GATE Instrumentation Engineering (Batch 5)
-
Introduction to Analog Circuits
2.44
-
Diode and Its Equation
6.38
-
Diode Parameters
3.32
-
Diode Clipper Circuits - A
11.55
-
Diode Clipper Circuits - B
7.45
-
Biased Clipper
9.09
-
Clipper Using Zener Diode
13.42
-
Introduction to Number System
10.55
-
Number System Conversion
24.04
-
Numericals Based on Number System-Part 1
21.36
-
Numericals Based on Number System-Part 2
18.14
-
Complement Number Representation
19.31
-
Clamper Using Diode
22.16
-
Voltage Doubler /Tripler/Quadrupler
10.57
-
Rectifier Using Diode
12.4
-
Signed Number Representation for Binary
32
-
Important Properties of 1's and 2's Complement Numbers
17.43
-
Concept of Overflow and Sign Extension
18.52
-
Subtraction Using R's and (R-1)'s Complement Method
34.04
-
DC Load Line of Diode
7.55
-
Diode Numerical Session 1
13.39
-
Diode Numerical Session 2
8.41
-
Diode Numerical Session 3
12.15
-
Diode Numerical Session 4
9.36
-
Diode Numerical Session 5
8.11
-
Binary Codes
30.06
-
Generation of Gray Code
14.41
-
Conversion of Binary to Gray and Gray to Binary Codes
12.57
-
Gate Numerical on Number System Part 1
28
-
Gate Numerical on Number System Part 2
25.07
-
BJT Introduction
9.04
-
BJT CE Configuration
11.03
-
BJT BJT Q Point & Stability
13.51
-
BJT Biasing Circuits
15.01
-
Boolean Laws
25.16
-
Concept of Minterms and Maxterm
22.32
-
Problems Based on Minterms and Maxterms
32.37
-
Complementing the Function
11.25
-
BJT Small Signal Models
16.38
-
BJT Small Signal AC Analysis
13.05
-
BJT Frequency Response
24.01
-
Introduction to K-Map
15.49
-
Grouping Techniques in K-Map
31.56
-
Numerical Based on Boolean Algebra
28.24
-
BJT As a Switch & CB/CC Amplifier
10.36
-
BJT Numerical Session 1
16.11
-
BJT Numerical Session 2
11
-
BJT Numerical Session 3
11.13
-
BJT Numerical Session 4
8.35
-
BJT Numerical Session 5
9.56
-
Basic Logic Gates
6.26
-
Universal Logic Gates
16.25
-
Numericals Based on Universal Logic Gates
22.3
-
Ex-OR Gate
13.37
-
Important Properties of Ex-OR Gate
20.02
-
Gate Numericals on Logic Gates
36.04
-
Introduction to Timer IC 555
10.54
-
555 MMV
11.01
-
555 AMV
10.35
-
Introduction to Combinational Logic Circuit
11.24
-
Half Adder
7.14
-
Half Subtractor
7.17
-
Full Adder
12.23
-
Implementing Full Adder with Half Adder
10.46
-
Concept of Comparator
20.47
-
4-Bit Parallel/ Ripple Adder
15.55
-
4-Bit Serial Adder
18.46
-
MOSFET Basics
12.1
-
MOSFET Biasing
9.3
-
MOSFET AC Model & Amplifier
10.51
-
As Square Wave Generator
4.33
-
Timer-555 : Numerical Session 1
7.07
-
Timer-555 : Numerical Session 2
6.28
-
4-Bit Adder/ Subtractor
11.03
-
Encoder
8.11
-
Decoder
11.36
-
Full Adder Using 3:8 Decoder
14.56
-
Decoder Expansion
17.34
-
Concept of Demultiplexer
7.37
-
Decoder Using Demultiplexer
6.35
-
Concept of Multiplexer
8.47
-
Multiplexer Expansion
14.4
-
CMOS using MOSFET
9.44
-
MOSFET Frequency Response
7.49
-
MOSFET Numerical Session 1
10.05
-
MOSFET Numerical Session 2
7.5
-
MOSFET Numerical Session 3
10
-
MOSFET Numerical Session 4
8.26
-
MOSFET Numerical Session 5
4.21
-
Implementing 2:1 Mux Using 4:1 Mux
8.4
-
2:1 Multiplexer as Universal Logic Circuit
16.03
-
4:1 Multiplexer as Universal Logic Gate
5.52
-
Gate Problems on Mux, Decoder and Decoder
29.13
-
Introduction to Sequential Logic Circuit
