程序代写代做代考 C Lab 1: Intro to Logic Simulation

Lab 1: Intro to Logic Simulation
Due Friday, 16 October 2020, 11:59 PM
Minimum Submission Requirements
¡ñ Your Lab1 folder must contain the following files:
¡ð Lab1.lgi (note the capitalization for both the file name and extension) ¡ð README.txt
¡ñ Commit and push your repository
¡ñ Complete the Google Form with the correct commit ID of your final submission
Note
You should have created the Lab1 directory and a blank README.txt file in the last
lab assignment.
Objective
This lab will introduce you to a schematic entry logic simulation program, Multimedia
Logic (MMLogic or MML). In this lab you will practice creating truth tables and
implementing logic based on those truth tables.
Tutorial
Before starting the lab assignment, follow this tutorial on how to build a very
simple circuit.
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Lab 1
Start a new circuit by clicking on from the toolbar.
Bring up the Tool Palette by clicking on from the toolbar.
Select the Switch by clicking on from the palette.
Place a switch by clicking the left mouse button on the schematic.
Select an LED by clicking on from the palette.
Place an LED by clicking the left mouse button to the right of the switch.
Select the Wiring device by clicking on from the palette.
Click the left mouse button down on the output node (black dot) and hold it. Drag the mouse over to the LED input node (black dot) and let the mouse go.
Select the Pointer Tool by clicking on from the palette.
Double click on the center of the LED . Change the color to Yellow and Click OK.
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¡ñ
¡ñ Run the simulator by clicking on from the toolbar.
¡ñ Click on the Switch on the schematic and notice what happens.
¡ñ Stop the simulator by clicking on from the toolbar.
Resources
Browse the Index in the help menu in MML:
These YouTube videos might be helpful.

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Template
Use the template provided on Canvas. You must use senders and receivers such that the output is shown on the first page of the template. Do not change the first
page of the template file, except for the text fields – your name, CruzID, and descriptions of the outputs. Additional wires and logic circuits shall be drawn
on subsequent pages of your Multimedia Logic schematic. Remember to rename the template file to Lab1.lgi.
Additional wires and logic circuits shall be drawn on subsequent pages. Remember to rename the template file to Lab1.lgi before committing to your
repository.
On the third page, there are placeholder signal senders and receivers that you can
use. You may remove these senders and receivers as you use them in your design.
Note
Some operating systems capitalize the extension and will save the file as Lab1.LGI.
You must rename this file to have the extension .lgi (in all lowercase). The first letter of Lab1 should be capitalized.
Specification
For all parts of the design, assume an ON LED represents ¡°1¡± and an OFF LED represents ¡°0.¡± Consider the input switches as a 4-bit binary number with input switch in_3 as the most significant (left-most) bit and input switch in_0 as the least significant (right-most) bit.
Part A
Connect the wires from the user input switches to the 7 segment display component.
Part B
Design a circuit that outputs the three bits shown in the truth table given the four bits as input. The three output bits have b_2 as the left-most bit and b_0 as the right-most bit.
For example, for input = 1111, the output should be 010 which means
b_2 = 0 = OFF
b_1 = 1 = ON
b_0 = 0 = OFF
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Do you notice any patterns? You can use these patterns and Boolean algebra or
intuition to simplify your circuit.
in_3 in_2 in_1 in_0 | b_2 b_1 b_0 0000|000 0001|110 0010|100 0011|010 0100|000 0101|110 0110|100 0111|010 1000|000 1001|110 1010|100 1011|010 1100|000 1101|110 1110|100 1111|010
Part C
For Part C, you may ignore input in_3. Implement the truth table below using either Sum of Products (SOP) or Product of Sums (POS). Output the result on the LED connected to receiver c_0.
in_2 in_1 in_0 | c_0 000|0 001|1 010|0 011|1 100|1 101|1 110|0 111|0
Next, implement the SOP or POS using only NAND gates. Output this result to the LED connected to receiver c_1.
Lastly, build the same SOP or POS using only NOR gates. Output the result to c_2. You can create a NAND gate by double clicking on an AND gate which brings up the
options:
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You can create a NOR gate by double clicking on an OR gate which brings up the
options:
Documentation Standards
Follow the documentation guidelines found here. Refer to the sections on the README
and schematic visual structure. Diagram.pdf is not required for this lab.
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Simulation
To ensure the circuit simulates without error, make sure there is at least one receiver for every sender and that each receiver has exactly one sender. In addition, do not modify the canvas size.
If you do not have at least one receiver for every sender or if you have more than
one sender with the same name, your circuit will not simulate and you will lose
points.
Google Form
You are required to answer questions about the lab in this Google Form
Missing Wire Best Practices
MML has a known bug which causes some wires to disappear during the save process. To reduce the likelihood of this occurring, DO NOT use the
¡°Node¡± tool (it¡¯s a black dot located at the top-right of the tool palette). This tool is particularly vulnerable to the bug.
If this bug occurs, the grader will attempt to repair the missing wire
in your file. This is only possible if your circuit is very readable.
Make sure that wires do not cross whenever possible. Wire paths should be short and direct. Use senders and receivers liberally.
Grading Rubric (40 pt total)
4 pt simulates without errors
NOTE: All senders must have at least one receiver and every receiver must have exactly one sender.
Do not resize the canvas.
26 pt output matches the specification
6 pt part A
10 pt part B
10 pt part C
2 pt complete header comments on every page of schematic
2 pt useful & sufficient comments
2 pt clean visual structure / use of white space
2 pt README.txt file complete
2 pt Google form complete with at least 150 words
-2 pt for using AND + NOT gates instead of NAND gates
-2 pt for using OR + NOT gates instead of NOR gates
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-10 pt if first or second page of template is modified incorrectly, or
if the template isn’t used properly
-10 pt incorrect naming convention (e.g .LGI or lab1.lgi)
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Appendix
Here is some documentation from MML’s help menu:
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