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Digital Ruler

Kayley Seow's APCSA winter break project.
Shortcuts: Introduction, Photos and Demo, Slide Deck, Project Presentation.

Introduction

TL;DR I made a ruler — just take a look at this beauty!

A photo of the one and only Digital Ruler

About

This repository contains my code to make the Digital Ruler using an Arduino Uno, a four seven-segment display, and a HC-SR04 (an ultrasonic ranging module) sensor. The entirety of the project was created and built during winter break as my submission for Project GradeBoost.

Repository Navigation

Here is a quick guide to the Digital Ruler repository. If you are looking for a specific file or want to know what each file is for, this should help you.

  • DigitalRuler.ino is the main file containing the code I used to run my fully assembled Digital Ruler. Should be run using the Arduino IDE.
  • HCSR04Test.ino is code I write to test out and calibrate my HC-SR04 sensor to see if it was working. I added line 24 because my sensor was having trouble calibrating and I will explain why I did that later — you might want to consider doing something similar with your sensor.
  • Test1.ino is the first four seven-segment test file. This file tests the digits one at a time.
  • Test2.ino is the second four seven-segment test file. This file tests all the digits together.

Materials List

  • 1 Arduino Uno
    • I borrowed it from Mr. B, which came in a kit from Vilros.
  • 1 Breadboard
  • 1 Four Seven-Segment Display
  • 1 HC-SR04 Sensor
  • 8 4-Band Resistors
    • From my kit, I chose the resistors with 330 Ohms with ± 5% Tolerance (Orange Orange Brown Gold)
    • You need 8 to control the 8 different parts of the Seven-Segment Display (7 segments + 1 for decimal point)
  • 14 Jumper Wires (MM)

Photos and Demo

  • Slide Deck with Photos
  • Setup and Test of the HC-SR04 Sensor. Left to Right: Top view of HC-SR04 Sensor, Sensor Setup with Data on Monitor, Top View of the Sensor Setup.
    Photo of HC-SR04 Sensor, Top View Photo of HC-SR04 Sensor Setup With Data Displayed on Monitor Photo of HC-SR04 Sensor Setup, Top View
  • Testing the Four Seven-Segment Display. Left to Right: Top View of FSSD, Testing the first digit of the FSSD, Testing all the digits of the FSSD, Combining both HC-SR04 Sensor and the Four Seven Segment Display (at this point the FSSD was not displaying the correct numbers).
    Photo of the Four Seven-Segment Display, Top View Testing First Digit of the Four Seven-Segment Display Testing All of the Digits of the Four Seven-Segment Display Combining both the HC-SR04 Sensor and the Four Seven Segment Display
  • Demo and Final Setup of the Digital Ruler. Left to Right: Demo of the Digital Ruler at 1cm increments, Demo of the Digital Ruler at a 5cm increment, Photo of the Complete Digital Ruler, Full photo of the complete Digital Ruler.
    Demo of the Digital Ruler at 1cm increments Demo of the Digital Ruler at a 5cm increment Photo of the Complete Digital Ruler Photo of the Complete Digital Ruler zoomed out for better view

Project Presentation (Original Presentation)

Arduino Interface

  • Arduino has its own open source IDE which sends code to the connected Arduino board
  • I coded my project in C++, because that is the language which the Arduino can run on (it was a bit of a challenge for me)
  • In the code, there is a void setup which sets out all the values needed (e.g. which pins are for what)
  • There is a void loop which runs the code inside it indefinitely, or until the Arduino is stopped

Accessories - 4 seven segment display

  • Need voltage in order to run
  • +-, one is low, other is high
  • In order to pass a current through, it has to be connected to positive
  • Connected to pins, which give it the voltage
  • Resistors help to determine brightness, so a large resistor is not as bright, vice versa
    • Explained by the equation current = voltage/resistance
  • The main thing about this display is to control the current
  • The logic behind a four seven segment display is that you need to switch between all the digits really quickly in order to give the illusion of a stable display, something like a flipbook

Accessories - HC-SR04

  • Measures from 2cm to 4 meters
  • Receives and puts out signals to detect the length
  • Trigger pin sends waves out and asks the unit to start to measure
  • When the wave comes back it is recorded by echo pin and sent to the board, which measures out the actual distance
  • The the input is a 10 microseconds ttl pulse
    • By the way, ttl stands for transistor transistor logic
  • Needs 5 volts to run, thus connected to the five volt pin

The Process:

1. Setup and test the HC-SR04 sensor

  • The echo and the trigger pins are connected to pins 2 and 3
  • The ground and voltage is also connected to the ground and the 5 volt
  • My setup: I ran the code and marked tape along my desk in order to test out the sensor
  • Problems with the sensor input
    • The serial output for the original code was printing out wack values so I had to measure out distances, gather the values, and calibrate my code using resulting ratio
    • Graph of actual distance vs. distance appearing on serial was linear, which meant I was able to get a ratio
    • I averaged out the ratios and got my average adjustment factor, which I multiplied the actual distance by
    • The logic: measured distance (distance appearing on serial) divided by average adjustment factor ≈ actual distance
    • When I do not divide the distance by the calculated average adjustment factor, the values that are displayed are not correct (you can tell by the outrageous numbers)
    • When I divide the distance by the calculated average adjustment factor, the values that are displayed are much more reasonable

2. Setup and test the 4 seven-segment display

  • I tested the display separate to the ultrasonic sensor to see if it was working
  • Tested two different ways, the first being testing the first digit and then testing the digits all together
  • I did not run into any problems with my 4 seven-segment display

3. Combine the two together

  • I had problems with the display
  • First, I was constricted to the 14 pins on the Arduino board
  • The ultrasonic ranging module would not function if I used pins 0 or 1
  • The display could not use pins 0 and 1 due to the interference from the ultrasonic ranging module thus, with two less pins to work with, I had to sacrifice the first digit and the decimal point
  • The display can only display 1 digit at a time, so in order to create the illusion of a stable 4 digit display, I need to turn on one at a time and repeat at an extremely fast rate

4. THE RULER FINALLY WORKS!!

  • What I learned:
    • How to code C++ in order to run the Arduino
    • The debugging process for both hardware and software is extremely long and tedious, but the results are often rewarding
    • How to work around my limitations, like the limited number of pins on my board
    • Deeper knowledge of how my accessories work and how to troubleshoot them if problems arise and a new understanding of how my accessories interact with each other and the board

Bibliography