Module Name | Download |
---|---|
noc18_ee18_Assignment1 | noc18_ee18_Assignment1 |
noc18_ee18_Assignment2 | noc18_ee18_Assignment2 |
noc18_ee18_Assignment3 | noc18_ee18_Assignment3 |
noc18_ee18_Assignment4 | noc18_ee18_Assignment4 |
noc18_ee18_Assignment5 | noc18_ee18_Assignment5 |
noc18_ee18_Assignment6 | noc18_ee18_Assignment6 |
noc18_ee18_Assignment7 | noc18_ee18_Assignment7 |
noc18_ee18_Assignment8 | noc18_ee18_Assignment8 |
noc18_ee18_Assignment9 | noc18_ee18_Assignment9 |
Sl.No | Chapter Name | MP4 Download |
---|---|---|
1 | Preliminaries | Download |
2 | Current | Download |
3 | Voltage | Download |
4 | Electrical elements and circuits | Download |
5 | Kirchhoff's current law(KCL) | Download |
6 | Kirchhoff's voltage law(KVL) | Download |
7 | Voltage source | Download |
8 | Current source | Download |
9 | Resistor | Download |
10 | Capacitor | Download |
11 | Inductor | Download |
12 | Mutual inductor | Download |
13 | Linearity of elements | Download |
14 | Series connection-Voltage sources in series | Download |
15 | Series connection of R, L, C, current source | Download |
16 | Elements in parallel | Download |
17 | Current source in series with an element; Voltage source in parallel with an element | Download |
18 | Extreme cases: Open and short circuits | Download |
19 | Summary | Download |
20 | Voltage controlled voltage source(VCVS) | Download |
21 | Voltage controlled current source(VCCS) | Download |
22 | Current controlled voltage source(CCVS) | Download |
23 | Current controlled current source(CCCS) | Download |
24 | Scaling an element's value using controlled sources | Download |
25 | Example calculation | Download |
26 | Power and energy absorbed by electrical elements | Download |
27 | Power and energy in a resistor | Download |
28 | Power and energy in a capacitor | Download |
29 | Power and energy in an inductor | Download |
30 | Power and energy in a voltage source | Download |
31 | Power and energy in a current source | Download |
32 | Goals of circuit analysis | Download |
33 | Number of independent KCL equations | Download |
34 | Number of independent KVL equations and branch relationships | Download |
35 | Analysis of circuits with a single independent source | Download |
36 | Analysis of circuits with multiple independent sources using superposition | Download |
37 | Superposition: Example | Download |
38 | What is nodal analysis | Download |
39 | Setting up nodal analysis equations | Download |
40 | Structure of the conductance matrix | Download |
41 | How elements appear in the nodal analysis formulation | Download |
42 | Completely solving the circuit starting from nodal analysis | Download |
43 | Nodal analysis example | Download |
44 | Matrix inversion basics | Download |
45 | Nodal analysis with independent voltage sources | Download |
46 | Supernode for nodal analysis with independent voltage sources | Download |
47 | Nodal analysis with VCCS | Download |
48 | Nodal analysis with VCVS | Download |
49 | Nodal analysis with CCVS | Download |
50 | Nodal analysis with CCCS | Download |
51 | Planar circuits | Download |
52 | Mesh currents and their relationship to branch currents | Download |
53 | Mesh analysis | Download |
54 | Mesh analysis with independent current sources-Supermesh | Download |
55 | Mesh analysis with current controlled voltage sources | Download |
56 | Mesh analysis with current controlled current sources | Download |
57 | Mesh analysis using voltage controlled sources | Download |
58 | Nodal analysis versus Mesh analysis | Download |
59 | Superposition theorem | Download |
60 | Pushing a voltage source through a node | Download |
61 | Splitting a current source | Download |
62 | Substitution theorem: Current source | Download |
63 | Substitution theorem: Voltage source | Download |
64 | Substituting a voltage or current source with a resistor | Download |
65 | Extensions to Superposition and Substitution theorem | Download |
66 | Thevenin's theorem | Download |
67 | Worked out example: Thevenin's theorem | Download |
68 | Norton's theorem | Download |
69 | Worked out example: Norton's theorem | Download |
70 | Maximum power transfer theorem | Download |
71 | Preliminaries | Download |
72 | Two port parameters | Download |
73 | y parameters | Download |
74 | y parameters: Examples | Download |
75 | z parameters | Download |
76 | z parameters: Examples | Download |
77 | h parameters | Download |
78 | h parameters: Examples | Download |
79 | g parameters | Download |
80 | g parameters: Examples | Download |
81 | Calculations with a two-port element | Download |
82 | Calculations with a two-port element | Download |
83 | Degenerate cases | Download |
84 | Relationships between different two-port parameters | Download |
85 | Equivalent circuit representation for two ports | Download |
86 | Reciprocity | Download |
87 | Proof of reciprocity of resistive two-ports | Download |
88 | Proof for 4-terminal two-ports | Download |
89 | Reciprocity in terms of different two-port parameters | Download |
90 | Reciprocity in circuits containing controlled sources | Download |
91 | Examples | Download |
92 | Feedback amplifier using an opamp | Download |
93 | Ideal opamp | Download |
94 | Negative feedback around the opamp | Download |
95 | Finding opamp signs for negative feedback | Download |
96 | Example: Determining opamp sign for negative feedback | Download |
97 | Analysis of circuits with opamps | Download |
98 | Inverting amplifier | Download |
99 | Summing amplifier | Download |
100 | Instrumentation amplifier | Download |
101 | Negative resistance and Miller effect | Download |
102 | Finding opamp signs for negative feedback-circuits with multiple opamps | Download |
103 | Opamp supply voltages and saturation | Download |
104 | KCL with an opamp and supply currents | Download |
105 | Circuits with storage elements(capacitors and inductors) | Download |
106 | First order circuit with zero input-natural response | Download |
107 | First order RC circuit with zero input-Example | Download |