14.44
-
NOR Latch
14.54
-
NAND Latch
10.32
-
Introduction
14.57
-
Comparison and Analysis of Negative Feedback Amplifier
16.44
-
Negative Feedback Numerical Session 1
7.06
-
Problem with RS Latch
17.43
-
Delay Latch/Flip Flop
4.49
-
JK Latch and T- Latch
7.48
-
Excitation Table for all Latches/Flip Flops
19.52
-
Latch/Flip Flop Conversion Concept
23.22
-
SR Latch to JK Latch Conversion
18.09
-
DA using BJT
14.37
-
DA Gain Equation
8.47
-
Negative Feedback Numerical Session 2
8.16
-
Negative Feedback Numerical Session 3
8.28
-
Negative Feedback Numerical Session 4
6
-
D Latch to JK Latch Conversion
8.58
-
D Latch to T Latch Conversion
6.46
-
Concept of Triggering
14.17
-
Difference Between Latch and Flipflop
10.59
-
Behaviour of Flip Flop in Toggle Mode
13.19
-
Race Around Condition in JK Latch
14.44
-
Master-Slave JK Flip Flop
9.03
-
Introduction to Shift Register
9.17
-
CCS and CM
11.36
-
DA Using MOSFET and CCS & CM
8.59
-
DA Numerical Session 1
13.37
-
DA Numerical Session 2
7.34
-
DA Numerical Session 3
4.53
-
Classification of Shift Register
28.48
-
Ring Counter
17.46
-
Twisted Ring Counter
14.12
-
Introduction to Asynchronous Counter
10.03
-
Asynchronous Up Counter
15.14
-
Asynchronous Down Counter
19.45
-
Introduction and Two Stage Analysis
25.48
-
Cascode Amplifier and Darlington Amplifier
15.25
-
Asynchronous Up/Down Counter
14.1
-
Introduction To Asynchronous MOD Counter
17.3
-
Designing Asynchronous MOD 10 Counter
11.53
-
Introduction to Synchronous Counter
11.55
-
Designing Synchronous Counter - Part 1
12.59
-
Designing Synchronous Counter - Part 2
15.03
-
Finite State Machine
10.45
-
Three Stage Amplifier
5.24
-
Multistage Amplifier Numerical Session 1
15.54
-
Multistage Amplifier Numerical Session 2
8.28
-
Multistage Amplifier Numerical Session 3
12.18
-
Multistage Amplifier Numerical Session 4
8.43
-
Non Overlapping Sequence Detector
16.52
-
Overlapping Sequence Detector
28.48
-
Gate Numericals Based on Sequential Logic Circuit
33.18
-
Gate Numericals on FSM
22.36
-
OP-AMP Introduction
17.14
-
OP-AMP As Square Wave Generator
9.12
-
OP-AMP First Order Active Filters
15.43
-
Introduction to ADC and DAC
10.4
-
Concept of Specifications of DAC
16.53
-
Binary Weighted Resistor Type DAC
18.53
-
R-2R Ladder Type DAC
7.43
-
Numerical on DAC
14
-
Counter Type ADC
23.27
-
Successive Approximation Register Type DAC
20.18
-
Flash Type ADC
28.52
-
OP-AMP Second Order Active Filters and Instrumentation Amplifier
13.01
-
OP-AMP Oscillator and Triangular Wave Generator
14.57
-
OP-AMP Log Circuits and Precision Rectifier
16.14
-
Introduction to Microprocessor
12.45
-
Structure of Memory
10.59
-
Significance of System Bus
23.51
-
Features of Microprocessor 8085
28.46
-
Register Organization of Microprocessor 8085
19.4
-
Flag Register of 8085
25.41
-
OP-AMP SCHMITT Trigger Circuits
9.42
-
OP-AMP As Comparator
4.45
-
OP-AMP and Application Numerical Session 1
7.32
-
OP-AMP and Application Numerical Session 2
10.23
-
OP-AMP and Application Numerical Session 3
10.03
-
Numerical on Memory - Part 1
15.53
-
Generation of Control Signals
18.1
-
IO Mapped IO & Memory Mapped IO
13.48
-
Numerical on Memory - Part 2
40.21
-
Instruction Set of 8085 - Part 1
25.15
-
Numerical Session 1
8.25
-
Numerical Session 2
8.01
-
