Grading Criteria

• How well is Software & Hardware Design described?
• How well can this report be used to reproduce this project?
• Code Quality
• Overall Report Quality:
  • Software Block Diagrams
  • Hardware Block Diagrams

    Schematic Quality

  • Quality of technical challenges and solutions adopted.

In Memory of Chi Lam

In Memory of Chi Lam

June 7th, 1991 - October 27th, 2014

This project is dedicated to Chi Lam, a beloved friend, dedicated Computer Engineering student, and member of this team.

You will be missed, friend

Self-Driving Autonomous Car

Abstract

The objective of the project is to create a self-driving autonomous car in a 15 person team. The car utilizes several components and sensors in order to get from Point A to Point B. Implementation of the car involves multiple SJONE processor boards using FreeRTOS to communicate with each other via CAN bus.

Objectives & Introduction

Show list of your objectives. This section includes the high level details of your project. You can write about the various sensors or peripherals you used to get your project completed.

Team Members & Responsibilities

The team consisted of 15 undergraduate students taking a graduate level course, thus competing against the Master's level students.

We are

Master Controller Team
Charles Pham	Joshua Ambion	Michael Schneider
- Overall vehicle logic - Overall software vehicle Integration - CAN TX/RX messages architecture	- Vehicle hardware interfacing - Assistant to other teams - Module specific logic	- Module specific logic - CAN RX processing

Motor Controller Team
Nikko Esplana	Chi Lam
- Motor/steering control via PWM signals - interface/test/attach wheel encoder	- Rest in peace Chi!

Sensor Controller Team
Sanjay Maharaj	Wei-chieh "Andy" Lo
- Vehicle hardware - Sensor implementation - CAN communication	- Sensor implementation - Sensor values verification - CAN communication

Geographical Controller Team
Carlos Fernandez-Martinez	Zach Baumgartner	Albert Chen
- Compass calibration/integration	- GPS testing/integration	- CAN communication

Bridge Controller Team
Robert Julius	Tim Martin	Joseph Bourne
- Android Application	- Bluetooth Message Interface	- Board to CAN Communication

IO Controller Team
Devin Villarosa	George Sebastian
- Receive Task - GUI Interface - Headlights Task - uLCD Library	- Event Handle Task - GUI Interface - Headlights Task - uLCD Library

Schedule

Show a simple table or figures that show your scheduled as planned before you started working on the project. Then in another table column, write down the actual schedule so that readers can see the planned vs. actual goals. The point of the schedule is for readers to assess how to pace themselves if they are doing a similar project.

Final Product Schedule

Week#	Date	Task	Actual
1	10/12	CAN Network Benchtest	Complete
2	10/15	Basic CAN Communication	Complete
3	10/31	Secure devices to R/C car	Complete
4	11/7	Basic Vehicle Self-Driving Test	In progress
5	11/14	P2P testing and improved obstacle avoidance	In progress
6	11/31	Buffer time for previous tasks and increased vehicle speed	In progress

Sensor Controller Schedule

Week#	Date	Task	Actual
1	10/13	Sensor Input Distance Calibration	Incomplete: Sonar is mostly calibrated, IR still needs work. Need sensor value "filtering" logic.
2	10/17	Off car CAN network test (full team)	Completed. Able to send raw sensor value to master.
3	10/20	Interface Sensors with CAN	Completed. Updates to the formatting of data being sent is ongoing.
4	10/27	Mount Sensors and test coverage	Completed. Still need to mount with actual brackets.
5	10/31	Mount Sensors with 3d printed brackets	Completed. IR brackets to be printed based on offset.
6	11/1	Implement diagnostic LED patterns	Completed.
7	11/3	Send obstacle avoidance decisions to master	Completed. Raw values sent to master for processing.
8	11/4	Add RJ11 cabling to all sensors	Completed. Still need to make neat and tidy.
9	11/10	Eliminate outliers (software)	Completed.
10	11/13	Eliminate outliers by strengthening sensor wiring (hardware)	Completed.
12	11/24	Continue testing and tuning as necessary	In progress

Motor Controller Schedule

Week#	Date	Task	Actual
1	10/12	Open up servo and motor modules, find a speed sensor	Complete
2	10/19	Interface/test PWM bus to steering servo and DC motor	Complete
3	10/26	Allow self-driving capability with master/bridge/sensor teams	Incomplete, only partial self-driving achieved
4	11/2	Improve fine motor movements with master/sensor teams	Incomplete, still needs tweaking.
5	11/9	Once wheel encoder comes in, learn/test/implement onto car	Incomplete, wheel encoder cannot be implemented, scrapping.
6	11/16	Integrate wheel encoder with rest of car	Incomplete, scrapped wheel encoder.
7	11/23	Test for proper operation	Complete, added functionality for center steer and forward speed calibration.
8	11/30	Continue testing until proper operation	Complete, motor works as intended.

