Solve for A (complex solution)
\left\{\begin{matrix}A=\frac{Ql}{K\Delta \theta }\text{, }&\theta \neq 0\text{ and }\Delta \neq 0\text{ and }K\neq 0\text{ and }l\neq 0\\A\in \mathrm{C}\text{, }&\left(\theta =0\text{ or }\Delta =0\text{ or }K=0\right)\text{ and }Q=0\text{ and }l\neq 0\end{matrix}\right.
Solve for K (complex solution)
\left\{\begin{matrix}K=\frac{Ql}{A\Delta \theta }\text{, }&\theta \neq 0\text{ and }\Delta \neq 0\text{ and }A\neq 0\text{ and }l\neq 0\\K\in \mathrm{C}\text{, }&\left(\theta =0\text{ or }\Delta =0\text{ or }A=0\right)\text{ and }Q=0\text{ and }l\neq 0\end{matrix}\right.
Solve for A
\left\{\begin{matrix}A=\frac{Ql}{K\Delta \theta }\text{, }&\theta \neq 0\text{ and }\Delta \neq 0\text{ and }K\neq 0\text{ and }l\neq 0\\A\in \mathrm{R}\text{, }&\left(\theta =0\text{ or }\Delta =0\text{ or }K=0\right)\text{ and }Q=0\text{ and }l\neq 0\end{matrix}\right.
Solve for K
\left\{\begin{matrix}K=\frac{Ql}{A\Delta \theta }\text{, }&\theta \neq 0\text{ and }\Delta \neq 0\text{ and }A\neq 0\text{ and }l\neq 0\\K\in \mathrm{R}\text{, }&\left(\theta =0\text{ or }\Delta =0\text{ or }A=0\right)\text{ and }Q=0\text{ and }l\neq 0\end{matrix}\right.
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Ql=KA\Delta \theta
Multiply both sides of the equation by l.
KA\Delta \theta =Ql
Swap sides so that all variable terms are on the left hand side.
K\Delta \theta A=Ql
The equation is in standard form.
\frac{K\Delta \theta A}{K\Delta \theta }=\frac{Ql}{K\Delta \theta }
Divide both sides by K\Delta \theta .
A=\frac{Ql}{K\Delta \theta }
Dividing by K\Delta \theta undoes the multiplication by K\Delta \theta .
Ql=KA\Delta \theta
Multiply both sides of the equation by l.
KA\Delta \theta =Ql
Swap sides so that all variable terms are on the left hand side.
A\Delta \theta K=Ql
The equation is in standard form.
\frac{A\Delta \theta K}{A\Delta \theta }=\frac{Ql}{A\Delta \theta }
Divide both sides by A\Delta \theta .
K=\frac{Ql}{A\Delta \theta }
Dividing by A\Delta \theta undoes the multiplication by A\Delta \theta .
Ql=KA\Delta \theta
Multiply both sides of the equation by l.
KA\Delta \theta =Ql
Swap sides so that all variable terms are on the left hand side.
K\Delta \theta A=Ql
The equation is in standard form.
\frac{K\Delta \theta A}{K\Delta \theta }=\frac{Ql}{K\Delta \theta }
Divide both sides by K\Delta \theta .
A=\frac{Ql}{K\Delta \theta }
Dividing by K\Delta \theta undoes the multiplication by K\Delta \theta .
Ql=KA\Delta \theta
Multiply both sides of the equation by l.
KA\Delta \theta =Ql
Swap sides so that all variable terms are on the left hand side.
A\Delta \theta K=Ql
The equation is in standard form.
\frac{A\Delta \theta K}{A\Delta \theta }=\frac{Ql}{A\Delta \theta }
Divide both sides by A\Delta \theta .
K=\frac{Ql}{A\Delta \theta }
Dividing by A\Delta \theta undoes the multiplication by A\Delta \theta .
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