Numerical session 3
9.29
-
Numerical session 4
8.37
-
OP-AMP and Application Numerical Session 4
7.17
-
OP-AMP and Application Numerical Session 5
11.25
-
Instruction Set of 8085 - Part 2
32.36
-
Concept of DAA instruction
13.47
-
Rotate Instructions
14.31
-
Memory Read and Memory Write Machine Cycles
15.58
-
Concept of Machine Cycles and T-States
14.01
-
Identifying Machine Cycles - Part 1
12.37
-
Identifying Machine Cycles - Part 2
26
-
Definition and Parameters
10.04
-
Zener Voltage Regulator
11.14
-
Voltage Regulator Numerical Session 1
11.23
-
Voltage Regulator Numerical Session 2
7.59
-
Generation of Software Delay
21.06
-
Numerical on Software Delay
8.41
-
Numerical on Programming 8085 Microprocessor
26
-
Voltage Regulator Numerical Session 3
7.47
-
Voltage Regulator Numerical Session 4
6.57
-
Voltage Regulator Numerical Session 5
10.17
-
Introduction
10.23
-
Class A Power Amplifier
12.53
-
Class B Power Amplifier
12.13
-
Class AB Power Amplifier
6.35
-
Class C PA and Heat Sink
9.25
-
Comparison
5.17
-
Power Amplifier Numerical Session 1
7.41
-
Power Amplifier Numerical Session 2
6.55
-
Power Amplifier Numerical Session 3
5.07
-
Types of Elements
13.57
-
Energy Sources
12.03
-
Problem Based on Energy Sources
8.18
-
Kirchoff's Law
18.32
-
Introduction of Control System
37.26
-
Need of Laplace Transform in Control System
31.05
-
Problems on Laplace Transform
11.14
-
Transfer Function - Part 1
28.21
-
Equivalent Circuits
26.04
-
Problems Based on Equivalent Cicuits Part 1
22.02
-
Problems Based on Equivalent Cicuits Part 2
24.34
-
Energy and Power for R, L and C
9.18
-
Problems Based on Energy and Power
36.42
-
Transfer Function - Part 2
41.01
-
Problems Based on Transfer Function
37.05
-
Initial Value and Final Value Theorem
43.48
-
Solving DC Circuits Using KVL/KCL - Part1
9.26
-
Solving DC Circuits Using KVL/KCL - Part2
23.01
-
Solving DC Circuits Using KVL/KCL - Part3
26.22
-
Solving DC Circuits Using KVL/KCL - Part4
20.03
-
Block Diagram Reduction Rules
45.37
-
Problem Based on Block Diagram Reduction - Part 1
14.51
-
Problem Based on Block Diagram Reduction - Part 2
19.59
-
Introduction to Signal Flow Graph
24.5
-
Problem Based on Signal Flow Graph - Part 1
24.38
-
Problem Based on Signal Flow Graph - Part 2
16.44
-
Problem Based on Signal Flow Graph - Part 3
30.01
-
Introduction to Thevenin's and Norton's Theorem
17.43
-
Problems on TEC and NEC- Part 1
21.15
-
Problems on TEC and NEC- Part 2
24.19
-
GATE Problem Based on Block Diagram and SFG
22.53
-
Introduction to Time Domain Analysis
29.14
-
Standard 1st Order System Analysis
23.24
-
Introduction to Superposition Theorem
11.42
-
Introduction to Maximum Power Transfer Theorem
40.58
-
Standard 2nd Order System Analysis - Part 1
54.23
-
Standard 2nd Order System Analysis - Part 2
47.58
-
Problems on M.P.T. - Part 1
16.32
-
Introduction to Two Port Network
23.16
-
Equivalent Circuits in Two Port Network
21.33
-
Standard 2nd Order System Analysis - Part 3
25.02
-
Time Domain Specifications
20.5
-
Location of Poles and Time Domain Specifications
15.49
-
Problems on 1st Order and 2nd Order Systems
43.46
-
Interconnection of Two Port Networks
18.48
-
Symmetricity and Reciprocity in Two Port Network
34
-
Introduction to Steady State Error
7.53
-
Static Error Analysis - Part 1