I/O Schedule

Week#	Date	Task	Actual
1	10/4	Create LCD Screen Library (create ability to set value, get value, and write string to LCD screen)	10/4 (String function completed on ~10/18)
2	10/4	Create LCD Screen GUI (generate forms for debugging and general usage)	10/4
3	10/11	LCD Library Test (Do unit tests on individual functions for LCD library) Ability to get value from gauge on screen. Ability to set value to gauge on screen. Ability to send a string value to screen.	10/11 (Finished string function on ~10/18)
4	10/11	Interface LCD with CAN Create task for LCD event loop. Create task for Receiving on CAN.	Complete (Completed on 10/26/2014)
5	10/18	Test LCD with CAN Process CAN Messages from system	Complete (Completed on 10/25/2014)
6	10/25	Implement onto Final Product	Complete (Completed on 11/23/2014)
7	11/2	Headlights for car (hardware and software) + Aesthetics for GUI + Clean up code	Complete (Completed on 12/01/2014) *NOTE Headlights are lost in hardware land

Communication Bridge and Android Schedule

Week#	Date	Task	Actual
1	10/13	CAN Network Test	Complete
2	10/20	Interface Bluetooth Module with CAN	Complete
3	10/27	Mount PCB on car	In progress
4	11/3	Create basic Android application	Completed on 10/18
5	11/10	Add map onto the Android application	In Progress
6	11/17	Send/receive CAN Messages via Android Application	Sending completed on 10/18, receiving in progress
7	11/24	Debug and Optimize Android Application	In progress
8	12/1	Continue Debugging and Optimizing as Necessary	In progress

Geographical Controller Schedule

Week#	Date	Task	Actual
1	10/8	Interface with GPS/Compass	Complete - receiving values
2	10/15	Finish core API	Complete
3	10/22	GPS get fix and receive raw data	Complete - raw data received, but need faster fix
4	10/22	Compass determine heading	Complete - heading may require additional calibration
5	10/29	Self calibration completed	Complete
6	10/29	GPS parse raw data to extract needed data	Complete - returns latitude, longitude, and calculated heading
7	10/29	Compass use heading from GPS to improve accuracy	In progress - may not provide tangible improvement
8	11/5	Improve GPS satellite procurement (antennae?)	Complete - attached antennae to GPS unit
9	11/12	Improve boot up time of GPS module via warm start	N/A - EZ start fast fix mode cannot coincide with 10 Hz update rate (defaults down to 1 Hz)
10	11/12	Fine tune compass calibration technique for accuracy	In progress
11	12/3	Buffer time for completion of previous tasks	In progress

Master Controller Schedule

Line Item #	Expected End Date	Task	Status
1	10/15/14	Decide on raw CAN struct architecture	Early completion
2	10/18/14	Develop and layout general common CAN messages	On-time completion
3	10/20/14	Design vehicle initialization procedure	Early completion
4	10/23/14	Develop and layout Inter-Controller Communication - Each Module's CAN messages	Early completion
5	10/25/14	Design vehicle initial running freed drive mode procedure - Controlled via Phone, no object detection and avoidance, no GPS, no Heading	Early completion
6	10/28/14	Complete design on vehicle running free drive mode procedure	On-time completion
7	10/30/14	Design vehicle initial running indoor drive mode procedure - Timed autonomous drive , object detection and avoidance, (possibly heading), and no GPS	In progress
8	11/01/14	All CAN message definitions complete	Early Completion
9	11/02/14	Design vehicle initial running gps drive mode procedure - Full autonomous drive , object detection and avoidance, heading and GPS	In progress
10	11/05/14	All CAN message receive processing complete	On-time completion
11	11/14/14	All basic vehicle functionality state machines implemented and verified	On-time completion
12	11/15/14	Complete design on vehicle running indoor drive mode procedure	In progress
13	11/20/14	Complete design on vehicle running gps drive mode procedure	In progress
14	11/30/14	Any additional advanced functionality implemented and verified	In progress

Parts List & Cost

Line Item#	Part Desciption	Vendor	Part Number	Qty	Cost ($)
1	CAN Board	Waveshare International Limited	SN65HVD230	15	92.00
2	Traxxas Slash Pro 2WD Short-Course R/C Truck	Traxxas	58034 Slash	1	337.00
3	Adafruit Ultimate GPS Breakout	Adafruit	MTK3339	1	39.95 + (4.685 Shipping)
4	Triple-axis Accelerometer+Magnetometer (Compass) Board	Adafruit	LSM303	1	14.95 + (4.685 Shipping)
5	GPS Antenna - External Active Antenna - 3-5V 28dB 5 Meter SMA	Adafruit	960	1	12.95 + (4.735 Shipping)
6	SMA to uFL/u.FL/IPX/IPEX RF Adapter Cable	Adafruit	851	1	3.95 + (4.735 Shipping)
7	3.5" Intelligent module w/ Touch	4D Systems	uLCD 35DT	1	89.00
8	2GB microSD Card
9	uUSB-PA5 Programming Adaptor
10	150mm 5 way Female-Female jumper cable
11	5 way Male-Male adaptor
12	Sharp Infrared Range Finder	4D Systems	GP2Y0A21	2	9.95 + 3.32 Shipping
13	SainSmart Sonar Ranging Detector	Amazon	HC-SR04	3	5.59
14	RC LED Headlights	Amazon Prime		2	5.99
15	XBee Bluetooth	Amazon Prime	WLS04051P	1	27.50
16	SJONE Board	Preet Industries		6	480.00
17	Traxxas XL5 ESC unit	dollarhobbyz.com	2WDS ESC	2	54.00 + (4.67 Shipping)
	Additional Shipping				$$$.$$
	Total Cost				$$$.$$

Design & Implementation

The design section can go over your hardware and software design. Organize this section using sub-sections that go over your design and implementation.

