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FIGURE 6-1 The amount of current flowing into junction point A equals the total amount of current flowing out of the junction.

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Presentation on theme: "FIGURE 6-1 The amount of current flowing into junction point A equals the total amount of current flowing out of the junction."— Presentation transcript:

1 FIGURE 6-1 The amount of current flowing into junction point A equals the total amount of current flowing out of the junction.

2 FIGURE 6-2 The current in a parallel circuit splits (divides) according to the resistance in each branch.

3 FIGURE 6-3 In a typical parallel circuit, each resistance has power and ground and each leg operates independently of the other legs of the circuit.

4 FIGURE 6-4 A schematic showing two resistors in parallel connected to a 12 volt battery.

5 FIGURE 6-5 A parallel circuit with three resistors connected to a 12 volt battery.

6 FIGURE 6-6 Using an electronic calculator to determine the total resistance of a parallel circuit.

7 FIGURE 6-7 Another example of how to use an electronic calculator to determine the total resistance of a parallel circuit. The answer is ohms. Notice that the effective resistance of this circuit is less than the resistance of the lowest branch (20 ohms).

8 FIGURE 6-8 A parallel circuit containing four 12 ohm resistors
FIGURE 6-8 A parallel circuit containing four 12 ohm resistors. When a circuit has more than one resistor of equal value, the total resistance can be determined by simply dividing the value of the resistance (12 ohms in this example) by the number of equal-value resistors (4 in this example) to get 3 ohms.

9 FIGURE 6-9 Example 1.

10 FIGURE 6-10 Example 2.

11 FIGURE 6-11 Example 3.

12 FIGURE 6-12 Example 4.

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