circuitlaws i-120122051920-phpapp01
TRANSCRIPT
Kirchhoff's Laws Kirchhoff's circuit laws are two equalities that deal with
the conservation of charge and energy in electrical circuits. There basically two Kirchhoff's law :-
1. Kirchhoff's current law (KCL) – Based on principle of conservation of electric charge.
2. Kirchhoff's voltage law (KVL) - Based on principle of conservation of energy.
Kirchhoff's current law (KCL) This law is also called Kirchhoff's first law, Kirchhoff's point
rule, Kirchhoff's junction rule (or nodal rule), and Kirchhoff's first rule.
The principle of conservation of electric charge implies that: At any node (junction) in an electrical circuit, the sum
of currents flowing into that node is equal to the sum of currents flowing out of that node, or The algebraic sum of currents in a network of conductors meeting at a point is zero.
Strictly speaking KCL only applies to circuits with steady currents (DC).However, for AC circuits having dimensions much smaller than a wavelength, KCL is also approximately applicable.
The current entering any junction is equal to the current leaving that junction. i1 + i4 =i2 + i3
Recalling that current is a signed (positive or negative) quantity reflecting direction towards or away from a node, this principle can be stated as:
0I
Kirchhoff's voltage law (KVL) This law is also called Kirchhoff's second law, Kirchhoff's loop
(or mesh) rule, and Kirchhoff's second rule. The principle of conservation of energy implies that The directed sum of the electrical potential
differences (voltage) around any closed circuit is zero, or More simply, the sum of the emfs in any closed loop is
equivalent to the sum of the potential drops in that loop Strictly speaking KVL only applies to circuits with steady
currents (DC). However, for AC circuits having dimensions much smaller than
a wavelength, KVL is also approximately applicable.
The algebraic sum of the products of the resistances of the conductors and the currents in them in a closed loop is equal to the total emf available in that loop. Similarly to KCL, it can be stated as:
OR RIVemfVn
loop 0KVL:
The sum of all the voltages around the loop is equal to zero. v1 + v2 + v3 - v4 = 0
Mesh Analysis Mesh analysis (or the mesh current method) is a method that
is used to solve planar circuits for the currents (and indirectly the voltages) at any place in the circuit. Planar circuits are circuits that can be drawn on a plane surface with no wires crossing each other.
Mesh analysis works by arbitrarily assigning mesh currents in the essential meshes. An essential mesh is a loop in the circuit that does not contain any other loop.
Steps to Determine Mesh Currents:1. Assign mesh currents i1, i2, .., in to the n meshes.
Current direction need to be same in all meshes either clockwise or anticlockwise.
2. Apply KVL to each of the n meshes. Use Ohm’s law to express the voltages in terms of the mesh currents.
3. Solve the resulting n simultaneous equations to get the mesh currents
ExampleA circuit with two meshes.
Apply KVL to each mesh. For mesh 1,
For mesh 2,
123131
213111
)(0)(
ViRiRRiiRiRV
223213
123222
)(0)(
ViRRiRiiRViR
Solve for the mesh currents.
Use i for a mesh current and I for a branch current. It’s evident from Fig. 3.17 that
2
1
2
1
323
331
VV
ii
RRRRRR
2132211 , , iiIiIiI
Nodal Analysis In electric circuits analysis, nodal analysis, node-voltage
analysis, or the branch current method is a method of determining the voltage (potential difference) between "nodes" (points where elements or branches connect) in an electrical circuit in terms of the branch currents.
Nodal analysis is possible when all the circuit elements branch constitutive relations have an admittance representation.
Kirchhoff’s current law is used to develop the method referred to as nodal analysis
STEPS FOR NODAL ANALYSIS:-• Note all connected wire segments in the circuit. These are
the nodes of nodal analysis.• Select one node as the ground reference. The choice does not
affect the result and is just a matter of convention. Choosing the node with most connections can simplify the analysis.
• Assign a variable for each node whose voltage is unknown. If the voltage is already known, it is not necessary to assign a variable.
• For each unknown voltage, form an equation based on Kirchhoff's current law. Basically, add together all currents leaving from the node and mark the sum equal to zero.
• If there are voltage sources between two unknown voltages, join the two nodes as a super node. The currents of the two nodes are combined in a single equation, and a new equation for the voltages is formed.
• Solve the system of simultaneous equations for each unknown voltage.
1. Reference Node
The reference node is called the ground node where V = 0
+
–
V 500W
500W
1kW
500W
500WI1 I2
Example
V1, V2, and V3 are unknowns for which we solve using KCL
500W
500W
1kW
500W
500WI1 I2
1 2 3
V1 V2 V3
Steps of Nodal Analysis1. Choose a reference (ground) node.2. Assign node voltages to the other nodes.3. Apply KCL to each node other than the reference
node; express currents in terms of node voltages.4. Solve the resulting system of linear equations for
the nodal voltages.
