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Learning Functions with Sesame Street
By: Tom Caron, Stephen Joseph, Marianne
Mousigian, and Leslie Savage
~*Exponential Function*~
Exponential Equation:
y=abx
Where: a does not equal b, b>0, and b does not equal 1.
Domain: set of all real numbers
Range: Set of all positive real numbers
Intercepts: Y intercept is 1
Asymptotes: the x axis
Exponential Growth and Decay
• The graph on the left shows an example of exponential growth with an equation of y=5x
• The graph on the right shows an example of exponential decay with an equation of y=.7x
~* Real-life Situation *~• Cookie Monster is baking cookies because he
only has cookie left in is cookie jar. He decides to bake 1 extra large cookie. While adding the eggs he accidentally tipped over the yeast into the bowl. He didn’t realize this until he took the cookie out of the oven and saw how big the cookie was. If the cookie goes into the oven with a diameter of 6 inches by 3 inches every 20 minutes how large will the cookie be when Cookie takes it out of the oven in an hour and a half?
Process
• For this situation we have come up with this equation to graph.
• 6 x 3 ^ 6.5
This graph models the real life situation.
Solution
~* Linear Function *~
Linear Equation in Slope Intercept Form y= mx+b
Where: m= slope
b= y-intercept (or initial condition)
Domain: set of real numbers
Range: set of real numbers
Constant increase situation: positive slope (m)
Constant decrease situation: negative slope (-m)
Extra InformationExtra Information
*Graphs with same slope (m) in y= mx+b form are parallel lines.
* If 2 non-vertical lines are parallel, then they have the same slope.
Standard form: Ax+By= C
Point-slope form: y-y1 = m(x-x1) where m is the slope
* The graph of Ax+By= C where A and B are not 0, is a line.
Horizontal and Vertical Lines
• The graph to the direct left models the equation X=3. It is an example of a vertical line. The slope is undefined.
• The graph to the direct left models the equation y=3. It is an example of a vertical line. The slope = 0.
Process for Oblique lines• Question:
Graph the equation 6x-3y=12
Answer:First find the x-intercept 6x-3(0)=12
x=2Then find the y-intercept 6(0)-3y=12
y=-4On the next page you will find the points (2,0)
and (0,-4) plotted on a graph. A line has been drawn that contains these 2 points.
•Oblique lines: (Ex: the line y = x) When in Ax+ By= C form, the slope equals
(– A/B when A and B are not equal to 0)
The graph to the right models the equation
6x-3y=12.
The line passes through the origin an x-intercept of 2 and a y-intercept of –4.
~* Real-life Situation *~ Zoe’s house is 5,280 feet away from Elmo’s house.
Elmo is walking Zoe home from his house. They are currently 100 feet from Elmo’s house and are moving at a rate of 10 feet per 7 seconds. If they continue to walk at this rate, how much longer in minutes will it take them to reach Zoe’s house?
This graph models the real life situation. As the graph shows this equation has a negative slope because the further they
walk the closer they get to their destination.
Process
• With this we plot the intercepts (5280,0) and (0,5280) and connect the line. We then use linear regression in to find the equation which is:
y = -1x+5280
Here we now have to take the total distance and subtract that from the distance already traveled.
5280 – 100ft = 2180ft
Now we see that for every 10ft traveled it takes 7 seconds. So we divide the distance left by the rate which is 10.
5180/10 = 518
Process (continued)
Now multiply by the time it takes to travel this which is 7 seconds per ten feet.
518 (7) = 3626 seconds
Now it asks for this time in minutes so you have to convert this value into minutes by dividing it by 60.
3626/60 = 60.433
60.4 minutes more minutes until they reach Zoe’s house from Elmo’s.
Solution
At the constant speed of 10ft per 7seconds, it will take 60.4 more minutes until they reach Zoe’s house from Elmo’s.
~*Power Function*~
Equation:
f(x)=xn where n is a positive integer
Domain: set of all real numbers
Range: when nn is positive = all positive real numbers
when nn is negative = set of all real numbers
Asymtotes:
Extra Information
Symmetry:
When nn is even: Reflectional symmetry to the y-axis
when nn is odd: Rotational Symmetry of 180 degrees around the origin
Postulates:Product of powers – x^m times x^n = x^(m+t)
Power of Power – (x^m)^n = x^(mn)
Power of Product – (xy)^n = x^n times y^n
Quotient of powers – For x not equaling 0 (x^m)/(x^n) = x^(m-n)
Simple Power Functions
• Graph to the left represents the equation f(x)=x, or the identity function.
• The Graph to the left represents the equation f(x)=x2, or the squaring function.
The graph at the left models the function f(x)=x3, or the cubing function.
~*Real Life Situation*~
Big Bird is opening his first savings account. If he puts his life savings of 14 cents in the bank, at a rate of 9% compounded quarterly, how long will it take him to accumulate a whole dollar?
Process
First we create the power function expression. Which is modeled after:
A = P(1+(r/n)nt
When PP is the principal amount deposited, rr is the rate, nn is the # of times interest is
calculated in one year, and tt is the years
The equation is :
0.14(1+(.09/4))4t
This graph models the real life situation.
Solution
Using the data table to find the value of xx when yy was equal to or greater than 1.00
When yy is 1.03 , xx is 6.75 so it took six years and nine months to accumulate one dollar.
Big Bird thanks you with his whole heart!!
