Assignment 5

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The family is defined by

y = A (x-h) ^ p + c for p = -3: A = 1, h = -3 to 3, c = 0.

Substituting p = -3, A = 1, h = -3 and c = 0 into the form y = A (x-h) ^ p + c we obtain

y = 1 * (x - (-3) ) ^ (-3) + 0 = 1 * (x + 3)^(-3), or just y = (x + 3)^3.

The values of p, A and c remain unchanged. The value of h, however, changes from -3 to 3. Using integer values -3, -2, -1, 0, 1, 2, 3 as representative values of h, our next step would be to substitute h = -2 along with the unchanged values of p, A and c. We would get

y = 1 * (x - (-2) ) ^ (-3) + 0 = 1 * (x + 2)^(-3), or just y = (x + 2)^3.

We would then substitute -1 for h, obtaining

y = 1 * (x - (-1) ) ^ (-3) + 0 = 1 * (x + 1)^(-3), or just y = (x + 1)^3.

We would continue this process until we readh h = 3, in which case we would get

y = 1 * (x - (3) ) ^ (-3) + 0 = 1 * (x - 3)^(-3), or just y = (x - 3)^3.

Our family would therefore have representative members

y = (x + 3)^3

y = (x + 2)^3

y = (x + 3)^3

y = (x + 0)^3 or just y = x^3

y = (x - 1)^3

y = (x - 2)^3

y = (x - 3)^3.

The pattern should be clear.

So we turn to actually constructing the graphs. Starting with the graph of y = (x + 3)^3:

The graph of (x + 3) ^ (-3) is the same as the graph of x^-3, just shifted left 3 units; when x is replaced by x + 3 the

same y values occur 3 units 'earlier', or 3 units 'to the left'.

To graph y = x^-3 you use the basic points.

For a power function the basic points are at x = -1, 0, 1/2, 1 and 2.

The corresponding values of x^-3 are -1, (undefined), 8, 1 and 1/8 (recall that x^-3 = 1 / x^3).

You should sketch these points on paper. Then you can observe the following:

In the first quadrant the points (1/2, 8), (1, 1) and (1/2, 1/8), along with the undefined value at x = 0, indicate a graph which decreases from a vertical asymptote with the positive y axis, toward a horizontal asymptote with the x axis.

The graph is symmetric with respect to the origin

• You can see this from the points (1, 1) and (-1, -1), and you can make sure by using the symmetry test f(-x) = - f(x); f(-x) = (-x)^3 = - x^3, and f(x) = x^3, so f(x) = -f(x).

• So the graph in the third quadrant is just a reflection through the origin of the first-quadrant graph.

• The graph in this quadrant falls as you go from left to right, descending from an asymptote along the negative x axis, though the point (-1, -1) to its vertical asymptote with the negative y axis. It should be clear that in the process the graph passes through the points (-2, -1/8), (-1, -1) and (-1/2, -8).

The instructor has chosen not to include a picture of the graph, which would divert most students from the process of actually constructing it. This would be to the disadvantage of the typical student. Ample examples of such graphs are given in the worksheets.

In any case, when this graph is shifted -3 units in the x direction the vertical asymptotes shift 3 units to the left, to the

vertical line x = -3. The points on the graph shift accordingly.

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Self-critique (if necessary): ok

elf-critique Rating:ok

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Question:

Query Add comments on any surprises or insights you experienced as a result of this assignment.

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Your solution:

I was not surprised by anything in the lesson because it is a review of Algebra II.

confidence rating #$&*: 3

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Given Solution:

** STUDENT COMMENT: I have never worked with graphs in the power family, and very little in the exponential family. I am always amazed at the patterns that a function produces. It helps me understand the equation so much better than a list of numbers. I do feel that I need the data table with the graph to fully understand it.

INSTRUCTOR RESPONSE: The data table is certainly helpful, especially when you see the reasons for the number patterns in the formula as well as you do. **

""

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Self-critique (if necessary):

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Self-critique rating:

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Question: `qdescribe the graph of the exponential family y = 2^x + c for the values c = -3 to 3.

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Your solution:

Each graph is a different version of the original.