108 | First order circuit with a constant input | Download |
109 | General form of the first order circuit response | Download |
110 | First order RC circuit with a constant input-Example | Download |
111 | First order circuit with piecewise constant input | Download |
112 | First order circuit with piecewise constant input-Example | Download |
113 | First order circuit-Response of arbitrary circuit variables | Download |
114 | Summary: Computing first order circuit response | Download |
115 | Does a capacitor block DC? | Download |
116 | Finding the order of a circuit | Download |
117 | First order RC circuits with discontinuous capacitor voltages | Download |
118 | Summary: Computing first order circuit response with discontinuities | Download |
119 | First order RL circuits | Download |
120 | First order RL circuit with discontinuous inductor current-Example | Download |
121 | First order RC circuit with an exponential input | Download |
122 | First order RC response to its own natural response | Download |
123 | First order RC response to a sinusoidal input | Download |
124 | First order RC response to a sinusoidal input-via the complex exponential | Download |
125 | Summary: Linear circuit response to sinusoidal input via the complex exponential | Download |
126 | Three methods of calculating the sinusoidal steady state response | Download |
127 | Calculating the total response including initial conditions | Download |
128 | Why are sinusoids used in measurement? | Download |
129 | Second order system natural response | Download |
130 | Second order system as a cascade of two first order systems | Download |
131 | Second order system natural response-critically damped and underdamped | Download |
132 | Generalized form of a second order system | Download |
133 | Numerical example | Download |
134 | Series and parallel RLC circuits | Download |
135 | Forced response of a second order system | Download |
136 | Steady state response calculation and Phasors | Download |
137 | Phasors cont'd | Download |
138 | Magnitude and Phase plots | Download |
139 | Magnitude and phase plotes of a second order system | Download |
140 | Maximum power transfer and Conjugate matching | Download |
Sl.No | Chapter Name | English |
---|---|---|
1 | Preliminaries | Download Verified |
2 | Current | Download Verified |
3 | Voltage | Download Verified |
4 | Electrical elements and circuits | Download Verified |
5 | Kirchhoff's current law(KCL) | Download Verified |
6 | Kirchhoff's voltage law(KVL) | Download Verified |
7 | Voltage source | Download Verified |
8 | Current source | Download Verified |
9 | Resistor | Download Verified |
10 | Capacitor | Download Verified |
11 | Inductor | Download Verified |
12 | Mutual inductor | Download Verified |
13 | Linearity of elements | Download Verified |
14 | Series connection-Voltage sources in series | Download Verified |
15 | Series connection of R, L, C, current source | Download Verified |
16 | Elements in parallel | Download Verified |
17 | Current source in series with an element; Voltage source in parallel with an element | Download Verified |
18 | Extreme cases: Open and short circuits | Download Verified |
19 | Summary | Download Verified |
20 | Voltage controlled voltage source(VCVS) | Download Verified |
21 | Voltage controlled current source(VCCS) | Download Verified |
22 | Current controlled voltage source(CCVS) | Download Verified |
23 | Current controlled current source(CCCS) | Download Verified |
24 | Scaling an element's value using controlled sources | Download Verified |
25 | Example calculation | Download Verified |
26 | Power and energy absorbed by electrical elements | Download Verified |
27 | Power and energy in a resistor | Download Verified |
28 | Power and energy in a capacitor | Download Verified |
29 | Power and energy in an inductor | Download Verified |
30 | Power and energy in a voltage source | Download Verified |
31 | Power and energy in a current source | Download Verified |
32 | Goals of circuit analysis | Download Verified |
33 | Number of independent KCL equations | Download Verified |
34 | Number of independent KVL equations and branch relationships | Download Verified |
35 | Analysis of circuits with a single independent source | Download Verified |
36 | Analysis of circuits with multiple independent sources using superposition | Download Verified |
37 | Superposition: Example | Download Verified |
38 | What is nodal analysis | Download Verified |
39 | Setting up nodal analysis equations | Download Verified |
40 | Structure of the conductance matrix | Download Verified |
41 | How elements appear in the nodal analysis formulation | Download Verified |
42 | Completely solving the circuit starting from nodal analysis | Download Verified |
43 | Nodal analysis example | Download Verified |
44 | Matrix inversion basics | Download Verified |
45 | Nodal analysis with independent voltage sources | Download Verified |
46 | Supernode for nodal analysis with independent voltage sources | Download Verified |
47 | Nodal analysis with VCCS | Download Verified |
48 | Nodal analysis with VCVS | Download Verified |
49 | Nodal analysis with CCVS | Download Verified |
50 | Nodal analysis with CCCS | Download Verified |
51 | Planar circuits | Download Verified |
52 | Mesh currents and their relationship to branch currents | Download Verified |
53 | Mesh analysis | Download Verified |
54 | Mesh analysis with independent current sources-Supermesh | Download Verified |
55 | Mesh analysis with current controlled voltage sources | Download Verified |
56 | Mesh analysis with current controlled current sources | Download Verified |
57 | Mesh analysis using voltage controlled sources | Download Verified |
58 | Nodal analysis versus Mesh analysis | Download Verified |
59 | Superposition theorem | Download Verified |
60 | Pushing a voltage source through a node | Download Verified |
61 | Splitting a current source | Download Verified |
62 | Substitution theorem: Current source | Download Verified |