~*Quadratic Function*~
Equation:ax2+bx+c=0 : standard from of a quadratic
Domain:
Set of all real numbers
Range:
Determined by examining the graph of the function
~*Real Life Example*~
Bert and Ernie are in a jam. They need to know the total area of their pool and surrounding walkway. Rubber ducky is refusing to return Bert’s paper clips and bathe with Ernie until he is told the answer. Their pool is a rectangle with a length of 50 + 2w meters and a width of 20 + 2w meters. “w” is the width of their walkway which is 5 meters.
Process
• To solve we draw a diagram then expand the binomial:
= (50 + 2w)(20 + 2w)
= (50 + 2w) * 20 + (50 + 2w) * 2w
= 1000 + 40w + 100w + 4w2
= 4w2 + 140w + 1000
• Now we use the graph to find the y y value when xx is equal to 5.
The graph shows the curve like shape that is a characteristic of all Quadratic Expressions.
Solution
4w2 + 140w + 1000 when (w = 5 )
4(5)2 + 140(5) + 1000
100 + 700 + 1000
1800m2
When xx is equal to five yy is 1800m2
Solution
• Rubber ducky was so happy that we solved this that he returned Bert’s paper clips and bathed with Ernie instantly. Thank you so much!
~*Polynomial Equations*~
• Expression: Anxn + An-1xn-1 + An-2xn-2 …+ A1x1 +A0
• Domain: all real numbers
• Range: all real numbers
• Intercepts: N/A
• Asymptote: none
Extra Information
• Leading Coefficient is An
• Degree is the largest exponent of xx which is nn
• The number nn the degree of the polynomial
• This is sometimes called the nnth degree polynomial
~*Real Life Situation*~ Grover has a problem he just can’t figure out. Can
you help him?… Great!
His cousin , Clover, back in Bun Town has decided to attend college. She is planning to attend the fall after her senior year but it costs $5,000.00. So she is saving during the next four years of high school.
She plans to save $2,000.00 her Freshmen year, $1,450.00 her Sophomore year, only $750.00 her Junior year, and $500.00 her Senior year. At the end of each year she will put the money in a savings account with an annual yield of 7%. Will Clover have enough money to attend college?
Process
Since Clover will deposit her Freshmen savings at the end of the year it will collect interest for three years. Her sophomore savings will collect for two years, her junior savings will save for only one year, and her senior savings will not collect interest at all. With this we write the following equation.
2000(1.07)^3 + 1450(1.07)^2 + 750(1.07)^1 + 500
The graph above models the real life situation.
Process (continued)
2000(1.07)^3 + 1450(1.07)^2 + 750(1.07)^1 + 500
2450.086 + 1450(1.07)^2 + 750(1.07)^1 + 500
2450.086 + 1660.105 + 750(1.07)^1 + 500
2450.086 + 1660.105 + 802.5 +500
4110.191 + 1302.5
5412.691 ~ $5412.70
Answer
The polynomial solves out to be approximately $5412.70. This is enough for Clover to attend college. Grover is ecstatic to tell his cousin that she will be able to attend and wants to thank you for your hard work.
• Here is Grover and Clover and her cat Cinnamon (left) and Grover saying “thank you”(bottom).
~* Logarithmic Functions *~ Common Logs: log to the base of ten written as
logbx=y which equals by=x iff. B>0 and not 1.
Natural Logs: logs with bases of eWritten as lnln for short:
ln1=0 since e0=1
Logs with bases different then ten: log to the base specified. Written as:
Log22=y or 2y=2
~* Logarithmic Functions *~Properties of logbx=y • Domain: all positive real• Range: all real• X-intercept is always one• Asymptote: y-axisProperties of common Log:• Domain: all positive real• Range: real numbers• Asymptote: x-axis and y-axis• x and y intercepts are always one Properties of Natural Log:• Domain: all positive real• Range: all real• Asymptotes: y-axis
Real Life Situation
• Grouch is mad because it is too loud for him. He closes his garbage lid but can still hear everything. He petitioned to make a noise ordinance but needs substantial evidence that it is to loud for him. He has measured the noise to be a whooping 1000 watts/ m2. He is recruiting us to help him on his mission that cannot fail. The comfort zone of hearing is between 20 decibels and 25 decibels. Can Grouch get the ordinance passed on Sesame Street?
Process
• We recall the formula:
D=10(log N + 12)
which converts the number of decibels D D from the sound intensity NN measured in
watts/m2.
So we plug the value of 1000 watts/m2 into the equation as N. And solve
Process (continued)
D=10(log N + 12)
D=10(log 1000 + 12)
D=10(log 1012)
D=10(3.00518)
D=30.0518
So there is noise up to 30 decibels on Sesame Street.
Solution
D=30.0518
This over the Grouches comfort zone of 20- 25 decibels. Thanks to you the Grouch got his way and in turn became less grouchy, well for a day anyways. And surprisingly
he thanks you. Good work!
How to Tell Them Apart
• Linear Functions are a straight line when graphed.• Exponential Functions, either growth of decay,
have a curve to them when graphed where there is no x-intercept and the y-intercept is one.
• Polynomial Functions have the longest formula of all and has the minimum of two intercepts.
• Quadratic Functions have the unmistacabel bell shape to them. They have a maximum of two x-intercepts.
• Logarithmic Functions have no y-intercept and the x-intercept is always one.