| 1 | Basic concepts. Definition of voltage, current, energy, power, and sample problem solutions. | [1] pg. 1-15, [2] pg.2-22 |
| 2 | Circuit laws and DC circuit solution methods: the serial-parallel circuit connections and features | [1] pg. 15-27, [2] pg.22-56 |
| 3 | Reduction of complex circuits to equivalent. Star-Delta transformations. | [1]pg. 27-43, [2]pg.73-76 |
| 4 | Eye flow method, the method of node potentials and sample problems. | [1] pg. 43-68, [2] pg.92-116 |
| 5 | Superposition theorem, Thevenin theorem. Nortons theorem and sample problems. | [1] pg. 68-94, [2] pg.116-126 |
| 6 | Maximum power transfer theorem, Millman theorem and sample problems. | [1] pg. 94-101, [2]pg.126-154 |
| 7 | Energy storing circuit components: Capacitor, Inductance. | [1] pg. 123-148, [2] pg.186-228 |
| 8 | The production of alternative current. Period, frequency and phase difference concepts. | [3] pg. 1-65, [4] pg.9-21 |
| 9 | The production of alternative current. Period, frequency and phase difference concepts. | [3] pg. 1-65, [4] pg.9-21 |
| 10 | Alternative Values of the stream. Resistance, capacitance and inductance in AV. | [3] pg. 67-111, [4] pg.21-28 |
| 11 | R, L and C serial circuits and solutions with complex numbers. | [3] pg. 111-131, [4] pg.28-33 |
| 12 | R, L and C parallel circuits and solutions with complex numbers. | [3] pg. 131-167, [4] pg.112-133 |
| 13 | AC power circuits. Compensation. | [3] pg. 167-227, [4] pg.67-97 |
| 14 | Resonant circuits. Strategies for the sustainability of the use of the knowledge acquired in this course | [3] pg. 231-279, [4] pg.97-112,133-139 |