63 | Substitution theorem: Voltage source | Download Verified |
64 | Substituting a voltage or current source with a resistor | Download Verified |
65 | Extensions to Superposition and Substitution theorem | Download Verified |
66 | Thevenin's theorem | Download Verified |
67 | Worked out example: Thevenin's theorem | Download Verified |
68 | Norton's theorem | Download Verified |
69 | Worked out example: Norton's theorem | Download Verified |
70 | Maximum power transfer theorem | Download Verified |
71 | Preliminaries | Download Verified |
72 | Two port parameters | Download Verified |
73 | y parameters | Download Verified |
74 | y parameters: Examples | Download Verified |
75 | z parameters | Download Verified |
76 | z parameters: Examples | Download Verified |
77 | h parameters | Download Verified |
78 | h parameters: Examples | Download Verified |
79 | g parameters | Download Verified |
80 | g parameters: Examples | Download Verified |
81 | Calculations with a two-port element | Download Verified |
82 | Calculations with a two-port element | Download Verified |
83 | Degenerate cases | Download Verified |
84 | Relationships between different two-port parameters | Download Verified |
85 | Equivalent circuit representation for two ports | Download Verified |
86 | Reciprocity | Download Verified |
87 | Proof of reciprocity of resistive two-ports | Download Verified |
88 | Proof for 4-terminal two-ports | Download Verified |
89 | Reciprocity in terms of different two-port parameters | Download Verified |
90 | Reciprocity in circuits containing controlled sources | Download Verified |
91 | Examples | Download Verified |
92 | Feedback amplifier using an opamp | Download Verified |
93 | Ideal opamp | Download Verified |
94 | Negative feedback around the opamp | Download Verified |
95 | Finding opamp signs for negative feedback | Download Verified |
96 | Example: Determining opamp sign for negative feedback | Download Verified |
97 | Analysis of circuits with opamps | Download Verified |
98 | Inverting amplifier | Download Verified |
99 | Summing amplifier | Download Verified |
100 | Instrumentation amplifier | Download Verified |
101 | Negative resistance and Miller effect | Download Verified |
102 | Finding opamp signs for negative feedback-circuits with multiple opamps | Download Verified |
103 | Opamp supply voltages and saturation | Download Verified |
104 | KCL with an opamp and supply currents | Download Verified |
105 | Circuits with storage elements(capacitors and inductors) | Download Verified |
106 | First order circuit with zero input-natural response | Download Verified |
107 | First order RC circuit with zero input-Example | Download Verified |
108 | First order circuit with a constant input | Download Verified |
109 | General form of the first order circuit response | Download Verified |
110 | First order RC circuit with a constant input-Example | Download Verified |
111 | First order circuit with piecewise constant input | Download Verified |
112 | First order circuit with piecewise constant input-Example | Download Verified |
113 | First order circuit-Response of arbitrary circuit variables | Download Verified |
114 | Summary: Computing first order circuit response | Download Verified |
115 | Does a capacitor block DC? | Download Verified |
116 | Finding the order of a circuit | Download Verified |
117 | First order RC circuits with discontinuous capacitor voltages | Download Verified |
118 | Summary: Computing first order circuit response with discontinuities | Download Verified |
119 | First order RL circuits | Download Verified |
120 | First order RL circuit with discontinuous inductor current-Example | Download Verified |
121 | First order RC circuit with an exponential input | Download Verified |
122 | First order RC response to its own natural response | Download Verified |
123 | First order RC response to a sinusoidal input | Download Verified |
124 | First order RC response to a sinusoidal input-via the complex exponential | Download Verified |
125 | Summary: Linear circuit response to sinusoidal input via the complex exponential | Download Verified |
126 | Three methods of calculating the sinusoidal steady state response | Download Verified |
127 | Calculating the total response including initial conditions | Download Verified |
128 | Why are sinusoids used in measurement? | Download Verified |
129 | Second order system natural response | Download Verified |
130 | Second order system as a cascade of two first order systems | Download Verified |
131 | Second order system natural response-critically damped and underdamped | Download Verified |
132 | Generalized form of a second order system | Download Verified |
133 | Numerical example | Download Verified |
134 | Series and parallel RLC circuits | Download Verified |
135 | Forced response of a second order system | Download Verified |
136 | Steady state response calculation and Phasors | Download Verified |
137 | Phasors cont'd | Download Verified |
138 | Magnitude and Phase plots | Download Verified |
139 | Magnitude and phase plotes of a second order system | Download Verified |
140 | Maximum power transfer and Conjugate matching | Download Verified |
Sl.No | Chapter Name | Gujarati |
---|---|---|
1 | Preliminaries | Download |
2 | Current | Download |
3 | Voltage | Download |
4 | Electrical elements and circuits | Download |
5 | Kirchhoff's current law(KCL) | Download |
6 | Kirchhoff's voltage law(KVL) | Download |
7 | Voltage source | Download |
8 | Current source | Download |
9 | Resistor | Download |
10 | Capacitor | Download |
11 | Inductor | Download |
12 | Mutual inductor | Download |
13 | Linearity of elements | Download |
14 | Series connection-Voltage sources in series | Download |
15 | Series connection of R, L, C, current source | Download |
16 | Elements in parallel | Download |
17 | Current source in series with an element; Voltage source in parallel with an element | Download |
18 | Extreme cases: Open and short circuits | Download |
19 | Summary | Download |