Currents and Node Voltages
500W
V1500WV1 V2
W
50021 VV
W5001V
3. KCL at Node 1
500W
500WI1
V1 V2
W
W
500500
1211
VVVI
3. KCL at Node 2
500W
1kW
500W V2 V3V1
0500k1500
32212 W
W
W VVVVV
3. KCL at Node 3
2323
500500IVVV
W
W
500W
500W
I2
V2 V3
Superposition Theorem• It is used to find the solution to networks with two or more
sources that are not in series or parallel• The current through, or voltage across, an element in a linear
bilateral network is equal to the algebraic sum of the currents or voltages produced independently by each source.
• For a two-source network, if the current produced by one source is in one direction, while that produced by the other is in the opposite direction through the same resistor, the resulting current is the difference of the two and has the direction of the larger
• If the individual currents are in the same direction, the resulting current is the sum of two in the direction of either current
Superposition Theorem• The total power delivered to a resistive element must be
determined using the total current through or the total voltage across the element and cannot be determined by a simple sum of the power levels established by each source
For applying Superposition theorem:-• Replace all other independent voltage sources with a short
circuit (thereby eliminating difference of potential. i.e. V=0, internal impedance of ideal voltage source is ZERO (short circuit)).
• Replace all other independent current sources with an open circuit (thereby eliminating current. i.e. I=0, internal impedance of ideal current source is infinite (open circuit).
Example:- Determine the branches current using Superposition theorem.
Solution:• The application of the superposition theorem is shown in
Figure 1, where it is used to calculate the branch current. We begin by calculating the branch current caused by the voltage source of 120 V. By substituting the ideal current with open circuit, we deactivate the current source, as shown in Figure 2.
120 V 3 W
6 W
12 A4 W
2 W
i1i2
i3i4
Figure 1
• To calculate the branch current, the node voltage across the 3Ω resistor must be known. Therefore
120 V 3 W
6 W
4 W
2 W
i'1 i'2i'3 i'4
v1
Figure 2
42v
3v
6120v 111
= 0
where v1 = 30 V
The equations for the current in each branch,
630120
= 15 A
i'2 = 3
30= 10 A
i'3 = i'
4 =
630
= 5 A
In order to calculate the current cause by the current source, we deactivate the ideal voltage source with a short circuit, as
shown
3 W
6 W
12 A4 W
2 W
i1"
i2"
i3"
i4"
i'1 =
To determine the branch current, solve the node voltages across the 3Ω dan 4Ω resistors as shown in Figure 4
The two node voltages are
3 W
6 W
12 A4 W
2 W
v3v4
+
-
+
-
2634333 vvvv
124
v2
vv 434
= 0
= 0
• By solving these equations, we obtain v3 = -12 V
v4 = -24 V
Now we can find the branches current,
To find the actual current of the circuit, add the currents due to both the current and voltage source,
Thevenin's theorem Thevenin's theorem for linear electrical networks states that
any combination of voltage sources, current sources, and resistors with two terminals is electrically equivalent to a single voltage source V and a single series resistor R.
Any two-terminal, linear bilateral dc network can be replaced by an equivalent circuit consisting of a voltage source and a series resistor
Thévenin’s Theorem The Thévenin equivalent circuit provides an equivalence at
the terminals only – the internal construction and characteristics of the original network and the Thévenin equivalent are usually quite different
• This theorem achieves two important objectives:– Provides a way to find any particular voltage or current
in a linear network with one, two, or any other number of sources
– We can concentration on a specific portion of a network by replacing the remaining network with an equivalent circuit
Calculating the Thévenin equivalent• Sequence to proper value of RTh and ETh • Preliminary
– 1. Remove that portion of the network across which the Thévenin equation circuit is to be found. In the figure below, this requires that the load resistor RL be temporarily removed from the network.
– 2. Mark the terminals of the remaining two-terminal network. (The importance of this step will become obvious as we progress through some complex networks)
– RTh:– 3. Calculate RTh by first setting all sources to zero
(voltage sources are replaced by short circuits, and current sources by open circuits) and then finding the resultant resistance between the two marked terminals. (If the internal resistance of the voltage and/or current sources is included in the original network, it must remain when the sources are set to zero)
• ETh:– 4. Calculate ETh by first returning all sources to their
original position and finding the open-circuit voltage between the marked terminals. (This step is invariably the one that will lead to the most confusion and errors. In all cases, keep in mind that it is the open-circuit potential between the two terminals marked in step 2)
• Conclusion:– 5. Draw the Thévenin
equivalent circuit with the portion of the circuit previously removed replaced between the terminals of the equivalent circuit. This step is indicated by the placement of the resistor RL between the terminals of the Thévenin equivalent circuit
Insert Figure 9.26(b)
Another way of Calculating the Thévenin equivalent
• Measuring VOC and ISC– The Thévenin voltage is again determined by
measuring the open-circuit voltage across the terminals of interest; that is, ETh = VOC. To determine RTh, a short-circuit condition is established across the terminals of interest and the current through the short circuit Isc is measured with an ammeter
– Using Ohm’s law:
RTh = Voc / Isc
Example:- find the Thevenin equivalent circuit.
