Search results
5 dni temu · Calculation Formula. The distance traveled by an object under constant acceleration is calculated using the formula: \[ \text{Distance} = \text{Initial Velocity} \times \text{Time} + \frac{1}{2} \times \text{Acceleration} \times \text{Time}^2 \] Where: Initial Velocity is the speed at which the object starts (meters per second, m/s).
3 dni temu · The formula for calculating the diagonal distance (DD) is: \[ DD = \sqrt{V^2 + H^2} \] where: \(DD\) is the Diagonal Distance, \(V\) is the vertical distance, \(H\) is the horizontal distance. Example Calculation. Suppose you have a vertical distance of 3 meters and a horizontal distance of 4 meters. The diagonal distance can be calculated as ...
3 dni temu · Use the magnification of a mirror formula to obtain the size of the object. Accordingly depict its nature using the sign of the image height. Formula Used: The mirror equation $\dfrac{1}{v} + \dfrac{1}{u} = \dfrac{1}{f}$ Where $v$ is the image distance,$u$ is the object distance and $f$ is the focal length.
23 godz. temu · class X Solved question of coordinate geometry from RD Sharma
4 dni temu · The fourth step is to compute the heliocentric distance r from the true anomaly θ by Kepler's first law: (+ ) = Using the relation above between θ and E the final equation for the distance r is: = ().
4 dni temu · I have a solution where i am looping over every point of a map, and every object, calculating the distance to all of them, and then leaving only minimum distance. The problem here is that if I am woking with real data, the map can easily contain 10s of millions of points, and there can be more than 100 objects.