20 | Voltage controlled voltage source(VCVS) | Download |
21 | Voltage controlled current source(VCCS) | Download |
22 | Current controlled voltage source(CCVS) | Download |
23 | Current controlled current source(CCCS) | Download |
24 | Scaling an element's value using controlled sources | Download |
25 | Example calculation | Download |
26 | Power and energy absorbed by electrical elements | Download |
27 | Power and energy in a resistor | Download |
28 | Power and energy in a capacitor | Download |
29 | Power and energy in an inductor | Download |
30 | Power and energy in a voltage source | Download |
31 | Power and energy in a current source | Download |
32 | Goals of circuit analysis | Download |
33 | Number of independent KCL equations | Download |
34 | Number of independent KVL equations and branch relationships | Download |
35 | Analysis of circuits with a single independent source | Download |
36 | Analysis of circuits with multiple independent sources using superposition | Download |
37 | Superposition: Example | Download |
38 | What is nodal analysis | Download |
39 | Setting up nodal analysis equations | Download |
40 | Structure of the conductance matrix | Download |
41 | How elements appear in the nodal analysis formulation | Download |
42 | Completely solving the circuit starting from nodal analysis | Download |
43 | Nodal analysis example | Download |
44 | Matrix inversion basics | Download |
45 | Nodal analysis with independent voltage sources | Download |
46 | Supernode for nodal analysis with independent voltage sources | Download |
47 | Nodal analysis with VCCS | Download |
48 | Nodal analysis with VCVS | Download |
49 | Nodal analysis with CCVS | Download |
50 | Nodal analysis with CCCS | Download |
51 | Planar circuits | Download |
52 | Mesh currents and their relationship to branch currents | Download |
53 | Mesh analysis | Download |
54 | Mesh analysis with independent current sources-Supermesh | Download |
55 | Mesh analysis with current controlled voltage sources | Download |
56 | Mesh analysis with current controlled current sources | Download |
57 | Mesh analysis using voltage controlled sources | Download |
58 | Nodal analysis versus Mesh analysis | Download |
59 | Superposition theorem | Download |
60 | Pushing a voltage source through a node | Download |
61 | Splitting a current source | Download |
62 | Substitution theorem: Current source | Download |
63 | Substitution theorem: Voltage source | Download |
64 | Substituting a voltage or current source with a resistor | Download |
65 | Extensions to Superposition and Substitution theorem | Download |
66 | Thevenin's theorem | Download |
67 | Worked out example: Thevenin's theorem | Download |
68 | Norton's theorem | Download |
69 | Worked out example: Norton's theorem | Download |
70 | Maximum power transfer theorem | Download |
71 | Preliminaries | Download |
72 | Two port parameters | Download |
73 | y parameters | Download |
74 | y parameters: Examples | Download |
75 | z parameters | Download |
76 | z parameters: Examples | Download |
77 | h parameters | Download |
78 | h parameters: Examples | Download |
79 | g parameters | Download |
80 | g parameters: Examples | Download |
81 | Calculations with a two-port element | Download |
82 | Calculations with a two-port element | Download |
83 | Degenerate cases | Download |
84 | Relationships between different two-port parameters | Download |
85 | Equivalent circuit representation for two ports | Download |
86 | Reciprocity | Download |
87 | Proof of reciprocity of resistive two-ports | Download |
88 | Proof for 4-terminal two-ports | Download |
89 | Reciprocity in terms of different two-port parameters | Download |
90 | Reciprocity in circuits containing controlled sources | Download |
91 | Examples | Download |
92 | Feedback amplifier using an opamp | Download |
93 | Ideal opamp | Download |
94 | Negative feedback around the opamp | Download |
95 | Finding opamp signs for negative feedback | Download |
96 | Example: Determining opamp sign for negative feedback | Download |
97 | Analysis of circuits with opamps | Download |
98 | Inverting amplifier | Download |
99 | Summing amplifier | Download |
100 | Instrumentation amplifier | Download |
101 | Negative resistance and Miller effect | Download |
102 | Finding opamp signs for negative feedback-circuits with multiple opamps | Download |
103 | Opamp supply voltages and saturation | Download |
104 | KCL with an opamp and supply currents | Download |
105 | Circuits with storage elements(capacitors and inductors) | Download |
106 | First order circuit with zero input-natural response | Download |
107 | First order RC circuit with zero input-Example | Download |
108 | First order circuit with a constant input | Download |
109 | General form of the first order circuit response | Download |
110 | First order RC circuit with a constant input-Example | Download |
111 | First order circuit with piecewise constant input | Download |
112 | First order circuit with piecewise constant input-Example | Download |
113 | First order circuit-Response of arbitrary circuit variables | Download |
114 | Summary: Computing first order circuit response | Download |
115 | Does a capacitor block DC? | Download |
116 | Finding the order of a circuit | Download |
117 | First order RC circuits with discontinuous capacitor voltages | Download |
118 | Summary: Computing first order circuit response with discontinuities | Download |
119 | First order RL circuits | Download |
120 | First order RL circuit with discontinuous inductor current-Example | Download |
121 | First order RC circuit with an exponential input | Download |
122 | First order RC response to its own natural response | Download |
123 | First order RC response to a sinusoidal input | Download |
124 | First order RC response to a sinusoidal input-via the complex exponential | Download |
125 | Summary: Linear circuit response to sinusoidal input via the complex exponential | Download |
126 | Three methods of calculating the sinusoidal steady state response | Download |
