Assignment 5b

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course Mth 173

Resubmission of Assignment 5b

If your solution to stated problem does not match the given solution, you should self-critique per instructions at

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.

Your solution, attempt at solution.

If you are unable to attempt a solution, give a phrase-by-phrase interpretation of the problem along with a statement of what you do or do not understand about it. This response should be given, based on the work you did in completing the assignment, before you look at the given solution.

005. `query 5

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Question: `q Growth rate and growth factor: Describe the difference between growth rate and growth factor and give a short example of how each might be used

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Your solution:

Growth rate is the amount of growth that is obtained by the starting quantity over the course of the year.

Growth factor is the multiplier used to give that same amount so we can find additional time frames.

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Given Solution:

** Specific statements:

When multiplied by a quantity the growth rate tells us how much the quantity will change over a single period.

When multiplied by the quantity the growth factor gives us the new quantity at the end of the next period. **

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Question: `q Class notes #05 trapezoidal representation.

Explain why the slope of a depth vs. time trapezoid represents the average rate of change of the depth with respect to the time during the time interval represented

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Your solution:

The slope of the trapezoid uses our information about quantity or depth and gives us the average rate of change of that quantity. We use rise over run in this case the rise is the depth and the run would be the time. This results in depth over time and the slope is the average of two points within that curve.

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Given Solution:

** GOOD ANSWER BY STUDENT WITH INSTRUCTOR COMMENTS:

The slope of the trapezoids will indicate rise over run

or the slope will represent a change in depth / time interval

thus an average rate of change of depth with respect to time

INSTRUCTOR COMMENTS:

More detail follows:

** To explain the meaning of the slope you have to reason the question out in terms of rise and run and slope.

For this example rise represents change in depth and run represent change in clock time; rise / run therefore represents change in depth divided by change in clock time, which is the average rate of change. **

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Question: `q Explain why the area of a rate vs. time trapezoid for a given time interval represents the change in the quantity corresponding to that time interval.

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Your solution:

The average altitude gives us the average rate of the graph. The width of the trapezoid corresponds to the time interval we are looking for. Therefore the area is equal to the time interval times the average rate which gives us the total change in quantity.

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Given Solution:

**STUDENT RESPONSE WITH INSTRUCTOR COMMENTS:

The area of a rate vs. time graph rep. the change in quantity.

Calculating the area under the graph is basically integration

The accumulated area of all the trapezoids for a range will give us thetotal change in quantity.

The more trapezoids used the more accurate the approx.

INSTRUCTOR COMMENTS: All very good but the other key point is that the average altitude represents the average rate, which when multiplied by the width which represents time interval gives the change in quantity

You have to reason this out in terms of altitudes, widths and areas.

For the rate of depth change example altitude represents rate of depth change so average altitude represents average rate of depth change, and width represents change in clock time.

average altitude * width therefore represents ave rate of depth change * duration of time interval = change in depth.

For the rate of change of a quantity other than depth, the reasoning is identical except you'll be talking about something besides depth. **

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Question: `q ÿÿÿ #17. At 10:00 a.m. a certain individual has 550 mg of penicillin in her bloodstream. Every hour, 11% of the penicillin present at the beginning of the hour is removed by the end of the hour. What is the function Q(t)?

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Your solution:

Growth rate = -.11

Growth factor = 1.0 + -.11 = -.89

Q(t) = 550mg(-.89)^t

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Given Solution:

** Every hour 11% or .11 of the total is lost so the growth rate is -.11 and the growth factor is 1 + r = 1 + (-.11) = .89 and we have

Q(t) = Q0 * (1 + r)^t = 550 mg (.89)^t or

Q(t)=550(.89)^tÿ **

How much antibiotic is present at 3:00 p.m.?

** 3:00 p.m. is 5 hours after the initial time so at that time there will be

Q(5) = 550 mg * .89^5 = 307.123mg

in the blood **

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Question: `q Describe your graph and explain how it was used to estimate half-life.