27.19
-
Static Error Analysis - Part 2
49.51
-
Standard Two Port Networks and Parameters
20.57
-
Numericals on Two Port Network - Part 1
28.43
-
Numericals on Two Port Network - Part 2
20.35
-
Numericals on Two Port Network - Part 3
30.24
-
Dynamic Error analysis
26.55
-
Problems on Error Analysis
46.51
-
Introduction to Transient Analysis
22.46
-
Behaviour of R, L and C for t>0
11.15
-
Numericals on Transients - Part 1
15.25
-
Concept of Stability
8.1
-
Routh Hurwitz's Criterion Part 1
10.58
-
Routh Hurwitz's Criterion Part 2
50.15
-
Routh Hurwitz's Criterion Part 3
23.27
-
Numericals on Transients - Part 2
51.42
-
Routh Hurwitz's Criterion Part 4
16.23
-
Introduction to Root Locus
22.44
-
Root Locus - Part 1
47.28
-
Root Locus - Part 2
25.04
-
Numericals on Transients - Part 3
28.28
-
Numericals on Transients - Part 4
35.43
-
Root Locus - Part 3
38.47
-
Problems on Routh Hurwitz's Criterion
25.03
-
Problems on Root Locus
20.41
-
Introduction to Laplace Transformation
12.05
-
Application of Laplace Transform in Electrical Circuits
13.3
-
Numericals on Laplace Transformation - Part 1
18.09
-
Numericals on Laplace Transformation - Part 2
25.58
-
Introduction to Frequency Domain Analysis
24.02
-
FDA for 2nd Order System
38.03
-
Polar Plot - Part 1
24.31
-
Polar Plot - Part 2
57.45
-
A.C. Fundamentals
8.4
-
Concept of Average and RMS Values
17.26
-
Numericals on Average and RMS Values
25.27
-
Polar Plot - Part 3
37.45
-
Polar Plot - Part 4
48.48
-
Polar Plot - Part 5
57.31
-
Vector Representation
15.57
-
Behaviour of R, L and C in A.C. Circuits
22.11
-
RL Series Circuit
10.59
-
RC Series Circuit
12.45
-
Stability in Frequency Domain
9.42
-
Nyquist Plot - Part 1
41.13
-
Nyquist Plot - Part 2
16.37
-
Nyquist Stability Criteria
28.36
-
RLC Series Circuit
9.49
-
Classification of Power
14.06
-
Numericals on Fundamentals of A.C. Circuit - Part 1
24.35
-
Numericals on Fundamentals of A.C. Circuit - Part 2
19.02
-
Examples on Nyquist Stability Criteria
42.17
-
Numericals on Nyquist Stability Criteria
31.32
-
Relative Stability in Frequency Domain
40.22
-
Numericals on Fundamentals of A.C. Circuit - Part 3
19.19
-
Numericals on Fundamentals of A.C. Circuit - Part 4
14.49
-
Numericals on Fundamentals of A.C. Circuit - Part 5
16.35
-
Introduction to Bode Plot
37.2
-
How to Draw Bode Plot
56.19
-
Numericals on Bode plot
12.26
-
Relative Stability using Bode Plot
11.5
-
Numericals on Fundamentals of A.C. Circuit - Part 6
20.14
-
Series Resonance in A.C. Circuits
24.06
-
Parallel RL Circuit
9.44
-
Introduction to Controllers and Compensators
12.07
-
Compensators
49.06
-
Controllers
21.4
-
Numericals on Controllers and Compensators
10.5
-
Parallel RC Circuit
8.01
-
Parallel RLC Circuit
7.06
-
Parallel Resonance in A.C. Circuits - Part 1
24.15
-
Parallel Resonance in A.C. Circuits - Part 2
12.38
-
Introduction to State Space Analysis
69.29
-
State Space Analysis in Electrical Circuits
27.01
-
Concept of Q-Factor
4.2
-
Q-Factor Calculation in RL, RC and RLC Circuits
9.43
-
Relation Between Q Factor and Bandwidth
6.22
-
GATE Numericals on A.C. Circuits - Part 1
31.44
-
Transfer Function from State Space Model
48.37
-
Introduction to Canonical Forms
12.52
-
Controllable Canonical Form
45.24
-
GATE Numericals on A.C. Circuits - Part 2
