A balanced wye-to-delta circuit comprises balanced Y-connected voltage sources and delta-connected loads with no neutral line connection.

The initial step in analyzing a wye-to-delta circuit is to assume a positive phase sequence. These phase voltages are then utilized to calculate the line voltages that occur directly across the delta-connected load impedances. V_an, V_bn, and V_cn are the phase voltages in wye, and V_ab, V_bc, and V_ca are the line voltages for a delta circuit. The relation between the line voltages for a wye-to-delta circuit can be calculated as:

These voltages across the load impedances are subsequently used to calculate the phase currents using Ohm's law. Due to the balanced nature of the circuit, these phase currents have identical magnitudes but are separated in phase by 120 degrees.

Kirchhoff's Current Law (KCL) is applied at the nodes of the delta-connected loads to derive the relationship between line and phase currents.

In a balanced wye-to-delta system, the magnitude of the line currents is related to the magnitudes of the phase currents by a factor of the square root of 3. Line currents lag 30 degrees from their corresponding phase Currents in the delta configuration.

One alternate method of analyzing the wye-to-delta circuit is to transform the delta-connected loads to an equivalent wye configuration. This will convert the circuit into a balanced wye-to-wye system, which can be simplified into single-phase equivalent circuits for analysis. In this manner, the phase currents can be estimated from their corresponding line currents, considering the phase shift introduced by the transformation.

This detailed understanding of phase and line currents and the relationship between wye-connected sources and delta-connected loads is essential for designing and operating an efficient electrical system.