Calculus (Book): Difference between revisions
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| 11.16 || Exercises || 443 | | 11.16 || Exercises || 443 | ||
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! colspan="3" | | ! colspan="3" | 12. VECTOR ALGEBRA | ||
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| 1 || | | 12.1 || Historical introduction || 445 | ||
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| 2 || | | 12.2 || The vector space of n-tuples of real numbers || 446 | ||
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| 3 || | | 12.3 || Geometric interpretation for \(n \leq 3\) || 448 | ||
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| 12.4 || Exercises || 450 | |||
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| | | 12.5 || The dot product || 451 | ||
|- | |- | ||
| 2 || | | 12.6 || Length or norm of a vector|| 453 | ||
|- | |||
| 12.7 || Orthogonality of vectors || 455 | |||
|- | |||
| 12.8 || Exercises || 456 | |||
|- | |||
| 12.9 || Projections. Angle between vectors in n-space || 457 | |||
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| 12.10 || The unit coordinate vectors || 458 | |||
|- | |||
| 12.11 || Exercises || 460 | |||
|- | |||
| 12.12 || The linear span of a finite set of vectors || 462 | |||
|- | |||
| 12.13 || Linear independence || 463 | |||
|- | |||
| 12.14 || Bases || 466 | |||
|- | |||
| 12.15 || Exercises || 467 | |||
|- | |||
| 12.16 || The vector space \(V_N(C)\) of n-tuples of complex numbers || 468 | |||
|- | |||
| 12.17 || Exercises || 470 | |||
|- | |||
! colspan="3" | 13. APPLICATIONS OF VECTOR ALGEBRA TO ANALYTIC GEOMETRY | |||
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| 1 || Introduction || 471 | |||
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| 2 || Lines in n-space || 472 | |||
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! colspan="3" | Chapter 16: Induction and Summations | ! colspan="3" | Chapter 16: Induction and Summations |
Revision as of 17:08, 20 September 2021
Calculus | |
Information | |
---|---|
Author | Tom Apostol |
Language | English |
Publisher | Wiley |
Publication Date | 16 January 1991 |
Pages | 666 |
ISBN-10 | 0471000051 |
ISBN-13 | 978-0471000051 |
The textbook Calculus by Tom Apostol introduces calculus.
Table of Contents
Chapter/Section # | Title | Page # |
---|---|---|
I. INTRODUCTION | ||
Part 1: Historical Introduction | ||
I 1.1 | The two basic concepts of calculus | 1 |
I 1.2 | Historical background | 2 |
I 1.3 | The method of exhaustion for the area of a parabolic segment | 3 |
*I 1.4 | Exercises | 8 |
I 1.5 | A critical analysis of the Archimedes' method | 8 |
I 1.6 | The approach to calculus to be used in this book | 10 |
Part 2: Some Basic Concepts of the Theory of Sets | ||
I 2.1 | Introduction to set theory | 11 |
I 2.2 | Notations for designating sets | 12 |
I 2.3 | Subsets | 12 |
I 2.4 | Unions, intersections, complements | 13 |
I 2.5 | Exercises | 15 |
Part 3: A set of Axioms for the Real-Number System | ||
I 3.1 | Introduction | 17 |
I 3.2 | The field axioms | 17 |
*I 3.3 | Exercises | 19 |
I 3.4 | The order axioms | 19 |
*I 3.5 | Exercises | 21 |
I 3.6 | Integers and rational numbers | 21 |
I 3.7 | Geometric interpretation of real numbers as points on a line | 22 |
I 3.8 | Upper bound of a set, maximum element, least upper bound (supremum) | 23 |
I 3.9 | The least-Upper-bound axiom (completeness axiom) | 25 |
I 3.10 | The Archimedean property of the real-number system | 25 |
I 3.11 | Fundamental properties of the supremum and infimum | 26 |
*I 3.12 | Exercises | 28 |
*I 3.13 | Existence of square roots of nonnegative real numbers | 29 |
*I 3.14 | Roots of higher order. Rational powers | 30 |
*I 3.15 | Representation of real numbers by decimals | 30 |
Part 4: Mathematical Induction, Summation Notation, and Related Topics | ||
I 4.1 | An example of a proof by mathematical induction | 32 |
I 4.2 | The principle of mathematical induction | 34 |
*I 4.3 | The well-ordering principle | 34 |
I 4.4 | Exercises | 35 |
*I 4.5 | Proof of the well-ordering principle | 37 |
I 4.6 | The summation notation | 37 |
I 4.7 | Exercises | 39 |
I 4.8 | Absolute values and the triangle inequality | 41 |
