Circuit Theory/Phasors/proof8


 * $$g(t)=G_m sin(\omega t - \phi)$$
 * $$g(t)=G_m cos(\omega t - \phi - \frac{\pi}{2})$$
 * $$g(t)=G_m \operatorname{Re}(e^{j(\omega t - \phi - \frac{\pi}{2})})$$
 * $$g(t)=G_m \operatorname{Re}(e^{j*(-\phi - \frac{\pi}{2})}e^{j\omega t})$$
 * $$g(t)=\operatorname{Re}(G_m e^{j*(-\phi - \frac{\pi}{2})}e^{j\omega t})$$
 * $$g(t)=\operatorname{Re}(\mathbb{G} e^{j\omega t})$$
 * $$\mathbb{G} = G_m e^{j*(-\phi - \frac{\pi}{2})} = G_m(cos(-\phi - \frac{\pi}{2}) + j*sin(-\phi - \frac{\pi}{2}))$$
 * $$ = G_m cos(-\phi - \frac{\pi}{2}) + j G_m sin(-\phi - \frac{\pi}{2})$$
 * $$ = G_m (cos(-\phi) cos(\frac{\pi}{2}) + sin(-\phi) sin(\frac{\pi}{2})) + j G_m (sin(-\phi)cos(\frac{\pi}{2})- cos(-\phi)sin(\frac{\pi}{2}))$$
 * $$ = G_m sin(-\phi) - j G_m cos(-\phi)$$
 * $$ = -G_m sin(\phi) - j G_m cos(\phi)$$