17.3
-
GATE Numericals on A.C. Circuits - Part 3
19
-
GATE Numericals on A.C. Circuits - Part 4
30.39
-
Observable Canonical Form
9.26
-
Examples on Controllable Canonical Form and Observable Canonical Form
16.49
-
Diagonal Canonical Form
25.24
-
Jordan’s Canonical Form
12.39
-
Examples on Diagonal Canonical Form and Jordan Canonical Form
37.29
-
Introduction to Graph Theory
19.22
-
Incidence, Cutset and Tieset Marix
29.17
-
GATE Numericals on Graph Theory - Part 1
12.48
-
GATE Numericals on Graph Theory - Part 2
12.45
-
Stability Using State Space
25.03
-
Solution to State Space Equations (Inverse Laplace Transform Approach)
58.19
-
Solution to State Space Equations (Cayley Hamilton Theorem)
39.06
-
Introduction to Coupling Factor and Mutual Inductance
18.24
-
Numericals on Magnetically Coupled Circuit
14.36
-
Solution to State Space Equations When Input is Non-Zero
50.05
-
Concept of Controllability and Observability
23.36
-
Numericals on State Space Analysis
36.29
-
Numericals Part 01
60.01
-
Numericals Part 02
41.26
-
Numericals Part 03
26.36
-
Numericals Part 04
46.42
-
Numericals Part 05
22.05
-
Introduction to Optical Instrumentation
5.06
-
Reflection and Refraction
11.21
-
Course Introduction and Weightage for GATE Exam
7.33
-
Cartesian Coordinate System
11.29
-
Line Integration, Surface Integration and Volume Integration in Cartesian Coordinate System
13.41
-
Numerical 1 on Line Integration
3.02
-
Numerical 1 on Surface Integration
2.36
-
Numerical 1 on Volume Integration
2.26
-
Concept of Signal
33.03
-
Operation on Continuous Time Signal - Part 1
36.07
-
Operation on Continuous Time Signal - Part 2
21.27
-
Static Characteristics of Measuring Instruments: Static Error, Accuracy
15.24
-
Numerical on Accuracy
9.49
-
Static Characteristics of Measuring Instruments: Precision, Sensitivity
9.09
-
Numerical on Sensitivity
14.01
-
Loading Effect
4.58
-
Cylindrical Coordinate System
12.50
-
Vector Conversion Between Cylindrical and Cartesian Coordinate System
8.16
-
Numerical 1 for Vector Conversion Between Cartesian and Cylindrical Coordinate System
3.15
-
Line Integration, Surface Integration and Volume Integration in Cylindrical Coordinate System
6.49
-
Numerical 2 on Line Integration
7.27
-
Numerical 1 Based on Snell's Law
4.05
-
Numerical 2 Based on Snell's Law
3.16
-
Numerical 3 Based on Snell's Law
4.55
-
Numerical Based on Signal
35.49
-
Elementary Continuous Time Signals
8.04
-
Operation on Step Signal
22.14
-
Numericals on Step Signal
13.1
-
Generation of Signum Function
24.07
-
Static Characteristics of Measuring Instruments: Resolution, Hysteresis Error, Dead Time, Dead Zone and Linearity
8.06
-
Numerical on Resolution
4.04
-
Dynamic Characteristics of Measuring Instruments: Speed of Response, Fidelity and Overshoot
8.47
-
Types of Static Errors
13.32
-
Numerical on Error Analysis - Part 1
41.28
-
Numerical on Error Analysis - Part 2
25.45
-
Numerical 2 on Surface Integration
9.43
-
Spherical Coordinate System
10.06
-
Vector Conversion Between Spherical and Cartesian Coordinate System
2.36
-
Numerical 1 for Vector Conversion Between Spherical and Cartesian Coordinate System
3.15
-
Numerical 4 Based on Snell's Law
3.45
-
Numerical 5 Based on Relative Refractive Index
1.47
-
Total Internal Reflection