Hardware Design

    Discuss System Level Hardware Design
    *INCLUDE BLOCK DIAGRAM and PIN CONNECTIONS

Overall Hardware Design Components

58034 Traxxas Slash RC Truck: Traxxas Slash Pro 2WD Short-Course Truck: Came with TQ 2.4GHz radio transceiver + remote control, 8.4V/3000mAh Ni-MH Power 7-Cell Battery, and wall charger. Optional purchase: 7.4V/5800mAh Li-Po battery for longer operation.
SN65HVD230 CAN Board Transceiver: INSERT DESCRIPTION HERE The SN65HVD230 CAN board transceiver is used to interface the microcontrollers logical signals to CAN electrical specifications. The SN65HVD230 CAN board transceiver was chosen specifically because not only did it work perfectly for CAN interfacing, but it came pre-built with the in-line resistors. Because there were fifteen people in our team, this was desired because a lot of work would be needed if we built each CAN board transceiver individually. The transceivers were purchased on eBay for $8.99 each. However, the item's location was in China, so ordering early would be best for future students.
3D Printed Materials: Insert Description (Replace picture with 3D Prints)

Sensor Controller Team Hardware Design

    Discuss your hardware design of Sensor Controller
    *INCLUDE BLOCK DIAGRAM and PIN CONNECTIONS

Sensor Pin Connections

Line Item#	Node A Source	Node A Pin	Node B Source	Node B Pin	Description
1	3.3V Power Supply	3.3V	SJOne Board	3V3	SJOne Power
2	3.3V Power Supply	GND	SJOne Board	GND	SJOne Ground
3	CAN Transceiver	Tx	SJOne Board	P0.1 (Tx)	SJOne - CAN Tx
4	CAN Transceiver	Rx	SJOne Board	P0.0 (Rx)	SJOne - CAN Rx
5	CAN Transceiver	3.3V	3.3V Power Supply	3.3V	SJOne - CAN Power
6	CAN Transceiver	Ground	3.3V Power Supply	GND	SJOne - CAN Ground
7	HC-SR04 Ultrasonic Sensor (Front Left)	Vcc	5V Power Supply	+5V	Front Left Sensor Power
8	HC-SR04 Ultrasonic Sensor (Front Left)	GND	5V Power Supply	GND	Front Left Sensor GND
9	HC-SR04 Ultrasonic Sensor (Front Left)	Echo	SJOne Board	P2.0	Front Left Sensor Echo
10	HC-SR04 Ultrasonic Sensor (Front Left)	Trig	SJOne Board	P2.1	Front Left Sensor Trig
11	HC-SR04 Ultrasonic Sensor (Front Right)	Vcc	5V Power Supply	+5V	Front Right Sensor Power
12	HC-SR04 Ultrasonic Sensor (Front Right)	GND	5V Power Supply	GND	Front Right Sensor GND
13	HC-SR04 Ultrasonic Sensor (Front Right)	Echo	SJOne Board	P2.2	Front Right Sensor Echo
14	HC-SR04 Ultrasonic Sensor (Front Right)	Trig	SJOne Board	P2.3	Front Right Sensor Trig
15	LV-MaxSonar-EZ-0 Ultrasonic Range Sensor (Front Middle)	Vcc	5V Power Supply	+5V	Front Middle Sensor Power
16	LV-MaxSonar-EZ-0 Ultrasonic Range Sensor (Front Middle)	GND	5V Power Supply	GND	Front Middle Sensor GND
17	LV-MaxSonar-EZ-0 Ultrasonic Range Sensor (Front Middle)	Echo	SJOne Board	P2.4	Front Middle Sensor Echo
18	LV-MaxSonar-EZ-0 Ultrasonic Range Sensor (Front Middle)	Trig	SJOne Board	P2.5	Front Middle Sensor Trig
19	HC-SR04 Ultrasonic Sensor (Rear Left)	Vcc	5V Power Supply	+5V	Rear Left Sensor Power
20	HC-SR04 Ultrasonic Sensor (Rear Left)	GND	5V Power Supply	GND	Rear Left Sensor GND
21	HC-SR04 Ultrasonic Sensor (Rear Left)	Echo	SJOne Board	P2.6	Rear Left Sensor Echo
22	HC-SR04 Ultrasonic Sensor (Rear Left)	Trig	SJOne Board	P2.7	Rear Left Sensor Trig
23	HC-SR04 Ultrasonic Sensor (Rear Right)	Vcc	5V Power Supply	+5V	Rear Right Sensor Power
24	HC-SR04 Ultrasonic Sensor (Rear Right)	GND	5V Power Supply	GND	Rear Right Sensor GND
25	HC-SR04 Ultrasonic Sensor (Rear Right)	Echo	SJOne Board	P2.8	Rear Right Sensor Echo
26	HC-SR04 Ultrasonic Sensor (Rear Right)	Trig	SJOne Board	P2.9	Rear Right Sensor Trig
27	CAN Transceiver	CANL	CAN BUS	CANL	CANL to CAN BUS
28	CAN Transceiver	CANR	CAN BUS	CANR	CANR to CAN BUS

Sensor Controller Hardware Design Components

Method of Operation
1. INPUT: The sensor is triggered by a 10uS pulse HIGH on the trig pin.
2. RANGING: The sensor sends out eight 40kHz sonar pulses.
3. OUTPUT: The sensor outputs a pulse HIGH with the pulse time depending on the distance of the object on the echo pin.

