For Newtonian gravity, observe that the force (F) between two bodies is a function of only the mass of the bodies and distance between the center of mass of those bodies.
F = (G*m1*m2)/r^2; where, G = Gravitational constant, m1 = mass of one body, m2 = mass of second body, r = distance between bodies.
It is directly proportional to the mass of the bodies and inversely proportional to the square of the distance between them. Thus, the methods of increasing the magnitude of the force are to increase the mass of either or both of the bodies or decrease the distance between the bodies. Reducing the force can be accomplished by doing the opposite: decreasing mass or increasing distance.
It decreases.
decreases
The gravitational force IS the centripetal force in this case.
Higher magnification decreases working distance. Magnification and WD have inverse relation. One goes up the othe goes down. For example a 40X finite conjugate objective lens has WD of only 0.5mm while a 10X has WD of 6.30mm.
The formula for potential energy is mass times height times the local acceleration of gravity. Working with this, you have 1000 * 9.8 * 200.
It decreases.
the working distance decreases as the magnification increases
Working distance is the distance between the front edge of the object lens and the specimen surface. Working distance decreases as the magnification and numerical aperture both increases.
decreases
decreases
Formula for working out height of a tree is (distance from eye to base of tree/distance from eye to base of stick) x length of stick = tree height.(distance from eye to base of tree/distance from eye to base of stick) x length of stick = tree height is the formula for working out height of a tree.
One Fourth as muchNote:When you talk about gravitational forces, the "distance" you're working withis the distance between the object and the center of the Earth. That's about4,000 miles more than its altitude above the surface.
As speed=Distance/time, distance would be, distance = Speed x time or, s = vt where s is distance, v is speed or change in velocity and t is time
The gravitational force IS the centripetal force in this case.
Do the following factors increase or decrease as one moves to higher magnifications with the microscope? Resolution, working distance, amount of light needed, and depth of field
Higher magnification decreases working distance. Magnification and WD have inverse relation. One goes up the othe goes down. For example a 40X finite conjugate objective lens has WD of only 0.5mm while a 10X has WD of 6.30mm.
The formula is:Perimeter = (distance all the way around the figure).Exactly how you implement the formula depends onthe shape of the figure you're working with.