10
-
Generation of DC Signal and GATE Function
13.56
-
Elementary Continuous Time Signal (Impulse Signal)
17.29
-
Elementary Continuous Time Signal (Ramp Signal)
14.26
-
Numericals on Elementary Continuous Time Signals
18.09
-
Interrelationship Between Elementary Continuous Time Signal
11.45
-
Operations with Continuous Time Impulse Signal
14.31
-
Classification of Electrical Instruments
11.13
-
Torques in Indicating Instruments
9.3
-
Divergence of Vector and Divergence Theorem
8.40
-
Numerical 1 on Divergence
1.47
-
Numerical 2 on Divergence
2.33
-
Numerical 1 on Divergence Theorem
2.53
-
Numerical 2 on Divergence Theorem
3.32
-
Curl and Stoke's Theorem
6.03
-
Numerical 1 on Curl
2.48
-
Numerical 2 on Curl
2.33
-
Basic of Optical Fiber
6.51
-
Advantages of Optical Fiber
5.57
-
Product Property of Continuous Time Impulse Signal
11.2
-
Elementary Discrete Time Signals - Part 1 (Unit Impulse)
7.58
-
Elementary Discrete Time Signals - Part 2 (Unit Step)
7.35
-
Elementary Discrete Time Signals - Part 3 (Unit Ramp)
6.27
-
Elementary Discrete Time Signals - Part 4 (Exponential Signal)
7.28
-
Classification of Signals - Part 1 (Even and Odd)
29.08
-
Classification of Signals - Part 2 (Even Conjugate and Odd Conjugate)
23.05
-
Deflecting Torque
9.11
-
Controlling Torque
8.25
-
Damping Torque
12.51
-
Numerical on Torque
3.45
-
Permanent Magnet Moving Coil (PMMC) Instrument
15.38
-
Numerical 1 on PMMC Instrument
1.45
-
Extension of Range of PMMC Ammeter
6.5
-
Numerical 1 on Ammeter Shunts
3.01
-
Numerical 2 on PMMC Ammeter
2.57
-
Numerical 1 on Stoke's Theorem
5.14
-
Gradient of Scalar
2.59
-
Numerical 1 on Gradient
3.15
-
Numerical 2 on Gradient
1.35
-
Losses in Optical Fiber
10.51
-
Classification of Signals - Part 3 (Periodic and Nonperiodic Signals)
42.22
-
Numericals Based on Periodicity of Signal
36.1
-
Classification of Signals - Part 4 (Energy and Power)
16.54
-
Extension of Range of PMMC Voltmeter Series Multipliers
4.58
-
Numerical on Voltmeter Series Multipliers
6.59
-
Numerical on Loading Effect in Voltmeter
5.15
-
Moving Iron (MI) Instruments: Attraction Type MI Instruments
21.45
-
Repulsion Type MI Instruments
4.21
-
Extension of Range of MI Ammeter
8.26
-
Numerical 1 on MI Instrument
5.45
-
Condition For Linear Scale in MI Instrument
4.04
-
Numerical 2 on MI Instrument
5.53
-
Introduction and Coulomb's Law
6.45
-
Numerical 1 on Coulomb's Law
2.45
-
Electric Field Intensity
2.16
-
Numerical 1 on Electric Field Intensity
2.02
-
Distributed Charges Line Charge Surface Charge and Volume Charge
5
-
Electric Field Intensity Due to Line Charge
7.54
-
Numerical 1 on Line Charge Electric Field
3.27
-
Classification of Optical Fiber
12.02
-
Numericals Based on Energy and Power
37.52
-
Effect of Time Shifting, Scaling and Reversal on Energy and Power
34.12
-
Introduction to Systems
6.42
-
Static and Dynamic Systems
19.03
-
Errors in PMMC and MI Instruments
11.34
-
Electrodynamometer (EDM) Type Instruments
7.56
-
Numerical 1 on EDM Instruments
5.35
-
Electrodynamometer Wattmeter
6.51
-
Electrodynamometer Ammeter
5.36
-
Electrodynamometer Voltmeter
7.14
-
Error Due to Wattmeter Connection
10.52
-
Numerical 2 on EDM Instruments
8.43
-
Electric Field Intensity Due to Surface Charge
7.32
-
Numerical 1 on Surface Charge Electric Field
