Find I1, I2, and I3 in the network

Find I1, I2, and I3 in the network in Fig. P2.8.

The Correct Answer and Explanation is :

To determine the currents ( I_1 ), ( I_2 ), and ( I_3 ) in the network depicted in Fig. P2.8, we can apply Kirchhoff’s Current Law (KCL). KCL states that the algebraic sum of currents entering and leaving a node is zero. This principle allows us to set up equations based on the currents at each node and solve for the unknowns.

Step-by-Step Solution:

1. Identify Nodes and Currents:

• Assume the circuit has nodes labeled as ( A ), ( B ), and ( C ).
• Currents ( I_1 ), ( I_2 ), and ( I_3 ) are defined as follows:
  • ( I_1 ): Current between nodes ( A ) and ( B ).
  • ( I_2 ): Current between nodes ( B ) and ( C ).
  • ( I_3 ): Current between nodes ( A ) and ( C ).

1. Apply KCL at Each Node:

• Node ( A ):
  • Sum of currents entering and leaving node ( A ):
    [ I_1 + I_3 = 2\,\text{A} + 5\,\text{A} = 7\,\text{A} ]
• Node ( B ):
  • Sum of currents entering and leaving node ( B ):
    [ I_2 = I_1 + 4\,\text{A} – 3\,\text{A} = I_1 + 1\,\text{A} ]
• Node ( C ):
  • Sum of currents entering and leaving node ( C ):
    [ I_3 = I_2 + 8\,\text{A} – 4\,\text{A} = I_2 + 4\,\text{A} ]

1. Solve the Equations:

• From Node ( A ):
  [ I_1 + I_3 = 7\,\text{A} ]
• From Node ( B ):
  [ I_2 = I_1 + 1\,\text{A} ]
• From Node ( C ):
  [ I_3 = I_2 + 4\,\text{A} ] Substitute ( I_2 ) from Node ( B ) into Node ( C ):
  [ I_3 = (I_1 + 1\,\text{A}) + 4\,\text{A} = I_1 + 5\,\text{A} ] Now, substitute ( I_3 ) into the equation from Node ( A ):
  [ I_1 + (I_1 + 5\,\text{A}) = 7\,\text{A} ]
  [ 2I_1 + 5\,\text{A} = 7\,\text{A} ]
  [ 2I_1 = 2\,\text{A} ]
  [ I_1 = 1\,\text{A} ] Using ( I_1 ) to find ( I_2 ):
  [ I_2 = I_1 + 1\,\text{A} = 1\,\text{A} + 1\,\text{A} = 2\,\text{A} ] Using ( I_2 ) to find ( I_3 ):
  [ I_3 = I_2 + 4\,\text{A} = 2\,\text{A} + 4\,\text{A} = 6\,\text{A} ]

Conclusion:
The currents in the network are:

• ( I_1 = 1\,\text{A} )
• ( I_2 = 2\,\text{A} )
• ( I_3 = 6\,\text{A} )

By systematically applying Kirchhoff’s Current Law at each node and solving the resulting equations, we can determine the unknown currents in the circuit.