#$&* course MTH 173 10/21 00:35
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Given Solution: `aThe rate of temperature change is given by the derivative function ( T ( t ) ) ', also written T ' (t). Since T(t) is the sum of the constant function 70, whose derivative is zero, and 120 times the composite function e^(-.1 t), whose derivative is -.1 e^(-.1 t), we see that T ' (t) = 120 * ( -.1 e^(-.1 t) ) = -12 e^(-.1 t). Note that e^(-.1 t) is the composite of f(z) = e^z and g(t) = -.1 t, and that its derivative is therefore found using the chain rule. When t = 5, we have T ' (5) = -12 e^(-.1 * 5 ) = -12 e^-.5 = -7.3, approx.. This represents rate = change in T / change in t in units of degrees / minute, so at t = 5 minutes the temperature is changing by -7.3 degrees/minute. &&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&& Self-critique (if necessary): OK ------------------------------------------------ Self-critique Rating: OK ********************************************* Question: `q002. The weight in grams of a growing plant is closely modeled by the function W(t) = .01 e^(.3 t ), where t is the number of days since the seed germinated. At what rate is the weight of the plant changing when t = 10? YYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYY Your solution: Given weight function W(t) = .01 * e^(.3t) where t in number of days since germinated and W is weight in grams. The rate function at which the weight is changing is found by differentiating the weight function with respect to time. Thus W’(t) = .01 e ^ (.3t) * .3 = .003e^(.3t) grams / number of days. Thus rate wt which the weight of plant is changing at t = 10 days will be T’(10) T’(10) = .003e^(3) grams/number of days = 0.0602 grams/number of days confidence rating #$&*: 3 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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Given Solution: `aThe rate of change of weight is given by the derivative function ( W ( t ) ) ', also written W ' (t). Since W(t) is .01 times the composite function e^(.3 t), whose derivative is .3 e^(.3 t), we see that W ' (t) = .01 * ( .3 e^(.3 t) ) = .003 e^(.3 t). Note that e^(.3 t) is the composite of f(z) = e^z and g(t) = .3 t, and that its derivative is therefore found using the chain rule. When t = 10 we have W ' (10) = .003 e^(.3 * 10) = .03 e^(3) = .06. Since W is given in grams and t in days, W ' will represent change in weight / change in clock time, measured in grams / day. Thus at t = 10 days the weight is changing by .06 grams / day. &&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&& Self-critique (if necessary): OK ------------------------------------------------ Self-critique Rating: OK ********************************************* Question: `q003. The height above the ground, in feet, of a child in a Ferris wheel is given by y(t) = 6 + 40 sin ( .2 t - 1.6 ), where t is clock time in seconds. At what rate is the child's height changing at the instant t = 10? YYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYY Your solution: Given the height function y(t) = 6 + 40sin( .2t - 1.6 ) where y is in feet and t in sec. The rate function at which the height is changing can be found by differentiating the height function with respect to time. Thus y’(t) = 0 + 40cos( .2t - 1.6)*.2 = 8cos( .2t - 1.6 ) feet/sec Thus the rate at which the height is changing at t = 10 sec will be y’(10). Thus y’(10) = 8cos(2 - 1.6) = 8cos(0.4) = 8 * 0.921(approx.) = 7.368 feet confidence rating #$&*: 3 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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Given Solution: `aThe rate of change of altitude is given by the derivative function ( y ( t ) ) ', also written y ' (t). Since y(t) is the sum of the constant term 6, with derivative zero, and 40 times the composite function sin (.2 t - 1.6), whose derivative is .2 cos(.2 t - 1.6), we see that y ' (t) = 40 * ( .2 cos(.2 t - 1.6) ) = 8 cos(.2 t - 1.6). Note that sin(.2t - 1.6) is the composite of f(z) = sin(z) and g(t) = .2 t - 1.6, and that its derivative is therefore found using the chain rule. Thus at t = 10 seconds we have rate y ' (10) = 8 cos( .2 * 10 - 1.6) = 8 cos( .4) = 7.4, approx.. Since y represents altitude in feet and t represents clock time in seconds, this represents 7.4 feet per second. The child is rising at 7.4 feet per second when t = 10 sec. &&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&& Self-critique (if necessary): OK ------------------------------------------------ Self-critique Rating: OK ********************************************* Question: `q004. The