#$&* course MTH 173 6/10/2013 at 8:43PM 023. `query 23
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Given Solution: `a** The function would have to be increasing for x < 3, which would make the first derivative positive. The second derivative could also be positive, with the function starting out with an asymptote to the negative x axis and gradually curving upward to reach (3,3). It would then have to start decreasing, which would make the first derivative negative, so the second derivative would have to be positive. The function would have be sort of 'pointed' at (3,3). The graph, which would have to remain positive, could then approach the positive x axis as an asymptote, always decreasing and always concave up. The horizontal asymptotes would not have to be at the x axis and could in fact by at any y < 3. The asymptote to the right also need not equal the asymptote to the left. ** STUDENT QUESTION Wouldn’t the graph be concave down? INSTRUCTOR RESPONSE If the graph is concave down the slope is decreasing, so the second derivative is negative. If that was the case then since the second and first derivatives have the same sign for x < 3, the first derivative would also be negative on that interval. This would contradict the condition that the point (3, 3) is a global maximum. There would also be a contradiction of the given conditions for x > 3. If the second derivative was negative, the first derivative would have to be positive, which again contradicts the global maximum. The correct graph turns out not to be a smooth curve, but rather one with a 'point' at (3, 3): The graph must be increasing to the left and decreasing to the right of the global maximum. So the first derivative must be positive to the left of the global maximum and negative to the right. So according to the given conditions the second derivative must be positive to the left and positive to the right. Thus the graph must be concave up on both sides of the point (3, 3). The only way for that to happen is for the graph to come to some sort of a 'point' at (3, 3). &&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&& Self-critique (if necessary): OK ------------------------------------------------ Self-critique Rating: OK ********************************************* Question: `qQuery problem 4.3.31 (3d edition 4.3.29) f(v) power of flying bird vs. v; concave up, slightly decreasing for small v; a(v) energy per meter. Why do you think the graph has the shape it does? YYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYYY Your solution: The graph says that for high velocities the rate of energy usage, in Joules / second, increases with increasing velocity. That makes sense because the bird will be fighting air resistance for a greater distance per second, which will require more energy usage. To make matters worse for the bird, as velocity increases the resistance is not only fought a greater distance every second but the resistance itself increases. So the increase in energy usage for high velocities isn't too hard to understand. However the graph also shows that for very low velocities energy is used at a greater rate than for slightly higher velocities. This is because low velocities imply hovering, or near-hovering, which requires more energy than the gliding action the bird achieves at somewhat higher velocities. confidence rating #$&*: ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ 3
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Given Solution: `a** the graph actually doesn't give energy vs. velocity -- the authors messed up when they said that -- it gives the rate of energy usage vs. velocity. They say this in the problem, but the graph is mislabeled. The graph says that for high velocities the rate of energy usage, in Joules / second, increases with increasing velocity. That makes sense because the bird will be fighting air resistance for a greater distance per second, which will require more energy usage. To make matters worse for the bird, as velocity increases the resistance is not only fought a greater distance every second but the resistance itself increases. So the increase in energy usage for high velocities isn't too hard to understand. However the graph also shows that for very low velocities energy is used at a greater rate than for slightly higher velocities. This is because low velocities imply hovering, or near-hovering, which requires more energy than the gliding action the bird achieves at somewhat higher velocities. ** &&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&& Self-critique (if necessary): OK ------------------------------------------------ Self-critique Rating: OK ********************************************* Question: `qQuery Add comments on any surprises or insights you experienced as a result of this assignment. I had some difficulty with the graphical interpretations, but I think going over more notes can give me a better understanding STUDENT COMMENT: I actually think I understand the general concept of the graphical interpretation and the first and second derivative but it helps me to think of this in relation to the trappazoid approximation graphs that we worked on earlier in the year is that a bad way fo thinking about this concept???? INSTRUCTOR RESPONSE The characteristics of trapezoidal approximation graphs seem to provide a good basis for interpreting graphs in general. &&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&& Self-critique (if necessary): OK ------------------------------------------------ Self-critique Rating: OK " Self-critique (if necessary): ------------------------------------------------ Self-critique rating: