Mutual Inductance Consider two circuits “linked” by a magnetic field (magnetically-coupled coils). ECE 201 Circuit Theory I.

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Presentation transcript:

Mutual Inductance Consider two circuits “linked” by a magnetic field (magnetically-coupled coils). ECE 201 Circuit Theory I

“Self-Inductances” are L1 and L2. The “Mutual” Inductance is M. The voltage induced in one circuit is related to the time-varying current in the other circuit. ECE 201 Circuit Theory I

Analysis Easiest with mesh-current method. ECE 201 Circuit Theory I

Write the circuit equations in terms of the coil currents. Arbitrarily assign the current directions. There will be two voltages across each coil, the “self-induced” voltage, L(di/dt), and a “mutually induced” voltage, M(di/dt). ECE 201 Circuit Theory I

Determination of Voltage Polarities “Dot convention” Dots indicate the direction in which the coils are wound. ECE 201 Circuit Theory I

The Rule for using the Dot Convention When the reference direction for a current enters the dotted terminal of a coil, the reference polarity of the voltage that it induces in the other coil is positive at its dotted terminal. ECE 201 Circuit Theory I

Alternate Rule for the Dot Convention When the reference direction for a current leaves the dotted terminal of a coil, the reference polarity of the voltage that it induces in the other coil is negative at its dotted terminal. ECE 201 Circuit Theory I

For this Example The voltage induced in coil 1 by the current in coil 2 is negative at the dotted terminal of coil 1, and is a voltage rise with respect to current i1. ECE 201 Circuit Theory I

For this Example The voltage induced in coil 2 by the current in coil 1 is positive at the dotted terminal of coil 2, and is a voltage rise with respect to current i2. ECE 201 Circuit Theory I

Write the Mesh Equations ECE 201 Circuit Theory I

Example 6.6, page 206 Write a set of mesh equations that describe the circuit shown in terms of i1 and i2. ECE 201 Circuit Theory I

ECE 201 Circuit Theory I

ECE 201 Circuit Theory I

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