2.34
-
Numerical 2 on Line and Surface Charge Electric Field
5.17
-
Flux Density and Gauss's Law, Maxwell Equation
5.34
-
Numerical 1 on Gauss's Law
5.01
-
Acceptance Angle and Numerical Aperture
13.41
-
Invertible and Non Invertible System
15.31
-
Causal and Non Causal System
11
-
Stable and Unstable System
16.58
-
Time Variant and Time Invariant System
22.26
-
Linear and Non Linear System
21.34
-
Errors in Wattmeters Due to Potential Coil Inductance
20.28
-
Numerical 1 on Wattmeter Errors
4.58
-
Numerical 2 on Gauss's Law
5.33
-
Numerical 3 on Gauss's Law
3.04
-
Numerical 4 on Gauss's Law
3.45
-
Work Done and Electric Potential and Maxwell Equation
6.46
-
Numerical 1 on Work Done
2.42
-
Numerical 2 on Work Done
5.21
-
Numerical 6 Based on Acceptance Angle
3.2
-
Numerical 7 Based on Numerical Aperture
3.32
-
Numerical 8 Based on Numerical Aperture
3.34
-
Numerical 9 Based on Numerical Aperture
2
-
Impulse Response
23.12
-
Introduction to Convolution
17.18
-
Discrete Time Convolution - Part 1
40.26
-
Errors in Dynamometer Type Instruments
5.35
-
Numerical on Indicating Instruments - Part 1
38.25
-
Numerical on Indicating Instruments - Part 2
35.53
-
Numerical 1 on Potential V
3.35
-
Relationship Between E and V
2.35
-
Numerical 2 on Potential V
1.57
-
Electric Boundary Condition (Dielectric Dielectric Interface)
9.24
-
Numerical 10 Based on Critical Angle
3.1
-
V Number and Brewster Angle
10.53
-
Discrete Time Convolution - Part 2
25.4
-
Convolution of Input with Impulse Function
33.01
-
Convolution of Input with Step Function
27.36
-
Measurement of DC Power
10.18
-
Measurement of Power in 3 Phase Circuit: Two Wattmeter Method
25.58
-
Numerical on Two Wattmeter Method
10.42
-
Numerical 1 on Boundary Condition
10.06
-
Electric Field Behaviour on Conductor
4
-
Electric Boundary Condition (Dielectric Conductor Interface)
1.51
-
Numerical 2 on Boundary Condition
2.59
-
Poission's and Laplace's Equations
4.54
-
Numerical 1 on Laplace's Equation
2.46
-
Numerical 11 Based on V Number and Number of Modes
3.33
-
Numerical 12 Based on Brewster Angle
3.2
-
Numerical 13 Based on Dispersion Loss
2.39
-
Continuous Time Convolution of Rectangular Pulses
36.01
-
Numerical Based on Continuous Time Convolution
25.39
-
Convolution of Exponential Signals
27.48
-
Numerical Based on Convolution of Exponential Signal
12.16
-
Measurement of Reactive Power
4.11
-
Measurement of Energy: Single Phase Energy Meter
26.2
-
Numerical 1 on Energy Meter
5.5
-
Numerical 2 on Energy Meter
6.21
-
Creeping Error in Energy Meter
5.04
-
Numerical 3 on Energy Meter
5.4
-
Numerical 4 on Energy Meter
2.34
-
Numerical on Measurement of Power and Energy - Part 1
34.28
-
Numerical 2 on Laplace's Equation
3.29
-
Numerical 3 on Laplace's Equation
4.18
-
Parallel Plate Capacitor
6.03
-
Coaxial Capacitor
4.35
-
Spherical Capacitor
3.38
-
Numerical 1 on Capacitor
3.09
-
Method of Images (Image Theory)
3.34
-
Laser
13.01
-
Properties of Convolution
40.47
-
Causality and Stability Based on Impulse Response
31.14
-
Numerical on Measurement of Power and Energy - Part 2
29.22
-
Numerical 1 on Image Theory
4.29
-
Numerical 2 on Image Theory
2.12
-
Continuity Equation and Relaxation Time
8.28
-
Electric Dipole
5.01
-
Numerical 1 on Electric Dipole
2.31
-