I 4.9 | Exercises | 43 |
*I 4.10 | Miscellaneous exercises involving induction | 44 |
1. THE CONCEPTS OF INTEGRAL CALCULUS | ||
1.1 | The basic ideas of Cartesian geometry | 48 |
1.2 | Functions. Informal description and examples | 50 |
1.3 | Functions. Formal definition as a set of ordered pairs | 53 |
1.4 | More examples of real functions | 54 |
1.5 | Exercises | 56 |
1.6 | The concept of area as a set function | 57 |
1.7 | Exercises | 60 |
1.8 | Intervals and ordinate sets | 60 |
1.9 | Partitions and step functions | 61 |
1.10 | Sum and product of step functions | 63 |
1.11 | Exercises | 63 |
1.12 | The definition of the integral for step functions | 64 |
1.13 | Properties of the integral of a step function | 66 |
1.14 | Other notations for integrals | 69 |
1.15 | Exercises | 70 |
1.16 | The integral of more general functions | 72 |
1.17 | Upper and lower integrals | 74 |
1.18 | The area of an ordinate set expressed as an integral | 75 |
1.19 | Informal remarks on the theory and technique of integration | 75 |
1.20 | Monotonic and piecewise monotonic functions. Definitions and examples | 76 |
1.21 | Integrability of bounded monotonic functions | 77 |
1.22 | Calculation of the integral of a bounded monotonic function | 79 |
1.23 | Calculation of the integral \(\int_0^b x^p dx\) when \(p\) is a positive integer | 79 |
1.24 | The basic properties of the integral | 80 |
1.25 | Integration of polynomials | 81 |
1.26 | Exercises | 83 |
1.27 | Proofs of the basic properties of the integral | 84 |
2. SOME APPLICATIONS OF INTEGRATION | ||
2.1 | Introduction | 88 |
2.2 | The area of a region between two graphs expressed as an integral | 88 |
2.3 | Worked examples | 89 |
2.4 | Exercises | 94 |
2.5 | The trigonometric functions | 94 |
2.6 | Integration formulas for the sine and cosine | 94 |
2.7 | A geometric description of the sine and cosine functions | 94 |
2.8 | Exercises | 94 |
2.9 | Polar coordinates | 94 |
2.10 | The integral for area in polar coordinates | 94 |
2.11 | Exercises | 94 |
2.12 | Application of integration to the calculation of volume | 94 |
2.13 | Exercises | 94 |
2.14 | Application of integration to the calculation of work | 94 |
2.15 | Exercises | 94 |
2.16 | Average value of a function | 94 |
2.17 | Exercises | 94 |
2.18 | The integral as a function of the upper limit. Indefinite integrals | 94 |
2.19 | Exercises | 94 |
3. CONTINUOUS FUNCTIONS | ||
3.1 | Informal description of continuity | 126 |
3.2 | The definition of the limit of a function | 127 |
3.3 | The definition of continuity of a function | 130 |
3.4 | The basic limit theorems. More examples of continuous functions | 131 |
3.5 | Proofs of the basic limit theorems | 135 |
3.6 | Exercises | 138 |
3.7 | Composite functions and continuity | 140 |
3.8 | Exercises | 142 |
3.9 | Bolzano's theorem for continuous functions | 142 |
3.10 | The intermediate-value theorem for continuous functions | 144 |
3.11 | Exercises | 145 |
3.12 | The process of inversion | 146 |
3.13 | Properties of functions preserved by inversion | 147 |
3.14 | Inverses of piecewise monotonic functions | 148 |
3.15 | Exercises | 149 |
3.16 | The extreme-value theorem for continuous functions | 150 |
3.17 | The small-span theorem for continuous functions (uniform continuity) | 152 |
3.18 | The integrability theorem for continuous functions | 152 |
3.19 | Mean-value theorems for integrals of continuous functions | 154 |
3.20 | Exercises | 155 |
4. DIFFERENTIAL CALCULUS | ||
4.1 | Historical introduction | 156 |
4.2 | A problem involving velocity | 157 |
4.3 | The derivative of a function | 159 |
4.4 | Examples of derivatives | 161 |
4.5 | The algebra of derivatives | 164 |
4.6 | Exercises | 167 |
4.7 | Geometric interpretation of the derivative as a slope | 169 |
4.8 | Other notations for derivatives | 171 |
4.9 | Exercises | 173 |
4.10 | The chain rule for differentiating composite functions | 174 |
4.11 | Applications of the chain rule. Related rates and implicit differentiation | 176 |
4.12 | Exercises | 179 |
4.13 | Applications of the differentiation to extreme values of cuntions | 181 |
4.14 | The mean-value theorem for derivatives | 183 |
4.15 | Exercises | 186 |