The the output from the echo pin can be seen below, as captured by an oscilloscope.


While the HC-SR04 is an affordable way to implement distance ranging ability, there are some points to be aware of prior to implementation:
1. The sonar frequency is approximately 40kHz. Using multiple sonar sensors to detect the same object could lead to erroneous data due to interference.
2. As distance increases, so does noise. The reliable range of values in our case were between 3cm and 70 cm. Any other values were filtered out in software.

HC-SR04 Ultrasonic Distance Sensor: The HC-SR04 is a distance sensor which detects objects using ultrasonic signals. The sensor is capable of detecting distances within 2cm-500cm. The sensor runs off 5V DC. Four pins are used: Vcc, Ground, Trig, and Echo. These sensors are relatively inexpensive, so four sensors were purchased. The four HC-SR04 sensors were implemented on our car at the following locations: front-left, front-right, rear-left, and rear-right.

LV-MaxSonar-EZ0 Ultrasonic Range Sensor: The LV-MaxSonar-EZ0 is a high sensitivity and wide beam ultrasonic range sensor. The sensor is capable of reading objects at a maximum range of 645cm. The sensor is more expensive is, therefore, a lot stronger than the HC-SR04 sensors. Because the sensor's capabilities, it was used as the front-center sensor.

Motor Controller Team Hardware Design

As seen above, the car battery(accepts compatible Ni-MH, Li-Po, and Ni-Cad batteries) powers the ESC unit (XL-5), which in turn drives the Titan 12T-550 motor and also powers the steering servo. It is necessary for the ESC unit, steering servo and SJ One board to share a common ground in order for the PWM signals to have the same reference voltage.

The CAN transceiver requires the use of the SJ One Board's +3.3V and GND, as well as P0.0 (CAN RX) and P0.1 (CAN TX).

P2.0/P2.1 (PWM1/PWM2) controls the steering/motor via the SJ One board by sending out PWM signals that change the width of a 20ms period waveform. 1ms width represents a 0% duty cycle, 1.5ms width represents a 50% duty cycle, and 2ms width represents a 100% duty cycle.

Controlling motor and steering

In the photo above, a digital oscilloscope probes a PWM pin on the SJ One board and detects a signal with a 3.3 peak-to-peak voltage, a 100hz PWM frequency, and a width of 1.5ms (50% duty cycle). In terms of steering control, a width between 1ms to 1.499ms equates to left steering (1ms = max left angle) and a width between 1.501ms to 2ms equates to right steering (2ms = max right angle). The motor is similar, such that a width between 1ms to 1.499ms equates to a reverse throttle and a width between 1.501ms to 2ms equates to a forward throttle. For both steering and motor control, 1.5ms (50% duty cycle) represents a center steer or non-throttle.

Motor Controller Hardware Design Components

58034 Traxxas Slash RC Truck: Traxxas Slash Pro 2WD Short-Course Truck: Came with TQ 2.4GHz radio transceiver + remote control, 8.4V/3000mAh Ni-MH Power 7-Cell Battery, and wall charger. Optional purchase: 7.4V/5800mAh Li-Po battery for longer operation.
Traxxas XL-5 Electronic Speed Control (ESC) Unit: Waterproof ESC unit, it directly controls the movement of the Titan 12T 550. It is powered by the car battery and shares a common ground between the steering servo and SJ One board. The ESC controls the throttle of the motor via PWM signals being sent from the SJ One board, which is then sent as a positive or negative voltage to drive the motor.
Steering Servo: Powered by the ESC unit and shares a common ground between the ESC unit and SJ One board. It is controlled via PWM signals sent from the SJ One board and regulates the angle of the front wheels.

Motor Pin Connections

Line Item#	Node A Source	Node A Pin	Node B Source	Node B Pin	Description
1	3.3V Power Supply	3.3V	SJOne Board	3V3	SJOne Power
2	3.3V Power Supply	GND	SJOne Board	GND	SJOne Ground
3	CAN Transceiver	CAN Tx	SJOne Board	P0.1 (Tx)	SJOne - CAN Tx
4	CAN Transceiver	CAN Rx	SJOne Board	P0.0 (Rx)	SJOne - CAN Rx
5	CAN Transceiver	3.3V	3.3V Power Supply	3.3V	SJOne - CAN Power
6	CAN Transceiver	Ground	3.3V Power Supply	GND	SJOne - CAN Ground
7	CAN Transceiver	CANL	CAN BUS	CANL	CANL to CAN BUS
8	CAN Transceiver	CANR	CAN BUS	CANR	CANR to CAN BUS
9	Steering Servo	PWM Port	SJOne Board	P2.0 PWM	Steering Control
10	Steering Servo	Ground	SJOne Board	GND	Common ground for reference voltage
11	ESC/Motor	PWM Port	SJOne Board	P2.1 PWM	Motor Control
12	ESC/Motor	Ground	SJOne Board	GND	Common ground for reference voltage

