An Introduction to Random Signals and Co
β Bhagawandas P. Lathi
π Library
π
1970
π English
β¦ LIBER β¦
π
An Introduction to Communication Theory and Systems
β Scribed by Thomas, John B.
- Publisher
- Springer New York
- Year
- 1988
- Tongue
- English
- Leaves
- 359
- Series
- Springer texts in electrical engineering
- Category
- Library
β¬ Acquire This Volume
No coin nor oath required. For personal study only.
β¦ Synopsis
This book was written as a first treatment of statistical comΒ munication theory and communication systems at a seniorΒ graduate level. The only formal prerequisite is a knowledge of eleΒ mentary calculus; however, some familiarity with linear systems and transform theory will be helpful. Chapter 1 is introductory and contains no substantial techniΒ cal material. Chapter 2 is an elementary introduction to Read more...
β¦ Table of Contents
1-Introduction --
1.1-Communication Systems --
1.2-Statistical Communication Theory --
1.3-Additional Reading --
2-Probability and Random Variables --
2.1-Introductory Remarks --
2.2-Elements of Set Theory --
2.3-A Classical Concept of Probability --
2.4-Elements of Combinatorial Analysis --
2.5-The Axiomatic Foundation of Probability Theory --
2.6-Finite Sample Spaces --
2.7-Fields,?-Fields, and Infinite Sample Spaces --
2.8-Independence --
2.9-Random Variables, Discrete and Continuous --
2.10-Distribution Functions and Densities --
2.11-The Transformation of Random Variables --
2.12-Expectation --
2.13-Moments --
2.14-The Chebychev Inequality --
2.15-Generating Functions --
2.16-The Binomial Distribution --
2.17- The Poisson Distribution --
2.18- The Normal or Gaussian Distribution --
2.19- Limit Theorems --
2.20- Bivariate Distributions --
2.21- The Bivariate Normal Distribution --
2.22- The Multivariate Normal Distribution --
2.23- Linear Transformations on Normal Random Variables --
Problems --
References --
3-Random Processes and Spectral Analysis --
3.1- Definition --
3.2- Stationarity --
3.3- Correlation Functions --
3.4- Time Averages and Ergodicity --
3.5- Convergence of Random Variables --
3.6- Fourier Transforms --
3.7- Integrals of Random Processes --
3.8- Power Spectra --
3.9- Shot Noise --
3.10- Random Events in Time --
3.11- The Mean and Autocorrelation Function of Shot Noise --
3.12- The Amplitude Distribution of Shot Noise --
Problems --
References --
4-Linear Filtering of Stationary Processes:Steady-State Analysis --
4.1-Introduction --
4.2-Discrete-Time Filters --
4.3-Continuous-Time Filters --
4.4-Complete Statistical Description of the Output of a Linear System --
4.5-The Orthogonal Decomposition of Random Processes
Fourier Series --
4.6-The Karhunen-Loeve Expansion --
4.7-Optimal Truncation Properties of the Karhunen-Loeve Expansion --
4.8-The Sampling Theorem --
4.9-Narrow-Band Systems --
4.10-Narrow-Band Systems with Added Sinusoids --
Problems --
References --
5-Optimum Linear Systems: Steady-State Synthesis --
5.1-Introduction --
I -The Matched Filter For Continuous-Time Inputs --
5.2-Derivation --
5.3-The Unrealizable Matched Filter in Continuous Time --
5.4-Spectral Factorization for Continuous-Parameter Random Processes --
5.5-Solution of the Integral Equation for the Continuous- Time Matched Filter --
II -The Matched Filter for Discrete-Time Inputs --
5.6-Derivation --
5.7-The Unrealizable Matched Filter in Discrete Time --
5.8-Spectral Factorization for Discrete-Parameter Random Processes --
5.9-Solution of the Integral Equation for the Discrete-Time Matched Filter --
III -The Linear Least-Mean-Squared-Error Filter for Continuous-Time Inputs --
5.10-Formulation of the LLMSE Filtering and Prediction Problem in Continuous Time --
5.11-The Unrealizable LLMSE Filter in Continuous Time --
5.12-Solution of the Integral Equation for the Continuous- Time LLMSE Filter --
5.13-The Mean-Squared Error for the Continuous-Time Case --
5.14-The Pure Prediction Problem for the Continuous-Time Case --
IV -The Linear Least-Mean-Squared-Error Filter for Discrete-Time Inputs --
5.15-Formulation of the LLMSE Filtering and Prediction Problem in Discrete Time --
5.16-The Unrealizable LLMSE Filter in Discrete Time --
5.17-Solution of the Integral Equation for the Discrete-Time LLMSE Filter --
5.18-The Mean-Squared Error for the Discrete-Time Case --
5.19-The Pure Prediction Problem for the Discrete-Time Case --
Problems --
Appendices --
Appendix A -The Riemann-Stieltjes Integral --
Appendix B -The Dirac Delta Function --
Appendix C -The Transformation of Coordinates --
Appendix D -Fourier Series and the Fourier and Laplace Transforms --
Appendix E -Some Inequalities Including Schwarzβs Inequality --
Appendix F -The Calculus of Variations --
Table-The Unit Normal Distribution.
β¦ Subjects
Telecommunication;Communications Engineering, Networks
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