(if you send me same answer again, I will report you to answers...!)and please READ carefully my question. PLEASE please, pleeeeeaaaase download and use NI MULTISIM to answer followings!!!!!!!!this is Digital Electronics classagain, *This has to complete with NI Multisim. Finished part B which is on last picture. and I need help for Part A, Part C, Part D, and Part E to complete and put them all together. I will 100% give you rate BUT if you do with paper, ill have to give you bad rate...
sorry because this is our third time posting this same questions and we are not willing to wasted our post again. thanksand please READ carefully my question.
PLEASE please, pleeeeeaaaase download and use NI MULTISIM to answer followings!!!!!!!!
this is Digital Electronics class
again, *This has to complete with NI Multisim. Finished part B which is on last picture. and I need help for Part A, Part C, Part D, and Part E to complete and put them all together.
I will 100% give you rate BUT if you do with paper, ill have to give you bad rate...
sorry because this is our third time posting this same questions and we are not willing to wasted our post again. thanks- You Are Only Getting Bad Rate Because Your Answer Is Totally Wrong If You Send Me Same Answer Again I Will Report 1 (61.83 KiB) Viewed 18 times
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mapping each of the six states to a lighting pattern. Figure 2 shows a high-level diagram of two blocks. The left-side block represents Part A of the project. The right-side block represents the combinational logic to be designed. The inputs are three bits S0, S1 and 3 corresponding to the state, the outputs are the six lights. Do the following: 1. Create a function table that maps each state and to the lighting of each the six lights. 2. Produce a K-map for each of the six lights. Find the simplest logic solution for each. 3. Using the K-map results produce the simplest possible logic for lighting each light. 4. Create in Simulink full logic for implementing Figure 2. Main Red Main Yel Next State SO Sequential Logic S1 Combinational Logic Main Grn State Counter S2 Light Control Side Red Side Yel Side Gun Figure 2: Block diagram of state counter and combinational logic for controlling lighting sequence. Part C. Combinational Logic for Outputting the Wait time for each of the Six States Design combinational logic for outputting the wait time associated with each state. For example, state 000 has the main street green light on for 15 seconds. The combinational logic for the input 000 would have an output 1111 corresponding to decimal 15. Let the outputs W3, W2, W1 and Wo representa binary number corresponding to the wait time. Do the following: 1. Create a function table that maps the input 53, 51 and 50 to outputs W3, W2, W1 and Wo. 2. Create logic that maps the input state to the output. Using any method but show your work. 3. Create in Simulink the corresponding logic. You may add this to your Part B solution Part D: Sequential and Combinational Logic for Waiting Time Period before Activating Next State Figure 3 shows a high-level diagram of the full traffic controller and includes the sub-modules created in parts A, B and C of this project. The left-side of the diagram shows a clock input. This input is to rise and falls every 1 second. Upon initiating a new state, a register is loaded with the wait time associated with the new state and a 4-bit counter is reset. On clock pulses, the 4-bit counter is incremented. The Next_State output is set high when the counter matches the wait time. You are welcome to use a
different method such as a counter with parallel load that decrements. Your method must use logic and achieves the timing requirements. Do the following: 1. Create sequential and combinational logic that implements the left-most block of Figure 3. The inputs are the clock, W3, W2, W1 and Wo. The output (Next_State) is set high when counter matches W3, W2, W1 and Wo, otherwise, the output is low. Discuss your design. 2. Create in Simulink. Include a screenshot that demonstrating that it works. Main Red Clock Next State SO Sequential Combinational Logic Sequential Logic $1 Combinational Logic Main Yel Main Grn State Counter S2 Including 4-bit counter and register Light Control Side Red Side Yel Side Gen WO w1 Combinational Logic W2 Wait Time W3 Table Figure 3: Block diagram of traffic control including logic for wait time between state changes. Parte: Complete Working Traffic Controller Assemble the building blocks created in parts A, B, C and D such to create a working traffic controller simulated in Multisim. Use a 1 second clock input. Let the outputs be appropriately colored LEDs. Requirements for the Final Report You must use Multisim to simulate your project. Your report should include work such as K-maps and algebra where appropriate. You must use your own figures (not mine). Your final report must include the following sections: 1. Title page 2. Introduction 3. The requirements described in parts A, B, C, D and E. 4. Conclusion
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