Solve Illumination Problem: Use Derivatives & Differentials

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SUMMARY

The illumination on a surface is defined by the equation I=kSinZ/d², where Z is the angle of incidence, k is a constant intensity, and d is the distance from the light source. To maximize illumination at the corners of a rectangular room measuring 10 feet by 24 feet with a 10-foot ceiling, one must optimize the height of the light fixture using derivatives. The process involves redefining I in terms of Z, differentiating with respect to Z, and solving for Z when the derivative equals zero. The final solution indicates that the optimal height for the light fixture is 9.101 feet.

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  • Understanding of optimization techniques in calculus
  • Knowledge of derivatives and differentials
  • Familiarity with trigonometric functions, specifically sine and tangent
  • Ability to apply geometric principles to real-world problems
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  • Study optimization techniques in calculus, focusing on critical points and maxima/minima
  • Learn about the application of derivatives in real-world scenarios, particularly in physics
  • Explore trigonometric identities and their applications in geometry
  • Investigate the relationship between light intensity and distance in illumination theory
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Students in calculus, physics enthusiasts, and anyone involved in architectural lighting design or optimization problems related to illumination.

MC Escher
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Homework Statement


I am going to use "Z" to represent theta,
The amount of illumination on a surface is given by I=kSinZ/d^2
where Z is the angle at which the light strikes the surface, k is the intensity of illumination (and is constant), and d is the distance from the light to a surface. A rectangular room measures 10 feet by 24 feet, with a 10-foot ceiling. Determine the height at which the light should be placed (in the center of the room) to allow the corners of the floor to receive the maximum amount of light.


Homework Equations


Optimization
Use of Derivatives
Differentials
All of these could be relevant, there aren't really any "equations" per se.



The Attempt at a Solution


I am quite sure you need to rewrite in terms of Z. I have a triangle set up with d as the hypotenuse, x the opposite side, and Z as the adjacent angle. I have:
SinZ=x/d
TanZ=x/13
d=13TanZ/SinZ
Here are some "hints" that were given:
1. Redefine I in terms of Z
2. Differentiate wrt Z to get 'the change in illumination wrt to the angle'
3. Determine Z when the differentiated expression equals O, and keep in mind the angle must be less than 90 degrees.
4. Determine x at this Z value
5. Differentiate a second time to verify if the value is a max or a min.
 
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anyone? lol
 
Ok. What is the definition of 'maximum amount of light in a corner'? Do you want to maximize the sum of the intensities on each of the three surfaces meeting there? If so then you need to derive a formula relating the vertical height of the bulb to the three angles to each of these surfaces. Once you have done that then sum the three intensities and maximize wrt to the height. The lack of response here may be due to the fact that you didn't state a very definite 'question'. What part of this is presenting difficulties?
 
Last edited:
Dick said:
Ok. What is the definition of 'maximum amount of light in a corner'? Do you want to maximize the sum of the intensities on each of the three surfaces meeting there? If so then you need to derive a formula relating the vertical height of the bulb to the three angles to each of these surfaces. Once you have done that then sum the three intensities and maximize wrt to the height. The lack of response here may be due to the fact that you didn't state a very definite 'question'. What part of this is presenting difficulties?
I appreciate the help, but I solved the problem, 9.101
 

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