Presentation is loading. Please wait.

Presentation is loading. Please wait.

Limits, Continuity, Basic Differentiability, and Computing Derivatives

Published byMercy Gibson Modified over 5 years ago

Similar presentations

Presentation on theme: "Limits, Continuity, Basic Differentiability, and Computing Derivatives"— Presentation transcript:

1 Limits, Continuity, Basic Differentiability, and Computing Derivatives
By: Sameer, Snigdha, Aditya

2 Limits Recall that… A limit is when a function gets super close to a number from both sides of x, but the function never reaches that number… It’s predicting a number between two neighboring points. Let’s think about how we can solve these

3 Solving Limits - Ex1: Make a table
-0.1 -.01 -.001 0.001 0.01 0.1 Y Plug in on your calculator!

4 Solving Limits - Ex1: Make a table (cont.)
-0.1 -.01 -.001 0.001 0.01 0.1 Y 0.998 0.999 1 Therefore, the answer is 1 because as x approaches 0 from both sides, the value of the limit gets closer and closer to 1.

5 Solving Limits - Ex2: Graph
As x approaches 0 from both sides, what does f (x) get arbitrarily close to? lim f(x) = 2 x->0

6 Solving Limits - Ex3: Direct Substitution
When a function is given, your first tactic to solving a limit should be plugging in the value the limit approaches. Plug in x = 5!

7 Solving Limits - Ex4: Factoring/Simplifying
If direct substitution yields an indeterminate answer (0/0 or infinity/infinity), try factoring!

8 Solving Limits - Ex4: Factoring/Simplifying
Let’s try factoring.... And now let’s simplify... Now when we use direct substitution, we get 8/2, which is 4

9 Solving Limits - Ex5: Rationalizing the Numerator/Denominator
When you can’t use direct substitution or factoring, check for a radical and try rationalizing the numerator or denominator

10 Solving Limits - Ex5: Rationalizing the Numerator/Denominator
Multiply either the numerator or denominator by a radical that will get rid of the radical sign and use a different sign for the second term…

11 Solving Limits - Ex5: Rationalizing the Numerator/Denominator
Then, simplify:

12 Solving Limits - Ex5: Rationalizing the Numerator/Denominator
Finally, use direct substitution:

13 Limits - Does Not Exist (DNE)
This limit does not exist because on the limit from the left of x approaches 1 while on the right side of x it approaches 2.

14 Limits - Vertical Asymptotes
If f(x) approaches infinity or negative infinity as x approaches c from the right or left, then there is a vertical asymptote at x = c lim f(x) = infinity; therefore VA x->0

15 Limits - Vertical Asymptotes (cont.)
A constant divided by a small number yields infinity: This indicates a potential vertical asymptote

16 Limits - Horizontal Asymptote
The line y = L is a horizontal tangent if limit as x approaches infinity for f(x) = L

17 Limits - Horizontal Asymptotes (cont.)
Use coefficient rule: if highest power in the numerator and denominator match, then divide the coefficients for the limit/horizontal asymptote =3/2 If the power is smaller in numerator or the numerator has a slower function then the limit goes to 0.

18 Continuity Consider this hole in the road...is the road continuous?

19 Continuity - Definition
Most of you probably agreed that the road is not continuous...you wouldn’t want to drive over that! But...what would make the road continuous? Well, the road would have to: -Fill the hole (discontinuity filled by f(c)) -There would have to be road on either side of the road (limit must exist) -The road on either side and the filled in hole would have to connect (limit must equal f(c)

20 Continuity - Definition (cont.)
Similarly in calculus these rules also apply! The limit as x approaches c for f(x) must exist f(c) must exist and have a value The limit as x approaches c for f(x) must equal f(c) Now, justify if each of the points are continuous or not.

21 Continuity - Justification
Continuous.The limit as x approaches 0 is 1 and f(0) is also 1 Discontinuous. The limit as x approaches -2 does not exist Discontinuous. The limit as x approaches 3 is 0, but f(3) is -1. Therefore there is a discontinuity at x = 3

22 Continuity - Practice Problem
Hmm...let’s use the definition of continuity to solve this problem

23 Continuity - Practice Problem (cont.)
First, let’s look at x=1. f(1) = 2 so the limit as x approaches 1 must also equal 2. Use direct substitution!

24 Continuity - Practice Problem (cont.)
Plugging in x=1 gives us a + b = 2 Now let’s look at x = 3. f(3) gives -2 so the limit as x approaches 3 must also be -2. Again, use direct substitution… Plugging in x=3 gives us 3a + b = -2

25 Continuity - Practice Problem (cont.)
Now, setup a system of equations: a + b = 2 3a + b = -2 Solving for a gives - 2a = 4 a = -2. Plugging back in, we get -2 + b = 2, and b = 4

26 Basic Differentiability
A function is differentiable if its derivative exists at every point on its domain. A derivative is essentially the slope of a function and is denoted as f’(x) Differentiability implies Continuity However, continuity does not mean a function is 100% differentiable

27 Basic Differentiability - Non-differentiable functions
Corner Cusp

28 Basic Differentiability - Non-differentiable functions (cont.)
Vertical Tangent Jump Discontinuity

29 Computing a Derivative
Formal Definition of a Derivative This simply means the derivative of cos(x) at x= pi

30 Computing a Derivative - Polynomials
Here’s the formula for computing a derivative* *Note: there are special ways to derive trig, logarithmic, e^x, and other special case functions

31 Computing a Derivative - Polynomials (cont.)

32 Computing a Derivative - Rational Functions
Quotient Rule: When computing functions with quotients, you must use quotient rule.

