How were amplitudes of the $\cos$ and $\sin$ chosen?

Let’s concentrate on the important part, which is of the form $$ f(x)=a\cos x+b\sin x $$ which we want to express as $$ f(x)=A(\cos\varphi\cos x+\sin\varphi\sin x) $$ A necessary (and sufficient) condition is that $$ A\cos\varphi=a,\qquad A\sin\varphi=b $$ and therefore $a^2=A^2\cos^2\varphi$, $b^2=A^2\sin^2\varphi$. Hence $$ A^2=a^2+b^2 $$ We want $A>0$ (not necessary, but convenient), so we get $$ A=\sqrt{a^2+b^2},\quad \cos\varphi=\frac{a}{A},\quad \sin\varphi=\frac{b}{A} $$ The last two requirements can be fulfilled, because $(a/A,b/A)$ is a point on the unit circle.

Tags:

Trigonometry

Related

How to proof uniqueness with the usage of function and proving an inequality Can composition of integer polynomial and rational polynomial with a non-integer coefficient result in integer polynomial? Inequality for function of $\arctan(x)$ Let $b_{n}$ denote the number of compositions of $n$ into $k$ parts, where each part is one or two. Find the generating series for $b_{n}$ How can you approach $\int_0^{\pi/2} x\frac{\ln(\cos x)}{\sin x}dx$ Numbers from $1,\frac12,\frac13,...........\frac{1}{2010}$ are written and any two $x,y$ are taken and we replace $x,y$ by just $x+y+xy$ How to convince myself (imagine) that $\Bbb S^1$-action on $\Bbb S^3$ fixes a circle of sphere? Extraneous solution from substituting in equations Calculate the limit $\lim _{n \rightarrow \infty} \frac{[\ln (n)]^{2}}{n^{\frac{1}{\ln (\ln (n))}}}$. Idea behind "reparameterization hiding a corner" in single variable calculus Is there a closed form for $\sum_{n=1}^\infty\frac{2^{2n}H_n}{n^3{2n\choose n}}?$ A different approach to a common question

Recent Posts