|-
! scope="row"| Voltage
| <math> V = \oint_C int_C \mathbf{E(r)} . \mathbf{dl} </math>
|-
! scope="row"| Current
| <math> I = \int_oint_{C_o} \mathbf{H(r)} . \mathbf{dl} </math>
|-
! scope="row"| Electric Flux
|-
! scope="row"| Capacitance
| <math> C = Q/V = \int\int_{S_o} \epsilon \mathbf{E(r)} . \mathbf{ds} / \oint_C int_C \mathbf{E(r)} . \mathbf{dl} </math>
|-
! scope="row"| Inductance
| <math> L = \Phi_H/I = \int\int_S \mu \mathbf{H(r)} . \mathbf{ds} / \int_oint_{C_o} \mathbf{H(r)} . \mathbf{dl} </math>
|}