Unit I:
Exp. 1.1. To study the 1-V characteristics of a p-n junction diode (Forward and Reverse Bias)
Exp. 1.2. To study the 1-V characteristics of a zener diode and its application as voltage regulator
Exp. 1.3. Diode clamper and limiter (clipper) circuits
Exp. 1.4. Designing of power supply using bridge rectifier, capacitor filter and zener diode
Exp. 1.5. BJT Transistor characteristics of common-base and common-emitter configuration
Exp. 1.6. To design a single-stage CE. BJT Transistor amplifier
Exp. 1.7. To Study the V-I characteristics of a FET
Exp. 1.8. To plot the characteristics of UJT and design a relaxation oscillator
Exp. 1.9. To plot the V-I characteristics of silicon controlled rectifier.
Unit II: EXPERIMENTS BASED ON DIGITAL ELECTRONICS
Exp. 2.1 Verification of truth table of various logic gates using Ics and Diode Transistor logic (DTL)
Exp. 2.2 Verify DE Morgan's theorem. Reduce the given expression using K-map and implement used
Exp. 2.3 To Verify the truth table of Half Adder, Full Adder and Parallels adder using basic gates and universal gates (NAND, NOR).
Exp. 2.4 To Verify the truth table of Half Subtractor and Full Subtractor using basic gates (XOR,OR,NOT,AND) and universal gates (NAND, NOR)
Exp. 2.5 To design a combinational circuit that works as BCD (Binary Coded Decimal) Adder
Exp. 2.6 To design a 2-bit magnitude comparator circuit
Exp. 2.7 To design a code convertor circuit that converts binary to BCD (Binary Coded Decimal), Gray to Binary
Exp. 2.8 To Design 2-bit parity Generator / Checker Circuit
Exp. 2.9 To design a astable and monostable multivibrator circuit using 555 Timer
Exp. 2.10 To verify the truth table of various flip-flop (S-R,D,JK and JK m/s) using universal gates
Exp. 2.11 To design a four bit shift register busing D-flip flop
Exp. 2.12 To design a Asynchronous Mod-6, decade counter using flip flop
Exp. 2.13 To design Mod-6 and Mod-10 (Decade) Sychronous counter.
Unit III: EXPERIMENTS BASED ON OPERATIONAL AMPLIFIER
Exp. 3.1 To study the DC and AC characteristics of op-amp
Exp. 3.2 To design Differentiator for a particular gain using Op-Amp 741c
Exp. 3.3 To study the operational amplifier as inverting and Non-inverting feedback amplifier with verifying gain. Also plot the frequency response of the feedback amplifier
Exp. 3.4 To study operational amplifier as adder and averaging amplifier
Exp. 3.5 To design an op-amp integrator circuit
Exp. 3.6 To design comparator (Schmitt trigger) using op-amp
Exp. 3.7 To design active filter (Low pass and high pass) using op-amp 741 IC. Unit IV: 8085 MICROPROCESSOR
Exp. 4.1 Write a program in assembly language of 8085 microprocessor for addition of N 8-bit hexadecimal numbers without carry
Exp. 4.2 Addition of two 16-bit hexadecimal numbers.
Exp. 4.3 Write a program in assembly language of 8085 microprocessor for subtraction of N 8-bit hexadecimal numbers without borrow
Exp. 4.4 Write a program in assembly language of 8085 microprocessor for Subtraction of N8-bit/16-bit hexadecimal numbers with borrow
Exp. 4.5 Write a program to multiply two 8-bit numbers by repetitive addition 2 bit rotation
Exp. 4.6 Write a program to compare N 8-bit numbers and find out the largest/ smallest number and corresponding memory location
Exp. 4.7 Write a program to find the summation of n 8-bit natural numbers where result can be 16-b n Y=? N N=0
 Exp. 4.8 Write a program to calculate the average of N 8-bit numbers
Exp. 4.9 Write a program to calculate the factorial of an 8-bit number (n) and store a 16-bit result
Exp. 4.10 Write a program for summation of X? where X is a 16-bit number and is 8-bit hexadecimal
Exp. 4.11 Write a program to generate the terms of arithmetic progression series where a, d, n, are 8-bit hexadecimal numbers and result generate is 1bit
Exp. 4.12 Write a program to generate the geometric progression series where a and r are 8-bit hexadecimal nu

• Compilation of 41 experiments, the book is divided into four major units. Unit I experiments are based on semiconductor devices, unit II experiments are based on digital electronics, unit III experiments are based on operational amplifier, and unit IV experiments are on assembly language programing based on the 8085 microprocessor.
• Each experiment is preceded with an aim, material required, theoretical explanation per se, followed by results, and self-evaluation questions. 
• Each experiment is profusely illustrated with line drawings. 
• Every chapters have a self-evaluation exercise at the end.