1	Chapter 8 Methods of Analysis
2	Constant Current Sources Maintains same current in branch of circuit Doesn’t matter how components are connected external to the source Direction of current source indicates direction of current flow in branch
3	Constant Current Sources Voltage across current source Depends on how other components are connected
4	Constant Current Sources Series circuit Current must be same everywhere in circuit Current source in a series circuit Value of the current for that circuit For the circuit shown I = 2 mA
5	Constant Current Sources
6	Source Conversions Circuit analysis Sometimes convenient to convert between voltage sources and current sources To convert from a voltage source to a current source Calculate current from E/R_S
7	Source Conversions R_S does not change Place current source and resistor in parallel
8	Source Conversions Can also convert from a current source to a voltage source E = I•R_S Place voltage source in series with resistor
9	Source Conversions
10	Source Conversions A load connected to a voltage source or its equivalent current Should have same voltage and current for either source
11	Source Conversions Although sources are equivalent Currents and voltages within sources may differ Sources are only equivalent external to terminals
12	Current Sources in Parallel and Series Current sources in parallel Simply add together algebraically Magnitude and direction of resultant source Add currents in one direction Subtract currents in opposite direction
13	Current Sources in Parallel and Series Current sources with different values Never place in series This violates KCL
14	Branch Current Analysis For circuits having more than one source Use different methods of analysis Begin by arbitrarily assigning current directions in each branch Label polarities of the voltage drops across all resistors
15	Branch Current Analysis Write KVL around all loops Apply KCL at enough nodes so all branches have been included Solve resulting equations
16	Branch Current Analysis From KVL: 6 - 2I₁ + 2I₂ - 4 = 0 4 - 2I₂ - 4I₃ + 2 = 0 From KCL: I₃ = I₁ + I₂ Solve simultaneous equations
17	Mesh Analysis Arbitrarily assign a clockwise current to each interior closed loop (Mesh) Indicate voltage polarities across all resistors Write KVL equations
18	Mesh Analysis Solve resulting simultaneous equations Branch currents determined by: Algebraically combining loop currents common to branch
19	Mesh Analysis Assign loop currents and voltage polarities Using KVL: 6 - 2I₁ - 2I₁ + 2I₂ - 4 = 0 4 - 2I₂ + 2I₁ - 4I₂ + 2 = 0 Simplify and solve equations
20	Mesh Analysis
21	Format Approach Mutual resistors represent resistors shared between two loops R₁₂ represents resistor in loop 1 that is shared by loop 1 and loop 2 Coefficients along principal diagonal will be positive
22	Format Approach All other coefficients will be negative Terms will be symmetrical about principal diagonal
23	Format Approach Convert current sources into equivalent voltage sources Assign clockwise currents to each independent closed loop Write simultaneous linear equations Use format outline or matrix method
24	Format Approach Solve resulting simultaneous equations or matrix equations Use a calculator or software program to solve
25	Nodal Analysis Assign a reference node within circuit and indicate node as ground Convert voltage sources to current sources
26	Nodal Analysis Assign voltages V₁, V₂, etc. to remaining nodes Arbitrarily assign a current direction to each branch where there is no current source
27	Nodal Analysis Apply KCL to all nodes except reference node Rewrite each current in terms of voltage Solve resulting equations for voltages
28	Format Approach Mutual conductance Common to two nodes Mutual conductance G₂₃ Conductance at Node 2 Common to Node 3 Conductances at certain nodes are positive
29	Format Approach Mutual conductances are negative Equations are written correctly Terms will be symmetrical about principal diagonal
30	Format Approach Convert voltage sources into equivalent current sources Label reference node as ground Label remaining nodes as V₁, V₂, etc.
31	Format Approach Write linear equation for each node or in matrix form Solve resulting equations for voltages Method of solution is same as for mesh
32	Delta-Wye Conversion Resistors connected to a point of Y Obtained by finding product of resistors connected to same point in Delta Divide by sum of all Delta resistors
33	Delta-Wye Conversion Given a Delta circuit with resistors of 30, 60, and 90 W Resulting Y circuit will have resistors of 10, 15, and 30 W
34	Wye-Delta Conversions A Delta resistor is found: Taking sum of all two-product combinations of Y resistor values Divide by resistance of Y directly opposite resistor being calculated
35	Wye-Delta Conversions For a Y circuit having resistances of 2.4, 3.6, and 4.8 W Resulting Delta resistors will be 7.8, 10.4, and 15.6 W