127 | Calculating the total response including initial conditions | Download |
128 | Why are sinusoids used in measurement? | Download |
129 | Second order system natural response | Download |
130 | Second order system as a cascade of two first order systems | Download |
131 | Second order system natural response-critically damped and underdamped | Download |
132 | Generalized form of a second order system | Download |
133 | Numerical example | Download |
134 | Series and parallel RLC circuits | Download |
135 | Forced response of a second order system | Download |
136 | Steady state response calculation and Phasors | Download |
137 | Phasors cont'd | Download |
138 | Magnitude and Phase plots | Download |
139 | Magnitude and phase plotes of a second order system | Download |
140 | Maximum power transfer and Conjugate matching | Download |
Sl.No | Chapter Name | Malayalam |
---|---|---|
1 | Preliminaries | Download |
2 | Current | Download |
3 | Voltage | Download |
4 | Electrical elements and circuits | Download |
5 | Kirchhoff's current law(KCL) | Download |
6 | Kirchhoff's voltage law(KVL) | Download |
7 | Voltage source | Download |
8 | Current source | Download |
9 | Resistor | Download |
10 | Capacitor | Download |
11 | Inductor | Download |
12 | Mutual inductor | Download |
13 | Linearity of elements | Download |
14 | Series connection-Voltage sources in series | Download |
15 | Series connection of R, L, C, current source | Download |
16 | Elements in parallel | Download |
17 | Current source in series with an element; Voltage source in parallel with an element | Download |
18 | Extreme cases: Open and short circuits | Download |
19 | Summary | Download |
20 | Voltage controlled voltage source(VCVS) | Download |
21 | Voltage controlled current source(VCCS) | Download |
22 | Current controlled voltage source(CCVS) | Download |
23 | Current controlled current source(CCCS) | Download |
24 | Scaling an element's value using controlled sources | Download |
25 | Example calculation | Download |
26 | Power and energy absorbed by electrical elements | Download |
27 | Power and energy in a resistor | Download |
28 | Power and energy in a capacitor | Download |
29 | Power and energy in an inductor | Download |
30 | Power and energy in a voltage source | Download |
31 | Power and energy in a current source | Download |
32 | Goals of circuit analysis | Download |
33 | Number of independent KCL equations | Download |
34 | Number of independent KVL equations and branch relationships | Download |
35 | Analysis of circuits with a single independent source | Download |
36 | Analysis of circuits with multiple independent sources using superposition | Download |
37 | Superposition: Example | Download |
38 | What is nodal analysis | Download |
39 | Setting up nodal analysis equations | Download |
40 | Structure of the conductance matrix | Download |
41 | How elements appear in the nodal analysis formulation | Download |
42 | Completely solving the circuit starting from nodal analysis | Download |
43 | Nodal analysis example | Download |
44 | Matrix inversion basics | Download |
45 | Nodal analysis with independent voltage sources | Download |
46 | Supernode for nodal analysis with independent voltage sources | Download |
47 | Nodal analysis with VCCS | Download |
48 | Nodal analysis with VCVS | Download |
49 | Nodal analysis with CCVS | Download |
50 | Nodal analysis with CCCS | Download |
51 | Planar circuits | Download |
52 | Mesh currents and their relationship to branch currents | Download |
53 | Mesh analysis | Download |
54 | Mesh analysis with independent current sources-Supermesh | Download |
55 | Mesh analysis with current controlled voltage sources | Download |
56 | Mesh analysis with current controlled current sources | Download |
57 | Mesh analysis using voltage controlled sources | Download |
58 | Nodal analysis versus Mesh analysis | Download |
59 | Superposition theorem | Download |
60 | Pushing a voltage source through a node | Download |
61 | Splitting a current source | Download |
62 | Substitution theorem: Current source | Download |
63 | Substitution theorem: Voltage source | Download |
64 | Substituting a voltage or current source with a resistor | Download |
65 | Extensions to Superposition and Substitution theorem | Download |
66 | Thevenin's theorem | Download |
67 | Worked out example: Thevenin's theorem | Download |
68 | Norton's theorem | Download |
69 | Worked out example: Norton's theorem | Download |
70 | Maximum power transfer theorem | Download |
71 | Preliminaries | Download |
72 | Two port parameters | Download |
73 | y parameters | Download |
74 | y parameters: Examples | Download |
75 | z parameters | Download |
76 | z parameters: Examples | Download |
77 | h parameters | Download |
78 | h parameters: Examples | Download |
79 | g parameters | Download |
80 | g parameters: Examples | Download |
81 | Calculations with a two-port element | Download |
82 | Calculations with a two-port element | Download |
83 | Degenerate cases | Download |
84 | Relationships between different two-port parameters | Download |
85 | Equivalent circuit representation for two ports | Download |
86 | Reciprocity | Download |
87 | Proof of reciprocity of resistive two-ports | Download |
88 | Proof for 4-terminal two-ports | Download |
89 | Reciprocity in terms of different two-port parameters | Download |
90 | Reciprocity in circuits containing controlled sources | Download |
91 | Examples | Download |
92 | Feedback amplifier using an opamp | Download |
93 | Ideal opamp | Download |
94 | Negative feedback around the opamp | Download |
95 | Finding opamp signs for negative feedback | Download |
96 | Example: Determining opamp sign for negative feedback | Download |
97 | Analysis of circuits with opamps | Download |
98 | Inverting amplifier | Download |
99 | Summing amplifier | Download |
100 | Instrumentation amplifier | Download |
101 | Negative resistance and Miller effect | Download |
