The focal length of the lens.

Question

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Answer 1

Question

Chapter 23, Problem 50AP

(a)

To determine

The focal length of the lens.

(a)

Expert Solution

Answer to Problem 50AP

The focal length of the lens is −12.0 cm .

Explanation of Solution

Given info:

The radius if left side is −15.0 cm .

The radius if right side is 10.0 cm .

The refractive index is 1.50 .

Explanation:

Formula to calculate the focal length is,

f=1(n−1)(1R1−1R2)

f is the focal length
n is the refractive index
R1 is the radius of curvature of left side of the lens
R2 is the radius of curvature of right side of the lens

Substitute 1.50 for n , −15.0 cm for R1 and 10.0 cm for R2 to find f .

f=1(1.50−1)(1−15.0 cm−110.0 cm)=−12.0 cm

Thus, the focal length of the lens is −12.0 cm .

Conclusion:

The focal length of the lens is −12.0 cm .

(b)

To determine

The position of the image when the object is at infinity.

(b)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at infinity is −12.0 cm .

Explanation of Solution

Given info:

The initial object distance is ∝ .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

q is the image distance
p is the object distance

Substitute ∝ for p and −12.0 cm for f to find q .

q=1(1−12.0 cm−1∝ )=−12.0 cm

Thus, the position of the image when the object is at infinity is −12.0 cm .

Conclusion:

The position of the image when the object is at infinity is −12.0 cm .

(c)

To determine

The position of the image when the object is at a distance 3|f| .

(c)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance 3|f| is −9.00 cm .

Explanation of Solution

Given info:

The initial object distance is 3|f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute 3|f| for p and −12.0 cm for f to find q .

q=1(1f−13|f| )=1(1−12.0 cm−13|−12.0 cm| )=−9.00 cm

Thus, the position of the image when the object is at a distance 3|f| is −9.00 cm .

Conclusion:

The position of the image when the object is at a distance 3|f| is −9.00 cm .

(d)

To determine

The position of the image when the object is at a distance |f| .

(d)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f| is −6.00 cm .

Explanation of Solution

Given info:

The initial object distance is |f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f| for p and −12.0 cm for f to find q .

p=1(1f−1|f| )=1(1−12.0 cm−1|−12.0 cm| )=−6.00 cm

Thus, the position of the image when the object is at a distance |f| is −6.00 cm .

Conclusion:

The position of the image when the object is at a distance |f| is −6.00 cm .

(e)

To determine

The position of the image when the object is at a distance |f|/2 .

(e)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f|/2 is −4.00 cm

Explanation of Solution

Given info:

The initial object distance is |f|/2 .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f|/2 for p and −12.0 cm for f to find q .

q=1(1f−1|f|/2 )=1(1−12.0 cm−1|−12.0 cm| /2)=−4.00 cm

Thus, the position of the image when the object is at a distance |f|/2 is −4.00 cm .

Conclusion:

The position of the image when the object is at a distance |f|/2 is −4.00 cm .

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Answer 2

Question

Chapter 23, Problem 50AP

(a)

To determine

The focal length of the lens.

(a)

Expert Solution

Answer to Problem 50AP

The focal length of the lens is −12.0 cm .

Explanation of Solution

Given info:

The radius if left side is −15.0 cm .

The radius if right side is 10.0 cm .

The refractive index is 1.50 .

Explanation:

Formula to calculate the focal length is,

f=1(n−1)(1R1−1R2)

f is the focal length
n is the refractive index
R1 is the radius of curvature of left side of the lens
R2 is the radius of curvature of right side of the lens

Substitute 1.50 for n , −15.0 cm for R1 and 10.0 cm for R2 to find f .

f=1(1.50−1)(1−15.0 cm−110.0 cm)=−12.0 cm

Thus, the focal length of the lens is −12.0 cm .

Conclusion:

The focal length of the lens is −12.0 cm .

(b)

To determine

The position of the image when the object is at infinity.

(b)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at infinity is −12.0 cm .

Explanation of Solution

Given info:

The initial object distance is ∝ .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

q is the image distance
p is the object distance

Substitute ∝ for p and −12.0 cm for f to find q .

q=1(1−12.0 cm−1∝ )=−12.0 cm

Thus, the position of the image when the object is at infinity is −12.0 cm .

Conclusion:

The position of the image when the object is at infinity is −12.0 cm .

(c)

To determine

The position of the image when the object is at a distance 3|f| .

