Unit 2: Analog Electronics (Lab: PHYDSC253P)

1. Laboratory Objectives
2. PN Junction & Zener Diode Characteristics
3. Solar Cell Analysis
4. Bipolar Junction Transistor (BJT) Characteristics
5. RC-coupled Transistor Amplifier
6. Operational Amplifier (Op-amp) Fundamentals
7. Op-amp Applications: Math Operations
8. Lab Exam Focus Corner

1. Laboratory Objectives

The objective of this part is to provide students with hands-on knowledge and an overview of various instruments used in analog electronics. Students will learn to perform experiments related to semiconductor devices and report findings accurately.

2. PN Junction & Zener Diode Characteristics

These experiments involve studying the Volt-Ampere (V-I) relationship of semiconductor diodes.

PN Junction Diode: Students plot the current against the voltage in both forward and reverse bias to understand the unilateral behavior.
Zener Diode: The focus is on the reverse breakdown region to understand its role as a voltage regulator.

3. Solar Cell Analysis

The study includes plotting V-I and power curves for solar cells.

Goal: To find the maximum power point and calculate the overall efficiency of the solar cell.

4. Bipolar Junction Transistor (BJT) Characteristics

The characteristics of a BJT are studied in the Common Emitter (CE) configuration.

Input Characteristics: Base current vs. Base-Emitter voltage for constant Collector-Emitter voltage.
Output Characteristics: Collector current vs. Collector-Emitter voltage for constant Base current.

5. RC-coupled Transistor Amplifier

This practical involves designing and studying the performance of a single-stage amplifier.

Design: Using voltage divider biasing to achieve a specified mid-gain.
Frequency Response: Plotting gain against frequency to determine the bandwidth.

6. Operational Amplifier (Op-amp) Fundamentals

Students use IC-741 or IC-351 to design basic linear amplifier circuits.

Inverting Amplifier: The output is out of phase with the input.
Non-Inverting Amplifier: The output is in phase with the input.

Gain (Inverting) = -Rf / Ri
Gain (Non-Inverting) = 1 + (Rf / Ri)

7. Op-amp Applications: Math Operations

Advanced experiments involve using the Op-amp to perform mathematical operations on electrical signals.

Integrator: The output is the time integral of the input.
Differentiator: The output is the derivative of the input.
Adder/Subtractor: Combining multiple input signals into a single output.

Lab Exam Focus Corner

Frequently Asked Questions

Why is voltage divider bias used for transistors?
It provides the best stability for the Q-point against variations in temperature and transistor parameters.
What is 'Knee Voltage' in a diode?
It is the forward voltage at which the current starts to increase rapidly.

Common Mistakes

Biasing Polarity: Connecting the Zener diode in forward bias when trying to observe regulation. Remember, regulation occurs in reverse breakdown.
Clipping: In Op-amp circuits, expecting a gain that results in an output voltage higher than the supply voltage (+Vcc / -Vee). The output will saturate.

Lab Tips

Tip: When plotting the frequency response of an amplifier, use semi-log graph paper (logarithmic scale for frequency) to clearly see the flat mid-band region and the roll-off at low and high frequencies.