Exam 1 Math 1231: Single-Variable Calculus. Question 1: Limits.

Slides:

Advertisements

Similar presentations

The derivative as the slope of the tangent line (at a point)

Advertisements

2.1 The derivative and the tangent line problem

{ Semester Exam Review AP Calculus. Exam Topics Trig function derivatives.

Graphs of the Sine and Cosine Functions

Functions of Several Variables Copyright © Cengage Learning. All rights reserved.

Differentiating the Inverse. Objectives Students will be able to Calculate the inverse of a function. Determine if a function has an inverse. Differentiate.

Section 4.3 Indefinite Integrals and Net Change Theorem Math 1231: Single-Variable Calculus.

Section 5.5 – The Real Zeros of a Rational Function

Derivative as a function Math 1231: Single-Variable Calculus.

Section 4.3 Fundamental Theorem of Calculus Math 1231: Single-Variable Calculus.

Derivatives of Logarithmic Functions

Limits Basic facts about limits The concept of limit underlies all of calculus. Derivatives, integrals and series are all different kinds of limits. Limits.

10.2 Sequences Math 6B Calculus II. Limit of Sequences from Limits of Functions.

Math 1231: Single-Variable Calculus

Miss Battaglia BC Calculus. Alternative limit form of the derivative: provided this limit exists. Note the limit in this alternative form requires that.

Section 5.3 – The Definite Integral

4.4c 2nd Fundamental Theorem of Calculus. Second Fundamental Theorem: 1. Derivative of an integral.

Today in Calculus Go over homework Derivatives by limit definition Power rule and constant rules for derivatives Homework.

Warm-Up: Find f’(x) if f(x)=(3x 2 -6x+2) 3. SECTION 6.4: IMPLICIT DIFFERENTIATION Objective: Students will be able to…  Take the derivative of implicitly.

Antiderivatives An antiderivative of f(x) is any function F(x) such that F’(x) = f(x)

Section 4.1 Areas and Distances Math 1231: Single-Variable Calculus.

Chapter3: Differentiation DERIVATIVES OF TRIGONOMETRIC FUNCTIONS: Chain Rule: Implicit diff. Derivative Product Rule Derivative Quotient RuleDerivative.

4.2:Derivatives of Products and Quotients Objectives: Students will be able to… Use and apply the product and quotient rule for differentiation.

4.4 The Fundamental Theorem of Calculus If a function is continuous on the closed interval [a, b], then where F is any function that F’(x) = f(x) x in.

CHAPTER 4 SECTION 4.4 THE FUNDAMENTAL THEOREM OF CALCULUS.

5.4: Fundamental Theorem of Calculus Objectives: Students will be able to… Apply both parts of the FTC Use the definite integral to find area Apply the.

Warm up 1. Do in notebook. Be seated before the bell rings DESK homework Warm-up (in your notes) Agenda : warm-up Go over homework homework quiz Notes.

Section 2.5 Chain Rule Math 1231: Single-Variable Calculus.

Chapter 4 Additional Derivative Topics

Trigonometry Review Find sin(  /4) = cos(  /4) = tan(  /4) = Find sin(  /4) = cos(  /4) = tan(  /4) = csc(  /4) = sec(  /4) = cot(  /4) = csc(

Section 4.2 Definite Integral Math 1231: Single-Variable Calculus.

Math 1304 Calculus I 2.3 – Rules for Limits.

Review Limits When you see the words… This is what you think of doing…  f is continuous at x = a  Test each of the following 1.

Section 3.1 Maximum and Minimum Values Math 1231: Single-Variable Calculus.

Warmup 10-1 For the following questions, use the equation, h(t) = -5t t Find the height of the object at 5 seconds, or h(5). 2. What is.

Jarrod Asuncion Period 1 Brose. Equation f(b) – f(a) = f’(c) b – a Slope = f’(c)

Section 4.2 Rolle’s Theorem & Mean Value Theorem Calculus Winter, 2010.

1 3.2 The Mean Value Theorem. 2 Rolle’s Theorem 3 Figure 1 shows the graphs of four such functions. Figure 1 (c) (b) (d) (a) Examples:

5.3 Fundamental Theorem of Calculus Part 1 Fri Nov 20 Do Now Use geometry to compute the area represented by the integral.

Chapter 4: Polynomial and Rational Functions. Warm Up: List the possible rational roots of the equation. g(x) = 3x x 3 – 7x 2 – 64x – The.