grade point average of a certain group of students seems to be modeled as a function of weekly study time by G(t) = ( 10 + 3t ) / (20 + t ) + `sqrt( t / 60 ). At what rate does the grade point average go up as study time is added for a typical student who spends 40 hours per week studying? Without calculating G(40.5), estimate how much the grade point average for this student would go up if she spend another 1/2 hour per week studying. YYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYY Your solution: Given grade point function G(t) = ( 10 + 3t ) / (20 + t ) + sqrt( t / 60 ) where t is the number hours studied in a week. The rate function at which grade point average goes up is given by differentiating the grade point function with respect to t. Thus G’(t) = ((20 + t)*3 - (10 + 3t))/(20 + t)^2 + (1/2)*(1/sqrt(t60))* point/hour = 50/(20 + t)^2 + (1/2)*(1/sqrt(t60)) Thus gpa for a typical student who spends 40 hours per week studying, the rate at which GPA goes up will be G’(40) = 50/3600 + (1/2)*(1/sqrt(2400)) = 0.0139 + 0.0102 = 0.024 points/hour approx Also G(40) = ( 10 + 120 )/(20 + 40) + sqrt( 40/60 ) = 130/60 + sqrt(2/3) = 0.816+ 2.167 = 2.983(approx.) Thus since the rate at t = 40 hours is 0.024 points/hour and the width of the time interval between t = 40 hours and t = 40.5 hours is 0.5 hours the rise in the point during this interval will be Rise in points = 0.024 points/hour * 0.5 hours = 0.012 points. Since G(40) = 2.983, G(40.5) = 2.983 + 0.012 = 2.995 points. This is only an estimate of the GPA points at t = 40.5 hours without calculating the actual value by assuming that the rate for the t = 40 hours and t = 40.5 hours interval would almost remain constant to G’(40). Thus the rate at which the GPA point is rising at t = 40 hours is 0.024 points/ hour and an estimate of the point at t = 40.5 without calculating the actual value is 2.995 points. confidence rating #$&*: 3 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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Given Solution: `aThe rate of change of grade point average is given by the derivative function ( G ( t ) ) ', also written G ' (t). Since G(t) is the sum of the quotient function (10 + 3 t ) / ( 20 + t), with derivative 50 / ( 20 + t ) ^ 2, and the composite function `sqrt( t / 60) , whose derivative is 1 / (120 `sqrt( t / 60) ), we see that G ' (t) = 50 / ( 20 + t ) ^ 2 + 1 / (120 `sqrt( t / 60) ). Note that `sqrt(t / 60) is the composite of f(z) = `sqrt(z) and g(t) = t / 60, and that its derivative is therefore found using the chain rule. Thus if t = 40 we have rate G ' (40) = 50 / ( 20 + 40 ) ^ 2 + 1 / (120 `sqrt( 40 / 60) ) = .024, approx.. Since G represents grade point and t represents weekly study time in hours, this represents .024 grade points per hour of weekly study time. The grade point is rising by .024 per additional hour of study. To estimate G(40.5) we assume that the .024 grade point rise per additional hour of study time remains valid as we increase study time from 40 to 40.5 hours. This is in increase of .5 hours in weekly study time so we would expect the grade point to go up by grade point change = .5 hours * .024 points / hour = .012 points. Since G(40) = ( 10 + 3 * 40) / (20 + 40) + `sqrt( 40 / 60) = 2.97 approx, the additional half-hour per week will tend to raise this by .012 to around 2.97. If the student is aiming for a 3-point, a couple more hours would do but the .5 hours won't. STUDENT QUESTION How did you begin this solution in order to get 50/ (20 + t) ? INSTRUCTOR RESPONSE That's the derivative of the first term in the given function, obtained using the quotient rule. The quotient rule and chain rule were covered in preceding qa's, and the details would have been a distraction in the given solution. Here are the details: (10 + 3 t ) / ( 20 + t) is of the form f / g, a quotient function, with derivative (f ' g - g ' f) / g^2 = ( (10 + 3t) ' ( 20 + t) - (20 + t) ' ( 10 + 3 t) ) / (20 + t)^2 = ( 3 ( 20 + t ) - 1 ( 10 + 3 t) ) / (20 + t)^2 = 50 / (20 + t)^2. sqrt(t / 60) is of the form f(g(t)) with f(z) = sqrt(z) and g(t) = t / 60. The derivative is g ' (t) * f ' (g ( t ) ) = (t / 60) ' * 1 / (2 sqrt(z) ) = 1/60 * 1 / (2 sqrt(t/60) ) = 1 / (120 sqrt(t/60) ). &&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&& Self-critique (if necessary): OK ------------------------------------------------ Self-critique Rating: OK "" " Self-critique (if necessary): ------------------------------------------------ Self-critique rating: "" " Self-critique (if necessary): ------------------------------------------------ Self-critique rating: #*&!