No.
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 iris diaphragm controls the amount of light that passes through the stage and, consequently, through the specimen. Reducing the iris diaphragm aperture increases contrast for an image focused under high power by reducing the amount of light that both fills the objective lens and deracts around specimen edges. Opening the iris diaphragm under high magnification increases "flare", the appearance of light "washing out" an object. By decreasing the flow of light through the specimen, the iris diaphragm limits light defraction and saturation.
They are the same because magnification and resolution both let you see smaller detail.
Because each eye needs its own magnified image. Put another way: Your brain doesn't add the magnification power of the image seen on the left to the magnification power of the image seen on the right. If only one ocular was magnified, you wouldn't be able to see the magnified image in both eyes---the eye with the unmagnified image would see unmagnified and the eye with the magnified image would see magnified. Am I understanding the question correctly?
Watts and horsepower are both units of power.
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)
To calculate magnification , multiply mag.Power of both lenses 15 x 30 = 350
please help i need this question answered I believe a bi-convex lens, that is, a lens with an outward curve on both surfaces, would provide the greatest magnification in a simple (single) lens system.
This depend on type of microscope and in particular which specific model it is. High power may refer to the microscopes ability to enlarge a lot, not that it actually consumes power. In this understanding of the term, the microscope in question might have two separate but combined lenses of which the total magnification can be calculated from. It may have an objective lens and an eye piece lens, both of which that might be changed in order to achieve greater or less magnification. Typical configurations are: Objective lenses of 1, 2, 3, 4, 10, 40, 100X magnification Eye piece lenses of 5, 10, 15, 20X magnification. If your microscope fits this configuration, then the maximum magnification you can achieve is 100x20, a magnification of maximum 2000 times. The problem here is the wavelength of visible light. It does not allow for more magnification than approx 1500 times and even this is not a very detailed one.
the iris diaphragm controls the amount of light that passes through the stage and, consequently, through the specimen. Reducing the iris diaphragm aperture increases contrast for an image focused under high power by reducing the amount of light that both fills the objective lens and deracts around specimen edges. Opening the iris diaphragm under high magnification increases "flare", the appearance of light "washing out" an object. By decreasing the flow of light through the specimen, the iris diaphragm limits light defraction and saturation.
They both have something to do with a magnifying glass
they both are big words and are for big kids
The total magnification is equal to the magnification of the eyepiece multiplied by the magnification of the objective lens. So in this case the objective lens would need to be 100X.
The Onion cell and cheek cell both had cytoplasm, nucleuses, and cell membranes under 400x Magnification
That will depend upon personal requirements. Both have 3 power magnification. The second number is the diameter of the ocular. The larger the number the more light gathering power and the larger field of view the scope will have.
This depend on type of microscope and in particular which specific model it is. High power may refer to the microscopes ability to enlarge a lot, not that it actually consumes power. In this understanding of the term, the microscope in question might have two separate but combined lenses of which the total magnification can be calculated from. It may have an objective lens and an eye piece lens, both of which that might be changed in order to achieve greater or less magnification. Typical configurations are: Objective lenses of 1, 2, 3, 4, 10, 40, 100X magnification Eye piece lenses of 5, 10, 15, 20X magnification. If your microscope fits this configuration, then the maximum magnification you can achieve is 100x20, a magnification of maximum 2000 times. The problem here is the wavelength of visible light. It does not allow for more magnification than approx 1500 times and even this is not a very detailed one.
Actual magnification of light microscopes could reach up 1000x magnification depending on the type of light microscope. Light microscopes could be divided into brightfield microscope and phase-contrast microscope for viewing stained specimen and unstained specimen respectively. Magnification of electron microscope on the other hand could go up to 1000000x. The actual magnification as well depends on types of electron microscope which includes transmission-electron microscope and scanning-electron microscope where both of them are used in viewing internal cell structures and cell surface structures respectively.