(c)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance 3|f| is −9.00 cm .

Explanation of Solution

Given info:

The initial object distance is 3|f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute 3|f| for p and −12.0 cm for f to find q .

q=1(1f−13|f| )=1(1−12.0 cm−13|−12.0 cm| )=−9.00 cm

Thus, the position of the image when the object is at a distance 3|f| is −9.00 cm .

Conclusion:

The position of the image when the object is at a distance 3|f| is −9.00 cm .

(d)

To determine

The position of the image when the object is at a distance |f| .

(d)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f| is −6.00 cm .

Explanation of Solution

Given info:

The initial object distance is |f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f| for p and −12.0 cm for f to find q .

p=1(1f−1|f| )=1(1−12.0 cm−1|−12.0 cm| )=−6.00 cm

Thus, the position of the image when the object is at a distance |f| is −6.00 cm .

Conclusion:

The position of the image when the object is at a distance |f| is −6.00 cm .

(e)

To determine

The position of the image when the object is at a distance |f|/2 .

(e)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f|/2 is −4.00 cm

Explanation of Solution

Given info:

The initial object distance is |f|/2 .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f|/2 for p and −12.0 cm for f to find q .

q=1(1f−1|f|/2 )=1(1−12.0 cm−1|−12.0 cm| /2)=−4.00 cm

Thus, the position of the image when the object is at a distance |f|/2 is −4.00 cm .

Conclusion:

The position of the image when the object is at a distance |f|/2 is −4.00 cm .

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Answer 3

Question

Chapter 23, Problem 50AP

(a)

To determine

The focal length of the lens.

(a)

Expert Solution

Answer to Problem 50AP

The focal length of the lens is −12.0 cm .

Explanation of Solution

Given info:

The radius if left side is −15.0 cm .

The radius if right side is 10.0 cm .

The refractive index is 1.50 .

Explanation:

Formula to calculate the focal length is,

f=1(n−1)(1R1−1R2)

f is the focal length
n is the refractive index
R1 is the radius of curvature of left side of the lens
R2 is the radius of curvature of right side of the lens

Substitute 1.50 for n , −15.0 cm for R1 and 10.0 cm for R2 to find f .

f=1(1.50−1)(1−15.0 cm−110.0 cm)=−12.0 cm

Thus, the focal length of the lens is −12.0 cm .

Conclusion:

The focal length of the lens is −12.0 cm .

(b)

To determine

The position of the image when the object is at infinity.

(b)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at infinity is −12.0 cm .

Explanation of Solution

Given info:

The initial object distance is ∝ .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

q is the image distance
p is the object distance

Substitute ∝ for p and −12.0 cm for f to find q .

q=1(1−12.0 cm−1∝ )=−12.0 cm

Thus, the position of the image when the object is at infinity is −12.0 cm .

Conclusion:

The position of the image when the object is at infinity is −12.0 cm .

(c)

To determine

The position of the image when the object is at a distance 3|f| .

(c)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance 3|f| is −9.00 cm .

Explanation of Solution

Given info:

The initial object distance is 3|f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute 3|f| for p and −12.0 cm for f to find q .

q=1(1f−13|f| )=1(1−12.0 cm−13|−12.0 cm| )=−9.00 cm

Thus, the position of the image when the object is at a distance 3|f| is −9.00 cm .

Conclusion:

The position of the image when the object is at a distance 3|f| is −9.00 cm .

(d)

To determine

The position of the image when the object is at a distance |f| .

(d)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f| is −6.00 cm .

Explanation of Solution

Given info:

The initial object distance is |f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f| for p and −12.0 cm for f to find q .

p=1(1f−1|f| )=1(1−12.0 cm−1|−12.0 cm| )=−6.00 cm

Thus, the position of the image when the object is at a distance |f| is −6.00 cm .

Conclusion:

The position of the image when the object is at a distance |f| is −6.00 cm .

(e)

To determine

The position of the image when the object is at a distance |f|/2 .

(e)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f|/2 is −4.00 cm

Explanation of Solution

Given info:

The initial object distance is |f|/2 .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f|/2 for p and −12.0 cm for f to find q .

q=1(1f−1|f|/2 )=1(1−12.0 cm−1|−12.0 cm| /2)=−4.00 cm

Thus, the position of the image when the object is at a distance |f|/2 is −4.00 cm .

