CHAPTER 3 Resistive Network Analysis. Figure 3.2 3-1 Branch current formulation in nodal analysis.

CHAPTER 3 Resistive Network Analysis

Figure 3.2 3-1 Branch current formulation in nodal analysis

Use of KCL in nodal analysis Figure 3.3 3-2

Figure 3.4 3-3 Illustration of nodal analysis

Figure 3.6 3-4

Figure 3.11 3-5 Circuit for Example 3.6

Figure 3.12 3-6 Basic principle of mesh analysis Figure 3.12

Figure 3.13 Use of KVL in mesh analysis Figure 3.13 3-7

A two-mesh circuit Figure 3.14 3-8

Figure 3.15 Assignment of currents and voltages around mesh 1 3-9

Figure 3.17, 3.18 Figure 3.17 3-10 Figure 3.18

Figur e 3.21 3-11 Circuit used to demonstrate mesh analysis with current sources Figure 3.21

Figure 3.25 3-12 Figure 3.25

Figure 3.27 3-13 The principle of superposition Figure 3.27

Figur e 3.28 3-14 Zeroing voltage and current sources Figure 3.28

Figur e 3.34, 3.35 3-15 Illustration of Thévenin theorem Figure 3.34 Figure 3.35 Illustration of Norton theorem

Figure 3.36, 3.37 3-16 Computation of Thévenin resistance Figure 3.36 Figure 3.37 Equivalent resistance seen by the load

Figure 3.43 3-17 Equivalence of open-circuit and Thévenin voltage Figure 3.43

Figure 3.47 3-18 A circuit and its Thévenin equivalent Figure 3.47

Figure 3.54 3-19 Computation of Norton current Figure 3.54

Figur e 3.67 3-20 Measurement of open-circuit voltage and short-circuit current Figure 3.67

3-21 Power transfer between source and load Figure 3.70 Graphical representation of maximum power transfer Figure 3.69

Figure 3.73, 3.74 3-22 The i-v characteristic of exponential resistor Figure 3.73Figure 3.74 Representation of nonlinear element in a linear circuit

Figure 3.75, 3.76 3-23 Load line Figure 3.75 Figure 3.76 Graphical solution of equations 3.44 and 3.45

Presentation on theme: "CHAPTER 3 Resistive Network Analysis. Figure 3.2 3-1 Branch current formulation in nodal analysis."— Presentation transcript: