ATAR Notes: Forum

HSC Stuff => HSC Maths Stuff => HSC Subjects + Help => HSC Mathematics Extension 1 => Topic started by: Jefferson on April 28, 2019, 10:22:13 pm

Title: Simple Harmonic Motion shifted equilibrium position.
Post by: Jefferson on April 28, 2019, 10:22:13 pm

In BOSTES 2015 Q13 (c) (not actually asking about the question itself)

They introduced the equation

v² = n² ( a² - (x - c)² )

Where 'a' is said to be the amplitude.



When I tried proving this result from
d/dx (v²/2) = - n² ( x - c ), I am instead getting

v²  = n² ( ( a + c )² - x² )


Could you please show me the formal proof to get to the equation
v² = n² ( a² - ( x - c )² ), where a is the amplitude.

Thank you!

Title: Re: Simple Harmonic Motion shifted equilibrium position.
Post by: RuiAce on April 28, 2019, 10:35:15 pm

\[ \text{One way to buzzkill this proof is to actually recall that}\\ \boxed{\int (ax+b)^n\,dx = \frac{(ax+b)^{n+1}}{a(n+1)}+C}. \]
\begin{align*} \frac{d}{dx} \left( \frac{v^2}{2}\right) &= -n^2 (x-c)\\ \frac{v^2}{2} &= \frac{-n^2(x-c)^2}{2} + \frac{C}{2}\\ v^2 &= -n^2(x-c)^2+C \end{align*}
\[ \text{Recall that in SHM, }v=0\text{ when the particle is at its endpoints.}\\ \text{For a particle with centre of motion }c\text{ and amplitude }a,\\ \text{the endpoints of motion will be }x=c-a\text{ and }x=c+a.\]
\[ \text{Using either of these will then give}\\ 0 = -n^2a^2+C \implies \boxed{C=n^2a^2}. \]
\[ \text{Hence }v^2= -n^2(x-c)^2 + n^2a^2 = -n^2\left(a^2-(x-c)^2 \right)\]
Note that the proof should still work if we ordinarily integrate and get \( \frac{v^2}{2} = -n^2 \left( \frac{x^2}{2} - cx \right) \). My hunch, however, is that some completing the square would be needed later if we go down this route.

Title: Re: Simple Harmonic Motion shifted equilibrium position.
Post by: Jefferson on April 28, 2019, 10:52:30 pm

Quote from: RuiAce on April 28, 2019, 10:35:15 pm

\[ \text{One way to buzzkill this proof is to actually recall that}\\ \boxed{\int (ax+b)^n\,dx = \frac{(ax+b)^{n+1}}{a(n+1)}+C}. \]
\begin{align*} \frac{d}{dx} \left( \frac{v^2}{2}\right) &= -n^2 (x-c)\\ \frac{v^2}{2} &= \frac{-n^2(x-c)^2}{2} + \frac{C}{2}\\ v^2 &= -n^2(x-c)^2+C \end{align*}
\[ \text{Recall that in SHM, }v=0\text{ when the particle is at its endpoints.}\\ \text{For a particle with centre of motion }c\text{ and amplitude }a,\\ \text{the endpoints of motion will be }x=c-a\text{ and }x=c+a.\]
\[ \text{Using either of these will then give}\\ 0 = -n^2a^2+C \implies \boxed{C=n^2a^2}. \]
\[ \text{Hence }v^2= -n^2(x-c)^2 + n^2a^2 = -n^2\left(a^2-(x-c)^2 \right)\]
Note that the proof should still work if we ordinarily integrate and get \( \frac{v^2}{2} = -n^2 \left( \frac{x^2}{2} - cx \right) \). My hunch, however, is that some completing the square would be needed later if we go down this route.

Thank you so much! It seems I've made a huge blunder.
That makes a lot of sense!