Now that I look at this a little closer, I think the 50.43 is too short of a distance. If I'm capable of traveling at 2.05m/s after the first second, and then I'm capable of traveling at 4.1m/s by the second second and so on, I should be able to add each of those up and by second 12 I should have traveled at least 116 meters.
I'm beginning to think this over too much. Is there a better way to solve this? Am I getting into levels of math that are much higher than what I'm in, or will I eventually see this in algebra?
\(\displaystyle Let\ distance\ traveled\ during\ period = d.\)
\(\displaystyle Let\ time\ that\ period\ lasts = t.\)
\(\displaystyle Let\ average\ velocity\ during\ period = v = \dfrac{d}{t}.\) This is all straightforward. You with me to here?
If something is accelerating (or decelerating) during a period, the velocity is changing during the period. So the average velocity is just that, an average of different velocities. Still clear?
We are not going to consider the complicated case where acceleration is changing during the period. That takes calculus. We shall assume that acceleration is constant and positive.
We are also going to keep things simple by assuming that the velocity at the start of the period is zero.
\(\displaystyle Let\ the\ final\ velocity\ at\ the\ end\ of\ the\ period = f > 0.\)
The technical definition of acceleration is the change in velocity during the period divided by the time of the period.
The change in velocity is f - 0 = f. The time of the period = t. So
\(\displaystyle Let\ acceleration = a = \dfrac{f}{t}.\) How you holding up? That also means \(\displaystyle f = at.\)
Obviously f will be larger than v, because v is an average for the period and f is the highest velocity achieved. Still with me?
In fact, \(\displaystyle v = \dfrac{f + 0}{2} \implies f = 2v = 2 * \dfrac{d}{t} = \dfrac{2d}{t} \implies a = \dfrac{f}{t} = f * \dfrac{1}{t} = \dfrac{2d}{t} * \dfrac{1}{t} = \dfrac{2d}{t^2}.\)
Now do you see where the square comes from. We divided by t once to get velocity. We divided by t a second time to get acceleration.
The formula for distance given constant acceleration from an initial velocity of 0 is \(\displaystyle d = \dfrac{1}{2} * at^2.\)
Where in the world did that crazy looking formula come from?
\(\displaystyle d = vt.\)
\(\displaystyle But\ f = 2v \implies d = vt = \dfrac{1}{2} * ft = \dfrac{1}{2} * at * t = \dfrac{1}{2} at^2.\)
So let's look at your example.
\(\displaystyle f = \dfrac{24.6\ m}{sec}.\)
\(\displaystyle So\ f = 2v \implies v = \dfrac{12.3\ m}{sec.}\)
\(\displaystyle And\ a = \dfrac{f}{t} = \dfrac{24.6\ m\ per\ sec}{12\ sec}= \dfrac{24.6\ m}{sec} * \dfrac{1}{12\ sec} = \dfrac{2.05\ m}{sec^2}.\)
\(\displaystyle d = \dfrac{1}{2} * at^2 = \dfrac{1}{2} * \dfrac{2.05\ m}{sec^2} * (12\ sec)^2 = 1.025 * 144\ m = 147.6\ m.\)
We get the same answer by looking at \(\displaystyle d = vt = \dfrac{12.3\ m}{sec} * 12\ sec = 147.6\ m.\)