2^x-3 passes through the y axis at -3, then the other ones pass through at the values they were plugged in for (-2,-1,0,1,2, and 3).

confidence rating #$&*: 3

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Given Solution:

** There are 7 graphs, including y = 2^x + 0 or just y = 2^x.

The c = 1, 2, 3 functions are y = 2^x + 1, y = 2^x + 2 and y = 2^x + 3, which are shifted by 1, 2 and 3 units upward from the graph of y = 2^x.

The c = -1, -2, -3 functions are y = 2^x - 1, y = 2^x - 2 and y = 2^x - 3, which are shifted by 1, 2 and 3 units downward from the graph of y = 2^x. **

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Self-critique (if necessary):ok

elf-critique Rating:ok

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Question: `qquery problem 5. power function families

Describe the graph of the power function family y = A (x-h) ^ p + c for p = -3: A = 1, h = -3 to 3, c = 0.

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Your solution:

y = (x + 3)^(-3) has a vertical axis at x = -3

shifted 3 units to the left

y = (x - 3)^(-3) has its vertical axis at x = 3

shifted 3 units to the right of the graph of y = x^(-3).

The graphs all go across the plane from the negative to positive side with vertical asymptotes found by setting the dominator equal to 0(The dominator is there because you can’t have a negative exponent) and solving for the variable.

confidence rating #$&*: 3

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Given Solution:

** GOOD STUDENT RESPONSE: I sketched the graph of the power function family y = A (x-h)^p + c for p = -3: A = 1: h = -3 to 3, c = 0. Beginning on the left side of the graph the curve was infinitely close to its asmptote of y = 0. This was determined by the value of c. As we move from left to right the curves decreased at an increasing rate, approaching thier vertical asmptotes which was determined by thier individual values of h. The curves broke at x = c as this value was never possible due to division by zero. The curves resurfaced on the graph high on the right side of thier vertical asymptotes and from there they decreased at a decreasing rate, once again approaching thier horizontal asymptote of y = 0.

INSTRUCTOR COMMENTS: Only the h value changes. p=-3, A=1 and c=0, so the functions are y = 1 * (x-h)^-3 or y = (x-h)^-3.

For h = -3 to 3 the functions are y = (x - (-3))^-3, y = (x - (-2))^-3, y = (x - (-1))^-3, y = (x - 0)^-3, y = (x - 1)^-3, y = (x - 2)^-3, y = (x - 3)^-3.

These graphs march from left to right, moving 1 unit each time. Be sure you see in terms of the tables why this happens. **

STUDENT COMMENT/QUESTION

Lost..... Its not clicking for me. I understand its going to change by 1, but I need to see more information. The book is not helping me and I did a search

on the Internet and can only come up with a DNA Biology math reference. Where can I look for more explanation?

Thank You

INSTRUCTOR RESPONSE:

This is easier than you think, once you see it.

Your are told that p = -3. So y = A ( x - h)^p + c becomes

y = A ( x - h)^(-3) + c.

Then you're told that A = 1, so

y = 1 ( x - h)^(-3) + c, or just

y = (x - h)^(-3) + c.

Let's skip the h part for a minute and notice that c = 0. So now we have

y = (x - h)^(-3) + 0 or just

y = (x - h)^(-3).

Now to deal with h, which is said to vary from -3 to 3. There are an infinite number of values between -3 and 3 and of course you're not expected to write a separate function for each of them.

You could get the general idea using h values -3, 0 and 3. This gives you the functions

y = (x - (-3) ) ^ (-3)

y = (x - 0) ^ (-3)

y = (x - 3) ^ (-3). Simplifying these you have

y = (x + 3) ^ (-3)

y = x ^ (-3)

y = (x - 3) ^ (-3).

The graph of x^(-3) has a vertical asymptote at the y axis (note that the y axis is at x = 0). To the right of the asymptote it decreases at a decreasing rate toward a horizontal asymptote with the positive x axis. As x approaches 0 through the negative numbers, the graph decreases at an increasing rate and forms its asymptote with the negative y axis.

The graph of y = (x + 3)^(-3) has its vertical axis at x = -3; i.e., it's shifted 3 units to the left of the graph of y = x^(-3).

The graph of y = (x - 3)^(-3) has its vertical axis at x = 3; i.e., it's shifted 3 units to the right of the graph of y = x^(-3).

So the graphs 'march' across the x-y plane, from left to right, with vertical asymptotes varying from x = -3 to x = +3.

We could fill in the h = -2, -1, 1 and 2 graphs, and as many graphs between these as we might wish, but the pattern should be clear from the three graphs discussed here.

STUDENT QUESTION

For this equation, I had trouble graphing and seeing how the changes were made. I didn’t understand how to substitute these

values and get a shift. For example:

y = A(x-h)^p + c then substituting the values you have

y= 1 (x - (-3))^-3 + 0

I can see there is no vertical stretch on the y axis and then inside the parenthesis you would have

(x + 3) raised to a power of -3 and finally there is no shift on the c value. Does this mean the graph would shift left or

right according to the given values? But how do you solve (x + 3)^-3

The family is defined by

y = A (x-h) ^ p + c for p = -3: A = 1, h = -3 to 3, c = 0.

Substituting p = -3, A = 1, h = -3 and c = 0 into the form y = A (x-h) ^ p + c we obtain

y = 1 * (x - (-3) ) ^ (-3) + 0 = 1 * (x + 3)^(-3), or just y = (x + 3)^3.

The values of p, A and c remain unchanged. The value of h, however, changes from -3 to 3. Using integer values -3, -2, -1, 0, 1, 2, 3 as representative values of h, our next step would be to substitute h = -2 along with the unchanged values of p, A and c. We would get

y = 1 * (x - (-2) ) ^ (-3) + 0 = 1 * (x + 2)^(-3), or just y = (x + 2)^3.

We would then substitute -1 for h, obtaining

y = 1 * (x - (-1) ) ^ (-3) + 0 = 1 * (x + 1)^(-3), or just y = (x + 1)^3.

We would continue this process until we readh h = 3, in which case we would get

y = 1 * (x - (3) ) ^ (-3) + 0 = 1 * (x - 3)^(-3), or just y = (x - 3)^3.

Our family would therefore have representative members

y = (x + 3)^3

y = (x + 2)^3

y = (x + 3)^3

y = (x + 0)^3 or just y = x^3

y = (x - 1)^3

y = (x - 2)^3

y = (x - 3)^3.

The pattern should be clear.

So we turn to actually constructing the graphs. Starting with the graph of y = (x + 3)^3:

The graph of (x + 3) ^ (-3) is the same as the graph of x^-3, just shifted left 3 units; when x is replaced by x + 3 the

same y values occur 3 units 'earlier', or 3 units 'to the left'.

To graph y = x^-3 you use the basic points.

For a power function the basic points are at x = -1, 0, 1/2, 1 and 2.

The corresponding values of x^-3 are -1, (undefined), 8, 1 and 1/8 (recall that x^-3 = 1 / x^3).

You should sketch these points on paper. Then you can observe the following:

In the first quadrant the points (1/2, 8), (1, 1) and (1/2, 1/8), along with the undefined value at x = 0, indicate a graph which decreases from a vertical asymptote with the positive y axis, toward a horizontal asymptote with the x axis.

The graph is symmetric with respect to the origin

• You can see this from the points (1, 1) and (-1, -1), and you can make sure by using the symmetry test f(-x) = - f(x); f(-x) = (-x)^3 = - x^3, and f(x) = x^3, so f(x) = -f(x).

• So the graph in the third quadrant is just a reflection through the origin of the first-quadrant graph.

• The graph in this quadrant falls as you go from left to right, descending from an asymptote along the negative x axis, though the point (-1, -1) to its vertical asymptote with the negative y axis. It should be clear that in the process the graph passes through the points (-2, -1/8), (-1, -1) and (-1/2, -8).

The instructor has chosen not to include a picture of the graph, which would divert most students from the process of actually constructing it. This would be to the disadvantage of the typical student. Ample examples of such graphs are given in the worksheets.

In any case, when this graph is shifted -3 units in the x direction the vertical asymptotes shift 3 units to the left, to the

vertical line x = -3. The points on the graph shift accordingly.

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Self-critique (if necessary): ok

elf-critique Rating:ok

*********************************************

Question:

Query Add comments on any surprises or insights you experienced as a result of this assignment.

YYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYY

Your solution:

I was not surprised by anything in the lesson because it is a review of Algebra II.

@&

This is material that students should know after Algebra II. Unfortunately most students do not know this after Algebra II. I suspect that this is primarily the fault of the typical student, rather than the teaching.

In any case it's clear that you had a good Algebra II course, and that you learned the material well.

*@

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@&

Excellent. Check my one note.

*@