102 | Finding opamp signs for negative feedback-circuits with multiple opamps | Download |
103 | Opamp supply voltages and saturation | Download |
104 | KCL with an opamp and supply currents | Download |
105 | Circuits with storage elements(capacitors and inductors) | Download |
106 | First order circuit with zero input-natural response | Download |
107 | First order RC circuit with zero input-Example | Download |
108 | First order circuit with a constant input | Download |
109 | General form of the first order circuit response | Download |
110 | First order RC circuit with a constant input-Example | Download |
111 | First order circuit with piecewise constant input | Download |
112 | First order circuit with piecewise constant input-Example | Download |
113 | First order circuit-Response of arbitrary circuit variables | Download |
114 | Summary: Computing first order circuit response | Download |
115 | Does a capacitor block DC? | Download |
116 | Finding the order of a circuit | Download |
117 | First order RC circuits with discontinuous capacitor voltages | Download |
118 | Summary: Computing first order circuit response with discontinuities | Download |
119 | First order RL circuits | Download |
120 | First order RL circuit with discontinuous inductor current-Example | Download |
121 | First order RC circuit with an exponential input | Download |
122 | First order RC response to its own natural response | Download |
123 | First order RC response to a sinusoidal input | Download |
124 | First order RC response to a sinusoidal input-via the complex exponential | Download |
125 | Summary: Linear circuit response to sinusoidal input via the complex exponential | Download |
126 | Three methods of calculating the sinusoidal steady state response | Download |
127 | Calculating the total response including initial conditions | Download |
128 | Why are sinusoids used in measurement? | Download |
129 | Second order system natural response | Download |
130 | Second order system as a cascade of two first order systems | Download |
131 | Second order system natural response-critically damped and underdamped | Download |
132 | Generalized form of a second order system | Download |
133 | Numerical example | Download |
134 | Series and parallel RLC circuits | Download |
135 | Forced response of a second order system | Download |
136 | Steady state response calculation and Phasors | Download |
137 | Phasors cont'd | Download |
138 | Magnitude and Phase plots | Download |
139 | Magnitude and phase plotes of a second order system | Download |
140 | Maximum power transfer and Conjugate matching | Download |
Sl.No | Chapter Name | Tamil |
---|---|---|
1 | Preliminaries | Download |
2 | Current | Download |
3 | Voltage | Download |
4 | Electrical elements and circuits | Download |
5 | Kirchhoff's current law(KCL) | Download |
6 | Kirchhoff's voltage law(KVL) | Download |
7 | Voltage source | Download |
8 | Current source | Download |
9 | Resistor | Download |
10 | Capacitor | Download |
11 | Inductor | Download |
12 | Mutual inductor | Download |
13 | Linearity of elements | Download |
14 | Series connection-Voltage sources in series | Download |
15 | Series connection of R, L, C, current source | Download |
16 | Elements in parallel | Download |
17 | Current source in series with an element; Voltage source in parallel with an element | Download |
18 | Extreme cases: Open and short circuits | Download |
19 | Summary | Download |
20 | Voltage controlled voltage source(VCVS) | Download |
21 | Voltage controlled current source(VCCS) | Download |
22 | Current controlled voltage source(CCVS) | Download |
23 | Current controlled current source(CCCS) | Download |
24 | Scaling an element's value using controlled sources | Download |
25 | Example calculation | Download |
26 | Power and energy absorbed by electrical elements | Download |
27 | Power and energy in a resistor | Download |
28 | Power and energy in a capacitor | Download |
29 | Power and energy in an inductor | Download |
30 | Power and energy in a voltage source | Download |
31 | Power and energy in a current source | Download |
32 | Goals of circuit analysis | Download |
33 | Number of independent KCL equations | Download |
34 | Number of independent KVL equations and branch relationships | Download |
35 | Analysis of circuits with a single independent source | Download |
36 | Analysis of circuits with multiple independent sources using superposition | Download |
37 | Superposition: Example | Download |
38 | What is nodal analysis | Download |
39 | Setting up nodal analysis equations | Download |
40 | Structure of the conductance matrix | Download |
41 | How elements appear in the nodal analysis formulation | Download |
42 | Completely solving the circuit starting from nodal analysis | Download |
43 | Nodal analysis example | Download |
44 | Matrix inversion basics | Download |
45 | Nodal analysis with independent voltage sources | Download |
46 | Supernode for nodal analysis with independent voltage sources | Download |
47 | Nodal analysis with VCCS | Download |
48 | Nodal analysis with VCVS | Download |
49 | Nodal analysis with CCVS | Download |
50 | Nodal analysis with CCCS | Download |
51 | Planar circuits | Download |
52 | Mesh currents and their relationship to branch currents | Download |
53 | Mesh analysis | Download |
54 | Mesh analysis with independent current sources-Supermesh | Download |
55 | Mesh analysis with current controlled voltage sources | Download |
56 | Mesh analysis with current controlled current sources | Download |
57 | Mesh analysis using voltage controlled sources | Download |
58 | Nodal analysis versus Mesh analysis | Download |
59 | Superposition theorem | Download |
60 | Pushing a voltage source through a node | Download |
61 | Splitting a current source | Download |
62 | Substitution theorem: Current source | Download |
63 | Substitution theorem: Voltage source | Download |
64 | Substituting a voltage or current source with a resistor | Download |
65 | Extensions to Superposition and Substitution theorem | Download |
66 | Thevenin's theorem | Download |
67 | Worked out example: Thevenin's theorem | Download |
68 | Norton's theorem | Download |
69 | Worked out example: Norton's theorem | Download |
70 | Maximum power transfer theorem | Download |
71 | Preliminaries | Download |
72 | Two port parameters | Download |
73 | y parameters | Download |
74 | y parameters: Examples | Download |
75 | z parameters | Download |
76 | z parameters: Examples | Download |
77 | h parameters | Download |
78 | h parameters: Examples | Download |
79 | g parameters | Download |
80 | g parameters: Examples | Download |
81 | Calculations with a two-port element | Download |
82 | Calculations with a two-port element | Download |
83 | Degenerate cases | Download |
84 | Relationships between different two-port parameters | Download |
85 | Equivalent circuit representation for two ports | Download |
86 | Reciprocity | Download |
87 | Proof of reciprocity of resistive two-ports | Download |
88 | Proof for 4-terminal two-ports | Download |
89 | Reciprocity in terms of different two-port parameters | Download |
90 | Reciprocity in circuits containing controlled sources | Download |
91 | Examples | Download |
92 | Feedback amplifier using an opamp | Download |
93 | Ideal opamp | Download |
94 | Negative feedback around the opamp | Download |
95 | Finding opamp signs for negative feedback | Download |
96 | Example: Determining opamp sign for negative feedback | Download |
97 | Analysis of circuits with opamps | Download |
98 | Inverting amplifier | Download |
99 | Summing amplifier | Download |
100 | Instrumentation amplifier | Download |
101 | Negative resistance and Miller effect | Download |
102 | Finding opamp signs for negative feedback-circuits with multiple opamps | Download |
103 | Opamp supply voltages and saturation | Download |
104 | KCL with an opamp and supply currents | Download |
105 | Circuits with storage elements(capacitors and inductors) | Download |
106 | First order circuit with zero input-natural response | Download |
107 | First order RC circuit with zero input-Example | Download |
108 | First order circuit with a constant input | Download |
109 | General form of the first order circuit response | Download |
110 | First order RC circuit with a constant input-Example | Download |
111 | First order circuit with piecewise constant input | Download |
112 | First order circuit with piecewise constant input-Example | Download |
113 | First order circuit-Response of arbitrary circuit variables | Download |
114 | Summary: Computing first order circuit response | Download |
115 | Does a capacitor block DC? | Download |
116 | Finding the order of a circuit | Download |
117 | First order RC circuits with discontinuous capacitor voltages | Download |
118 | Summary: Computing first order circuit response with discontinuities | Download |
119 | First order RL circuits | Download |
120 | First order RL circuit with discontinuous inductor current-Example | Download |
121 | First order RC circuit with an exponential input | Download |
122 | First order RC response to its own natural response | Download |
123 | First order RC response to a sinusoidal input | Download |
124 | First order RC response to a sinusoidal input-via the complex exponential | Download |
125 | Summary: Linear circuit response to sinusoidal input via the complex exponential | Download |
126 | Three methods of calculating the sinusoidal steady state response | Download |
127 | Calculating the total response including initial conditions | Download |
128 | Why are sinusoids used in measurement? | Download |
129 | Second order system natural response | Download |
130 | Second order system as a cascade of two first order systems | Download |
131 | Second order system natural response-critically damped and underdamped | Download |
132 | Generalized form of a second order system | Download |
133 | Numerical example | Download |
134 | Series and parallel RLC circuits | Download |
135 | Forced response of a second order system | Download |
136 | Steady state response calculation and Phasors | Download |
137 | Phasors cont'd | Download |
138 | Magnitude and Phase plots | Download |
139 | Magnitude and phase plotes of a second order system | Download |
140 | Maximum power transfer and Conjugate matching | Download |
Sl.No | Chapter Name | Telugu |
---|---|---|
1 | Preliminaries | Download |
2 | Current | Download |
3 | Voltage | Download |
4 | Electrical elements and circuits | Download |
5 | Kirchhoff's current law(KCL) | Download |
6 | Kirchhoff's voltage law(KVL) | Download |
7 | Voltage source | Download |
8 | Current source | Download |
9 | Resistor | Download |
10 | Capacitor | Download |
11 | Inductor | Download |
12 | Mutual inductor | Download |
13 | Linearity of elements | Download |
14 | Series connection-Voltage sources in series | Download |
15 | Series connection of R, L, C, current source | Download |
16 | Elements in parallel | Download |
17 | Current source in series with an element; Voltage source in parallel with an element | Download |
18 | Extreme cases: Open and short circuits | Download |
19 | Summary | Download |
20 | Voltage controlled voltage source(VCVS) | Download |
21 | Voltage controlled current source(VCCS) | Download |
22 | Current controlled voltage source(CCVS) | Download |
23 | Current controlled current source(CCCS) | Download |
24 | Scaling an element's value using controlled sources | Download |
25 | Example calculation | Download |
26 | Power and energy absorbed by electrical elements | Download |
27 | Power and energy in a resistor | Download |
28 | Power and energy in a capacitor | Download |
29 | Power and energy in an inductor | Download |
30 | Power and energy in a voltage source | Download |
31 | Power and energy in a current source | Download |
32 | Goals of circuit analysis | Download |
33 | Number of independent KCL equations | Download |
34 | Number of independent KVL equations and branch relationships | Download |
35 | Analysis of circuits with a single independent source | Download |