I/O Team Hardware Design

    Discuss your hardware design of I/O
    *INCLUDE BLOCK DIAGRAM and PIN CONNECTIONS

I/O Design Components

uLCD-35DT Intelligent Display Module: INSERT DESCRIPTION HERE The uLCD-35DT is an intelligent display module used to display information of the system, such as viewing the GPS destination, and a controller for the system, such as setting the car to indoor mode which tests for sensor only navigation. The uLCD-35DT system was chosen specifically because of its touch screen capabilities. The display is driven by A DIABLO16 processor. The processor allows stand-alone functionality for the screen. In order to program the screen with an interactive GUI, the 4D Systems Workshop 4 IDE Software was used.

I/O Pin Connections

Line Item#	Node A Source	Node A Pin	Node B Source	Node B Pin	Description
1	LCD	1 (LCD +5V)	5V Power Supply	5V	uLCD 35DT LCD Power
2	LCD	7 (LCD GND)	5V Power Supply	GND	uLCD 35DT LCD Ground
3	LCD	5 (LCD RX)	SJOne Board	RX3	uLCD 35DT LCD Receive Pin
4	LCD	3 (LCD TX)	SJOne Board	TX3	uLCD 35DT LCD Transmit Pin
5	3.3V Power Supply	+3.3V	SJOne Board	3V3	SJOne Power
6	3.3V Power Supply	GND	SJOne Board	GND	SJOne Ground
7	UART2 RX	P2.9	SJOne RX
8	UART2 TX	P2.8	SJOne TX
9	+5V	GPIO P2.0	White LED1
10	+5V	GPIO P2.1	White LED2
11	+5V	GPIO P2.2	Red LED1
12	+5V	GPIO P2.3	Red LED2
13	CAN Transceiver	CAN Tx	SJOne Board	P0.1 (Tx)	SJOne - CAN Tx
14	CAN Transceiver	CAN Rx	SJOne Board	P0.0 (Rx)	SJOne - CAN Rx
15	CAN Transceiver	CAN 3.3V	3.3V Power Supply	3.3V	SJOne - CAN Power
16	CAN Transceiver	CAN Ground	3.3V Power Supply	GND	SJOne - CAN Ground
17	CAN Transceiver	CANL	CAN BUS	CANL	CANL to CAN BUS
18	CAN Transceiver	CANR	CAN BUS	CANR	CANR to CAN BUS

Communication Bridge + Android Hardware Design

    Discuss your hardware design of Communication Bridge and Android
    *INCLUDE BLOCK DIAGRAM and PIN CONNECTIONS

Communication Bridge Pin Connections

Line Item#	Node A Source	Node A Pin	Node B Source	Node B Pin	Description
1	3.3V Power Supply	3.3V	SJOne Board	3V3	SJOne Power
2	3.3V Power Supply	GND	SJOne Board	GND	SJOne Ground
3	CAN Transceiver	CAN Tx	SJOne Board	P0.1 (Tx)	SJOne - CAN Tx
4	CAN Transceiver	CAN Rx	SJOne Board	P0.0 (Rx)	SJOne - CAN Rx
5	CAN Transceiver	CAN 3.3V	3.3V Power Supply	3.3V	SJOne - CAN Power
6	CAN Transceiver	CAN Ground	3.3V Power Supply	GND	SJOne - CAN Ground
7	Bluetooth Bee	VCC	3.3V Power Supply	3V3	Bluetooth Bee Power
8	Bluetooth Bee	GND	3.3V Power Supply	GND	Bluetooth Bee GND
9	Bluetooth Bee	RX	SJOne Board	P2.9 (RXD2)	Bluetooth Bee RX
10	Bluetooth Bee	TX	SJOne Board	P2.8 (TXD2)	Bluetooth Bee TX
11	CAN Transceiver	CANL	CAN BUS	CANL	CANL to CAN BUS
12	CAN Transceiver	CANR	CAN BUS	CANR	CANR to CAN BUS

Communication Bridge + Android Hardware Design Components

Bluetooth Bee Standalone: INSERT DESCRIPTION HERE The Bluetooth Bee Standalone Module by Seeed Studio Works allows for the connection of a bluetooth module onto the XBee Socket of the SJOne Board. This module contains an ATMEGA168 for reprogramming. Only the SJOne Board's UART2/3 pins are capable of transferring data to the module, depending on which UART the XBee Socket is connected to with a switch configuration. When the module receives the command to enter pairing mode (by sending the message "\r\n+INQ=1\r\n" through UART), the red and blue LEDs will alternate flashing light. Once the module has been paired, then the bluetooth module's blue LED will flash once per two seconds. Otherwise, the blue LED will flash twice per second. This module was chosen for its XBee Socket compatibility.

