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MarkFL
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Here is the question:
I have posted a link there to this topic so the OP can see my work.
I have posted a link there to this topic so the OP can see my work.
Rate of Change of Plane's Distance from Radar Station - Gina's Question
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In summary: Therefore, in summary, the rate at which the distance from the plane to the station is increasing when it is 5 mi away from the station is approximately 461 mph.
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MarkFL
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Hello Gina,
First, let's draw a diagram:
View attachment 1445
The plane is at $P$, the radar station is at $R$, $h$ is the altitude of the plane (which is constant since its flight is said to be horizontal) and $x$ is the distance from the radar station to the point on the ground (or at the same level as the radar station) directly below the plane. $s$ is the distance from the plane the the radar station.
Using the Pythagorean theorem, we may state:
(1) \(\displaystyle x^2+h^2=s^2\)
Implicitly differentiating (1) with respect to time $t$, we find:
\(\displaystyle 2x\frac{dx}{dt}=2s\frac{ds}{dt}\)
We are interested in solving for \(\displaystyle \frac{ds}{dt}\) since we are asked to find the rate at which the distance from the plane to the station is increasing when it is 5 mi away from the station. So, we find:
\(\displaystyle \frac{ds}{dt}=\frac{x}{s}\frac{dx}{dt}\)
Now, we do not know $x$ but we know $h$ and $s$, and so solving (1) for $x$ (and taking the positive root since it represents a distance), we find:
\(\displaystyle x=\sqrt{s^2-h^2}\)
And so we have:
\(\displaystyle \frac{ds}{dt}=\frac{\sqrt{s^2-h^2}}{s}\frac{dx}{dt}\)
Now, the speed $v$ of the plane represents the time rate of change of $x$, hence:
\(\displaystyle v=\frac{dx}{dt}\)
and so we may write:
\(\displaystyle \frac{ds}{dt}=\frac{v\sqrt{s^2-h^2}}{s}\)
Now, we may plug in the given data:
\(\displaystyle v=470\frac{\text{mi}}{\text{hr}},\,s=5\text{ mi},\,h=1\text{ mi}\)
and we then find:
\(\displaystyle \frac{ds}{dt}=\frac{470\sqrt{5^2-1^2}}{5} \frac{\text{mi}}{\text{hr}}=188\sqrt{6}\frac{\text{mi}}{\text{hr}}\approx460.504071643238 \text{ mph}\)
And so we have found that the rate at which the distance from the plane to the station is increasing when it is 5 mi away from the station is about 461 mph.
First, let's draw a diagram:
View attachment 1445
The plane is at $P$, the radar station is at $R$, $h$ is the altitude of the plane (which is constant since its flight is said to be horizontal) and $x$ is the distance from the radar station to the point on the ground (or at the same level as the radar station) directly below the plane. $s$ is the distance from the plane the the radar station.
Using the Pythagorean theorem, we may state:
(1) \(\displaystyle x^2+h^2=s^2\)
Implicitly differentiating (1) with respect to time $t$, we find:
\(\displaystyle 2x\frac{dx}{dt}=2s\frac{ds}{dt}\)
We are interested in solving for \(\displaystyle \frac{ds}{dt}\) since we are asked to find the rate at which the distance from the plane to the station is increasing when it is 5 mi away from the station. So, we find:
\(\displaystyle \frac{ds}{dt}=\frac{x}{s}\frac{dx}{dt}\)
Now, we do not know $x$ but we know $h$ and $s$, and so solving (1) for $x$ (and taking the positive root since it represents a distance), we find:
\(\displaystyle x=\sqrt{s^2-h^2}\)
And so we have:
\(\displaystyle \frac{ds}{dt}=\frac{\sqrt{s^2-h^2}}{s}\frac{dx}{dt}\)
Now, the speed $v$ of the plane represents the time rate of change of $x$, hence:
\(\displaystyle v=\frac{dx}{dt}\)
and so we may write:
\(\displaystyle \frac{ds}{dt}=\frac{v\sqrt{s^2-h^2}}{s}\)
Now, we may plug in the given data:
\(\displaystyle v=470\frac{\text{mi}}{\text{hr}},\,s=5\text{ mi},\,h=1\text{ mi}\)
and we then find:
\(\displaystyle \frac{ds}{dt}=\frac{470\sqrt{5^2-1^2}}{5} \frac{\text{mi}}{\text{hr}}=188\sqrt{6}\frac{\text{mi}}{\text{hr}}\approx460.504071643238 \text{ mph}\)
And so we have found that the rate at which the distance from the plane to the station is increasing when it is 5 mi away from the station is about 461 mph.
Attachments
1. What is the rate of change of a plane's distance from a radar station?
The rate of change of a plane's distance from a radar station refers to how quickly the distance between the plane and the radar station is changing over time. This can be calculated by dividing the change in distance by the change in time.
2. Why is the rate of change of a plane's distance from a radar station important?
This rate of change is important because it can help track the movement and speed of a plane. It is also used to determine the direction the plane is traveling and its acceleration.
3. How is the rate of change of a plane's distance from a radar station measured?
The rate of change of a plane's distance from a radar station can be measured using specialized equipment such as radar or lidar. These devices use electromagnetic waves to track the distance of the plane and can calculate the rate of change over time.
4. What factors can affect the rate of change of a plane's distance from a radar station?
The rate of change of a plane's distance from a radar station can be affected by several factors such as the plane's speed, direction, and altitude. Other factors such as weather conditions, air traffic, and technical issues with the radar equipment can also impact the rate of change.
5. How is the rate of change of a plane's distance from a radar station used in aviation?
The rate of change of a plane's distance from a radar station is used in aviation for air traffic control, monitoring flight paths, and detecting potential collisions. It is also used for navigation and to provide real-time updates on a plane's location and movement.
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