Assignment 6 QA

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course Mth 163

006.

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Question: `q001. Note that this assignment has 10 questions

Recall that the graph of y = x^2 + 3 was identical to the graph of y = x^2, except that it was raised 3 units. This function is of the form y = x^2 + c. In the case of this specific function, c = 3. What function would this form give us for c = -1? How would the graph of this function compare with the graph of y = x^2?

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Your solution:

Down 1

confidence rating #$&*:

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3

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Given Solution:

If c = -1 the form y = x^2 + c gives us y = x^2 - 1. Every value on a table of this function would be 1 less than the corresponding value on a table of y = x^2, and the graph of y = x^2 - 1 will lie 1 unit lower at each point then the graph of y = x^2.

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Question: `q002. Suppose that we wish to graph the functions y = x^2 + c for c = -3, then for c = -2, then for c = -1, then for c = 0, then for c = 1, then for c = 2, then for c = 3. If all these functions were plotted on the same set of coordinate axes, what would the final graph look like? It is suggested that you actually sketch your graph and describe your sketch.

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Your solution:

It Goes Lower To higher

confidence rating #$&*:

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3

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Given Solution:

The graph of the c= -3 function y = x^2 - 3 will lie 3 units lower than the graph of y = x^2.

The graph of the c= -2 function y = x^2 - 2 will lie 2 units lower than the graph of y = x^2.

The progression should be obvious. The graph of the c= 3 function y = x^2 + 3 will lie 3 units higher than the graph of y = x^2.

The final graph will therefore show a series of 7 functions, with the lowest three units below the parabolic graph of y = x^2 and the highest three units above the graph of this function. Each graph will lie one unit higher than its predecessor.

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Question: `q003. The function y = (x -1)^3 is of the form y = (x -k)^3 with k = 1. What function would this form give us for k = 3? How would the graph of this function compare with that of y = x^3?

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Your solution:

3 to the Right

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3

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Given Solution:

Recall how the graph of y = (x-1)^3 lies one unit to the right of the graph of y = x^3. The k = 3 function y = (x -3)^3 will lie 3 units to the right of the graph of y = x^3.

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Question: `q004. Suppose we wish to graph the functions y = (x -k)^3 for k values 2, then 3, then 4. If we graph all these functions on the same set of coordinate axes, what will the graph look like? It is suggested that you actually sketch your graph and describe your sketch.

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Your solution:

Progressively get further to the right

confidence rating #$&*:

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3

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Given Solution:

The k = 2 graph will lie 2 units to the right of the graph of y = x^3, and the k = 4 graph will lie 4 units to the right. The three graphs will all have the same shape as the y = x^3 graph, but will lie 2, 3 and 4 units to the right.

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Question: `q005. The function y = 3 * 2^x is of the form y = A * 2^x for A = 3. What function would this form give us for A = 2? How would the graph of this function compare with that of y = 2^x?

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Your solution:

2 times as far

confidence rating #$&*:

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3

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Given Solution:

As we saw earlier, the graph of y = 3 * 2^x lies 3 times as far from the x-axis as a graph of y = 2^x and is at every point three times as steep. We would therefore expect the A = 2 function y = 2 * 2^x to lie 2 times is far from the x-axis as the graph of y = 2^x.

STUDENT QUESTION

In this case, is A stretching or shifting? I said shifting in my response, but as I'm recalling from the previous assignment I suspect it may actually be stretching the graph by 2 units instead of shifting.

INSTRUCTOR RESPONSE

Your suspicion is correct. The graph is stretching.

When a graph shifts, every point moves by the same amount.

When a graph stretches, every point moves to a multiple of its original distance from some axis. Points further from that axis move more, points closer to the axis move less.

For example the graph below depicts the x any y axes, and the graphs of the two functions. Vertical lines are drawn at x = 1 and x = 2. You should sketch a good copy of this graph and actually trace out the properties discussed below, and annotate your graph accordingly:

• Look first at the vertical line corresponding to x = 1. It should be clear that, along this line, the graph of the second function is about twice as far from the x axis as the graph of the first.

• Now look at the vertical line corresponding to x = 2. It should be clear that, along this line, the graph of the second function is about twice as far from the x axis as the graph of the first.

• You should also see that along the x = 1 line the second graph lies at a certain distance above the first, while at the x = 2 line the second graph lies at a greater distance above the first.

