Please I need to solve the l, Jy Matrix method Ja H.W- -2 Example 3.3 For the circuit shown in Fig. 39, find the node voltages. Solution: The supermode contains the 2-V source, nodes I and 2. and the 10-0 resistor. Applying KCL.to the supernode as shown in Fig 3.10a) gives 2V 2- ++7 2A O 1a 1a 07A Expressing h and is in terms of the node voltages S- 2, ++ 28 Figure 3.9 For Eumple 33 =-20 - 20, To get the relationship between v, and y, we apply KVL to the circuit in Fig. 3.100b. Going around the loop. we obtain -, -2+ e -0 - =, +2 a3) From Eq. (33.1) and (332), we write ,+2--20 - 20

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Please I need to solve the
4il, J Matrix method J
H.W
----2
--
Example 3.3
For the circuit shown in Fig. 3.9, find the node voltages
Solution:
The supemode contains the 2-V source, nodes I and 2, and the 10-11
resistor. Applying KCL. to the supernode as shown in Fig. 3.10(a) gives
2V
2=i, +i +7
2A O 2a 40 1A Expressing í, and iz in terms of the node voltages
2.
- S-20, + + 28
Figure 3.9
For Example 33
-20 - 20,
(33.1)
To get the relationship between v, and ey, we apply KVL to the circuit
in Fig. 3.10(b). Going around the loop, we obtain
-, - 2+ e =0 =e, +2 a32)
From Eqs. (13.1) and (33.2), we write
u = , +2=-20 - 20,
Transcribed Image Text:Please I need to solve the 4il, J Matrix method J H.W ----2 -- Example 3.3 For the circuit shown in Fig. 3.9, find the node voltages Solution: The supemode contains the 2-V source, nodes I and 2, and the 10-11 resistor. Applying KCL. to the supernode as shown in Fig. 3.10(a) gives 2V 2=i, +i +7 2A O 2a 40 1A Expressing í, and iz in terms of the node voltages 2. - S-20, + + 28 Figure 3.9 For Example 33 -20 - 20, (33.1) To get the relationship between v, and ey, we apply KVL to the circuit in Fig. 3.10(b). Going around the loop, we obtain -, - 2+ e =0 =e, +2 a32) From Eqs. (13.1) and (33.2), we write u = , +2=-20 - 20,
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