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Your solution:

The graph is decreasing at a reducing rate when moving to the right on the x axis. After plotting all of the resulting pairs, I drew a horizontal line at 15mg. At the point where this intersects the curve of the plotted data I drew a perpendicular line to the x axis to give me the time of half-life.

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Given Solution:

** Starting from any point on the graph we first project horizontally and vertically to the coordinate axes to obtain the coordinates of that point.

The vertical coordinate represents the quantity Q(t), so we find the point on the vertical axis which is half as high as the vertical coordinate of our starting point. We then draw a horizontal line directly over to the graph, and project this point down.

The horizontal distance from the first point to the second will be the distance on the t axis between the two vertical projection lines. **

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Question: `q What is the equation to find the half-life?ÿ What is its most simplified form?

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Your solution:

Q(`dt) = 30mg(0.85)^`dt = 15mg

0.85^`dt = 1/2mg

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Given Solution:

** Q(doublingTime) = 1/2 Q(0)or

550 mg * .89^doublingTIme = .5 * 550 mg. Dividing thru by the 550 mg we have

.89^doublingTime = .5.

We can use trial and error to find an approximate value for doublingTIme (later we use logarithms to get the accurate solution). **

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Question: `q #19. For the function Q(t) = Q0 (1.1^ t), a value of t such that Q(t) lies between .05 Q0 and .1 Q0.

0.05 = 1.1^t

Using trial and error I found -31.5 to be close

0.1 = 1.1^t

Using trial and error I found -24.1 to be close

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Question: `q For what values of t did Q(t) lie between .005 Q0 and .01 Q0?

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Your solution:

0.005 = 1.1 ^t

Trial and error found -55.5 to be close

0.01 = 1.1^t

Trial and error found -48.25 to be close

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Given Solution:

** Any value between about t = -24.2 and t = -31.4 will result in Q(t) between .05 Q0 and .1 Q0.

Note that these values must be negative, since positive powers of 1.1 are all greater than 1, resulting in values of Q which are greater than Q0.

Solving Q(t) = .05 Q0 we rewrite this as

Q0 * 1.1^t = .05 Q0. Dividing both sides by Q0 we get

1.1^t = .05. We can use trial and error (or if you know how to use them logarithms) to approximate the solution. We get

t = -31.4 approx.

Solving Q(t) = .1 Q0 we rewrite this as

Q0 * 1.1^t = .1 Q0. Dividing both sides by Q0 we get

1.1^t = .1. We can use trial and error (or if you know how to use them logarithms) to approximate the solution. We get

t = -24.2 approx.

(The solution for .005 Q0 is about -55.6, for .01 is about -48.3

For this solution any value between about t = -48.3 and t = -55.6 will work). **

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Question: `q explain why the negative t axis is a horizontal asymptote for this function.

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Your solution:

The negative t axis is a horizontal asymptote because as Q0 approaches 0 the time gets smaller and smaller.

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Given Solution:

** The value of 1.1^t increases for increasing t; as t approaches infinity 1.1^t also approaches infinity. Since 1.1^-t = 1 / 1.1^t, we see that for increasingly large negative values of t the value of 1.1^t will be smaller and smaller, and would in fact approach zero. **

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Question: `q #22. What value of b would we use to express various functions in the form y = A b^x? What is b for the function y = 12 ( e^(-.5x) )?

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Your solution:

B = 2^k

In y = 12 ( e^(-0.5x)) b is e^ -0.5

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Given Solution:

** 12 e^(-.5 x) = 12 (e^-.5)^x = 12 * .61^x, approx.

So this function is of the form y = A b^x for b = .61 approx.. **

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Question: `q what is b for the function y = .007 ( e^(.71 x) )?

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Your solution:

B = e^0.71

Y=A*b^x

Y= 0.007 * (e^0.71)^x

Y= 0.007 * (2.0339)^x

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Given Solution:

** .007 e^(.71 x) = .007 (e^.71)^x = .007 * 2.04^x, approx.

So this function is of the form y = A b^x for b = 2.041 approx.. **

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Question: `q what is b for the function y = -13 ( e^(3.9 x) )?

