Q1. (9) + (-5)1010 (ii) (3) – (8)1010

This is question 1 (null marks) from the GTU Digital Fundamentals BE Winter 2024 question paper. Subject code: 3130704.

Q1. Explain the characteristics of Digital ICs.

This is question 1 (7 marks) from the GTU Digital Fundamentals BE Winter 2024 question paper. Subject code: 3130704.

Q2. Design a 4-bit Binary to Gray Code Converter using K-map.

This is question 2 (7 marks) from the GTU Digital Fundamentals BE Winter 2024 question paper. Subject code: 3130704.

Q2. Draw a two input TTL NAND gate and explain its operation.

This is question 2 (7 marks) from the GTU Digital Fundamentals BE Winter 2024 question paper. Subject code: 3130704.

Q3. Explain Race Around Condition in JK flip flop.

This is question 3 (3 marks) from the GTU Digital Fundamentals BE Winter 2024 question paper. Subject code: 3130704.

Q3. Design a 1 - bit Magnitude Comparator.

This is question 3 (4 marks) from the GTU Digital Fundamentals BE Winter 2024 question paper. Subject code: 3130704.

WinterBE2024

Digital Fundamentals — Winter 2024

Q: Q1. (a) Perform the following mathematical operations using 2’s complement method.

This is question 1 (3 marks) from the GTU Digital Fundamentals BE Winter 2024 question paper. Subject code: 3130704.

Q: Q1. State and prove De-Morgan’s theorems using truth-tables.

This is question 1 (4 marks) from the GTU Digital Fundamentals BE Winter 2024 question paper. Subject code: 3130704.

Q: Q2. Design a Full Adder circuit using basic logic gates.

This is question 2 (3 marks) from the GTU Digital Fundamentals BE Winter 2024 question paper. Subject code: 3130704.

Q: Q2. Design a modulo-6 ripple counter using T-Flip-flops.

This is question 2 (4 marks) from the GTU Digital Fundamentals BE Winter 2024 question paper. Subject code: 3130704.

Subject Code3130704

ProgramBachelor of Engineering

Total Marks70

Questions16

Exam Date9 December 2024

Exam Time10:30 AM TO 01:00 PM

Questions26

(a) Perform the following mathematical operations using 2’s complement method.

[3 marks]

(9) + (-5)1010 (ii) (3) – (8)1010

[ marks]

State and prove De-Morgan’s theorems using truth-tables.

[4 marks]

Explain the characteristics of Digital ICs.

[7 marks]

Design a Full Adder circuit using basic logic gates.

[3 marks]

Design a modulo-6 ripple counter using T-Flip-flops.

[4 marks]

Download PDF

Explain Race Around Condition in JK flip flop.

[3 marks]

Design a 1 - bit Magnitude Comparator.

[4 marks]

Explain Hamming codes for error correction with a suitable example.

[7 marks]

Find expression for the following and implement using logic gates. F(A,B,C,D) = πM(0,2,3,6,7,8,9,12,13)

[3 marks]

Implement Dflip flop using JK flip flop.

[4 marks]

Design a 4-bit twisted Ring Counter using JK flip flops.

[7 marks]

Differentiate Synchronous Counters and Asynchronous Counters.

[3 marks]

Implement the following using 8:1 MUX. F = f(A,B,C,D) = Σm(2,4,5,7,10,14)

[4 marks]

Design a synchronous BCD counter using J-Kflip-flops.

[7 marks]

Implement full subtractor using 3:8 decoder and write a truth table.

[3 marks]

Explain the specifications of Digital to Analog Converters.

[4 marks]

Explain Successive Approximation type A/Dconverter.

[7 marks]

Differentiate Static RAM and Dynamic RAM.

[3 marks]

Write a short note on FPGA.

[4 marks]

Explain the operation of Dual-slope A/Dconverter.

[7 marks]

Explain basic structure of a CCD (Charge Coupled Device).

[3 marks]

Write a short note on Programmable Array Logic.

[4 marks]

Explain various types of Read Only Memory.

[7 marks]

Digital Fundamentals — Winter 2024

Questions26

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