<Dl> <Dd> A φ = μ 0 I 4 π 1 L a ρ (ζ k (k 2 + h 2 − h 2 k 2 h 2 k 2 K (k 2) − 1 k 2 E (k 2) + h 2 − 1 h 2 Π (h 2, k 2))) ζ − ζ +, (\ displaystyle A_ (\ phi) = (\ frac (\ mu _ (0) I) (4 \ pi)) (\ frac (1) (L)) (\ sqrt (\ frac (a) (\ rho))) \ left (\ zeta k \ left ((\ frac (k ^ (2) + h ^ (2) - h ^ (2) k ^ (2)) (h ^ (2) k ^ (2))) K (k ^ (2)) - (\ frac (1) (k ^ (2))) E (k ^ (2)) + (\ frac (h ^ (2) - 1) (h ^ (2))) \ Pi (h ^ (2), k ^ (2)) \ right) \ right) _ (\ zeta _ (-)) ^ (\ zeta _ (+)),) </Dd> </Dl> <Dd> A φ = μ 0 I 4 π 1 L a ρ (ζ k (k 2 + h 2 − h 2 k 2 h 2 k 2 K (k 2) − 1 k 2 E (k 2) + h 2 − 1 h 2 Π (h 2, k 2))) ζ − ζ +, (\ displaystyle A_ (\ phi) = (\ frac (\ mu _ (0) I) (4 \ pi)) (\ frac (1) (L)) (\ sqrt (\ frac (a) (\ rho))) \ left (\ zeta k \ left ((\ frac (k ^ (2) + h ^ (2) - h ^ (2) k ^ (2)) (h ^ (2) k ^ (2))) K (k ^ (2)) - (\ frac (1) (k ^ (2))) E (k ^ (2)) + (\ frac (h ^ (2) - 1) (h ^ (2))) \ Pi (h ^ (2), k ^ (2)) \ right) \ right) _ (\ zeta _ (-)) ^ (\ zeta _ (+)),) </Dd> <Dl> <Dd> ζ ± = z ± L 2, (\ displaystyle \ zeta _ (\ pm) = z \ pm (\ frac (L) (2)),) </Dd> <Dd> h 2 = 4 a ρ (a + ρ) 2, (\ displaystyle h ^ (2) = (\ frac (4a \ rho) ((a+ \ rho) ^ (2))),) </Dd> <Dd> k 2 = 4 a ρ (a + ρ) 2 + ζ 2, (\ displaystyle k ^ (2) = (\ frac (4a \ rho) ((a+ \ rho) ^ (2) + \ zeta ^ (2))),) </Dd> <Dd> K (m) = ∫ 0 π / 2 1 1 − m sin 2 ⁡ θ d θ, (\ displaystyle K (m) = \ int _ (0) ^ (\ pi / 2) (\ frac (1) (\ sqrt (1 - m \ sin ^ (2) \ theta))) d \ theta,) </Dd> <Dd> E (m) = ∫ 0 π / 2 1 − m sin 2 ⁡ θ d θ, (\ displaystyle E (m) = \ int _ (0) ^ (\ pi / 2) (\ sqrt (1 - m \ sin ^ (2) \ theta)) d \ theta,) </Dd> <Dd> Π (n, m) = ∫ 0 π / 2 1 (1 − n sin 2 ⁡ θ) 1 − m sin 2 ⁡ θ d θ . (\ displaystyle \ Pi (n, m) = \ int _ (0) ^ (\ pi / 2) (\ frac (1) ((1 - n \ sin ^ (2) \ theta) (\ sqrt (1 - m \ sin ^ (2) \ theta)))) d \ theta .) </Dd> </Dl> <Dd> ζ ± = z ± L 2, (\ displaystyle \ zeta _ (\ pm) = z \ pm (\ frac (L) (2)),) </Dd>

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