2.1 day 2: Step Functions “Miraculous Staircase” Loretto Chapel, Santa Fe, NM Two 360 o turns without support! Greg Kelly, Hanford High School, Richland,

Slides:

Advertisements

Similar presentations

2.2 Limits Involving Infinity

Advertisements

2.3 Continuity Grand Canyon, Arizona Created by Greg Kelly, Hanford High School, Richland, Washington Revised by Terry Luskin, Dover-Sherborn HS, Dover,

2.1 day 2: Step Functions “Miraculous Staircase” Loretto Chapel, Santa Fe, NM Two 360 o turns without support! Greg Kelly, Hanford High School, Richland,

4.1 Extreme Values of Functions Greg Kelly, Hanford High School, Richland, Washington Borax Mine, Boron, CA Photo by Vickie Kelly, 2004.

Solving One-step Inequalities. Inequalities Inequalities are similar to equations when solving. You can add, subtract, multiply or divide any amount to.

Introduction A step function is a function that is a series of disconnected constant functions. This type of function is also referred to as a stair.

4.1 Extreme Values of Functions Greg Kelly, Hanford High School, Richland, Washington Borax Mine, Boron, CA Photo by Vickie Kelly, 2004.

Piecewise Functions and Step Functions

2.1 Rates of Change and Limits Greg Kelly, Hanford High School, Richland, WashingtonPhoto by Vickie Kelly, 2007 Grand Teton National Park, Wyoming.

1.4 Parametric Equations Greg Kelly, Hanford High School, Richland, WashingtonPhoto by Greg Kelly, 2005 Mt. Washington Cog Railway, NH.

Using the Sandwich theorem to find. If we graph, it appears that.

Continuity Grand Canyon, Arizona Greg Kelly, Hanford High School, Richland, WashingtonPhoto by Vickie Kelly, 2002.

Warmup: Without a calculator find: 1). 2.1c: Rate of Change, Step Functions (and the proof using sandwich th.) (DAY 3) From:

9.3 Taylor’s Theorem: Error Analysis for Series

2.1 day 1: Step Functions “Miraculous Staircase” Loretto Chapel, Santa Fe, NM Two 360 o turns without support!

1998 AB Exam. 1.4 Parametric Equations Greg Kelly, Hanford High School, Richland, WashingtonPhoto by Greg Kelly, 2005 Mt. Washington Cog Railway, NH.

2.3 Continuity Grand Canyon, Arizona Greg Kelly, Hanford High School, Richland, WashingtonPhoto by Vickie Kelly, 2002.

3.8 Derivatives of Inverse Trig Functions Lewis and Clark Caverns, Montana Greg Kelly, Hanford High School, Richland, WashingtonPhoto by Vickie Kelly,

Piecewise Functions.

2.3 Continuity Grand Canyon, Arizona Greg Kelly, Hanford High School, Richland, WashingtonPhoto by Vickie Kelly, 2002.

2.1 Rates of Change and Limits. Suppose you drive 200 miles, and it takes you 4 hours. Then your average speed is: If you look at your speedometer during.

Differential equations and Slope Fields Greg Kelly, Hanford High School, Richland, Washington.

2.2 Limits Involving Infinity Greg Kelly, Hanford High School, Richland, Washington.

2.1: Rates of Change & Limits Greg Kelly, Hanford High School, Richland, Washington.

2.1: Rates of Change & Limits. Suppose you drive 200 miles, and it takes you 4 hours. Then your average speed is: If you look at your speedometer during.

Comparing and Ordering Integers LESSON 6-2 Compare –12 and –10. Since –12 is to the left of –10, –12 < –10. Graph –12 and –10 on the same number line.