4.16 | Applications of the mean-value theorem to geometric properties of functions | 187 |
4.17 | Second-derivative test for extrema | 188 |
4.18 | Curve sketching | 189 |
4.19 | Exercises | 191 |
4.20 | Worked examples of extremum problems | 191 |
4.21 | Exercises | 194 |
4.22 | Partial derivatives | 196 |
4.23 | Exercises | 201 |
5. THE RELATION BETWEEN INTEGRATION AND DIFFERENTIATION | ||
5.1 | The derivative of an indefinite integral. The first fundamental theorem of calculus | 202 |
5.2 | The zero-derivative theorem | 204 |
5.3 | Primitive functions and the second fundamental theorem of calculus | 205 |
5.4 | Properties of a function deduced from properties of its derivative | 207 |
5.5 | Exercises | 208 |
5.6 | The Leibniz notation for primitives | 210 |
5.7 | Integration by substitution | 212 |
5.8 | Exercises | 216 |
5.9 | Integration by parts | 217 |
5.10 | Exercises | 220 |
5.11 | Miscellaneous review exercises | 222 |
6. THE LOGARITHM, THE EXPONENTIAL, AND THE INVERSE TRIGONOMETRIC FUNCTIONS | ||
6.1 | Introduction | 226 |
6.2 | Motivation for the definition of the natural logarithm as an integral | 227 |
6.3 | The definition of the logarithm. Basic properties | 229 |
6.4 | The graph of the natural logarithm | 230 |
6.5 | Consequences of the functional equation \(L(ab) = L(a) + L(b)\) | 230 |
6.6 | Logarithms referred to any positive base \(b \ne 1\) | 232 |
6.7 | Differentiation and integration formulas involving logarithms | 233 |
6.8 | Logarithmic differentiation | 235 |
6.9 | Exercises | 236 |
6.10 | Polynomial approximations to the logarithm | 236 |
6.11 | Exercises | 242 |
6.12 | The exponential function | 242 |
6.13 | Exponentials expressed as powers of e | 242 |
6.14 | The definition of \(e^x\) for arbitrary real x | 244 |
6.15 | The definition of \(a^x\) for \(a > 0\) and x real | 245 |
6.16 | Differentiation and integration formulas involving exponentials | 245 |
6.17 | Exercises | 248 |
6.18 | The hyperbolic functions | 251 |
6.19 | Exercises | 251 |
6.20 | Derivatives of inverse functions | 252 |
6.21 | Inverses of the trigonometric functions | 253 |
6.22 | Exercises | 256 |
6.23 | Integration by partial fractions | 258 |
6.24 | Integrals which can be transformed into integrals of rational functions | 264 |
6.25 | Exercises | 267 |
6.26 | Miscellaneous review exercises | 268 |
7. POLYNOMIAL APPROXIMATIONS TO FUNCTIONS | ||
7.1 | Introduction | 272 |
7.2 | The Taylor polynomials generated by a function | 273 |
7.3 | Calculus of Taylor polynomials | 275 |
7.4 | Exercises | 278 |
7.5 | Taylor's formula with remainder | 278 |
7.6 | Estimates for the error in Taylor's formula | 280 |
7.7 | Other forms of the remainder in Taylor's formula | 283 |
7.8 | Exercises | 284 |
7.9 | Further remarks on the error in Taylor's formula. The o-notation | 286 |
7.10 | Applications to indeterminate forms | 289 |
7.11 | Exercises | 290 |
7.12 | L'Hopital's rule for the indeterminate form 0/0 | 292 |
7.13 | Exercises | 295 |
7.14 | The symbols \(+\inf\) and \(-\inf\). Extension of L'Hopital's rule | 296 |
7.15 | Infinite limits | 298 |
7.16 | The behavior of log\(x\) and \(e^x\) for large \(x\) | 300 |
7.17 | Exercises | 303 |
8. INTRODUCTION TO DIFFERENTIAL EQUATIONS | ||
8.1 | Introduction | 305 |
8.2 | Terminology and notation | 306 |
8.3 | A first-order differential equation for the exponential function | 307 |
8.4 | First-order linear differential equations | 308 |
8.5 | Exercises | 311 |
8.6 | Some physical problems leading to first-order linear differential equations | 313 |
8.7 | Exercises | 319 |
8.8 | Linear equations of second order with constant coefficients | 322 |
8.9 | Existence of solutions of the equation \(y^{} + by = 0\) | 323 |
8.10 | Reduction of the general equation to the special case \(y^{} + by = 0\) | 324 |
8.11 | Uniqueness theorem for the equation \(y^{} + by = 0\) | 324 |
8.12 | Complete solution of the equation \(y^{} + by = 0\) | 326 |
8.13 | Complete solution of the equation \(y^{} + ay^' + by = 0\) | 326 |
8.14 | Exercises | 328 |
8.15 | Nonhomogeneous linear equations of second order with constant coefficients | 329 |
8.16 | Special methods for determining a particular solution of the nonhomogeneous equation \(y^{} + ay^' + by = R\) | 332 |
8.17 | Exercises | 333 |
8.18 | Examples of physical problems leading to linear second-order equations with constant coefficients | 334 |
8.19 | Exercises | 339 |
8.20 | Remarks concerning nonlinear differential equations | 339 |
8.21 | Integral curves and direction fields | 341 |
8.22 | Exercises | 344 |
8.23 | First-order separable equations | 345 |
8.24 | Exercises | 347 |
8.25 | Homogeneous first-order equations | 347 |
8.26 | Exercises | 350 |
8.27 | Some geometrical and physical problems leading to first-order equations | 351 |
8.28 | Miscellaneous review exercises | 355 |
9. COMPLEX NUMBERS | ||
9.1 | Historical introduction | 358 |
9.2 | Definitions and field properties | 358 |
9.3 | The complex numbers as an extension of the real numbers | 360 |
9.4 | The imaginary unit \(i\) | 361 |
9.5 | Geometric interpretation. Modulus and argument | 362 |
9.6 | Exercises | 365 |
9.7 | Complex exponentials | 366 |
9.8 | Complex-valued functions | 368 |
9.9 | Examples of differentiation and integration formulas | 369 |
9.10 | Exercises | 371 |
10. SEQUENCES, INFINITE SERIES, IMPROPER INTEGRALS | ||
10.1 | Zeno's paradox | 374 |
10.2 | Sequences | 378 |
10.3 | Monotonic sequences of real numbers | 381 |
10.4 | Exercises | 382 |
10.5 | Infinite series | 383 |
10.6 | The linearity property of convergent series | 385 |
10.7 | Telescoping series | 386 |
10.8 | The geometric series | 388 |
10.9 | Exercises | 391 |
10.10 | Exercises on decimal expansions | 393 |
10.11 | Tests for convergence | 394 |
10.12 | Comparison tests for series of nonnegative terms | 394 |
10.13 | The integral test | 397 |
10.14 | Exercises | 398 |
10.15 | The root test and the ratio test for series of nonnegative terms | 399 |
10.16 | Exercises | 402 |
10.17 | Alternating series | 403 |
10.18 | Conditional and absolute convergence | 406 |
10.19 | The convergence tests of Dirichlet and Abel | 407 |
10.20 | Exercises | 409 |
10.21 | Rearrangements of series | 411 |
10.22 | Miscellaneous review exercises | 414 |
10.23 | Improper integrals | 416 |
10.24 | Exercises | 420 |
11. SEQUENCES AND SERIES OF FUNCTIONS | ||
11.1 | Pointwise convergence of sequences of functions | 422 |
11.2 | Uniform convergence of sequences of functions | 423 |
11.3 | Uniform convergence and continuity | 424 |
11.4 | Uniform convergence and integration | 425 |
11.5 | A sufficient condition for uniform convergence | 427 |
11.6 | Power series. Circle of convergence | 428 |
11.7 | Exercises | 430 |
11.8 | Properties of functions represented by real power series | 431 |
11.9 | The Taylor's series generated by a function | 434 |
11.10 | A sufficient condition for convergence of a Taylor's series | 435 |
11.11 | Power-series expansions for the exponential and trigonometric functions | 435 |
11.12 | Bernstein's theorem | 437 |
11.13 | Exercises | 438 |
11.14 | Power series and differential equations | 439 |
11.15 | The binomial series | 441 |
11.16 | Exercises | 443 |
12. VECTOR ALGEBRA | ||
12.1 | Historical introduction | 445 |
12.2 | The vector space of n-tuples of real numbers | 446 |
12.3 | Geometric interpretation for \(n \leq 3\) | 448 |
12.4 | Exercises | 450 |
12.5 | The dot product | 451 |
12.6 | Length or norm of a vector | 453 |
12.7 | Orthogonality of vectors | 455 |
12.8 | Exercises | 456 |
12.9 | Projections. Angle between vectors in n-space | 457 |
12.10 | The unit coordinate vectors | 458 |
12.11 | Exercises | 460 |
12.12 | The linear span of a finite set of vectors | 462 |
12.13 | Linear independence | 463 |
12.14 | Bases | 466 |
12.15 | Exercises | 467 |
12.16 | The vector space \(V_N(C)\) of n-tuples of complex numbers | 468 |
12.17 | Exercises | 470 |
13. APPLICATIONS OF VECTOR ALGEBRA TO ANALYTIC GEOMETRY | ||
1 | Introduction | 471 |
2 | Lines in n-space | 472 |
Chapter 16: Induction and Summations | ||
1 | Induction | 383 |
2 | Summations | 388 |
3 | Geometric series | 396 |
Chapter 17: Determinants | ||
1 | Matrices | 401 |
2 | Determinants of order 2 | 406 |
3 | Properties of 2 x 2 determinants | 409 |
4 | Determinants of order 3 | 414 |
5 | Properties of 3 x 3 determinants | 418 |
6 | Cramer's Rule | 424 |
Index | 429 |