Geographical Controller Team Hardware Design

    Discuss your hardware design of Geographical Controller
    *INCLUDE BLOCK DIAGRAM and PIN CONNECTIONS

Geographical Pin Connections

Line Item#	Node A Source	Node A Pin	Node B Source	Node B Pin	Description
1	3.3V Power Supply	3.3V	SJOne Board	3V3	SJOne Power
2	3.3V Power Supply	GND	SJOne Board	GND	SJOne Ground
3	CAN Transceiver	Tx	SJOne Board	P0.1 (Tx)	SJOne - CAN Tx
4	CAN Transceiver	Rx	SJOne Board	P0.0 (Rx)	SJOne - CAN Rx
5	CAN Transceiver	3.3V	3.3V Power Supply	3.3V	SJOne - CAN Power
6	CAN Transceiver	Ground	3.3V Power Supply	GND	SJOne - CAN Ground
7	MTK3339 GPS	VCC	5V Power Supply	+5V	MTK3339 GPS Power
8	MTK3339 GPS	GND	5V Power Supply	GND	MTK3339 GPS GND
9	MTK3339 GPS	RX	SJOne Board	RXD2	MTK3339 GPS RX
10	MTK3339 GPS	TX	SJOne Board	TXD2	MTK3339 GPS TX
7	LSM303 Compass + Accelerometer	VIN	5V Power Supply	+5V	Compass + Accelerometer Power
8	LSM303 Compass + Accelerometer	GND	5V Power Supply	GND	Compass + Accelerometer GND
9	LSM303 Compass + Accelerometer	RX	SJOne Board	RXD2	Compass + Accelerometer SCL
10	LSM303 Compass + Accelerometer	TX	SJOne Board	TXD2	Compass + Accelerometer SDA
11	CAN Transceiver	CANL	CAN BUS	CANL	CANL to CAN BUS
12	CAN Transceiver	CANR	CAN BUS	CANR	CANR to CAN BUS

Geographical Controller Hardware Design Components

Adafruit MTK3339 GPS: INSERT DESCRIPTION HERE
Adafruit LSM303 Compass: INSERT DESCRIPTION HERE

Master Controller Team Hardware Design

    Discuss your hardware design of Master Controller
    *INCLUDE BLOCK DIAGRAM and PIN CONNECTIONS

Master Pin Connections

Line Item#	Node A Source	Node A Pin	Node B Source	Node B Pin	Description
1	3.3V Power Supply	3.3V	SJOne Board	3V3	SJOne Power
2	3.3V Power Supply	GND	SJOne Board	GND	SJOne Ground
3	CAN Transceiver	CAN Tx	SJOne Board	P0.1 (Tx)	SJOne - CAN Tx
4	CAN Transceiver	CAN Rx	SJOne Board	P0.0 (Rx)	SJOne - CAN Rx
5	CAN Transceiver	CAN 3.3V	3.3V Power Supply	3.3V	SJOne - CAN Power
6	CAN Transceiver	CAN Ground	3.3V Power Supply	GND	SJOne - CAN Ground
7	CAN Transceiver	CANL	CAN BUS	CANL	CANL to CAN BUS
8	CAN Transceiver	CANR	CAN BUS	CANR	CANR to CAN BUS

Hardware Interface

In this section, you can describe how your hardware communicates, such as which BUSes used. You can discuss your driver implementation here, such that the Software Design section is isolated to talk about high level workings rather than inner working of your project.

SYSTEM LEVEL HARDWARE INTERFACE INTERFACE GOES HERE

Sensor Controller Team Hardware Interface

Sensor team uses CAN bus as a communication bus to communicate with master. The specific message ID used is 0x330. There are 5 sensor values (Front Left, Front, Front Right, Rear Left, Rear Right). 8 bits of integer is the size of our data for each sensor. frontLeftDistance:uint8_t:bytes[0] frontDistance:uint8_t:bytes[1] frontRightDistance:uint8_t:bytes[2] rearLeftDistance:uint8_t:bytes[3] rearDistance:uint8_t:bytes[4] rearRightDistance:uint8_t:bytes[5] After microcontroller obtained all the values, a tasks that is designated to send data to master will run. Every sensor value is updated periodically.

Motor Controller Team Hardware Interface

The motor team only uses the CAN bus for simple communication. Only 2 messages are being listened for: 0x100 and 0x124.

 -0x100 is the master heartbeat message and motor replies back with message 0x200 for acknowledgement.

 -0x124 is the master movement command message. Master sends a uint8_t byte, with unique numbers that 
  represent specific movement commands such as forward, reverse, left forward, right reverse, etc.

During each heartbeat, a second message is sent: 0x221

 -0x221 contains 2 dwords, as it sends two float values (reinterpreted to uint32_t) to I/O. dword[0] 
  is a float type containing the forward speed value and dword[1] is also a float type containing the 
  neutral steer value.

PWM signals are sent from the SJ One board towards the ESC unit and steering servo. Depending on the width of the signals sent (ranging between 1ms to 2ms), the motor and steering can be manipulated.