33 Computing a Derivative - Rational Functions (cont.)
Use quotient rule!

34 Computing a Derivative - Rational Functions (cont.)
Derivative of f(x)!

35 Computing a Derivative - Trigonometric Functions
Memorize these Trig Derivatives!

36 Computing a Derivative - Trigonometric Functions (cont.)
Quick introduction to chain rule: a derivative rule in which nested functions must be included in the derivative.

37 Computing a Derivative - Trigonometric Functions (cont.)
h(x) = sin(2x)...Find the derivative f(x) = sin(x) g(x) = 2x so: h’(x) = cos(2x)*2 or 2cos(2x)

38 Computing a Derivative - Exponential/Logarithmic Functions
You should know these derivatives:

39 Computing a Derivative - Exponential/Logarithmic Functions (cont.)
Finally, product rule:`

40 Computing a Derivative - Exponential/Logarithmic Functions (cont.)
Let’s take the derivative of this! Using chain rule, we get:

41 That’s All Folks… FIN.

Download ppt "Limits, Continuity, Basic Differentiability, and Computing Derivatives"

Similar presentations

Limits and Continuity Definition Evaluation of Limits Continuity

Limits and Continuity Definition Evaluation of Limits Continuity
Rational Expressions, Vertical Asymptotes, and Holes.

Rational Expressions, Vertical Asymptotes, and Holes.
3208 Unit 2 Limits and Continuity

3208 Unit 2 Limits and Continuity
WARM UP: Factor each completely

WARM UP: Factor each completely
Finding Limits Graphically and Numerically An Introduction to Limits Limits that Fail to Exist A Formal Definition of a Limit.

Finding Limits Graphically and Numerically An Introduction to Limits Limits that Fail to Exist A Formal Definition of a Limit.
AP CALCULUS 1003 Limits pt.3 Limits at Infinity and End Behavior.

AP CALCULUS 1003 Limits pt.3 Limits at Infinity and End Behavior.
3.7 Graphing Rational Functions Obj: graph rational functions with asymptotes and holes and evaluate limits of rational functions.

3.7 Graphing Rational Functions Obj: graph rational functions with asymptotes and holes and evaluate limits of rational functions.
Announcements Topics: -finish section 4.2; work on sections 4.3, 4.4, and 4.5 * Read these sections and study solved examples in your textbook! Work On:

Announcements Topics: -finish section 4.2; work on sections 4.3, 4.4, and 4.5 * Read these sections and study solved examples in your textbook! Work On:
Continuity 2.4.

Continuity 2.4.
State Standard – 1.0 Students demonstrate knowledge of limit of values of functions. This includes one-sided limits, infinite limits, and limits at infinity.

State Standard – 1.0 Students demonstrate knowledge of limit of values of functions. This includes one-sided limits, infinite limits, and limits at infinity.
Calculus 1.1: Review of Trig/Precal A. Lines 1. Slope: 2. Parallel lines—Same slope Perpendicular lines—Slopes are opposite reciprocals 3. Equations of.

Calculus 1.1: Review of Trig/Precal A. Lines 1. Slope: 2. Parallel lines—Same slope Perpendicular lines—Slopes are opposite reciprocals 3. Equations of.
9.3 Rational Functions and Their Graphs Rational Function – A function that is written as, where P(x) and Q(x) are polynomial functions. The domain of.

9.3 Rational Functions and Their Graphs Rational Function – A function that is written as, where P(x) and Q(x) are polynomial functions. The domain of.
Infinite Limits Lesson 1.5.

Infinite Limits Lesson 1.5.
1.5 Infinite Limits IB/AP Calculus I Ms. Hernandez Modified by Dr. Finney.

1.5 Infinite Limits IB/AP Calculus I Ms. Hernandez Modified by Dr. Finney.
1.5 Infinite Limits and 3.5 Limits at Infinity AP Calculus I Ms. Hernandez (print in grayscale or black/white)

1.5 Infinite Limits and 3.5 Limits at Infinity AP Calculus I Ms. Hernandez (print in grayscale or black/white)
3.3 Rules for Differentiation AKA “Shortcuts”. Review from 3.2 4 places derivatives do not exist: ▫Corner ▫Cusp ▫Vertical tangent (where derivative is.

3.3 Rules for Differentiation AKA “Shortcuts”. Review from places derivatives do not exist: ▫Corner ▫Cusp ▫Vertical tangent (where derivative is.
Introduction to Rational Equations 15 November 2010.

Introduction to Rational Equations 15 November 2010.
Definition of a Rational Function A rational function is a quotient of polynomials that has the form The domain of a rational function consists of all.

Definition of a Rational Function A rational function is a quotient of polynomials that has the form The domain of a rational function consists of all.
Limits and Their Properties. Limits We would like to the find the slope of the tangent line to a curve… We can’t because you need TWO points to find a.

Limits and Their Properties. Limits We would like to the find the slope of the tangent line to a curve… We can’t because you need TWO points to find a.
Calculus Chapter One Sec 1.5 Infinite Limits. Sec 1.5 Up until now, we have been looking at limits where x approaches a regular, finite number. But x.

Calculus Chapter One Sec 1.5 Infinite Limits. Sec 1.5 Up until now, we have been looking at limits where x approaches a regular, finite number. But x.

Similar presentations

Ads by Google