Energy Density in Electrostatic Field
4.40
-
Numerical 1 on Energy Density
1.5
-
Divergence Angle and Areal Spread
4.55
-
Numerical 14 Based on Divergence Angle
4.02
-
Numerical 15 Based on Divergence Angle
4.1
-
Introduction to Fourier Series
28.23
-
Fourier Series - Part 1
22.46
-
Fourier Series - Part 2
12.54
-
Fourier Series - Part 3
59.43
-
DC and AC Bridges
9.32
-
Inductance Measurements: Maxwell-Inductance Bridge
13.16
-
Maxwell Inductance Capacitance Bridge
10.35
-
Hays Bridge
12.19
-
Owne's Bridge
8.27
-
Anderson's Bridge
17.14
-
Introduction and Biot Savart Law
5.57
-
Magnetic Field Intensity Due to Infinite Long Current Carrying Wire
6.25
-
Numerical 1 Magnetic Field Due to Wire
2.49
-
Magnetic Field Intensity Due to Finite Length Current Carrying Wire
5.11
-
Numerical 2 Magnetic Field Due to Wire
4.09
-
Magnetic Field Due to Circular Loop
5.16
-
Numerical 16 Based on Areal Spread
3.41
-
Numerical 17 Based on Radiation Wavelength
4.38
-
Numerical 18 Based on Number of Photons
5.13
-
Fourier Series - Part 4
38.06
-
Fourier Series - Part 5
25.11
-
Fourier Series - Part 6
33.43
-
Capacitance Measurement: De-Sauty's Bridge
6.05
-
Modified De Sauty's Bridge
11.2
-
Schering Bridge
8.45
-
Numerical on Bridges
8.29
-
Measurement of Frequency: Wien's Bridge
8.49
-
Low Resistance Measurement: Kelvin's Double Bridge
16.14
-
Medium Resistance Measurement: V-A and A-V method
8.13
-
Numerical 1 on Magnetic Field Due to Circular Loop
2.12
-
Ampere's Law and Maxwell Equation
2.36
-
Numerical 1 on Ampere's Law
4.06
-
Numerical 2 on Ampere's Law
3.19
-
Magnetic Flux Density and Maxwell Equation
3.21
-
Magnetic Vector and Scalar Potential
4.2
-
Numerical 1 on Magnetic Vector Potential
2.36
-
Longitudinal Mode Separation
5.12
-
Numerical 19 Based on Longitudinal Mode Separation
1.49
-
Numerical 20 Based on Longitudinal Mode Separation
2.39
-
Properties of Fourier Series - Part 1
29.31
-
Properties of Fourier Series - Part 2
22.3
-
Numericals on Fourier Series
36.55
-
Substitution Method for Medium Resistance Measurement
6.17
-
Wheatstone Bridge
3.59
-
Ohm Meter for Medium Resistance Measurement
8.19
-
High Resistance Measurement: Loss of Charge Method
6.15
-
Numerical on Loss of Charge Method
3
-
Meggar for High Resistance Measurement
7.57
-
Numerical on Measurement of R, L and C - Part 1
23.23
-
Numerical on Measurement of R, L and C - Part 2
20.19
-
Magnetic Boundary Condition
8.57
-
Numerical 1 on Magnetic Boundary Condition
4.42
-
Numerical 2 on Magnetic Boundary Condition
5.17
-
Lorentz Force
3.07
-
Force on Current Carrying Wire in Magnetic Field
6.45
-
LED
7.24
-
Numerical 21 based on LED
2.47
-
Numerical 22 based on LED
2.43
-
Introduction to Fourier Transform
42.45
-
Fourier Transform - Part 1
29.34
-
Weston Type Frequency Meter
11.56
-
Electrodynamometer Type Power Factor Meter
11.09
-
Potentiometer or Null Deflector
12.4
-
Numerical 1 on Potentiometer
5.1
-
Faraday's Law
2.32
-
Transformer and Motional EMF
3.22
-
Numerical 1 on Transformer and Motional EMF
4.10
-
Modification in Ampere's Law for Time Varying Field
5.57
-
Maxwell's Equation for Time Varying Field
2.05
-
Numerical 1 on Displacement Current
1.56
-
Photo Diode
8.55
-
Quantum Efficiency
7.54
-
Fourier Transform - Part 2
51.3
-
Fourier Transform - Part 3
51.55