3. Design a combinational circuit that compares two 4 bit numbers (A and B) and has...
Design a combinational circuit that compares two 4-bit unsigned numbers A and B to see whether A is greater than B. The circuit has one output X, so that X = 0 if A ≤ B and X = 1 if A > B.
Design a combinational circuit which compares two 4-bit unsigned numbers A and B. The circuit should have one output X such that X = 1 whenever A>B and X = 0 whenever A?B. You may use any MSI modules as well as any other gates.
Design a combinational circuit that compares two 4-bit unsigned numbers A and B to see whether B is greater than 2A. The circuit has one output X, so that:X = 1 if 2A < B, andX = 0 if 2A >= B.Please de descriptive and detailed in drawing.The book we are using in class is this: http://www.cramster.com/logic-and-computer-design-fundamentals-4th-solutions-3631 and we are on chapter 4.
Combinational logic: a) Design a circuit to compare two numbers each is 1-bit: A, B. With 3 outputs X for A-B ,Y for A<B, Z for A B b) Use the previous output (or only one of them) as selection lines for a multiplexer to give the larger number to the output of the multiplexer.
Design a combinational circuit design that given a four-bit number as the input outputs an 8-bit number that represents the nth Fibonacci number in the sequence. For instance, if the input is 0001, the output should be the second number in the Fibonacci sequence. The Fibonacci series looks like the following: 0, 1, 1, 2, 3, 5, 8, 13, and so on. The first two numbers in the sequence are always 0 and 1. However, after that, you must add...
1- Please answer all the question 2- with clear handwriting Thank you, 3. Design a combinational circuit with inputs a, b, c, d and outputs w, z, y, z, where the input and output both represent a signed numbers (2s complement). The output is 7 less than the input, if the input is positive, or zero. If the input is negative, the output is 3 greater than the input. 7. Use the Boolean functions developed in problem #3 to create...
Please design and implement a combinational circuit called 4-bit adder to add two 4-bit binary numbers, e.g. 1011 + 1110 = 1 1 0 0 1, the 5-bit result is 1 1 0 0 1 in which the leftmost bit is carry-out bit and sum result is 1 0 0 1, so that final sum is 1 1 0 0 1 which is 25 in decimal. (b) Design and Implement the four-bit adder circuit preferably using CEDAR logic simulator...
Design a combinational circuit that adds 1 to 3-bit unsigned binary number and produces an unsigned binary result. Do the following: (1) determine the number of inputs/outputs, (2) write the truth table, (3) simplify the output functions by using maps and (4) draw the logic diagram by using AND OR and NOT gates. Show the truth table, the map, and the logic diagram. Do NOT use adders.
A comparator circuit has two 1-bit inputs A and B and three 1-bit outputs G (greater), E (equal), and L (less than). That is, G is 1 if A > B (0 otherwise), E is 1 if A == B (0 otherwise), and L is 1 if A < B (0 otherwise). a. Draw the truth table for a 1-bit comparator (the table has 2 inputs and 3 outputs). b. Implement G, E, and L circuits using only...
3) [9 marks] Using the combinational circuit design procedure discussed in the notes, design with a truth-table, simplify with K-maps, and draw the combinational circuit that accepts a 3-bit number and generates a 5-bit number output equal to 3X + 2 where X is the input number (if the input is 010 (2), the output should be (01000) 8 . Let the inputs be A, B, C and the outputs be V, W, X, Y, Z.