What is the value of the smallest objective?
If it is 4x,
The total magnification = eye piece x objective lens
= (10x) x (4x)
= 40x
magnification= ocular power *objective power=10X*60X
MP=(d/L)*(1-(L-l)f) where d would be the distance from the eye to the image without a lens L is the distance from the eye to the new virtual image (with a lens) l is the distance from the eye to the lens this equation only covers a single lens (whereas there tend to be two in a microscope), but that's no worry; use it twice! (i.e treat both lenses as independent sources of the image)
One can obtain a total magnification of 400x while using an objective lens of 40x. Such a lens should be used along an eyepiece of 10x.
The 'object lens' in a compound microscope is closest to the object being examined.
The total magnification of a microscope when the low power objective is locked in place is the product of the magnification of the eyepiece and the magnification of the objective lens. For most microscopes, the low power objective lens has a magnification of around 10x, and the standard eyepiece magnification is 10x. Therefore, the total magnification would be 100x.
To find the total magnifying power of a microscope, you multiply the magnification of the objective lens by the magnification of the eyepiece. For example, if the objective lens magnifies 10x and the eyepiece magnifies 20x, the total magnifying power would be 10x * 20x = 200x.
The low power objective is small lens with low magnifying power.
No, the magnifying power is not simply the sum of the magnifications of the two lenses. In a compound microscope, the total magnification is the product of the magnification of the objective lens and the eyepiece lens.
The total magnification would be 200x, since the total magnification is the magnification of the objective lens X the magnification of the eyepiece.
The total magnification of a microscope is calculated by multiplying the power of the objective lens by the power of the eyepiece lens. Given a total magnification of 200x and an eyepiece lens power of 10x, the power of the objective lens would be 200x/10x = 20x.
The magnifying power of the LPO (low power objective) lens on a microscope is typically 10x. This means that when viewing an object through the LPO lens, it will appear 10 times larger than its actual size.
magnification= ocular power *objective power=10X*60X
The main magnifying parts of a microscope are the objective lens and the ocular lens. The objective lens magnifies the specimen being viewed, while the ocular lens further magnifies the image produced by the objective lens. Together, they help to achieve high magnification for detailed observation of microscopic structures.
MP=(d/L)*(1-(L-l)f) where d would be the distance from the eye to the image without a lens L is the distance from the eye to the new virtual image (with a lens) l is the distance from the eye to the lens this equation only covers a single lens (whereas there tend to be two in a microscope), but that's no worry; use it twice! (i.e treat both lenses as independent sources of the image)
The magnifying parts of a compound microscope are the objective lens and the ocular lens. The objective lens is located near the specimen and provides the initial magnification, while the ocular lens further magnifies the image for viewing. Together, these lenses work to increase the overall magnification power of the microscope.
The focal length of EyePiece is relatively larger to that of the Objective lens. Power of a lens is inversely proportional to it's focal length. Therefore, Objective is slightly more powerful than EyePiece.
Total magnification with a low power objective lens is calculated by multiplying the magnification power of the objective lens by the magnification of the eyepiece (ocular lens). Typically, a low power objective lens has a magnification of 10x or 4x, and when combined with a standard 10x eyepiece, the total magnification would be 100x or 40x, respectively. Therefore, total magnification for low power objectives usually ranges from 40x to 100x.