The basic definition of speed is: speed = distance / time Solve this equation for distance, or solve it for time, to get two additional versions of the equation.
Speed = (Distance)/(Time to cover the distance)
i dont know that's why I'm asking
Distance = (speed) multiplied by (time)
Speed = Distance / Time
There is no such equation, what do you mean by "water from a distance".
Distance is a scalar quantity, as it has only magnitude and no direction. An example equation for distance is d = rt, where d is distance, r is rate, and t is time. This equation is used to calculate distance traveled when speed and time are known.
The basic definition of speed is: speed = distance / time Solve this equation for distance, or solve it for time, to get two additional versions of the equation.
To obtain this type of numerical information, it is necessary to use the Mirror Equation . The mirror equation expresses the quantitative relationship between the object distance (do), the image distance (di), and the focal length (f). The equation is stated as follows:1/f =1/d0 + 1/d1.
The equation for ideal mechanical advantage is: Output force/input force, Or input distance/ output distance.
Speed = (Distance)/(Time to cover the distance)
The equation for speed is derived from the formula: speed = distance / time. This equation is based on the definition of speed as the distance traveled divided by the time taken to cover that distance, providing a quantitative measure of how fast an object is moving.
speed = distance/time
speed
The equation to calculate the speed of an object is speed = distance / time. This equation gives the rate at which an object is moving over a given distance in a specific amount of time.
No, the equation showing distance varying inversely with time is not true. In reality, distance is directly proportional to time when an object is moving at a constant speed. This relationship is described by the equation distance = speed x time.
The equation relating acceleration, distance traveled, and time of fall is given by: distance = (1/2) * acceleration * time^2. This equation is derived from the kinematic equation for motion under constant acceleration.