Conclusion:

The position of the image when the object is at a distance |f|/2 is −4.00 cm .

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Answer 4

Question

Chapter 23, Problem 50AP

(a)

To determine

The focal length of the lens.

(a)

Expert Solution

Answer to Problem 50AP

The focal length of the lens is −12.0 cm .

Explanation of Solution

Given info:

The radius if left side is −15.0 cm .

The radius if right side is 10.0 cm .

The refractive index is 1.50 .

Explanation:

Formula to calculate the focal length is,

f=1(n−1)(1R1−1R2)

f is the focal length
n is the refractive index
R1 is the radius of curvature of left side of the lens
R2 is the radius of curvature of right side of the lens

Substitute 1.50 for n , −15.0 cm for R1 and 10.0 cm for R2 to find f .

f=1(1.50−1)(1−15.0 cm−110.0 cm)=−12.0 cm

Thus, the focal length of the lens is −12.0 cm .

Conclusion:

The focal length of the lens is −12.0 cm .

(b)

To determine

The position of the image when the object is at infinity.

(b)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at infinity is −12.0 cm .

Explanation of Solution

Given info:

The initial object distance is ∝ .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

q is the image distance
p is the object distance

Substitute ∝ for p and −12.0 cm for f to find q .

q=1(1−12.0 cm−1∝ )=−12.0 cm

Thus, the position of the image when the object is at infinity is −12.0 cm .

Conclusion:

The position of the image when the object is at infinity is −12.0 cm .

(c)

To determine

The position of the image when the object is at a distance 3|f| .

(c)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance 3|f| is −9.00 cm .

Explanation of Solution

Given info:

The initial object distance is 3|f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute 3|f| for p and −12.0 cm for f to find q .

q=1(1f−13|f| )=1(1−12.0 cm−13|−12.0 cm| )=−9.00 cm

Thus, the position of the image when the object is at a distance 3|f| is −9.00 cm .

Conclusion:

The position of the image when the object is at a distance 3|f| is −9.00 cm .

(d)

To determine

The position of the image when the object is at a distance |f| .

(d)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f| is −6.00 cm .

Explanation of Solution

Given info:

The initial object distance is |f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f| for p and −12.0 cm for f to find q .

p=1(1f−1|f| )=1(1−12.0 cm−1|−12.0 cm| )=−6.00 cm

Thus, the position of the image when the object is at a distance |f| is −6.00 cm .

Conclusion:

The position of the image when the object is at a distance |f| is −6.00 cm .

(e)

To determine

The position of the image when the object is at a distance |f|/2 .

(e)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f|/2 is −4.00 cm

Explanation of Solution

Given info:

The initial object distance is |f|/2 .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f|/2 for p and −12.0 cm for f to find q .

q=1(1f−1|f|/2 )=1(1−12.0 cm−1|−12.0 cm| /2)=−4.00 cm

Thus, the position of the image when the object is at a distance |f|/2 is −4.00 cm .

Conclusion:

The position of the image when the object is at a distance |f|/2 is −4.00 cm .

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Answer 5

Chapter 23, Problem 50AP

(a)

To determine

The focal length of the lens.

(a)

Expert Solution

Answer to Problem 50AP

The focal length of the lens is −12.0 cm .

Explanation of Solution

Given info:

The radius if left side is −15.0 cm .

The radius if right side is 10.0 cm .

The refractive index is 1.50 .

Explanation:

Formula to calculate the focal length is,

f=1(n−1)(1R1−1R2)

f is the focal length
n is the refractive index
R1 is the radius of curvature of left side of the lens
R2 is the radius of curvature of right side of the lens

Substitute 1.50 for n , −15.0 cm for R1 and 10.0 cm for R2 to find f .

f=1(1.50−1)(1−15.0 cm−110.0 cm)=−12.0 cm

Thus, the focal length of the lens is −12.0 cm .

Conclusion:

The focal length of the lens is −12.0 cm .

(b)

To determine

The position of the image when the object is at infinity.

(b)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at infinity is −12.0 cm .

Explanation of Solution

Given info:

The initial object distance is ∝ .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

q is the image distance
p is the object distance

Substitute ∝ for p and −12.0 cm for f to find q .

q=1(1−12.0 cm−1∝ )=−12.0 cm

Thus, the position of the image when the object is at infinity is −12.0 cm .

Conclusion:

The position of the image when the object is at infinity is −12.0 cm .