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Your solution:

B = e^3.9

Y= -13 (e^3.9)^x

Y = -13(49.4)^x

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Given Solution:

** -13 e^(3.9 x) = -13 (e^3.9)^x = -13 * 49.4^x, approx.

So this function is of the form y = A b^x for b = 49.4 approx.. **

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Question: `q List these functions, each in the form y = A b^x.

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Your solution:

Y= 12(e^-.5)^x = 12(0.6065)^x

Y=0.007(e^.71)^x = 0.007(2.03399)^x

Y= -13 ( e^3.9)^x = -13(49.4024)^x

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Given Solution:

** The functions are

y=12(.6065^x)

y=.007(2.03399^x) and

y=-13(49.40244^x) **

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Question: `q query text problem 1.1.31 5th; 1.1.23 4th dolphin energy prop cube of vel

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Your solution:

E = kv^3

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Given Solution:

** A proportionality to the cube would be E = k v^3. **

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Question: `q query text problem 1.1.37 5th; 1.1.32 4th temperature function H = f(t), meaning of H(30)=10, interpret vertical and horizontal intercepts

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Your solution:

F(30) =10 means that at t= 3- seconds the temperature is 10 degrees Celsius

The vertical intercept a shows the temperature at time equal to zero seconds

The horizontal intercept shows the time when the temperature reaches zero.

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Given Solution:

** The interpretation would be that the vertical intercept represents the temperature at clock time t = 0, while the horizontal intercept represents the clock time at which the temperature reaches zero. **

what is the meaning of the equation H(30) = 10?

** This means that when clock time t is 30, the temperature H is 10. **

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Question: `q What is the meaning of the vertical intercept?

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Your solution:

The vertical intercept a shows the temperature at time equal to zero seconds

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Given Solution:

** This is the value of H when t = 0--i.e., the temperature at clock time 0. **

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Question: `q What is the meaning of the horizontal intercept?

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Your solution:

The horizontal intercept shows the time when the temperature reaches zero.

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Given Solution:

** This is the t value when H = 0--the clock time when temperature reaches 0 **

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Question: `q query text problem 1.1.40 5th; 1.1.31 4th. Water freezes 0 C, 32 F; boils 100 C, 212 F. Give your solution.

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Your solution:

Slope is equal to (212 – 32 / 100-0) = 9/5 = 1.8

Y=mx+b

Y=1.8x + 32

Y =1.8(20) + 32

Y=36 + 32 = 68 degrees farenheit

Y= 1.8x +32 substitute y for x

Y = 1.8y +32 Subtract 1.8y from each side

-.8y = 32

Y = -40 degrees farenheit or Celsius

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Given Solution:

** The graph contains points (0, 32) and (100, 212). The slope is therefore (212-32) / (100-0) = 1.8.

The y-intercept is 32 so the equation of the line is

y = 1.8 x + 32, or using F and C

F = 1.8 C + 32.

To find the Fahrenheit temp corresponding to 20 C we substitute C = 20 into F = 1.8 C + 32 to get

F = 1.8 * 20 + 32 = 36 + 32 = 68

The two temperatures will be equal when F = C. Substituting C for F in F = 1.8 C + 32 we get

C = 1.8 C + 32. Subtracting 1.8 C from both sides we have

-.8 C = 32 or

C = 32 / (-.8) = -40.

The scales read the same at -40 degrees. **

STUDENT QUESTION

I understand all work shown except the answer for d? I understand how to substaute and see how you worked it, but don’t understand the logic for why this works ?

INSTRUCTOR RESPONSE

You have a linear function which gives you F when you substitute C.

That means that the graph of F vs. C is a straight line.

According to the given information the straight line passes through the points (0, 32) and (100, 212).

Given two points, there are a variety of ways to get the equation of the corresponding straight line. The given solution finds the slope, then uses slope-intercept form of the equation of a straight line.

Alternatively you could use the point-point form of the equation, which would lead to the same result.

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