I/O Team Hardware Interface

Communication Bridge + Android Hardware Interface

    Discuss your hardware design of Communication Bridge and Android
    *SHOW HOW FRAMES ARE SENT

123

Geographical Controller Team Hardware Interface

    Discuss your hardware design of Geographical Controller
    *SHOW HOW FRAMES ARE SENT
    

Master Controller Team Hardware Interface

    Discuss your hardware design of Master Controller
    *SHOW HOW FRAMES ARE SENT

Software Design

Show your software design. For example, if you are designing an MP3 Player, show the tasks that you are using, and what they are doing at a high level. Do not show the details of the code. For example, do not show exact code, but you may show psuedocode and fragments of code. Keep in mind that you are showing DESIGN of your software, not the inner workings of it.

SYSTEM LEVEL SOFTWARE DESIGN GOES HERE

Sensor Controller Team Software Design

    Describe how your hardware communicates. WHAT BUSes were used
    *SHOW SOFTWARE FLOWCHART DIAGRAM

Motor Controller Team Software Design

The Motor module only has one running task. That is to listen to two CAN messages from the Master module (0x100 and 0x124). During each heartbeat (0x100), Motor will send back an acknowledgement CAN message (0x200) and send the current forward speed value and neutral steer value with a CAN message (0x221) for the I/O module. When Motor receives (0x124) from Master, it will unpack that CAN message and execute the given movement command, which can be seen in the table below.

Motor Movement Commands

Master CAN Payload Value	Movement Command
0	No command
1	Slow forward
2	Fast forward
3	Slow reverse
4	Fast reverse
5	Slow right forward
6	Slow left forward
7	Slow right reverse
8	Slow left reverse
9	Stop

I/O Team Software Design

The I/O Software is based off of two tasks: The Event Handler Task and the RX Task.

Event Handler Task (High Priority):

This Task receives any immediate messages sent from the uLCD, processes the message, and sends the message to the CAN BUS.

This task enables the system to: Turn On/Off the Vehicle and Change Vehicle Modes.

RX Task (Low Priority):

This task receives all messages from the CAN BUS, and outputs message data onto the uLCD

High Level IO Software Logic

Event Handler Task Logic

RX Task Logic

Communication Bridge + Android Software Design

    Discuss your hardware design of Communication Bridge and Android
    *SHOW SOFTWARE FLOWCHART DIAGRAM

Geographical Controller Team Software Design

    Discuss your hardware design of Geographical Controller
    *SHOW SOFTWARE FLOWCHART DIAGRAM
    

Master Controller Team Software Design

    Discuss your hardware design of Master Controller
    *SHOW SOFTWARE FLOWCHART DIAGRAM

Software Interface

This section includes implementation, but again, not the details, just the high level. For example, you can list the steps it takes to communicate over a sensor, or the steps needed to write a page of memory onto SPI Flash. You can include sub-sections for each of your component implementation.

SYSTEM LEVEL SOFTWARE IMPLEMENTATION GOES HERE

Sensor Controller Team Software Interface

    Describe steps to communicate hardware
    

Motor Controller Team Software Interface

The main function initializes the CAN bus and proceeds to call the only task called CAN_rx_tx.

 -CAN_rx_tx.hpp contains an object declaration for a task that receives and sends out CAN messages.
 -CAN_rx_tx.cpp contains instructions on what CAN message IDs to listen for and what to execute when 
  those messages are received.
 -motor_typedef.h contains nomenclature for values used within the program.

I/O Team Software Interface

    Describe steps to communicate hardware

Communication Bridge + Android Software Interface

    Describe steps to communicate hardware

Geographical Controller Team Software Interface

    Describe steps to communicate hardware
    

Master Controller Team Software Interface

    Describe steps to communicate hardware

CAN Communication Table

Master CAN Communication Table

TX Message ID	TX Message Transmit Rate	TX Message Description	RX Response Message ID	RX Listening Module
0x100	1hz Periodic	Request Heartbeat (Module state and Timestamp)	0x200, 0x300, 0x400, 0x500, 0x600 (Respectively)	Motor, Sensor, Geo, Bridge, IO (Respectively)
0x101	1hz Periodic	Send Vehicle State	N/A	Motor, Sensor, Geo, Bridge, IO
0x124	Spontaneous	Set Torque and Steering	N/A	Motor
0x140	Spontaneous	Send Destination GPS	N/A	Geo
0x14A	Spontaneous	Request Calibrate Compass	N/A	Geo
0x14B	Spontaneous	Request Compass Heading	N/A	Geo
0x14C	Spontaneous	Request Current GPS	N/A	Geo
0x14D	Spontaneous	Request Current Time	N/A	Geo

Motor CAN Communication Table

TX Message ID	TX Message Transmit Rate	TX Message Description	RX Response Message ID	RX Listening Module
0x221	1z Periodic	Transmits forward speed and neutral steer values.	N/A	I/O

Sensor CAN Communication Table

TX Message ID	TX Message Transmit Rate	TX Message Description	RX Response Message ID	RX Listening Module
0x330	10hz Periodic	Transmit all sensor's distances	N/A	Master, IO

