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MarkFL
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Here are the questions:
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.
Kendra Leota's Calculus Questions @ Yahoo Answers
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In summary, we discussed three different word problems involving calculus. In the first problem, we looked at how to maximize the area of two adjacent rectangular corrals given a certain amount of fencing. In the second problem, we found a function to model the area of a rectangle inscribed in a semi-circle and determined an x-value that would produce a desired area. Finally, we used the tangent function to find the distance traveled by a rocket launched at a certain angle from a mounted camera.
- #2
MarkFL
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Hello Kendra Leota,
1.) I would first draw a sketch of the corrals:
View attachment 1204
We can now see that we have the objective function (the enclosed area $A$):
\(\displaystyle A(x,y)=xy\)
subject to the constraint (the amount of fencing $F$):
\(\displaystyle 2x+3y=F\)
I know of 3 methods to use here. The first two will require that we express $A$ as a function of 1 variable, so if we solve the constraint for $y$, we find:
\(\displaystyle y=\frac{F-2x}{3}\)
and by substitution we now have:
\(\displaystyle A(x)=x\left(\frac{F-2x}{3} \right)=\frac{1}{3}\left(x(F-2x) \right)\)
i) Pre-calculus technique:
We see that we have a parabolic function opening down, and so the vertex will be the global maximum. The vertex must be midway between the roots, and we can see the roots are at:
\(\displaystyle x=0,\,\frac{F}{2}\)
and so the axis of symmetry, which contains the vertex, is the line:
\(\displaystyle x=\frac{F}{4}\)
and thus:
\(\displaystyle y=\frac{F-2\left(\frac{F}{4} \right)}{3}=\frac{F}{6}\)
We then see that half of the fencing is in the horizontal segments and half is in the vertical segments.
ii) Using differentiation
Let's write the area function as:
\(\displaystyle A(x)=\frac{1}{3}\left(Fx-2x^2 \right)\)
Now, equate the first derivative to zero to find the critical point:
\(\displaystyle A'(x)=\frac{F}{3}-\frac{4}{3}x=0\implies x=\frac{F}{4}\)
$y$ is found in the same way as the first method. We see that:
\(\displaystyle A''(x)=-\frac{4}{3}<0\)
and so we know the function is concave down everywhere, so our critical value is a maximum.
iii) Multi-variable technique (Lagrange multipliers):
We obtain the following system:
\(\displaystyle y=2\lambda\)
\(\displaystyle x=3\lambda\)
This implies:
\(\displaystyle 2x=3y\)
and putting this into the constraint, we find:
\(\displaystyle x=\frac{F}{4},\,y=\frac{F}{6}\)
To finish up, letting \(\displaystyle F=200\text{ ft}\), we find the dimensions which maximize the enclosed area is:
\(\displaystyle x=50\text{ ft}\)
\(\displaystyle y=\frac{100}{3}\text{ ft}\)
2.) Let's draw a sketch:
View attachment 1205
We can see that we have the area of the rectangle as:
\(\displaystyle A(x,y)=2xy\)
Using the fact that $y$ is a function of $x$, we find:
\(\displaystyle A(x)=2x\sqrt{r^2-x^2}\)
Using the given \(\displaystyle r=8\), we have:
\(\displaystyle A(x)=2x\sqrt{8^2-x^2}\)
To find the value of $x$ when $A=30$, we may write:
\(\displaystyle 30=2x\sqrt{8^2-x^2}\)
Square both sides:
\(\displaystyle 900=4x^2\left(64-x^2 \right)\)
\(\displaystyle 225=x^2\left(64-x^2 \right)=64x^2-x^4\)
\(\displaystyle x^4-64x^2+225=0\)
Observing that we have a quadratic in $x^2$, we may apply the quadratic formula to obtain:
\(\displaystyle x^2=\frac{64\pm\sqrt{(-64)^2-4(1)(225)}}{2(1)}=32\pm\sqrt{799}\)
Hence, taking the positive root as we require $0\le x\le8$):
\(\displaystyle x=\sqrt{32\pm\sqrt{799}}\)
3.) Again, let's draw a sketch:
View attachment 1206
We now see that we may relate the two known sides of the triangle to the angle using the tangent function:
