دانلود کتاب Basic Transforms for Electrical Engineering
کتاب تبدیل های پایه برای مهندسی برق نسخه زبان اصلی
دانلود کتاب تبدیل های پایه برای مهندسی برق بعد از پرداخت مقدور خواهد بود
توضیحات کتاب در بخش جزئیات آمده است و می توانید موارد را مشاهده فرمایید
توضیحاتی در مورد کتاب Basic Transforms for Electrical Engineering
نام کتاب : Basic Transforms for Electrical Engineering
عنوان ترجمه شده به فارسی : تبدیل های پایه برای مهندسی برق
سری :
نویسندگان : Orhan Özhan
ناشر : Springer
سال نشر : 2022
تعداد صفحات : 642
[643]
ISBN (شابک) : 3030988457 , 9783030988456
زبان کتاب : English
فرمت کتاب : pdf
حجم کتاب : 17 Mb
بعد از تکمیل فرایند پرداخت لینک دانلود کتاب ارائه خواهد شد. درصورت ثبت نام و ورود به حساب کاربری خود قادر خواهید بود لیست کتاب های خریداری شده را مشاهده فرمایید.
توضیحاتی در مورد کتاب :
کتاب درسی محبوبترین تبدیلهای مورد استفاده در مهندسی برق را به همراه مبانی ریاضی تبدیلها پوشش میدهد و به طور منحصربهفردی این دو را در یک متن واحد گرد هم میآورد. این کتاب که برای یک کلاس در سطح فوق لیسانس یا فارغ التحصیل طراحی شده است، تبدیل های پر استفاده از جمله تبدیل فوریه، لاپلاس، فوریه گسسته، z-، فوریه کوتاه مدت و تبدیل کسینوس گسسته را پوشش می دهد. این کتاب شامل اعداد مختلط، توابع مختلط و ادغام مختلط است که برای درک تبدیلها ضروری است. نویسنده تلاش میکند تا مطالعه موضوع را با توسل به استفاده از نرمافزارهای محبوبی مانند ابزار مجازی LabVIEW، M-فایلهای Matlab و منابع برنامهنویسی C قابل دسترس کند. پروژه های کامپیوتری در انتهای فصل ها روند یادگیری را بیشتر تقویت می کنند. این کتاب بر اساس سالهای تدریس نویسنده دروس ریاضیات مهندسی و درس سیگنال است و میتواند در برنامه درسی مهندسی برق و ریاضیات استفاده شود.
- هم تحولات مهندسی برق و هم آنها را ارائه میدهد. مبانی ریاضی به صورت قابل فهم، آموزشی و کاربردی رویکرد؛
- متداولترین تبدیلها برای مهندسین الکترونیک و ارتباطات از جمله تبدیل لاپلاس، تبدیل فوریه، STFT، تبدیل z را پوشش میدهد. span>
- ویژگیهای فایلهای ابزار مجازی LabVIEW (vi)، فایلهای شبیهسازی LTSpice، فایلهای MATLAB m و پروژههای کامپیوتری در فصل مشکلات.
