Classical electric circuit theory represents voltages, currents, and impedances using complex numbers, a convention adopted historically for algebraic convenience rather than physical necessity. Here we develop a complete real-tensor formulation of circuit theory in which voltages and currents are genuine vectors in a two-dimensional real space, while impedances are second-order tensors composed of an isotropic scaling operator and the antisymmetric generator of the rotation group SO (2). The traditional complex impedance π = π + ππ is replaced by the tensor π = π π + ππ, πππ = π πΏππ + ππ½ππ, (πΌ, π½ = 1, 2) where π is the identity and π is the canonical 90Β° rotation tensor. We define a mapping Ξ¦: β β β^2Γ2, Ξ¦ (π₯ + ππ¦) = π₯π + π¦π that establishes an algebra isomorphism between complex numbers and the two-dimensional real subalgebra spanned by π and π, demonstrating that the complex formalism is merely the algebraic projection of a richer real-geometric structure. The fundamental circuit law becomes the coordinate-invariant tensor equation, a genuine geometric physical law: π = π (π), π^πΌ = Ξ£π^πΌπ½ πΌ_π½. Phase shift, active and reactive power, resonance, and impedance matching emerge naturally as geometric phenomena in βΒ². Power flow is encoded in the power tensor π = πβ¨π, π^πΌπ½ = π^πΌ πΌ^π½, whose symmetric part describes dissipative transfer of energy and antisymmetric part encodes reversible oscillatory exchange. This tensor formulation reveals that complex AC analysis is not intrinsically complex-valued physics but a compressed representation of real two-dimensional geometry, offering a physically transparent and systematically extensible foundation for circuit theory.
Kwon Se Kyun (Mon,) studied this question.
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