Derivatives Derivatives By: Josh Hansen Brady Thompson Rex McArthur.

Section 3.9 Antiderivatives

Chapter 4: Polynomial and Rational Functions. Determine the roots of the polynomial 4-4 The Rational Root Theorem x 2 + 2x – 8 = 0.

Rate of Change and Derivative Math 1231: Single-Variable Calculus.

5.4 Second Fundamental Theorem of Calculus. If you were being sent to a desert island and could take only one equation with you, might well be your choice.

Warm up Problems More With Integrals It can be helpful to guess and adjust Ex.

Math 1304 Calculus I 1.6 Inverse Functions. 1.6 Inverse functions Definition: A function f is said to be one-to- one if f(x) = f(y) implies x = y. It.

Trigonometry Review Find sin(  /4) = cos(  /4) = tan(  /4) = Find sin(  /4) = cos(  /4) = tan(  /4) = csc(  /4) = sec(  /4) = cot(  /4) = csc(

Trigonometry Review Find sin(  /4) = cos(  /4) = tan(  /4) = Find sin(  /4) = cos(  /4) = tan(  /4) = csc(  /4) = sec(  /4) = cot(  /4) = csc(

Chapter 16B.5 Graphing Derivatives The derivative is the slope of the original function. The derivative is defined at the end points of a function on.

The Product Rule. Do Now  Find the derivative of f(x) = x(x 2 + 2x – 1).  What is the derivative of sinx? of cosx?

Calculus Section 5.3 Differentiate exponential functions If f(x) = e x then f’(x) = e x f(x) = x 3 e x y= √(e x – x) Examples. Find the derivative. y =

Chapter 1 Summary Math 1231: Single-Variable Calculus.

Section 3.2 Mean Value Theorem Math 1231: Single-Variable Calculus.

Math 1304 Calculus I 3.2 – Derivatives of Trigonometric Functions.

1. How do you confirm when you have a vertical or a horizontal asymptote Thought of the Day.

Calculus 6.1 Antiderivatives and Indefinite Integration.

MATH342: Numerical Analysis Sunjae Kim.

Mean Value Theorem.

3.3 Increasing and Decreasing Functions and the First Derivative Test

Important Values for Continuous functions

Exam2: Differentiation

Implicit Differentiation

Increasing, Decreasing, Constant

Derivatives: definition and derivatives of various functions

Exam2: Differentiation

MATH 1314 Lesson 6: Derivatives.

tangent line: (y - ) = (x - ) e2

2.3 The Product Rule Notice the order doesn’t matter!

Lesson 39 - Derivatives of Transcendental Functions

Presentation transcript:

Exam 1 Math 1231: Single-Variable Calculus

Question 1: Limits

Question 2: Implicit Function 1. Prove there is a root for the equation cosθ=θ in the interval (0, π). Define f(θ)=cosθ-θ, f(0)=1, f(π)=-1-π, f(θ) have opposite sign on the boundary points, IVP implies there is a root. 2. Prove there is a root for the equation cosy=y in the interval (0, π). Define f(y)=cosy-y, f(0)=1, f(π)=-1-π, f(y) have opposite sign on the boundary points, IVP implies there is a root. 3. Prove there is a root for the equation cosx=x in the interval (0, π). Define f(x)=cosx-x, f(0)=1, f(π)=-1-π, f(x) have opposite sign on the boundary points, IVP implies there is a root. Prove there is a root for the equation sqrt(y)=-1+y in the interval (0, 4). Define f(y)=sqrt(y)+1-y, f(0)=1, f(4)=-1, f(y) have opposite sign on the boundary points, IVP implies there is a root.

Question 2: Implicit Function Use parenthesis!!!

Question 2: Implicit Function

Question 3: Continuity and Derivative f(x) is continuous only if lim x  0 f(x)=f(0)=0. How to show that lim x  0 x 2 sin(1/x) =0?

Question 3: Continuity and Derivative Squeeze theorem

Question 3: Continuity and Derivative f(x) is continuous only if lim x  0 f(x)=f(0)=0. How to show that lim x  0 x 2 sin(1/x) =0? -1 <= sin(1/x) <= 1  -x 2 <= x 2 sin(1/x) <= x 2. Note that -x 2 and x 2 approach 0 as x goes to 0, so does x 2 sin(1/x).

Question 3: Continuity and Derivative

Question 4: Derivative Rules

Question 5: Related Rates