Explain about the derivation of equations of motion.
Answers
Answer:
derivation of first equation is v=u+at
Explanation:
then a=v-u/t
calculus derivations
Calculus is an advanced math topic, but it makes deriving two of the three equations of motion much simpler. By definition, acceleration is the first derivative of velocity with respect to time. Take the operation in that definition and reverse it. Instead of differentiating velocity to find acceleration, integrate acceleration to find velocity. This gives us the velocity-time equation. If we assume acceleration is constant, we get the so-called first equation of motion [1].
a =
dv
dt
dv = a dt
v
⌠
⌡ dv
v0 =
t
⌠
⌡ a dt
0
v − v0 = at
v = v0 + at [1]
Again by definition, velocity is the first derivative of position with respect to time. Reverse this operation. Instead of differentiating position to find velocity, integrate velocity to find position. This gives us the position-time equation for constant acceleration, also known as the second equation of motion [2].
v =
ds
dt
ds = v dt
ds = (v0 + at) dt
s
⌠
⌡ ds
s0 =
t
⌠
⌡ (v0 + at) dt
0
s − s0 = v0t + ½at2
s = s0 + v0t + ½at2 [2]
Unlike the first and second equations of motion, there is no obvious way to derive the third equation of motion (the one that relates velocity to position) using calculus. We can't just reverse engineer it from a definition. We need to play a rather sophisticated trick.
The first equation of motion relates velocity to time. We essentially derived it from this derivative…
dv = a
dt
The second equation of motion relates position to time. It came from this derivative…
ds = v
dt
The third equation of motion relates velocity to position. By logical extension, it should come from a derivative that looks like this…
dv = ?
ds
But what does this equal? Well nothing by definition, but like all quantities it does equal itself. It also equals itself multiplied by 1. We'll use a special version of 1 (
dt
dt
) and a special version of algebra (algebra with infinitesimals). Look what happens when we do this. We get one derivative equal to acceleration (
dv
dt
) and another derivative equal to the inverse of velocity (
dt
ds
).
dv = dv 1
ds ds
dv = dv dt
ds ds dt
dv = dv dt
ds dt ds
dv = a 1
ds v
Next step, separation of variables. Get things that are similar together and integrate them. Here's what we get when acceleration is constant…
dv
ds =
a 1
v
v dv = a ds
v
⌠
⌡ v dv
v0 =
s
⌠
⌡ a ds
s0
½(v2 − v02) = a(s − s0)
v2 = v02 + 2a(s − s0) [3]