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Μάθημα: Διαφορικός Λογισμός > Ενότητα 4
Μάθημα 4: Introduction to related rates- Related rates intro
- Analyzing problems involving related rates
- Analyzing related rates problems: expressions
- Analyzing related rates problems: expressions
- Analyzing related rates problems: equations (Pythagoras)
- Analyzing related rates problems: equations (trig)
- Analyzing related rates problems: equations
- Differentiating related functions intro
- Worked example: Differentiating related functions
- Differentiate related functions
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Analyzing related rates problems: equations (Pythagoras)
A crucial part of solving related rates problems is picking an equation that correctly relates the quantities. We recommend making a diagram before doing that.
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- [Instructor] Two cars are
driving towards an intersection from perpendicular directions. The first car's velocity
is 50 kilometers per hour. And the second car's velocity
is 90 kilometers per hour. At a certain instant, T sub zero, the first car is a
distance X sub T of zero, or X of T sub zero of half a kilometer from the intersection. And the second car is a distance Y of T sub zero of 1.2 kilometers from the intersection. What is the rate of change of the distance D of T between the cars at that instant? So at T sub zero. Which equation should be
used to solve the problem? And they give us a choice of four equations right over here. So you could pause the video and try to work through it on your own. But I'm about to do it, as well. So let's just draw what's going on that's always a healthy thing to do. So two cars are driving
towards an intersection from perpendicular directions. So, let's say that this is one car right over here. And, it is moving in the X direction towards that intersection which is right over there. And then you have another car that is moving in the Y direction. So let's say it's moving like this. So this is the other car. And I should have maybe done a top view. Oh, here we go. This square represents the car. And it is moving in that direction. Now, they say at a certain
instance T sub zero. So let's draw that instant. So, the first car is a
distance X of T of zero of 0.5 kilometers. So this distance right over here, let's just call this X of T. And let's call this
distance right over here Y of T. Now how does the distance between the cars relate to X of T and Y of T? Well, we could just use
the distance formula which is essentially just
the Pythagorean Theorem to say, well the distance between the cars would be the hypotenuse of this right triangle. Remember, they're traveling
from perpendicular directions so that's a right triangle there. So this distance, right over here, would be X of T squared plus Y of T squared. And the square root of that. And that's just the Pythagorean
Theorem right over here. This would be D of T. Or, we could say that D of T squared is equal to X of T X of T squared. Plus Y. Too many parentheses. Plus Y of T squared. So that's the relationship between D of T, X of T, and Y of T. And, it's useful for solving this problem because now we could take the derivative of both sides of this
equation with respect to T. And we would be using
various derivative rules including the chain
rule, in order to do it. And then that would give us a relationship between the rate of change of D of T which would be D prime of T. And the rate of change of X of T, Y of T, and X of T, and Y of T themselves. And so, if we look at these
choices right over here we indeed see that D sets up that exact same relationship that we just did ourselves. That it shows the distance squared between the cars is equal to that X distance from
the intersection squared plus the Y distance from
the intersection squared. And then we can take the
derivative of both sides to actually figure out this related rates question.