Lenses and Autocollimation: Altering Focal Length and the Lensmaker's Equation

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SUMMARY

The discussion focuses on the autocollimation experiment involving a thin convex lens and the application of the lensmaker's equation to determine focal length. The focal length can be calculated using the formula 1/f = 2(n - 1)/r, where 'n' is the refractive index and 'r' is the radius of curvature. To increase the focal length of a symmetrical biconvex lens, one must make the lens rounder, thereby increasing the radius. The participants emphasize the importance of understanding the lensmaker's equation and its application in practical scenarios.

PREREQUISITES
  • Understanding of the lensmaker's equation
  • Knowledge of optical principles, specifically regarding convex lenses
  • Familiarity with the concept of autocollimation
  • Basic skills in solving algebraic equations related to optics
NEXT STEPS
  • Study the lensmaker's equation in detail, focusing on its derivation and applications
  • Explore the effects of lens curvature on focal length in optical systems
  • Investigate autocollimation techniques and their practical uses in optics
  • Learn about different types of lenses and their characteristics, particularly biconvex lenses
USEFUL FOR

Students in physics, optical engineers, and anyone interested in the practical applications of lens design and focal length manipulation.

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Homework Statement



a) In the autocollimation experiment of Sec. 3.5, a thin convex lens is placed 25 cm from a pinhole that acts as a point source of light. A plane mirror placed 20 cm behind the lens reflects the light back through the lens, and the reflected light forms a sharp spot beside the pinhole.
What is the focal length of the lens (in cm)?

b) Consider a symmetrical biconvex lens with r1 = r2 = r
How would you alter the lens if you wanted to make the focal length longer?
Make it flatter (more like a flat slide) or make it rounder (more like a sphere)?

A. 1/f = 0
B. 1/f = 2(n - 1)/r
C. 1/f = 2(1 - n)/r
D. 1/f = (n - 1)/r

Homework Equations



1/o+1/i=1/f

(n-1)(2/r)=1/f

The Attempt at a Solution


a)I used the lensmaker's equation but the answer was wrong. Shouldn't this formula apply?

b) Increasing the focal length would occur if the radius was increased. Since it is a biconvex lens, they will increase if the lens is made to go outward more, such as if it was a sphere instead of flat.
 
Last edited:
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Something tells me that I know you :)

Anyway

for (a) Read page 42, section 3.1.2 in your physics lab book
for (b) use equation 3.2 (see below)

(n-1)(1/r' -1/r'') = 1/f
for a biconvex lens, r'' is negative

hence (n-1)(1/r' - 1/-r'') = 1/f
(n-1)(1/r' + 1/r'') = 1/f
but since r' = r'' = r, substitute and solve and you'll get your answer
 

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