Wiki User
∙ 15y agoIf you are looking to get an object up the highest, shoot it straight up. If you want to go for a specific horizontal displacement, use the range equation. R = v2sin(twice the launch angle)/ g. g is the gravitaional constant, 9.8 meters per second. Use degrees for the angle. v is the launch velocity. R is the horizontal displacement. This formula only works if your start altitude and end altitude are the same, i.e. you must shoot over a level field.
Wiki User
∙ 15y agoThe formula for resultant displacement can be calculated using the Pythagorean theorem. It is given by: Resultant displacement = √(horizontal displacement^2 + vertical displacement^2)
A comprehensive and detailed examination beyond the scope of a real estate home inspection might be considered
It is a simple 'difference' formula. Altitude at 'a' altitude at 'b' Take 'a' from 'b' = displacement.
To convert a Fischer projection into a wedge and dash formula, you rotate the molecule to position the horizontal groups as wedges (pointing towards you) and the vertical groups as dashes (pointing away from you). The orientation of the groups in Fischer projections (up or down) dictates their placement as wedges or dashes. Remember, dashes represent bonds going away from you, while wedges represent bonds coming towards you.
dy= (v1sinO)2/2gdx= (Vx)(t)
A vertical line HAS NO slope! The slope is undefined in this case.
To calculate the vertical force acting on an external brake shoe, you can use the formula F = W * sin(θ), where F is the vertical force, W is the weight acting on the brake shoe, and θ is the angle of the shoe with the horizontal. To calculate the horizontal force, you can use the formula F = W * cos(θ), where F is the horizontal force, W is the weight acting on the brake shoe, and θ is the angle of the shoe with the horizontal.
the formula for slope is y=mx+b, a horizontal line has the slope of zero and the slope of a vertical line can be answered as undefined
The formula for the time period of the projection of a particle is T = 2 * (Vertical component of initial velocity) / g, where T is the time period, g is the acceleration due to gravity, and the vertical component of the initial velocity is the initial velocity multiplied by the sine of the launch angle.
Displacement is the shortest distance travelled . formula of Displacement= speed * time in meters
It is: (y1-y2)/(x1-x2) whereas x is the horizontal axis and y is the vertical axis on the Cartesian plane
To determine the gradient of a ramp, you can use the formula: Gradient = vertical rise / horizontal run. Measure the height of the ramp (vertical rise) and the distance along the slope (horizontal run), then calculate the gradient by dividing the height by the distance. The gradient represents the steepness of the ramp.