$\sum_{i=0}^n i^2 = \frac{(n^2+n)(2n+1)}{6}$
$RC \gt\gt \frac{T_0}{2}$
$RC \lt\lt \frac{T_0}{2}$
$0 \lt t \lt \frac{T_0}{2}$
$\Large V_C=V_m(1-e^\frac{-t}{RC})$
$V_i = V_C + V_R$
$\Large V_R=V_m\,e^\frac{-t}{RC})$
read more$\sum_{i=0}^n i^2 = \frac{(n^2+n)(2n+1)}{6}$
$RC \gt\gt \frac{T_0}{2}$
$RC \lt\lt \frac{T_0}{2}$
$0 \lt t \lt \frac{T_0}{2}$
$\Large V_C=V_m(1-e^\frac{-t}{RC})$
$V_i = V_C + V_R$
$\Large V_R=V_m\,e^\frac{-t}{RC})$
read more$\sum_{i=0}^n i^2 = \frac{(n^2+n)(2n+1)}{6}$
$RC \gt\gt \frac{T_0}{2}$
$RC \lt\lt \frac{T_0}{2}$
$0 \lt t \lt \frac{T_0}{2}$
$\Large V_C=V_m(1-e^\frac{-t}{RC})$
$V_i = V_C + V_R$
$\Large V_R=V_m\,e^\frac{-t}{RC})$
read more$\sum_{i=0}^n i^2 = \frac{(n^2+n)(2n+1)}{6}$
$RC \gt\gt \frac{T_0}{2}$
$RC \lt\lt \frac{T_0}{2}$
$0 \lt t \lt \frac{T_0}{2}$
$\Large V_C=V_m(1-e^\frac{-t}{RC})$
$V_i = V_C + V_R$
$\Large V_R=V_m\,e^\frac{-t}{RC})$
read more$\sum_{i=0}^n i^2 = \frac{(n^2+n)(2n+1)}{6}$
$RC \gt\gt \frac{T_0}{2}$
$RC \lt\lt \frac{T_0}{2}$
$0 \lt t \lt \frac{T_0}{2}$
$\Large V_C=V_m(1-e^\frac{-t}{RC})$
$V_i = V_C + V_R$
$\Large V_R=V_m\,e^\frac{-t}{RC})$
read more$\sum_{i=0}^n i^2 = \frac{(n^2+n)(2n+1)}{6}$
$RC \gt\gt \frac{T_0}{2}$
$RC \lt\lt \frac{T_0}{2}$
$0 \lt t \lt \frac{T_0}{2}$
$\Large V_C=V_m(1-e^\frac{-t}{RC})$
$V_i = V_C + V_R$
$\Large V_R=V_m\,e^\frac{-t}{RC})$
read more$\sum_{i=0}^n i^2 = \frac{(n^2+n)(2n+1)}{6}$
$RC \gt\gt \frac{T_0}{2}$
$RC \lt\lt \frac{T_0}{2}$
$0 \lt t \lt \frac{T_0}{2}$
$\Large V_C=V_m(1-e^\frac{-t}{RC})$
$V_i = V_C + V_R$
$\Large V_R=V_m\,e^\frac{-t}{RC})$
read more$\sum_{i=0}^n i^2 = \frac{(n^2+n)(2n+1)}{6}$
$RC \gt\gt \frac{T_0}{2}$
$RC \lt\lt \frac{T_0}{2}$
$0 \lt t \lt \frac{T_0}{2}$
$\Large V_C=V_m(1-e^\frac{-t}{RC})$
$V_i = V_C + V_R$
$\Large V_R=V_m\,e^\frac{-t}{RC})$
read more$\sum_{i=0}^n i^2 = \frac{(n^2+n)(2n+1)}{6}$
$RC \gt\gt \frac{T_0}{2}$
$RC \lt\lt \frac{T_0}{2}$
$0 \lt t \lt \frac{T_0}{2}$
$\Large V_C=V_m(1-e^\frac{-t}{RC})$
$V_i = V_C + V_R$
$\Large V_R=V_m\,e^\frac{-t}{RC})$
read more