36 | Analysis of circuits with multiple independent sources using superposition | Download |
37 | Superposition: Example | Download |
38 | What is nodal analysis | Download |
39 | Setting up nodal analysis equations | Download |
40 | Structure of the conductance matrix | Download |
41 | How elements appear in the nodal analysis formulation | Download |
42 | Completely solving the circuit starting from nodal analysis | Download |
43 | Nodal analysis example | Download |
44 | Matrix inversion basics | Download |
45 | Nodal analysis with independent voltage sources | Download |
46 | Supernode for nodal analysis with independent voltage sources | Download |
47 | Nodal analysis with VCCS | Download |
48 | Nodal analysis with VCVS | Download |
49 | Nodal analysis with CCVS | Download |
50 | Nodal analysis with CCCS | Download |
51 | Planar circuits | Download |
52 | Mesh currents and their relationship to branch currents | Download |
53 | Mesh analysis | Download |
54 | Mesh analysis with independent current sources-Supermesh | Download |
55 | Mesh analysis with current controlled voltage sources | Download |
56 | Mesh analysis with current controlled current sources | Download |
57 | Mesh analysis using voltage controlled sources | Download |
58 | Nodal analysis versus Mesh analysis | Download |
59 | Superposition theorem | Download |
60 | Pushing a voltage source through a node | Download |
61 | Splitting a current source | Download |
62 | Substitution theorem: Current source | Download |
63 | Substitution theorem: Voltage source | Download |
64 | Substituting a voltage or current source with a resistor | Download |
65 | Extensions to Superposition and Substitution theorem | Download |
66 | Thevenin's theorem | Download |
67 | Worked out example: Thevenin's theorem | Download |
68 | Norton's theorem | Download |
69 | Worked out example: Norton's theorem | Download |
70 | Maximum power transfer theorem | Download |
71 | Preliminaries | Download |
72 | Two port parameters | Download |
73 | y parameters | Download |
74 | y parameters: Examples | Download |
75 | z parameters | Download |
76 | z parameters: Examples | Download |
77 | h parameters | Download |
78 | h parameters: Examples | Download |
79 | g parameters | Download |
80 | g parameters: Examples | Download |
81 | Calculations with a two-port element | Download |
82 | Calculations with a two-port element | Download |
83 | Degenerate cases | Download |
84 | Relationships between different two-port parameters | Download |
85 | Equivalent circuit representation for two ports | Download |
86 | Reciprocity | Download |
87 | Proof of reciprocity of resistive two-ports | Download |
88 | Proof for 4-terminal two-ports | Download |
89 | Reciprocity in terms of different two-port parameters | Download |
90 | Reciprocity in circuits containing controlled sources | Download |
91 | Examples | Download |
92 | Feedback amplifier using an opamp | Download |
93 | Ideal opamp | Download |
94 | Negative feedback around the opamp | Download |
95 | Finding opamp signs for negative feedback | Download |
96 | Example: Determining opamp sign for negative feedback | Download |
97 | Analysis of circuits with opamps | Download |
98 | Inverting amplifier | Download |
99 | Summing amplifier | Download |
100 | Instrumentation amplifier | Download |
101 | Negative resistance and Miller effect | Download |
102 | Finding opamp signs for negative feedback-circuits with multiple opamps | Download |
103 | Opamp supply voltages and saturation | Download |
104 | KCL with an opamp and supply currents | Download |
105 | Circuits with storage elements(capacitors and inductors) | Download |
106 | First order circuit with zero input-natural response | Download |
107 | First order RC circuit with zero input-Example | Download |
108 | First order circuit with a constant input | Download |
109 | General form of the first order circuit response | Download |
110 | First order RC circuit with a constant input-Example | Download |
111 | First order circuit with piecewise constant input | Download |
112 | First order circuit with piecewise constant input-Example | Download |
113 | First order circuit-Response of arbitrary circuit variables | Download |
114 | Summary: Computing first order circuit response | Download |
115 | Does a capacitor block DC? | Download |
116 | Finding the order of a circuit | Download |
117 | First order RC circuits with discontinuous capacitor voltages | Download |
118 | Summary: Computing first order circuit response with discontinuities | Download |
119 | First order RL circuits | Download |
120 | First order RL circuit with discontinuous inductor current-Example | Download |
121 | First order RC circuit with an exponential input | Download |
122 | First order RC response to its own natural response | Download |
123 | First order RC response to a sinusoidal input | Download |
124 | First order RC response to a sinusoidal input-via the complex exponential | Download |
125 | Summary: Linear circuit response to sinusoidal input via the complex exponential | Download |
126 | Three methods of calculating the sinusoidal steady state response | Download |
127 | Calculating the total response including initial conditions | Download |
128 | Why are sinusoids used in measurement? | Download |
129 | Second order system natural response | Download |
130 | Second order system as a cascade of two first order systems | Download |
131 | Second order system natural response-critically damped and underdamped | Download |
132 | Generalized form of a second order system | Download |
133 | Numerical example | Download |
134 | Series and parallel RLC circuits | Download |
135 | Forced response of a second order system | Download |
136 | Steady state response calculation and Phasors | Download |
137 | Phasors cont'd | Download |
138 | Magnitude and Phase plots | Download |
139 | Magnitude and phase plotes of a second order system | Download |
140 | Maximum power transfer and Conjugate matching | Download |