Position, velocity, and acceleration Suppose the position of a...

Question

Position, velocity, and acceleration Suppose the position of an object moving horizontally along a line after t seconds is given by the following functions s = f(t), where s is measured in feet, with s > 0 corresponding to positions right of the origin.
b. Find and graph the velocity function. When is the object stationary, moving to the right, and moving to the left?
f(t) = 18t-3t²; 0 ≤ t ≤ 8

b. Find and graph the velocity function. When is the object stationary, moving to the right, and moving to the left?

f(t) = 18t-3t²; 0 ≤ t ≤ 8

Accepted Answer

Hello. In this video, we are going to be working on the following velocity problem. So, we are told that a particle is moving along a horizontal line, and its position after T seconds is given by the equation S of T is equal to 10 T minus 2 T squad, where S is measured in meters. For the interval, from 0 to 5 seconds, we want to find the velocity function and determine when the particle is stationary, moving to the right, and moving to the left. We also want to graph the velocity function. So, let's go ahead and start this problem by finding our velocity function. Now, in order to find velocity, we will need to take the derivative of the given position function. That function is given to us ass of T. is equal to 10T minus 2 T squared. So In order to get the velocity, we will be taking the derivative of the position function with respect to T. We will call our velocity function V of T. And by using the power rule on each of the terms of position function, we our velocity function will be 10 minus 4 T. That is going to be the first piece of information we need in order to solve the remainder of the problem. OK, now that we have our velocity function, we want to use the velocity function to determine when the particle is stationary, when it is moving to the right, and when it is moving to the left. Let's go ahead and first figure out when the particle is stationary. Now, when the particle is stationary, what that means is that it is not moving at all. If the particle is not moving, then the velocity is going to be zero. So in order to find the times in which velocity is zero, we will go ahead and take our velocity function, set it equal to 0, and solve for T. So let's go ahead and start that. So, our velocity function is 10 minus 4 T, and we will be setting this equal to 0. Let's go ahead and solve for tea. We will subtract 10 from both sides of the equation. That will leave us with -4 T is equal to -10. Dividing both sides of the equation will leave us with T is equal to 10 divided by 4, which further simplifies to 5 divided by 2. And if we represent this fraction as a decimal, T is equal to 2.5 seconds. What this means is that there is one point in time in which the velocity is zero and the particle is stationary. The particle is stationary at 2.5 seconds. Now that we've figured out the first piece of information we need, let's go ahead and now determine when the particle is moving to the left. And if the particle is moving to the left, that means that it is moving in the negative direction respective to its position. And if the particle is moving in the negative direction, then our velocity will be negative as well. What this means is that if we want to determine when the particle is moving to the left, we will take our velocity function and set it less than 0. This will give us the time in which the particle is moving to the left. So, we will take 10 minus 4 T, set it less than 0, and now let's solve for T in the inequality. We will subtract 10 from both sides of the of the inequality, leaving us with -4T less than -10. And if we divide both sides of the inequality by -4, we will have T greater than 2.5. What this tells us is that on the time interval from 2.5 to 5 seconds, The particle will be moving to the left. Now that we've figured out when the particle is moving to the left, let's figure out when the particle is moving to the right. Now, if the particle is moving to the right, that means that it is moving to the positive direction with respect to its position, and if the particle is moving positively, that means the velocity will be positive as well. So, in order to figure out the time interval in which the particle is moving to the right, we will set our velocity greater than 0 and solve for that time interval. That is going to give us 10 minus 40 greater than 0. Let's go ahead and solve for tea. We will subtract 10 to both sides of the inequality, leaving us with -4T greater than -10. And if we divide both sides of the inequality by -4, we will have T less than 2.5 seconds. What this tells us is that on the time interval from 0 to 2.5 seconds, the particle is going to be moving to the right. So, now that we have the time intervals of when the particle is moving to the right, to the left, and when it is stationary, the last thing we need to do is now graph our velocity function. So, again, our velocity function is V of T is equal to 10 minus 4 T. And since we only want to observe the time from 0 to 5 seconds for T, we are only going to be graphing the time interval from 0 seconds all the way to 5 seconds. Now, using the information above, Recall that the particle is stationary at 2.5 seconds. What this means is that we are going to have a point intersecting the axis respective to time at 2.5 seconds. But now we need the end behaviors of the graph of velocity at 0 and 5. In order to figure out those end behaviors, let's go ahead and plug in the values 0 and 5 into our velocity. If we plug in 0, we get 10 minus 4 multiplied by 0, which has a final value of 10. What this means is that the starting position of our velocity function will be located at 0.10. Finally, we'll repeat this process with the end behavior at 5 seconds. That will leave us with 10 minus 4 multiplied by 5. This simplifies to 10 minus 20, which is equal to -10. And what this means is that our velocity function will have an endpoint located at 5.10. Now, what about the shape of our velocity function? While our velocity function is in the form of a linear function. And what this means is that the shape of our velocity will be decreasing, passing through the point located at 2.5 seconds. And it will decrease from 0 to 5, and this is going to be the graph of our velocity function. So I hope it's this helps you understand how to approach this problem in this video, and I'll go ahead and see you all in the next video.

Key Concepts

Position Function

Velocity Function

Graphing Functions

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