• At the origin, the graphs meet. Then if we move from left to right, starting at the origin, the vertical distance between the graphs keeps increasing.

The graph below includes 'heavier' vertical line segments representing the increasing vertical distance between the graphs:

This graph represents a vertical stretch, in every point of the second graph lies at double the vertical distance from the horizontal axis as the corresponding point of the first.

By contrast, consider the graph shown below, in which the second graph is shifted in the vertical direction relative to the first.

• On this graph the vertical distance is the same on every vertical line.

• It probably doesn't look like this is the case. There's an optical illusion at work here, which is due to the fact that the upper graph gets closer and closer to the lower graph. However, despite appearances, this isn't the case if the distances are measured along the vertical lines.

• In the first figure below we show the line segments which represent these vertical distances. They are all of the same length. In the second figure below, these line segments are depicted without the graph.

In this example, all points of the second graph lie at the same vertical distance above the first.

This graph represents a vertical shift. In a vertical shift all points point of one graph lie at the same vertical displacement relative to the first.

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Question: `q006. Suppose we wish to graph the functions y = A * 2^x for values A ranging from 2 to 5. If we graph all such functions on the same set of coordinate axes, what will the final graph look like? It is suggested that you actually sketch your graph and describe your sketch.

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Your solution:

It will Range From 2 to 5

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Given Solution:

These graphs will range from 2 times as far to 5 times as far from the x-axis as the graph of y = 2^x, and will be from 2 to 5 times as steep. The y intercepts of these graphs will be (0,2), (0, 3), (0, 4), (0,5).

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Question: `q007. What is the slope of a straight line connecting the points (3, 8) and (9, 12)?

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Your solution:

12-8/9-3

4/6=2/3=M

confidence rating #$&*:

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3

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Given Solution:

The rise between the points is from y = 8 to y = 12. This is a rise of 12-8 = 4.

The run between these points is from x = 3 to x = 9, a run of 9 - 3 = 6.

The slope between these points is therefore rise/run = 4/6 = 2/3, with decimal equivalent .6666....

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Question: `q008. What are the coordinates of the t = 5 and t = 9 points on the graph of y = 2 t^2 + 3? What is the slope of the straight line between these points?

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Your solution:

Y=2(5)^2+3

5^2=25*2=50+3=53

Y=2(9)^2+3

9^2=81*2=162+3=165

165-53/9-5

112/4

confidence rating #$&*:

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3

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Given Solution:

The t = 5 value is y = 2 * 5^2 + 3 = 2 * 25 + 3 = 50 + 3 = 53.

The t = 9 value is similarly calculated. We obtain y = 165.

The rise between these points is therefore 165-53 = 112. The run is from t = 5 to t = 9, a run of 9 - 5 = 4. This slope of a straight line connecting these points is therefore rise/run = 112/4 = 28.

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Question: `q009. Suppose y = 2 t^2 + 3 represents the depth, in cm, of water in a container at clock time t, in seconds. At what average rate does the depth of water change between t = 5 seconds and t = 9 seconds?

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Your solution:

53cm 165cm

165-53/9-5= 112cm/4Sec

28cm/sec

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Given Solution:

The t = 5 second and t = 9 second depths are easily calculated to be y = 53 cm and y = 165 cm. The depth therefore changes from 53 cm to 165 cm, a change of 165 cm - 53 cm = 112 cm, in the 4 seconds between the to clock times. The average rate of depth changes therefore 112 cm/(4 seconds) = 28 cm/second.

We note that this calculation is identical to the calculation of the slope of the straight line connecting the t = 5 and t = 9 points of the graph y = 2 t^2 + 3.

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Question: `q010. If we have a graph of depth y vs. clock time t, then how to we know that the slope of a straight line connecting two points of the graph represents the average rate at which depth changes over the corresponding time interval?

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Your solution:

Rise is change in depth run is change in time depth/change represents average rate in depth change

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Given Solution:

The rise of the graph represents the change in the depth y and the run represents the change clock time t. The slope, which is rise/run, therefore represents change in depth/change in clock time, which is the average rate at which the depth changes.

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#*&!

&#Very good responses. Let me know if you have questions. &#

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Everything was there in this document so I was able to review it. As expected it looks very good.

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