Chapter 1 Functions and limits
1.1 Mappings and functions
1.1.1 Sets
1.1.2 Mappings
1.1.3 Functions
Exercise 1-1
1.2 Limits of sequences
1.2.1 Concept of limits of sequences
1.2.2 Properties of convergent sequences
Exercise 1-2
1.3 Limits of functions
1.3.1 Definitions of limits of functions
1.3.2 The properties of functional limits
Exercise 1-3
1.4 Infinitesimal and infinity quantity
1.4.1 Infinitesimal quantity
1.4.2 Infinity quantity
Exercise 1-4
1.5 Rules of limit operations
Exercises 1-5
1.6 Principle of limit existence two important limits
Exercise 1-6
1.7 Comparing with two infinitesimals
Exercise 1-7
1.8 Continuity of functions and discontinuous points
1.8.1 Continuity of functions
1.8.2 Discontinuous points of functions
Exercise 1-8
1.9 Operations on continuous functions and the continuity of elementary functions
1.9.1 Continuity of the sum,difference,product and quotient of continuous functions
1.9.2 Continuity of inverse functions and composite functions
1.9.3 Continuity of elementary functions
Exercise 1-9
1.10 Properties of continuous functions on a closed interval
1.10.1 Boundedness and maximum-minimum theorem
1.10.2 Zero point theorem and intermediate value theorem
*1.10.3 Uniform continuity
Exercise 1-10
Exercise 1
Chapter 2 Derivatives and differential
2.1 Concept of derivatives
2.1.1 Examples
2.1.2 Definition of derivatives
2.1.3 Geometric interpretation of derivative
2.1.4 Relationship between derivability and continuity
Exercise 2-1
2.2 Fundamental Derivation Rules
2.2.1 Derivation rules for sum,difference,product and quotient of functions
2.2.2 The rules of derivative of inverse functions
2.2.3 The rules of derivative of composite functions(The Chain Rule)
2.2.4 Basic derivation rules and derivative formulas
Exercise 2-2
2.3 Higher-order derivatives
Exercise 2-3
2.4 Derivation of implicit functions and functions defined by parametric equations
2.4.1 Derivation of implicit functions
2.4.2 Derivation of a function defined by parametric equations
2.4.3 Related rates of change
Exercise 2-4
2.5 The Differentials of functions
2.5.1 Concept of the differential
2.5.2 Geometric meaning of the differential
2.5.3 Formulas and rules on differentials
2.5.4 Application of the differential in approximate computation
Exercise 2-5
Exercise 2
Chapter 3 Mean value theorems in differential calculus and applications of derivatives
3.1 Mean value theorems in differential calculus
Exercise 3-1
3.2 L’Hospital’s rule
Exercise 3-2
3.3 Taylor formula
Exercise 3-3
3.4 Monotonicity of functions and convexity of curves
3.4.1 Monotonicity of functions
3.4.2 Convexity of curves and inflection points
Exercise 3-4
3.5 Extreme values of functions,maximum and minimum
3.5.1 Extreme values of functions
3.5.2 Maximum and minimum of function
Exercise 3-5
3.6 Differentiation of arc and curvature
3.6.1 Differentiation of an arc
3.6.2 Curvature
Exercise 3-6
Exercise 3
Chapter 4 Indefinite integral
4.1 Concept and property of indefinite integral
4.1.1 Concept of antiderivative and indefinite integral
4.1.2 Table of fundamental indefinite integrals
4.1.3 Properties of the indefinite integral
Exercise 4-1
4.2 Integration by substitutions
4.2.1 Integration by substitution of the first kind
4.2.2 Integration by substitution of the second kind
Exercise 4-2
4.3 Integration by parts
Exercise 4-3
4.4 Integration of rational function
4.4.1 Integration of rational function
4.4.2 Integration which can be transformed into the integration of rational function
Exercise 4-4
Exercise 4
Chapter 5 Definite integrals
5.1 Concept and properties of definite integrals
5.1.1 Examples of definite integral problems
5.1.2 The definition of define integral
5.1.3 Properties of definite integrals
Exercise 5-1
5.2 Fundamental formula of calculus
5.2.1 The relationship between the displacement and the velocity
5.2.2 A function of upper limit of integral
5.2.3 Newton-Leibniz formula
Exercise 5-2
5.3 Integration by substitution and parts for definite integrals
5.3.1 Integration by substitution for definite integrals
5.3.2 Integration by parts for definite integral
Exercise 5-3
5.4 Improper integrals
5.4.1 Improper integrals on an infinite interval
5.4.2 Improper integrals of unbounded functions
Exercise 5-4
5.5 Tests for Convergence of improper integrals Γ-function
5.5.1 Test for convergence of infinite integral
5.5.2 Test for convergence of improper integrals of unbounded functions
5.5.3 Γ-function
Exercise 5-5
Exercise 5
Chapter 6 Applications of definite integrals
6.1 Method of elements for definite integrals
6.2 The applications of the definite integral in geometry
6.2.1 Areas of plane figures
6.2.2 The volumes of solid
6.2.3 Length of plane curves
Exercise 6-2
6.3 The applications of the definite Integral in physics
6.3.1 Work done by variable force
6.3.2 Force by a liquid
6.3.3 Gravity
Exercise 6-3
Exercise 6
Chapter 7 Differential equations
7.1 Differential equations and their solutions
Exercise 7-1
7.2 Separable equations
Exercise 7-2
7.3 Homogeneous equations
7.3.1 Homogeneous equations
7.3.2 Reduction to homogeneous equation
Exercise 7-3
7.4 A first-order linear differential equations
7.4.1 Linear equations
7.4.2 Bernoulli’s equation
Exercise 7-4
7.5 Reducible second-order equations
7.5.1 y(n)=f(x)
7.5.2 y″=f(x,y′)
7.5.3 y″=f(y,y′)
Exercise 7-5
7.6 second-order linear equations
7.6.1 Construction of solutions of second-order linear equation
7.6.2 The method of variation of parameters
Exercise 7-6
7.7 Homogeneous linear differential equation with constant coefficients
Exercise 7-7
7.8 Nonhomogeneous linear differential equation with constant coefficients
7.8.1 f(x)=eλxPm(x)
7.8.2 f(x)=eλxP(1)l(x)cosωx+P(2)n(x)sinωx
Exercise 7-8
7.9 Euler’s differential equation
Exercise 7-9
Exercise 7
Reference