Besar kuat medan magnet

\(\bbox[10px, border: 2px solid red]{B = \dfrac {\mu_o \:.\: i}{2 \pi \:.\: a}}\)

\(\mu_o = 4\pi \times 10^{-7}\)

i = besar kuat arus

a = jarak ke kawat

\(\bbox[10px, border: 2px solid red]{B = \dfrac {\mu_o \:.\: i}{2 \:.\: a}}\)

\(\mu_o = 4\pi \times 10^{-7}\)

i = besar kuat arus

a = jarak ke kawat

\(\bbox[10px, border: 2px solid red]{B = \dfrac {\mu_o \:.\: i \:.\: a}{2 \:.\: b^2} \:.\: \sin \theta}\)

\(\mu_o = 4\pi \times 10^{-7}\)

i = besar kuat arus

a = jarak ke kawat

Besar kuat medan magnet pada pusat solenoida

\(\bbox[10px, border: 2px solid red]{B = N \:.\: \dfrac {\mu_o \:.\: i}{l}}\)

Besar kuat medan magnet pada ujung solenioda

\(\bbox[10px, border: 2px solid red]{B = N \:.\: \dfrac {\mu_o \:.\: i}{2l}}\)

\(\mu_o = 4\pi \times 10^{-7}\)

N = banyaknya lilitan

i = besar kuat arus

l = panjang solenoida

\(\bbox[10px, border: 2px solid red]{B = N \:.\: \dfrac {\mu_o \:.\: i}{2 \pi \:.\: a}}\)

\(\bbox[10px, border: 2px solid red]{B = N \:.\: \dfrac {\mu_o \:.\: i}{\pi \:.\: (R_1 + R_2)}}\)

\(\mu_o = 4\pi \times 10^{-7}\)

N = banyaknya lilitan

i = besar kuat arus

a = radius toroida

R₁ = radius dalam toroida

R₂ = radius luar toroida

Besar gaya Lorentz

\(\bbox[10px, border: 2px solid red]{F = B \:.\: i \:.\: l \:.\: \sin \alpha}\)