Substitution & Separable Differential Equations

2.3 The Product and Quotient Rules (Part 1)

Rates of Change and Limits

Rates of Change and Limits

Differential Equations by Separation of Variables

3.8 Derivatives of Inverse Trig Functions

3.6 part 2 Derivatives of Inverse Trig Functions

Substitution & Separable Differential Equations

2.1 day 2: Step Functions “Miraculous Staircase”

2.3 Continuity Grand Canyon, Arizona

6.4 day 1 Separable Differential Equations

2.3 Continuity Grand Canyon, Arizona

Optimisation: Extreme Values of Functions

Extreme Values of Functions

Mark Twain’s Boyhood Home

Mark Twain’s Boyhood Home

Derivatives of Inverse Trig Functions

Substitution & Separable Differential Equations

Separable Differential Equations

3.8 Derivatives of Inverse Trig Functions

5.3 Inverse Function (part 2)

“Step functions” are sometimes used to describe real-life situations.

Integration by Substitution M.L.King Jr. Birthplace, Atlanta, GA

5.4 First Fundamental Theorem

3.8 Derivatives of Inverse Trig Functions

1.4 Parametric Equations Mt. Washington Cog Railway, NH

2.2 Limits Involving Infinity

2.2: Rates of Change & Limits

Looks like y=1.

3.2 Differentiability Arches National Park

A step function has the same y-value for several x-values and then steps up or down to another y-value.  The graph looks like stair steps.

2.3: Limit Laws and Step Functions

2.4 Continuity Grand Canyon, Arizona

Substitution & Separable Differential Equations

4.6 The Trapezoidal Rule Mt. Shasta, California

1.4 Parametric Equations Mt. Washington Cog Railway, NH

3.2 Differentiability Arches National Park

2.5 Limits Involving Infinity

Bell-ringer 9/21/09 Graph the function:

Rates of Change and Limits

Limits Involving Infinity

5.3 Inverse Function (part 2)

Substitution & Separable Differential Equations

Presentation transcript:

2.1 day 2: Step Functions “Miraculous Staircase” Loretto Chapel, Santa Fe, NM Two 360 o turns without support! Greg Kelly, Hanford High School, Richland, Washington Photo by Vickie Kelly, 2003

“Step functions” are sometimes used to describe real-life situations. Our book refers to one such function: This is the Greatest Integer Function. The TI-nspire contains the command, but it is important that you understand the function rather than just entering it in your calculator.

Greatest Integer Function:

This notation was introduced in 1962 by Kenneth E. Iverson. Recent by math standards! Greatest Integer Function: The greatest integer function is also called the floor function. The notation for the floor function is: We will not use these notations. Some books use or.

The TI-nspire command for the floor function is either int (x) or floor (x). Graph the floor function. Use Zoom – Standard. F floor( Notice that the calculator does not include the open and closed circles at the endpoints.

Least Integer Function:

The least integer function is also called the ceiling function. The notation for the ceiling function is: Least Integer Function: The TI-nspire command for the ceiling function is ceiling (x). Don’t worry, there are not wall functions, front door functions, fireplace functions!

Using the Sandwich theorem to find

If we graph, it appears that

We might try to prove this using the sandwich theorem as follows: Unfortunately, neither of these new limits are defined, since the left and right hand limits do not match. We will have to be more creative. Just see if you can follow this proof. Don’t worry that you wouldn’t have thought of it. Unfortunately, neither of these new limits are defined, since the left and right hand limits do not match.

(1,0) 1 Unit Circle P(x,y) Note: The following proof assumes positive values of. You could do a similar proof for negative values.

(1,0) 1 Unit Circle P(x,y) T AO

(1,0) 1 Unit Circle P(x,y) T AO

(1,0) 1 Unit Circle P(x,y) T AO

(1,0) 1 Unit Circle P(x,y) T AO

(1,0) 1 Unit Circle P(x,y) T AO

(1,0) 1 Unit Circle P(x,y) T AO

(1,0) 1 Unit Circle P(x,y) T AO

(1,0) 1 Unit Circle P(x,y) T AO

multiply by two divide by Take the reciprocals, which reverses the inequalities. Switch ends.

By the sandwich theorem: 