(c)

To determine

The position of the image when the object is at a distance 3|f| .

(c)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance 3|f| is −9.00 cm .

Explanation of Solution

Given info:

The initial object distance is 3|f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute 3|f| for p and −12.0 cm for f to find q .

q=1(1f−13|f| )=1(1−12.0 cm−13|−12.0 cm| )=−9.00 cm

Thus, the position of the image when the object is at a distance 3|f| is −9.00 cm .

Conclusion:

The position of the image when the object is at a distance 3|f| is −9.00 cm .

(d)

To determine

The position of the image when the object is at a distance |f| .

(d)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f| is −6.00 cm .

Explanation of Solution

Given info:

The initial object distance is |f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f| for p and −12.0 cm for f to find q .

p=1(1f−1|f| )=1(1−12.0 cm−1|−12.0 cm| )=−6.00 cm

Thus, the position of the image when the object is at a distance |f| is −6.00 cm .

Conclusion:

The position of the image when the object is at a distance |f| is −6.00 cm .

(e)

To determine

The position of the image when the object is at a distance |f|/2 .

(e)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f|/2 is −4.00 cm

Explanation of Solution

Given info:

The initial object distance is |f|/2 .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f|/2 for p and −12.0 cm for f to find q .

q=1(1f−1|f|/2 )=1(1−12.0 cm−1|−12.0 cm| /2)=−4.00 cm

Thus, the position of the image when the object is at a distance |f|/2 is −4.00 cm .

Conclusion:

The position of the image when the object is at a distance |f|/2 is −4.00 cm .

Answer 6

Chapter 23, Problem 50AP

(a)

To determine

The focal length of the lens.

(a)

Expert Solution

Answer to Problem 50AP

The focal length of the lens is −12.0 cm .

Explanation of Solution

Given info:

The radius if left side is −15.0 cm .

The radius if right side is 10.0 cm .

The refractive index is 1.50 .

Explanation:

Formula to calculate the focal length is,

f=1(n−1)(1R1−1R2)

f is the focal length
n is the refractive index
R1 is the radius of curvature of left side of the lens
R2 is the radius of curvature of right side of the lens

Substitute 1.50 for n , −15.0 cm for R1 and 10.0 cm for R2 to find f .

f=1(1.50−1)(1−15.0 cm−110.0 cm)=−12.0 cm

Thus, the focal length of the lens is −12.0 cm .

Conclusion:

The focal length of the lens is −12.0 cm .

Answer 7

Chapter 23, Problem 50AP

(a)

To determine

The focal length of the lens.

Answer 8

(a)

Expert Solution

Answer to Problem 50AP

The focal length of the lens is −12.0 cm .

Answer 9

(a)

Expert Solution

Answer 10

(a)

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

Given info:

The radius if left side is −15.0 cm .

The radius if right side is 10.0 cm .

The refractive index is 1.50 .

Explanation:

Formula to calculate the focal length is,

f=1(n−1)(1R1−1R2)

f is the focal length
n is the refractive index
R1 is the radius of curvature of left side of the lens
R2 is the radius of curvature of right side of the lens

Substitute 1.50 for n , −15.0 cm for R1 and 10.0 cm for R2 to find f .

f=1(1.50−1)(1−15.0 cm−110.0 cm)=−12.0 cm

Thus, the focal length of the lens is −12.0 cm .

Conclusion:

The focal length of the lens is −12.0 cm .

Answer 13

(b)

To determine

The position of the image when the object is at infinity.

(b)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at infinity is −12.0 cm .

Explanation of Solution

Given info:

The initial object distance is ∝ .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

q is the image distance
p is the object distance

Substitute ∝ for p and −12.0 cm for f to find q .

q=1(1−12.0 cm−1∝ )=−12.0 cm

Thus, the position of the image when the object is at infinity is −12.0 cm .

Conclusion:

The position of the image when the object is at infinity is −12.0 cm .

Answer 14

(b)

To determine

The position of the image when the object is at infinity.

Answer 15

(b)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at infinity is −12.0 cm .

Answer 16

(b)

Expert Solution

Answer 17

(b)

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

Given info:

The initial object distance is ∝ .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

q is the image distance
p is the object distance

Substitute ∝ for p and −12.0 cm for f to find q .

q=1(1−12.0 cm−1∝ )=−12.0 cm

Thus, the position of the image when the object is at infinity is −12.0 cm .

Conclusion:

The position of the image when the object is at infinity is −12.0 cm .

