Pass the FE Exam with the FE Review Manual, 3rd Edition: Tips and Strategies
FE Review Manual: Rapid Preparation for the Fundamentals of Engineering Exam, 3rd Edition
If you are an engineering student or a recent graduate who wants to become a licensed professional engineer, you need to take and pass the Fundamentals of Engineering (FE) exam. The FE exam is a computer-based test that covers various topics related to engineering fundamentals. It is administered by the National Council of Examiners for Engineering and Surveying (NCEES) and is offered year-round at approved Pearson VUE test centers.
fe review manual 3rd edition pdf zip
Passing the FE exam is a crucial step toward achieving your career goals as an engineer. It demonstrates your competence and credibility in your chosen field. It also opens up more opportunities for advancement and higher salaries. However, passing the FE exam is not easy. It requires a lot of preparation and practice.
That's why you need a reliable and comprehensive study guide that can help you review all the topics covered in the exam. One such study guide is FE Review Manual: Rapid Preparation for the Fundamentals of Engineering Exam, 3rd Edition by Michael R. Lindeburg PE. This book is designed to help you pass the FE exam on your first try. It offers complete review for all disciplines of engineering, including civil, mechanical, electrical, chemical, industrial, environmental, and other disciplines.
What is the FE review manual and how can it help you prepare for the exam?
The FE review manual is a book that contains 54 chapters covering all the subjects that you need to know for the FE exam. It also includes two mini diagnostic tests (one for each discipline) plus two full-length practice exams with questions answered and explained for both disciplines. The book is organized into three parts:
Part I: Units and Fundamental Constants
Part II: Conversion Factors
Part III: Review
The book is written in a clear and concise manner, with plenty of examples, illustrations, tables, charts, formulas, and equations to help you understand and apply the concepts. The book also follows the NCEES FE Reference Handbook, which is the only reference material that you can use during the exam.
The book is part of a comprehensive learning management system that includes online resources such as web books, eTextbooks, quizzes, flashcards, diagnostic exams, practice problems, video solutions, and more. You can access these online resources at ppi2pass.com/etextbook-program.
What are some of the topics covered in the FE review manual?
The FE review manual covers all the topics that you need to know for both morning (general) and afternoon (discipline-specific) sessions of the FE exam. Here are some of them:
Units and Fundamental Constants
This chapter introduces you to some basic units and constants that are used in engineering calculations. It also explains how to convert between different units using dimensional analysis.
Conversion Factors
This chapter provides you with a list of conversion factors that can help you convert between various units of measurement. It also shows you how to use these conversion factors in solving problems.
Mathematics
This chapter reviews some essential mathematical concepts and skills that are required for engineering analysis. It covers topics such as algebra, trigonometry, geometry, calculus, differential equations, linear algebra, numerical methods, statistics, probability, and more.
Statics
This chapter covers some fundamental principles of statics that are used to analyze forces and moments acting on rigid bodies at rest or in equilibrium. It covers topics such as vectors, free-body diagrams, equilibrium equations, trusses, frames, machines, friction, centroids, moments of inertia, shear force and bending moment diagrams, and more.
Dynamics
This chapter covers some basic concepts of dynamics that are used to analyze forces and motions of particles and rigid bodies in motion. It covers topics such as kinematics, kinetics, work, energy, power, impulse, momentum, collisions, vibrations, and more.
Mechanics of Materials
This chapter covers some fundamental concepts of mechanics of materials that are used to analyze stress and strain in deformable bodies subjected to external loads. It covers topics such as axial loading, torsion, bending, shear, combined loading, stress transformation, strain transformation, Mohr's circle, deflection, buckling, failure theories, and more.
Fluid Mechanics
This chapter covers some basic principles of fluid mechanics that are used to analyze fluid flow and behavior under various conditions. It covers topics such as fluid properties, fluid statics, fluid dynamics, continuity equation, Bernoulli's equation, energy equation, momentum equation, viscous flow, laminar flow, turbulent flow, pipe flow, open-channel flow, flow measurement, dimensional analysis, similitude, and more.
Thermodynamics
This chapter covers some fundamental concepts of thermodynamics that are used to analyze energy and heat transfer between systems and surroundings. It covers topics such as thermodynamic systems, properties, processes, cycles, laws, equations of state, entropy, reversibility, irreversibility, efficiency, power cycles, refrigeration cycles, psychrometrics and more.
Heat Transfer
This chapter covers some basic modes of heat transfer that are used to analyze heat transfer rates and temperature distributions in various media and systems. It covers topics such as conduction convection radiation heat exchangers fins transient heat conduction lumped parameter analysis and more.
Transport Phenomena
This chapter covers some fundamental aspects of transport phenomena that are used to analyze mass transfer and diffusion in various media and systems. It covers topics such as Fick's law mass diffusion coefficient molecular diffusion convective mass transfer mass transfer coefficient dimensionless numbers analogies between heat mass and momentum transfer and more.
Electric Circuits
This subchapter covers some essential concepts of electric circuits that are used to analyze voltage current resistance power energy capacitance inductance impedance admittance reactance resonance filters transformers three-phase circuits Kirchhoff's laws mesh analysis nodal analysis Thevenin's theorem Norton's theorem superposition theorem maximum power transfer theorem phasor analysis complex power power factor correction balanced/unbalanced systems per-unit system symmetrical components fault analysis transient response Laplace transform Fourier series Fourier transform Bode plot Nyquist plot stability criteria feedback control systems state-space representation root locus method frequency response method PID controller design PLC