A simple physical approach to understand the Taylor series
[Maths
Physics
Intro
]
Do you know that the displacement formula with acceleration in one dimension which you had learned in Physics class actually reveals the existence of Taylor series implicitly?
I still remember the first time that I meet the concept of Taylor series was in one AP calculus textbook. It’s kind of a pity that the AP calculus textbook I was reading at that time didn’t give any further explanation about why and how this formula came up, etc. So I just questioned myself about its formation and finally I did figured it out at that time by using the knowledge I’ve learned in Physics. I guess you may wonder why wouldn’t I just search on the Internet and see the proof of Taylor series, in fact, I did do that, but didn’t work for me at that point, since I lack too much Maths knowledge to understand that proof. Therefore I found a new way to help myself understand the Taylor series at that time.
Firstly, let us derive the displacement formula with acceleration in one dimension:
Similarly, we can use the same deriving method of:
To get:
Then we substitute $v_t$ into $x_t$ , we would have:
Note that since $a_t$ is a constant (In fact, this is related to the Principle of least action in Physics: We assume that the accleration of any system must be a constant, in other words: $\dfrac{\mathrm{d}^3 (x)}{(\mathrm{d} t)^3} = 0$ ), therefore we could get our displacement formula with acceleration:
But the problem is: What if $a_t$ is not a constant anymore (And that situations do happen a lot in real life), for example, have you heard about presence of jerk ( $j_t =\dfrac{\mathrm{d} a}{\mathrm{d} t}$ ) before?
Then we need to deal with the equation $(1)$ again, through using the same deriving method stated above, we could get:
Next we substitute $a_t$ into $x_t$ , we can have:
And using some derivatives form to substitute in that equation:
Now I believe that you could clearly see the presence of the Taylor series in this equation right?
Therefore if we keep iterating using the same method and let $x_{t}=f(t)$ , we would be able to get the real Taylor series formula:
This also indicate us the essence of Taylor series: Knowing all of its $n$th ($n$ is natural numbers) derivatives value at one point is equivalent to Knowing the primitive formula of a function.