.3. Feedback Control Systems in the Frequency Domain

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