How Do You Calculate Image Distance and Magnification for a Camera Lens?

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ZedCar
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Homework Statement


Was wondering if someone could help...
A simple camera has a converging lens of focal length 50.0 mm.

It is used to photograph a tree 3.00 m high.

The tree is 8.00 m away from the lens.

Calculate the distance v between the lens and the film, giving your answer in mm to three significant figures.


Homework Equations


1/f = 1/u + 1/v
m = v/u

The Attempt at a Solution


Using:
1/f = 1/u + 1/v

1/50 = 1/8000 + 1/(v)
v = 50.3 mm


Then to calculate the linear magnification of the image, using m = v/u with same v and u values from above? (both in metres)

i.e.

m = 0.0503 / 8 = 0.0063

Though as the image gets flipped upside down it's probably:
m = -0.0503 / 8 = -0.0063


Thank you :smile:
 
on Phys.org
Redbelly98 said:
In fact the correct equation for magnification does have the minus sign:

m = -v/u

Thanks very much Redbelly98. I hadn't realized that!
 
Redbelly98 said:
In fact the correct equation for magnification does have the minus sign:

m = -v/u

Is that definitely correct?

I looked the equation up in my CGP Physics Revision Guide and it states the equation as:

m = v/u
 
ZedCar said:
Is that definitely correct?

I looked the equation up in my CGP Physics Revision Guide and it states the equation as:

m = v/u

Yes, it is m=-v/u.
 
So substituting with the numbers from the initial post:
m = -v / u
m = -0.0503 / 8 = -0.0063

So the answer for m is definitely a -'ve answer and not +'ve ?
 
I had thought, from what I learned in class, that the -'ve sign indicated that the image was virtual.

I hadn't realized it was an indication of whether the image was inverted.

Which is why I thought the m would be +'ve since the camera image is real.

I haven't been studying diagrams for long, so it would appear that I have not quite got the concept correct yet.
 
The fundamental definition of magnification is the ratio of the heights, himage/hobject, with an inverted image treated as a negative height. Many physics textbooks use a geometric argument, using similar triangles, to show that this is equivalent to -v/u. The -v/u formula is generally more useful, since it's more common to give information about the distance from the lens rather than the height.