2) Starting with the Gaussian formula, 1 1 1 + S S show that the magnification for a single thin lens can also be writtens 1 MT =-S + 1 In other words, if you graph the magnification as a function of s', you will get a line with slope of -1/f and y-intercept of 1.
2) Starting with the Gaussian formula, 1 1 1 + S S show that the magnification for a single thin lens can also be writtens 1 MT =-S + 1 In other words, if you graph the magnification as a function of s', you will get a line with slope of -1/f and y-intercept of 1.
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Question
![2) Starting with the Gaussian formula,
1
+
1
1
S
S
show that the magnification for a single thin lens can also be written si
f
1
MT
In other words, if you graph the magnification as a function of s', you will get a
line with slope of -1/f and y-intercept of 1.
==
s +1](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F0c015292-e614-4754-9a92-673e636d111d%2F93717b9c-8b92-4904-ad5d-554c16352dfa%2Fdfxvm4_processed.jpeg&w=3840&q=75)
Transcribed Image Text:2) Starting with the Gaussian formula,
1
+
1
1
S
S
show that the magnification for a single thin lens can also be written si
f
1
MT
In other words, if you graph the magnification as a function of s', you will get a
line with slope of -1/f and y-intercept of 1.
==
s +1
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