Solution• In order to find the Thevenin equivalent circuit for the circuit
shown in Figure1 , calculate the open circuit voltage, Vab. Note that when the a, b terminals are open, there is no current flow to 4Ω resistor. Therefore, the voltage vab is the same as the voltage across the 3A current source, labeled v1.
• To find the voltage v1, solve the equations for the singular node voltage. By choosing the bottom right node as the reference node,
25 V 20 W
+
-
v13 A
5 W 4 W+
-
vab
a
b
• By solving the equation, v1 = 32 V. Therefore, the Thevenin voltage Vth for the circuit is 32 V.
• The next step is to short circuit the terminals and find the short circuit current for the circuit shown in Figure 2. Note that the current is in the same direction as the falling voltage at the terminal.
0320v
525v 11
25 V 20 W
+
-
v23 A
5 W 4 W+
-
vab
a
b
isc
Figure 2
04
v3
20v
525v 222
Current isc can be found if v2 is known. By using the bottomright node as the reference node, the equationfor v2 becomes
By solving the above equation, v2 = 16 V. Therefore, the short circuitcurrent isc is
The Thevenin resistance RTh is
Figure 3 shows the Thevenin equivalent circuit for the Figure 1.
Figure 3
Norton theorem Norton's theorem for linear electrical networks states that
any collection of voltage sources, current sources, and resistors with two terminals is electrically equivalent to an ideal current source, I, in parallel with a single resistor.
Any two linear bilateral dc network can be replaced by an equivalent circuit consisting of a current and a parallel resistor.
Calculating the Norton equivalent
• The steps leading to the proper values of IN and RN
• Preliminary– 1. Remove that portion of the network across
which the Norton equivalent circuit is found– 2. Mark the terminals of the remaining two-
terminal network
• RN:– 3. Calculate RN by first setting all sources to zero
(voltage sources are replaced with short circuits, and current sources with open circuits) and then finding the resultant resistance between the two marked terminals. (If the internal resistance of the voltage and/or current sources is included in the original network, it must remain when the sources are set to zero.) Since RN = RTh the procedure and value obtained using the approach described for Thévenin’s theorem will determine the proper value of RN
Norton’s Theorem• IN :
– 4. Calculate IN by first returning all the sources to their original position and then finding the short-circuit current between the marked terminals. It is the same current that would be measured by an ammeter placed between the marked terminals.
– Conclusion:– 5. Draw the Norton equivalent circuit with the
portion of the circuit previously removed replaced between the terminals of the equivalent circuit
Example Derive the Norton equivalent circuit
Solution Step 1: Source transformation (The 25V voltage
source is converted to a 5 A current source.)
25 V 20 W 3 A
5 W 4 W a
b
20 W 3 A5 W
4 W a
b
5 A
4 W8 A
4 W a
b
Step 3: Source transformation (combined serial resistance to produce the Thevenin equivalent circuit.)
8 W
32 V
a
b
Step 2: Combination of parallel source and parallel resistance
• Step 4: Source transformation (To produce the Norton equivalent circuit. The current source is 4A (I = V/R = 32 V/8 W))
Norton equivalent circuit.
8 Ωa
b
4 A
Maximum power transfer theorem
The maximum power transfer theorem states that, to obtain maximum external power from a source with a finite internal resistance, the resistance of the load must be equal to the resistance of the source as viewed from the output terminals. A load will receive maximum power from a linear bilateral
dc network when its total resistive value is exactly equal to the Thévenin resistance of the network as “seen” by the load
RL = RTh
Resistance network which contains dependent and independent sources
L
2Th
R4V
2L
L2
Th
R2
RVpmax = =
• Maximum power transfer happens when the load resistance RL is equal to the Thevenin equivalent resistance, RTh. To find the maximum power delivered to RL,
Application of Network Theorems• Network theorems are useful in simplifying analysis of some
circuits. But the more useful aspect of network theorems is the insight it provides into the properties and behaviour of circuits
• Network theorem also help in visualizing the response of complex network.
• The Superposition Theorem finds use in the study of alternating current (AC) circuits, and semiconductor (amplifier) circuits, where sometimes AC is often mixed (superimposed) with DC