The updated tenth edition of this clear, precise calculus text with superior applications sets the standard in calculus. This proven text was carefully revised to give students the solid base they need to succeed in math, science and engineering programs. Through a comprehensive technology package, this edition now includes more opportunity to incorporate optional, but meaningful, technology into the course.
(Practice Exercises, Additional Exercises, and Questions to Guide Your Review appear at the end of each chapter.) P. Preliminaries. Lines. Functions and Graphs. Exponential Functions. Inverse Functions and Logarithms. Trigonometric Functions and Their Inverses. Parametric Equations. Modeling Change. 1. Limits and Continuity. Rates of Change and Limits. Finding Limits and One-Sided Limits. Limits Involving Infinity. Continuity. Tangent Lines. 2. Derivatives. The Derivative as a Function. The Derivative as a Rate of Change. Derivatives of Products, Quotients, and Negative Powers. Derivatives of Trigonometric Functions. The Chain Rule and Parametric Equations. Implicit Differentiation. Related Rates. 3. Applications of Derivatives. Extreme Values of Functions. The Mean Value Theorem and Differential Equations. The Shape of a Graph. Graphical Solutions of Autonomous Differential Equations. Modeling and Optimization. Linearization and Differentials. Newtons Method. 4. Integration. Indefinite Integrals, Differential Equations, and Modeling. Integral Rules; Integration by Substitution. Estimating with Finite Sums. Riemann Sums and Definite Integrals. The Mean Value and Fundamental Theorems. Substitution in Definite Integrals. Numerical Integration. 5. Applications of Integrals. Volumes by Slicing and Rotation About an Axis. Modeling Volume Using Cylindrical Shells. Lengths of Plane Curves. Springs, Pumping, and Lifting. Fluid Forces. Moments and Centers of Mass. 6. Transcendental Functions and Differential Equations. Logarithms. Exponential Functions. Derivatives of Inverse Trigonometric Functions; Integrals. First-Order Separable Differential Equations. Linear First-Order Differential Equations. Eulers Method; Population Models. Hyperbolic Functions. 7. Integration Techniques, LHopitals Rule, and Improper Integrals. Basic Integration Formulas. Integration by Parts. Partial Fractions. Trigonometric Substitutions. Integral Tables, Computer Algebra Systems, and Monte Carlo Integration. LHopitals Rule. Improper Integrals. 8. Infinite Series. Limits of Sequences of Numbers. Subsequences, Bounded Sequences, and Picards Method. Infinite Series. Series of Nonnegative Terms. Alternating Series, Absolute and Conditional Convergence. Power Series. Taylor and Maclaurin Series. Applications of Power Series. Fourier Series. Fourier Cosine and Sine Series. 9. Vectors in the Plane and Polar Functions. Vectors in the Plane. Dot Products. Vector-Valued Functions. Modeling Projectile Motion. Polar Coordinates and Graphs. Calculus of Polar Curves. 10. Vectors and Motion in Space. Cartesian (Rectangular) Coordinates and Vectors in Space. Dot and Cross Products. Lines and Planes in Space. Cylinders and Quadric Surfaces. Vector-Valued Functions and Space Curves. Arc Length and the Unit Tangent Vector T. The TNB Frame; Tangential and Normal Components of Acceleration. Planetary Motion and Satellites. 11. Multivariable Functions and Their Derivatives. Functions of Several Variables. Limits and Continuity in Higher Dimensions. Partial Derivatives. The Chain Rule. Directional Derivatives, Gradient Vectors, and Tangent Planes. Linearization and Differentials. Extreme Values and Saddle Points. Lagrange Multipliers. Partial Derivatives with Constrained Variables. Taylors Formula for Two Variables. 12. Multiple Integrals. Double Integrals. Areas, Moments and Centers of Mass. Double Integrals in Polar Form. Triple Integrals in Rectangular Coordinates. Masses and Moments in Three Dimensions. Triple Integrals in Cylindrical and Spherical Coordinates. Substitutions in Multiple Integrals. 13. Integration in Vector Fields. Line Integrals. Vector Fields, Work, Circulation, and Flux. Path Independence, Potential Functions, and Conservative Fields. Greens Theorem in the Plane. Surface Area and Surface Integrals. Parametrized Surfaces. Stokes Theorem. Divergence Theorem and a Unified Theory. Appendices. Mathematical Induction. Proofs of Limit Theorems in Section 1.2. Proof of the Chain Rule. Complex Numbers. Simpsons One-Third Rule. Cauchys Mean Value Theorem and the Stronger Form of LHopitals Rule. Limits That Arise Frequently. Proof of Taylors Theorem. The Distributive Law for Vector Cross Products. Determinants and Cramers Rule. The Mixed Derivative Theorem and the Increment Theorem. The Area of a Parallelograms Projection on a Plane. Conic Sections.