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Lecture Description of this above Topic:
Lecture 79: Emitter-Bias Configuration (Solved Problem)
Lecture 80: Collector Feedback Biasing
Lecture 81: Collector Feedback Biasing (Solved Problem)
Lecture 82: Collector Feedback Bias with Emitter Resistance
Lecture 83: Voltage Divider Bias
Lecture 84: Voltage Divider Bias (Solved Problem)
Lecture 85: Thermal Runaway in Transistors
Lecture 86: Bias Stabilization and Stability Factors
Lecture 87: Stability Factor for Fixed-Bias Configuration
Lecture 88: Stability Factor for Emitter-Bias Configuration
Lecture 89: Stability Factor for Collector Feedback Biasing
Lecture 90: Stability Factor for Voltage Divider Bias
Lecture 91: Transistor Saturation
Lecture 92: Small Signal Analysis of BJT
Lecture 93: AC Equivalent Circuit of BJT Amplifier
Lecture 94: Hybrid Model (Calculation of h-Parameters)
Lecture 95: Hybrid Model (Equivalent Circuit)
Lecture 99: Approximate Hybrid Equivalent Model
Lecture 100: Conversion of h-Parameters
Lecture 101: re Transistor Model (Part 1)
Lecture 102: re Transistor Model (Part 2)
Lecture 103: re Model (Fixed-Bias Configuration) | Part 1
Lecture 104: re Model (Fixed-Bias Configuration) | Part 2
Lecture 105: re Model (Fixed-Bias Configuration) | Part 3
Lecture 106: re Model (Solved Problem 1)
Lecture 107: re Model (Voltage-Divider Bias)
Lecture 108: re Model (Solved Problem 2)
Lecture 109: Hybrid-Ï€ Model
Lecture 110: Hybrid-Ï€ Model (Solved Problem)
Lecture 111: Emitter-Follower Configuration (Part 1)
Lecture 112: Emitter-Follower Configuration (Part 2)
Lecture 113: Two-Port Systems Approach
Lecture 114: Two-Port Systems Approach (with Load Resistance)
Lecture 115: Two-Port Systems Approach (with Source Resistance)
Lecture 117: Two-Port Systems Approach (Solved Problem)
Lecture 118: Cascaded Systems
Lecture 119: Cascaded Systems (Solved Problem)
Lecture 120: Darlington Pair
Lecture 121: Touch Sensor Using Darlington Pair
Lecture 122: DC Analysis of Darlington Circuit
Lecture 123: Introduction to Field-Effect Transistors (FETs)
Lecture 124: Construction and Working of JFET
Lecture 125: Working of JFET (Zero Voltage at the Gate)
Lecture 126: Pinch-off Voltage
Lecture 127: JFET as a Current Source
Lecture 128: Working of JFET (Negative Voltage at the Gate)
Lecture 129: Output or Drain Characteristics of JFET
Lecture 130: JFET as Voltage-Controlled Resistor
Lecture 131: Transfer Characteristics of JFET
Lecture 132: BJT Vs JFET
Lecture 133: JFET Solved Problems (Part 1)
Lecture 134: JFET Solved Problems (Part 2)
Lecture 137: Drain Characteristics of Enhancement-Type MOSFET
Lecture 139: Construction of Depletion-Type MOSFET
Lecture 140: Working of Depletion-Type MOSFET
Lecture 142: MOSFET Solved Problems (Part 1)
Lecture 143: MOSFET Solved Problems (Part 2)
Lecture 144: Introduction to FET Biasing
Lecture 147: Fixed-Bias Configuration of JFET (Solved Problem)
Lecture 149: Self-Bias Configuration of JFET (Graphical Approach)
Lecture 150: Voltage-Divider Bias Configuration of JFET
Lecture 151: Common-Gate Configuration of JFET
Lecture 152: JFET Biasing (Special Case)
Lecture 153: Introduction to Depletion-Type MOSFET Biasing
Lecture 154: Self-Bias Configuration of Depletion-Type MOSFET
Lecture 155: Depletion-Type MOSFET Biasing (Special Case)
Lecture 157: Depletion-Type MOSFET Biasing (Solved Problem)
Lecture 158: Introduction to Enhancement-Type MOSFET Biasing