فهرست مطالب :
Foreword Contents List of Symbols and Abbreviations Part I Background 1 Complex Numbers 1.1 Representation of Complex Numbers 1.2 Euler's Identity 1.2.1 Complex Exponential 1.2.2 Conjugate of a Complex Number 1.3 Mathematical Operations 1.3.1 Identity 1.3.2 Addition and Subtraction 1.3.3 Multiplication and Division 1.3.4 Rotating a Number in Complex Plane 1.4 Roots of a Complex Number 1.5 Applications of Complex Numbers 1.5.1 Complex Numbers Versus Trigonometry 1.5.2 Integration 1.5.3 Phasors 1.5.4 3-Phase Electric Circuits 1.5.5 Negative Frequency 1.5.6 Complex Numbers in Mathematics Software 1.5.7 Roots of a Polynomial Further Reading Problems 2 Functions of a Complex Variable 2.1 Limit of a Complex Function 2.2 Derivative of Complex Functions and Analyticity 2.3 Cauchy–Riemann Conditions 2.4 Rules of Differentiation 2.5 Harmonic Functions 2.6 Applications of Complex Functions and Analyticity 2.6.1 Elementary Functions Polynomial and Rational Functions Exponential Function of a Complex Variable Logarithm of a Complex Number Trigonometric Functions of a Complex Variable Hyperbolic Functions of a Complex Variable A Worked-Out Example: The Inverse Cosine Function 2.6.2 Conformal Mapping 2.6.3 Fractals Further Reading Problems 3 Complex Integration 3.1 Integrating Complex Functions of a Real Variable 3.2 Contours 3.3 Integrating Functions of a Complex Variable 3.4 Numerical Computation of the Complex Integral 3.5 Properties of the Complex Integral 3.6 The Cauchy–Goursat Theorem 3.6.1 Integrating Differentiable Functions 3.6.2 The Principle of Contour Deformation 3.6.3 Cauchy's Integral for Multiply Connected Domains 3.7 Cauchy's Integral Formula 3.8 Higher-Order Derivatives of Analytic Functions 3.9 Complex Sequences and Series 3.10 Power Series Expansions of Functions 3.10.1 Taylor and Maclaurin Series 3.10.2 Differentiation and Integration of Power Series 3.11 Laurent Series 3.12 Residues 3.12.1 Residue Theorem 3.12.2 Residue at Infinity 3.12.3 Finding Residues 3.13 Residue Integration of Real Integrals 3.14 Fourier Integrals Further Reading Problems Part II Transforms 4 The Laplace Transform 4.1 Motivation to Use Laplace Transform 4.2 Definition of the Laplace Transform 4.3 Properties of the Laplace Transform 4.3.1 Linearity 4.3.2 Real Differentiation 4.3.3 Real Integration 4.3.4 Differentiation by s 4.3.5 Real Translation 4.3.6 Complex Translation 4.3.7 Periodic Functions 4.3.8 Laplace Transform of Convolution 4.3.9 Initial Value Theorem 4.3.10 Final Value Theorem 4.4 The Inverse Laplace Transform 4.4.1 Real Poles 4.4.2 Complex Poles 4.4.3 Multiple Poles 4.5 More on Poles and Zeros 4.5.1 Factoring Polynomials 4.5.2 Poles and Time Response 4.5.3 An Alternative Way to Solve Differential Equations 4.6 Inverse Laplace Transform by Contour Integration 4.7 Applications of Laplace Transform 4.7.1 Electrical Systems 4.7.2 Inverse LTI Systems 4.7.3 Evaluation of Definite Integrals Problems 5 The Fourier Series 5.1 Vectors and Signals 5.2 The Fourier Series 5.3 Calculating Fourier Series Coefficients 5.4 Properties of the Fourier Series 5.4.1 Linearity 5.4.2 Symmetry Properties Even Symmetry Odd Symmetry Half-Period Symmetry 5.4.3 Shifting in Time 5.4.4 Time Reversal 5.4.5 Differentiation 5.4.6 Integration 5.5 Parseval's Relation 5.6 Convergence of Fourier Series 5.7 Gibbs Phenomenon 5.8 Discrete-Time Fourier Series 5.8.1 Periodic Convolution 5.8.2 Parseval's Relation for Discrete-Time Signals 5.9 Applications of Fourier Series Problems 6 The Fourier Transform 6.1 Introduction 6.2 Definition of the Fourier Transform 6.3 Fourier Transform Versus Fourier Series 6.4 Convergence of the Fourier Transform Dirichlet Conditions 6.5 Properties of the Fourier Transform 6.5.1 Symmetry Issues 6.5.2 Linearity 6.5.3 Time Scaling 6.5.4 Time Reversal 6.5.5 Time Shift 6.5.6 Frequency Shift (Amplitude Modulation) 6.5.7 Differentiation with Respect to Time 6.5.8 Integration with Respect to Time 6.5.9 