\(\displaystyle \tan(\theta)=\frac{x}{d}\implies x=d\tan(\theta)\)
Using the given \(\displaystyle d=300\text{ ft}\) we have:
\(\displaystyle x(\theta)=300\tan(\theta)\text{ ft}\)
To find the distance traveled by the rocket when $\theta=20^{\circ}$, we may write:
\(\displaystyle x\left(20^{\circ} \right)=300\tan\left(20^{\circ} \right)\text{ ft}\approx109.191070279861\text{ ft}\)
1.) I would first draw a sketch of the corrals:
View attachment 1204
We can now see that we have the objective function (the enclosed area $A$):
\(\displaystyle A(x,y)=xy\)
subject to the constraint (the amount of fencing $F$):
\(\displaystyle 2x+3y=F\)
I know of 3 methods to use here. The first two will require that we express $A$ as a function of 1 variable, so if we solve the constraint for $y$, we find:
\(\displaystyle y=\frac{F-2x}{3}\)
and by substitution we now have:
\(\displaystyle A(x)=x\left(\frac{F-2x}{3} \right)=\frac{1}{3}\left(x(F-2x) \right)\)
i) Pre-calculus technique:
We see that we have a parabolic function opening down, and so the vertex will be the global maximum. The vertex must be midway between the roots, and we can see the roots are at:
\(\displaystyle x=0,\,\frac{F}{2}\)
and so the axis of symmetry, which contains the vertex, is the line:
\(\displaystyle x=\frac{F}{4}\)
and thus:
\(\displaystyle y=\frac{F-2\left(\frac{F}{4} \right)}{3}=\frac{F}{6}\)
We then see that half of the fencing is in the horizontal segments and half is in the vertical segments.
ii) Using differentiation
Let's write the area function as:
\(\displaystyle A(x)=\frac{1}{3}\left(Fx-2x^2 \right)\)
Now, equate the first derivative to zero to find the critical point:
\(\displaystyle A'(x)=\frac{F}{3}-\frac{4}{3}x=0\implies x=\frac{F}{4}\)
$y$ is found in the same way as the first method. We see that:
\(\displaystyle A''(x)=-\frac{4}{3}<0\)
and so we know the function is concave down everywhere, so our critical value is a maximum.
iii) Multi-variable technique (Lagrange multipliers):
We obtain the following system:
\(\displaystyle y=2\lambda\)
\(\displaystyle x=3\lambda\)
This implies:
\(\displaystyle 2x=3y\)
and putting this into the constraint, we find:
\(\displaystyle x=\frac{F}{4},\,y=\frac{F}{6}\)
To finish up, letting \(\displaystyle F=200\text{ ft}\), we find the dimensions which maximize the enclosed area is:
\(\displaystyle x=50\text{ ft}\)
\(\displaystyle y=\frac{100}{3}\text{ ft}\)
2.) Let's draw a sketch:
View attachment 1205
We can see that we have the area of the rectangle as:
\(\displaystyle A(x,y)=2xy\)
Using the fact that $y$ is a function of $x$, we find:
\(\displaystyle A(x)=2x\sqrt{r^2-x^2}\)
Using the given \(\displaystyle r=8\), we have:
\(\displaystyle A(x)=2x\sqrt{8^2-x^2}\)
To find the value of $x$ when $A=30$, we may write:
\(\displaystyle 30=2x\sqrt{8^2-x^2}\)
Square both sides:
\(\displaystyle 900=4x^2\left(64-x^2 \right)\)
\(\displaystyle 225=x^2\left(64-x^2 \right)=64x^2-x^4\)
\(\displaystyle x^4-64x^2+225=0\)
Observing that we have a quadratic in $x^2$, we may apply the quadratic formula to obtain:
\(\displaystyle x^2=\frac{64\pm\sqrt{(-64)^2-4(1)(225)}}{2(1)}=32\pm\sqrt{799}\)
Hence, taking the positive root as we require $0\le x\le8$):
\(\displaystyle x=\sqrt{32\pm\sqrt{799}}\)
3.) Again, let's draw a sketch:
View attachment 1206
We now see that we may relate the two known sides of the triangle to the angle using the tangent function:
\(\displaystyle \tan(\theta)=\frac{x}{d}\implies x=d\tan(\theta)\)
Using the given \(\displaystyle d=300\text{ ft}\) we have:
\(\displaystyle x(\theta)=300\tan(\theta)\text{ ft}\)
To find the distance traveled by the rocket when $\theta=20^{\circ}$, we may write:
\(\displaystyle x\left(20^{\circ} \right)=300\tan\left(20^{\circ} \right)\text{ ft}\approx109.191070279861\text{ ft}\)
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