Answer 20

(c)

To determine

The position of the image when the object is at a distance 3|f| .

(c)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance 3|f| is −9.00 cm .

Explanation of Solution

Given info:

The initial object distance is 3|f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute 3|f| for p and −12.0 cm for f to find q .

q=1(1f−13|f| )=1(1−12.0 cm−13|−12.0 cm| )=−9.00 cm

Thus, the position of the image when the object is at a distance 3|f| is −9.00 cm .

Conclusion:

The position of the image when the object is at a distance 3|f| is −9.00 cm .

Answer 21

(c)

To determine

The position of the image when the object is at a distance 3|f| .

Answer 22

(c)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance 3|f| is −9.00 cm .

Answer 23

(c)

Expert Solution

Answer 24

(c)

Expert Solution

Answer 25

Expert Solution

Answer 26

Explanation of Solution

Given info:

The initial object distance is 3|f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute 3|f| for p and −12.0 cm for f to find q .

q=1(1f−13|f| )=1(1−12.0 cm−13|−12.0 cm| )=−9.00 cm

Thus, the position of the image when the object is at a distance 3|f| is −9.00 cm .

Conclusion:

The position of the image when the object is at a distance 3|f| is −9.00 cm .

Answer 27

(d)

To determine

The position of the image when the object is at a distance |f| .

(d)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f| is −6.00 cm .

Explanation of Solution

Given info:

The initial object distance is |f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f| for p and −12.0 cm for f to find q .

p=1(1f−1|f| )=1(1−12.0 cm−1|−12.0 cm| )=−6.00 cm

Thus, the position of the image when the object is at a distance |f| is −6.00 cm .

Conclusion:

The position of the image when the object is at a distance |f| is −6.00 cm .

Answer 28

(d)

To determine

The position of the image when the object is at a distance |f| .

Answer 29

(d)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f| is −6.00 cm .

Answer 30

(d)

Expert Solution

Answer 31

(d)

Expert Solution

Answer 32

Expert Solution

Answer 33

Explanation of Solution

Given info:

The initial object distance is |f| .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f| for p and −12.0 cm for f to find q .

p=1(1f−1|f| )=1(1−12.0 cm−1|−12.0 cm| )=−6.00 cm

Thus, the position of the image when the object is at a distance |f| is −6.00 cm .

Conclusion:

The position of the image when the object is at a distance |f| is −6.00 cm .

Answer 34

(e)

To determine

The position of the image when the object is at a distance |f|/2 .

(e)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f|/2 is −4.00 cm

Explanation of Solution

Given info:

The initial object distance is |f|/2 .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f|/2 for p and −12.0 cm for f to find q .

q=1(1f−1|f|/2 )=1(1−12.0 cm−1|−12.0 cm| /2)=−4.00 cm

Thus, the position of the image when the object is at a distance |f|/2 is −4.00 cm .

Conclusion:

The position of the image when the object is at a distance |f|/2 is −4.00 cm .

Answer 35

(e)

To determine

The position of the image when the object is at a distance |f|/2 .

Answer 36

(e)

Expert Solution

Answer to Problem 50AP

The position of the image when the object is at a distance |f|/2 is −4.00 cm

Answer 37

(e)

Expert Solution

Answer 38

(e)

Expert Solution

Answer 39

Expert Solution

Answer 40

Explanation of Solution

Given info:

The initial object distance is |f|/2 .

Explanation:

Formula to calculate the image distance is,

q=1(1f−1p)

Substitute |f|/2 for p and −12.0 cm for f to find q .

q=1(1f−1|f|/2 )=1(1−12.0 cm−1|−12.0 cm| /2)=−4.00 cm

Thus, the position of the image when the object is at a distance |f|/2 is −4.00 cm .

Conclusion:

The position of the image when the object is at a distance |f|/2 is −4.00 cm .

Answer 41

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The focal length of the lens.

Concept explainers

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The focal length of the lens.

Answer to Problem 50AP

Explanation of Solution

The position of the image when the object is at infinity.

Answer to Problem 50AP

Explanation of Solution

The position of the image when the object is at a distance 3|f| .

Answer to Problem 50AP

Explanation of Solution

The position of the image when the object is at a distance |f| .

Answer to Problem 50AP

Explanation of Solution

The position of the image when the object is at a distance |f|/2 .

Answer to Problem 50AP

Explanation of Solution

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