Formula | Definition and explanations |
\(
s_{av} = \dfrac{d}{\Delta t}
\)
| sav is the average speed (scalar) d is the distance Δ t is the time elapsed
|
\(
v_{av} = \dfrac{x_f - x_i}{t_f - t_i} =\dfrac{\Delta x}{\Delta t}
\)
| vav is the average velocity (vector) Δ x is the displacement(vector) Δ t is the time elapsed
|
\(
a_{av} = \dfrac{v_f - v_i}{t_f - t_i} =\dfrac{\Delta v}{\Delta t}
\)
| aav is the average acceleartion (vector) Δ v is the change in velocity (vector) Δ t is the time elapsed
|
\(
v_{av} = \dfrac{v_i + v_f}{2}
\)
| vav is the average velocity (vector) vi is the initial velocity (vector) vf is the final velocity (vector)
|
\(
v_{f} = v_{i} + a \Delta t
\)
| vf is the final velocity (vector) vi is the initial velocity (vector) a is the acceleration (vector)
|
\(
\Delta x = v_i \Delta t + \dfrac{1}{2} a (\Delta t)^2
\)
| Δ x is the displacement (vector) vi is the initial velocity (vector) a is the acceleration (vector)
|
\(
\Delta x = v_f \Delta t - \dfrac{1}{2} a (\Delta t)^2
\)
| Δ x is the displacement (vector) vf is the final velocity (vector) a is the acceleration (vector)
|
\(
\Delta x = \dfrac{v_f+v_i}{2} \Delta t
\)
| Δ x is the displacement (vector) vf is the final velocity (vector) vi is the initial velocity (vector)
|
\(
v^2_f = v^2_i + 2 a \cdot \Delta x
\)
| vf is the final velocity (vector) vi is the initial velocity (vector) Δ x is the displacement (vector) a is the acceleration (vector)
|