Problem 4 [40 Points]: Finite State Machines Show the FSM diagram of a 3-bit up/down counter...
Finite state machine (FSM) counter design: Gray codes have a useful property in that consecutive numbers differ in only a single bit position. Table 1 lists a 3-bit modulo 8 Gray code representing the numbers 0 to 7. Design a 3-bit modulo 8 Gray code counter FSM. a) First design and sketch a 3-bit modulo 8 Gray code counter FSM with no inputs and three outputs, the 3-bit signal Q2:0. (A modulo N counter counts from 0 to N −...
Please show process and I will rate faster!!! 2. Design a two-bit up/down binary counter using T-fip-flops that can count in binary from 0 to 3. When the control input x is 0, the circuit counts up and when it is 1, the circuit counts down. (a) Obtain the state table of the two-bit counter (P. S., Input, N. S., Output). (b) Obtain the state diagram. (c) Draw the logic diagram of the circuit.
Up-Down counter with enable using JK flip-flops: Design, construct and test a 2-bit counter that counts up or down. An enable input E determines whether the counter is on or off. If E = 0, the counter is disabled and remains in the present count even though clock pulses are applied to the flip-flops. If E= 1, the counter in enabled and a second input, x, determines the count direction. If x= 1, the circuit counts up with the sequence...
3. Finite State Machine. Using a ROM based finite state machine (FSM), design a bi-directional repetitive 3-bit modulo-6 (0,1,2,3,4,5) counter (see Table 3). The design has one input named Dir and three outputs named B2, B1 and BO. The outputs (B2, B1 and BO) are dependent upon being in the present state only. After each clock pulse, when Dir is at logic "O', the outputs (B2, B1, BO) step through the count sequence in following order:- 0,1,2,3,4,5. After each clock...
Design a two-bit up/down binary counter using D flip-flops that can count in binary from 0 to 7. When the control input x is 0, the circuit counts down, and when it is 1, the circuit counts up. (a) Obtain the state table of the two-bit counter. (b) Obtain the state diagram (c) Draw the logic diagram of the circuit.
(20 points) Using any state encodings you want, generate a state table for the following state diagram. Note that there is one input, X, and there are two outputs, Y and Z. You can come up with whatever names you want for your state variables. And then generate the logic equations for the next state signals (assume D flip-flops for maintaining state) and the output signals, Y and Z 7. A0 A/Y 070 x=1 x=1 x =1 x =0 x...
Design a 3-bit down counter FSM with no inputs and three outputs. Do this using a T flip flop. a. Draw a state diagram and the corresponding state table. b. Derive the equations for output functions and flip-flop input functions c. Draw the logic circuit diagram
Please use Logicly! Create a 4 bit sequential counter that is capable of counting up or down. You have to accept one input from user, deciding the direction that it counts in. The circuit change the operation from count up and count down without skipping numbers. Use no more than 4 flip flops in the circuit. If the input is count up, the circuit should count from 0 to 15, then restart from 0. If user input is count down,...
1. Suppose you want to design a 2-bit binary up-counter. Construct the state table using A1 and AO as the previous state of bits and A1+, A0+ as the next bit states, ie, to count from 00 to 01, A1 stays at 0, but AO changes from 0 to 1. Let the counter wrap-around, such that 11 -> 00. Draw the state diagram. 2. Next, add in a third input, En, for enable. The counter can only count up when...
all please Design a 3-bit counter that has only one input, w. It counts down 7, 6,5,... 0, 7,.. whenever w-0, and counts up 0,1,2...7,0... when w 1 The output z-1, when the state of the counter is a prime number. Otherwise, z-0 1. List Inputs, Outputs and the count sequence. (5pts) 2. Draw the finite State machine for the counter. (10pts) 3. Draw the state transition table <extra columns for the flip flops values> (20pts) armed resource/content/1/case%20study.template.docx 4. Design...