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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.
Alex's question at Yahoo Answers regarding maximizing viewing angle
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In summary: for the summary, however, he believes that you should stand at least 1.5 feet from the screen to maximize your viewing angle.
- #2
MarkFL
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Hello Alex,
First let's draw a diagram:
View attachment 1638
\(\displaystyle s\) is the vertical height of the screen in feet.
\(\displaystyle h\) is the vertical distance from the bottom of the screen to eye level in feet.
\(\displaystyle \theta\) is the viewing angle, which we wish to maximize.
We see that using the definition of the tangent function, we may write:
(1) \(\displaystyle \tan(\beta)=\frac{h}{x}\)
(2) \(\displaystyle \tan(\beta+\theta)=\frac{h+s}{x}\)
Using the angle-sum identity for tangent, (2) may be expressed as:
\(\displaystyle \frac{\tan(\beta)+\tan(\theta)}{1-\tan(\beta)\tan(\theta)}=\frac{h+s}{x}\)
Using (1), this becomes:
\(\displaystyle \frac{\frac{h}{x}+\tan(\theta)}{1-\frac{h}{x}\tan(\theta)}=\frac{h+s}{x}\)
On the left, multiplying by \(\displaystyle 1=\frac{x}{x}\) we obtain:
\(\displaystyle \frac{h+x\tan(\theta)}{x-h\tan(\theta)}=\frac{h+s}{x}\)
Now we want to solve for $\tan(\theta)$. Cross-multiplying, we find:
\(\displaystyle hx+x^2\tan(\theta)=(h+s)x-h(h+s)\tan(\theta)\)
Adding through by \(\displaystyle h(h+2)\tan(\theta)-hx\) we get:
\(\displaystyle h(h+s)\tan(\theta)+x^2\tan(\theta)=(h+s)x-hx=sx\)
Factoring the left side:
\(\displaystyle \left(x^2+h(h+s) \right)\tan(\theta)=sx\)
Dividing through by \(\displaystyle x^2+h(h+s)\) we obtain:
\(\displaystyle \tan(\theta)=\frac{sx}{x^2+h(h+s)}\)
Now, differentiating with respect to $x$ and equating the result to zero to find the critical value(s), we find:
\(\displaystyle \sec^2(\theta)\frac{d\theta}{dx}=\frac{\left(x^2+h(h+s) \right)s-sx(2x)}{\left(x^2+h(h+s) \right)^2}=\frac{s\left(h(h+s)-x^2 \right)}{\left(x^2+h(h+s) \right)^2}=0\)
Multiply through by \(\displaystyle \cos^2(\theta)\) to get:
\(\displaystyle \frac{d\theta}{dx}=\frac{s\cos^2(\theta)\left(h(h+s)-x^2 \right)}{\left(x^2+h(h+s) \right)^2}=0\)
Since we must have \(\displaystyle \theta<\frac{\pi}{2}\), our only critical value comes from:
\(\displaystyle h(h+s)-x^2=0\)
Since \(\displaystyle 0<x\) we take the positive root:
\(\displaystyle x=\sqrt{h(h+s)}\)
Using the first derivative test, we see:
\(\displaystyle \left.\frac{d\theta}{dx} \right|_{x=\sqrt{\frac{h}{2}(h+s)}}=\frac{s\cos^2(\theta)\left(h(h+s)-\frac{h}{2}(h+s) \right)}{\left(\frac{h}{2}(h+s)+h(h+s) \right)^2}=\frac{s\cos^2(\theta)\left(\frac{h}{2}(h+s) \right)}{\left(\frac{3h}{2}(h+s) \right)^2}>0\)
\(\displaystyle \left.\frac{d\theta}{dx} \right|_{x=\sqrt{2h(h+s)}}= \frac{s\cos^2(\theta)\left(h(h+s)-2h(h+s) \right)}{\left(2h(h+s)+h(h+s) \right)^2}= -\frac{s\cos^2(\theta)\left(h(h+s) \right)}{\left(3h(h+s) \right)^2} <0\)
Thus, we conclude the critical value is at a maximum for $\theta$.
Now, using the given value $h=3\text{ ft}$, we find the distance $x$ from the screen that maximizes the viewing angle is given by:
\(\displaystyle x=\sqrt{3(3+s)}\)
First let's draw a diagram:
View attachment 1638
\(\displaystyle s\) is the vertical height of the screen in feet.
\(\displaystyle h\) is the vertical distance from the bottom of the screen to eye level in feet.
\(\displaystyle \theta\) is the viewing angle, which we wish to maximize.
We see that using the definition of the tangent function, we may write:
(1) \(\displaystyle \tan(\beta)=\frac{h}{x}\)
(2) \(\displaystyle \tan(\beta+\theta)=\frac{h+s}{x}\)
Using the angle-sum identity for tangent, (2) may be expressed as:
\(\displaystyle \frac{\tan(\beta)+\tan(\theta)}{1-\tan(\beta)\tan(\theta)}=\frac{h+s}{x}\)
Using (1), this becomes:
\(\displaystyle \frac{\frac{h}{x}+\tan(\theta)}{1-\frac{h}{x}\tan(\theta)}=\frac{h+s}{x}\)
On the left, multiplying by \(\displaystyle 1=\frac{x}{x}\) we obtain:
\(\displaystyle \frac{h+x\tan(\theta)}{x-h\tan(\theta)}=\frac{h+s}{x}\)
Now we want to solve for $\tan(\theta)$. Cross-multiplying, we find:
\(\displaystyle hx+x^2\tan(\theta)=(h+s)x-h(h+s)\tan(\theta)\)
Adding through by \(\displaystyle h(h+2)\tan(\theta)-hx\) we get:
\(\displaystyle h(h+s)\tan(\theta)+x^2\tan(\theta)=(h+s)x-hx=sx\)
Factoring the left side:
\(\displaystyle \left(x^2+h(h+s) \right)\tan(\theta)=sx\)
Dividing through by \(\displaystyle x^2+h(h+s)\) we obtain:
\(\displaystyle \tan(\theta)=\frac{sx}{x^2+h(h+s)}\)
Now, differentiating with respect to $x$ and equating the result to zero to find the critical value(s), we find:
\(\displaystyle \sec^2(\theta)\frac{d\theta}{dx}=\frac{\left(x^2+h(h+s) \right)s-sx(2x)}{\left(x^2+h(h+s) \right)^2}=\frac{s\left(h(h+s)-x^2 \right)}{\left(x^2+h(h+s) \right)^2}=0\)
Multiply through by \(\displaystyle \cos^2(\theta)\) to get:
\(\displaystyle \frac{d\theta}{dx}=\frac{s\cos^2(\theta)\left(h(h+s)-x^2 \right)}{\left(x^2+h(h+s) \right)^2}=0\)
Since we must have \(\displaystyle \theta<\frac{\pi}{2}\), our only critical value comes from:
\(\displaystyle h(h+s)-x^2=0\)
Since \(\displaystyle 0<x\) we take the positive root:
\(\displaystyle x=\sqrt{h(h+s)}\)
Using the first derivative test, we see:
\(\displaystyle \left.\frac{d\theta}{dx} \right|_{x=\sqrt{\frac{h}{2}(h+s)}}=\frac{s\cos^2(\theta)\left(h(h+s)-\frac{h}{2}(h+s) \right)}{\left(\frac{h}{2}(h+s)+h(h+s) \right)^2}=\frac{s\cos^2(\theta)\left(\frac{h}{2}(h+s) \right)}{\left(\frac{3h}{2}(h+s) \right)^2}>0\)
\(\displaystyle \left.\frac{d\theta}{dx} \right|_{x=\sqrt{2h(h+s)}}= \frac{s\cos^2(\theta)\left(h(h+s)-2h(h+s) \right)}{\left(2h(h+s)+h(h+s) \right)^2}= -\frac{s\cos^2(\theta)\left(h(h+s) \right)}{\left(3h(h+s) \right)^2} <0\)
Thus, we conclude the critical value is at a maximum for $\theta$.
Now, using the given value $h=3\text{ ft}$, we find the distance $x$ from the screen that maximizes the viewing angle is given by:
\(\displaystyle x=\sqrt{3(3+s)}\)
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- #3
Abraxis10
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Thanks for the break down! Adding points of interest in interval notation would be helpful: (0,\infty)
- #4
geraldjones
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gerald jones thanks you
Related to Alex's question at Yahoo Answers regarding maximizing viewing angle
1. What is the purpose of maximizing viewing angle?
The purpose of maximizing viewing angle is to increase the area or range in which an object or screen can be seen from a specific position. This can be useful in various settings such as TV watching, gaming, or presentations.
2. How is viewing angle measured?
Viewing angle is typically measured in degrees and refers to the angle at which an object or screen can be seen from a certain position. It is usually measured from the center of the screen or object to the farthest edge.
3. What factors affect the viewing angle of a screen or object?
The viewing angle of a screen or object can be affected by various factors such as the size and shape of the screen or object, the distance from the viewer, and the lighting conditions in the environment.
4. Can viewing angle be improved?
Yes, viewing angle can be improved by using certain techniques or technologies such as adjusting the screen or object position, using specialized lenses or filters, or utilizing screen technology with wider viewing angles.
5. Are there any drawbacks to maximizing viewing angle?
While maximizing viewing angle can be beneficial in certain situations, it can also result in decreased image quality or distortion at extreme angles. It is important to find a balance between maximizing viewing angle and maintaining image quality.
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