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History

The use of duality in circuit theory is due to Alexander Russell who published his ideas in 1904.¹²

Examples

Constitutive relations

• Resistor and conductor (Ohm's law) v = i R ⟺ i = v G {\displaystyle v=iR\iff i=vG\,}
• Capacitor and inductor – differential form i C = C d d t v C ⟺ v L = L d d t i L {\displaystyle i_{C}=C{\frac {d}{dt}}v_{C}\iff v_{L}=L{\frac {d}{dt}}i_{L}}
• Capacitor and inductor – integral form v C ( t ) = V 0 + 1 C ∫ 0 t i C ( τ ) d τ ⟺ i L ( t ) = I 0 + 1 L ∫ 0 t v L ( τ ) d τ {\displaystyle v_{C}(t)=V_{0}+{1 \over C}\int _{0}^{t}i_{C}(\tau )\,d\tau \iff i_{L}(t)=I_{0}+{1 \over L}\int _{0}^{t}v_{L}(\tau )\,d\tau }

Voltage division — current division

v R 1 = v R 1 R 1 + R 2 ⟺ i G 1 = i G 1 G 1 + G 2 {\displaystyle v_{R_{1}}=v{\frac {R_{1}}{R_{1}+R_{2}}}\iff i_{G_{1}}=i{\frac {G_{1}}{G_{1}+G_{2}}}}

Impedance and admittance

• Resistor and conductor Z R = R ⟺ Y G = G {\displaystyle Z_{R}=R\iff Y_{G}=G} Z G = 1 G ⟺ Y R = 1 R {\displaystyle Z_{G}={1 \over G}\iff Y_{R}={1 \over R}}
• Capacitor and inductor Z C = 1 C s ⟺ Y L = 1 L s {\displaystyle Z_{C}={1 \over Cs}\iff Y_{L}={1 \over Ls}} Z L = L s ⟺ Y c = C s {\displaystyle Z_{L}=Ls\iff Y_{c}=Cs}

See also

• Duality (electricity and magnetism)
• Duality (mechanical engineering)
• Dual impedance
• Dual graph
• Mechanical–electrical analogies
• List of dualities

• Turner, Rufus P, Transistors Theory and Practice, Gernsback Library, Inc, New York, 1954, Chapter 6.

References

1. Belevitch, V, "Summary of the history of circuit theory", Proceedings of the IRE, vol 50, Iss 5, pp. 848–855, May 1962 doi:10.1109/JRPROC.1962.288301. /wiki/Doi_(identifier) ↩

2. Alexander Russell, A Treatise on the Theory of Alternating Currents, volume 1, chapter XVII, Cambridge: University Press 1904 OCLC 264936988. /wiki/OCLC_(identifier) ↩