Duality 6.5.10 Convolution 6.5.11 Multiplication in Time Domain 6.5.12 Parseval's Relation 6.5.13 Two-way Transform: Fourier Integral Theorem 6.5.14 Fourier Transform of a Periodic Time Function 6.6 Sampling 6.6.1 Impulse-Sampling and Aliasing 6.6.2 Natural Sampling: The Zero-Order Hold 6.6.3 Undersampling 6.7 Fourier Transform Versus Laplace Transform 6.8 Discrete-Time Signals 6.9 Fourier Transform of Discrete Signals 6.9.1 The Discrete Fourier Transform 6.10 Two-Dimensional Fourier Transform 6.11 Applications 6.11.1 Signal Processing Spectrogram Cepstrum Analysis Correlation and Energy Spectrum Filtering 6.11.2 Circuit Applications 6.11.3 Communication Propagation Time-Division Multiplexing (TDM) Frequency-Division Multiplexing (FDM) Amplitude Modulation and Demodulation FM Slope Detectors 6.11.4 Instrumentation Further Reading Problems 7 Short-Time-Fourier Transform 7.1 Short-Time Fourier Transform 7.1.1 Frequency Resolution 7.1.2 Inverse Short-Time Fourier Transform 7.1.3 Discrete-Time STFT Windowing 7.2 Gabor Transform 7.3 STFT in LabVIEW Problems 8 Fast Fourier Transform 8.1 Radix-2 FFT Algorithms 8.1.1 Decimation in Time 8.1.2 Decimation in Frequency 8.2 Computer Implementation 8.2.1 LabVIEW Implementation 8.2.2 Implementing FFT in C Further Reading Assignments 9 z-Transform 9.1 Definition of the z-Transform 9.2 Region of Convergence for the z-Transform 9.3 z-Transform Properties 9.3.1 Linearity 9.3.2 Time Shifting 9.3.3 Multiplication by an Exponential Sequence 9.3.4 Multiplication by n 9.3.5 Division by n 9.3.6 Conjugate of a Complex Sequence 9.3.7 Convolution of Sequences 9.3.8 Time Reversal 9.3.9 Initial Value Theorem 9.4 The Inverse z-Transform 9.4.1 Inversion by Partial Fraction Expansion Complex Roots Multiple Roots 9.4.2 Inverse z-Transform Using Contour Integration 9.5 Complex Convolution Theorem 9.6 Parseval Theorem 9.7 One-Sided z-Transform 9.8 Difference Equations 9.9 Conversions Between Laplace Transform and z–Transform 9.10 Fourier Transform of Discrete-Time Signals 9.11 Applications of the z-Transform 9.11.1 Digital Oscillator A 3-Tap FIR Filter Derivative in Discrete-Time Fibonacci Sequence in Closed Form 9.12 Discrete Signal Processing vs Digital Technologies: A Historical Retrospect Further Reading Problems 10 Discrete Cosine Transform 10.1 From DFT to DCT 10.1.1 One-Dimensional Signal 10.1.2 Two-Dimensional Signal 10.2 DCT Implementation 10.3 DCT Applications Further Reading Problems References Index
توضیحاتی در مورد کتاب به زبان اصلی :
The textbook covers the most popular transforms used in electrical engineering along with the mathematical foundations of the transforms, uniquely bringing together the two in a single text. Geared towards an upper-undergraduate or graduate-level class, the book covers the most-used transforms including Fourier, Laplace, Discrete Fourier, z-, short-time Fourier, and discrete cosine transforms. The book includes the complex numbers, complex functions, and complex integration that are fundamental to understand the transforms. The author strives to make the study of the subject approachable by appealing to the use of popular software like LabVIEW virtual instruments, Matlab m-files, and C programming resources. Computer projects at the end of chapters further enhance the learning process. The book is based on the author’s years of teachıng Engineering Mathematics and Signal courses and can be used in both electrical engineering and mathematics curriculum.
- Presents both electrical engineering transforms and their mathematical foundations in an understandable, pedagogical, and applicable approach;
- Covers the most common transforms for electronics and communications engineers including Laplace transform, the Fourier transform, STFT, the z-transform;
- Features LabVIEW virtual instrument (vi) files, LTSpice simulation files, MATLAB m files, and computer projects in the chapter problems.
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