alphysicist said:Hi jcpwn2004,
The problem here is not a thin lens problem; it is finding an image produced by a refracting surface. What equation would you use for these problems?
jcpwn2004 said:ummm i really don't know lol, i thought refraction had to do with the n1sin01=n2sin02 equation...
alphysicist said:That equation (Snell's law) does describe the refraction of a light ray as it passes from one medium to the next.
However, in this problem we want to know how refraction at a single surface creates an image. You can use Snell's law to derive an expression that tells how an image is formed for light refracting from a surface. Your textbook probably does this for you and gives you the final result, which is something like:
[tex]
\frac{n_1}{p}+\frac{n_2}{q} =\frac{n_2-n_1}{R}
[/tex]
Many books use many different symbols for the quantities in the denominators, so look for a section titled something like "image formed by refraction" to find out how it's written in your book. (The section is commonly between the section on spherical mirrors and thin lenses.)
Once you find it, you'll need to interpret what the symbols mean, and then apply it to your problem. What do you get?
A concave lens is a type of lens that is thinner in the center and thicker at the edges. It is usually curved inward and causes light rays to spread out, making objects appear smaller and closer than they actually are.
To solve a concave lens problem, you will need to use the thin lens equation: 1/f = 1/do + 1/di, where f is the focal length of the lens, do is the object distance, and di is the image distance. You will also need to use the magnification equation: M = -di/do, where M is the magnification of the image. By plugging in the given values and solving for the unknown quantities, you can find the location and size of the image formed by the concave lens.
If you have multiple lenses in the problem, you will need to use the lensmaker's equation: 1/f = (n - 1)(1/R1 - 1/R2), where n is the refractive index of the lens material, and R1 and R2 are the radii of curvature of the two lens surfaces. You will also need to use the thin lens equation for each individual lens. By solving for the unknown quantities in each equation and using the object and image distances from the previous lens as the object and image distances for the next lens, you can find the final image location and size.
Some common mistakes when solving concave lens problems include forgetting to use the negative sign for the image distance in the magnification equation, using the wrong sign for the focal length, and not converting units correctly. It is important to double check all calculations and make sure all values are in the correct units before plugging them into the equations.
No, the same method cannot be used to solve convex lens problems. The thin lens equation and magnification equation are still used, but the sign conventions and direction of light rays are different for convex lenses. It is important to understand the differences between concave and convex lenses and use the appropriate equations and conventions when solving problems.