Geo CAN Communication Table

TX Message ID	TX Message Transmit Rate	TX Message Description	RX Response Message ID	RX Listening Module
0x441	10hz Periodic	Transmit Current GPS Coordinates	N/A	Master, IO
0x445	10hz Periodic	Transmit Current Heading and Bearing	N/A	Master, IO
0x449	10hz Periodic	Transmit Current GPS Heading	N/A	Master, IO
0x465	Spontaneous	Signal User that Calibration is complete	N/A	I/O

Bridge CAN Communication Table

TX Message ID	TX Message Transmit Rate	TX Message Description	RX Response Message ID	RX Listening Module
0x050	Spontaneous	Request Drive Mode change to Free Drive	N/A	Master
0x051	Spontaneous	Request Drive Mode change to GPS Drive	N/A	Master
0x052	Spontaneous	Request Drive Mode change to Indoor Drive	N/A	Master
0x053	Spontaneous	Transmit Destination GPS Coordinates	N/A	Master
0x055	Spontaneous	Request Vehicle Start Driving Command	N/A	Master
0x056	Spontaneous	Request Vehicle Turn Off	N/A	Master
0x057	Spontaneous	Request Vehicle Turn On	N/A	Master
0x058	Spontaneous	Send Free Drive Turn Left	N/A	Master
0x059	Spontaneous	Send Free Drive Straight	N/A	Master
0x05A	Spontaneous	Send Free Drive Turn Right	N/A	Master
0x05B	Spontaneous	Send Free Drive Stop	N/A	Master
0x05C	Spontaneous	Send Free Drive Reverse Left	N/A	Master
0x05D	Spontaneous	Send Free Drive Reverse Straight	N/A	Master
0x05E	Spontaneous	Send Free Drive Reverse Right	N/A	Master

IO CAN Communication Table

TX Message ID	TX Message Transmit Rate	TX Message Description	RX Response Message ID	RX Listening Module
0x060	Spontaneous	Request Drive Mode change to Free Drive	N/A	Master
0x061	Spontaneous	Request Drive Mode change to GPS Drive	N/A	Master
0x062	Spontaneous	Request Drive Mode change to Indoor Drive	N/A	Master
0x063	Spontaneous	Request Vehicle Turn On	N/A	Master
0x064	Spontaneous	Request Vehicle Turn Off	N/A	Master
0x065	Spontaneous	Transmit Destination GPS Coordinates	N/A	Master
0x066	Spontaneous	Request Vehicle Start Driving Command	N/A	Master
0x067	Spontaneous	Start Geo Calibration	N/A	Geo

Testing

---

Sensor Controller Testing

Sensor Controller Testing #1

Describe how you tested the Sensors Sensors are calibrated prior to any testings. 1. For individual sensors: Set a obstacle(36" x 48" poster board) in front of a sensor and sensor team verifies the sensor values with a ruler. Repeat this process with different distances (20cm, 40cm,and 60cm). 2. Detect any outlier: Set a obstacle and allow sensor to detect for period of time and sensor team verifies values within the period. If there were outliers, sensor team would verify the wiring or write a filtering algorithm. 3. Integrated test: After all sensors are tested individually, sensor team tested collaboratively with master. Sensor team would sent CAN message (5 sensor values) to master team and check if master team can perform certain operations according to different sensor values.

---

Motor Controller Testing

Motor Controller Testing #1

Describe how you tested the motors

---

I/O Testing

I/O Testing #1: uLCD UART Communication

Testing the following API calls: -Write String -Write int to String -Write float to String -uLCD TX events

I/O Testing #2: CAN COMMUNICATION

Tested if messages are sending and receiving tasks are operating correctly

I/O Testing #3: Data Processing

Tested if all tasks are processing the CAN frames appropriately

---

Communication Bridge + Android Testing

Communication Bridge + Android Testing #1

Describe how you tested the Communication Bridge + Android

---

Geographical Controller

Geographical Controller

Describe how you tested the Geographical Controller

---

Master Controller

Master Controller Testing #1

Describe how you tested the Master Controller

---

Technical Challenges

Sensor Controller Team Issues

MY ISSUE #1 TITLE

PROBLEM:

RESOLUTION:

FUTURE RECOMMENDATIONS:

MY ISSUE #2 TITLE

PROBLEM:

RESOLUTION:

FUTURE RECOMMENDATIONS:

Motor Controller Team Issues

Motor Controller Issue #1

PROBLEM:

RESOLUTION:

FUTURE RECOMMENDATIONS:

Motor Controller Issue #2

PROBLEM:

RESOLUTION:

FUTURE RECOMMENDATIONS:

I/O Team Issues

I/O Team Issue #1

PROBLEM:

Tasks blocking each other, thus slowing down performance

RESOLUTION:

Restructured task architecture

FUTURE RECOMMENDATIONS:

Draw out architecture first, then code

I/O Team Issue #2

PROBLEM:

RESOLUTION:

FUTURE RECOMMENDATIONS:

Communication Bridge + Android Team Issues

Communication Bridge + Android Issue #1

PROBLEM:

RESOLUTION:

FUTURE RECOMMENDATIONS:

Communication Bridge + Android #2

PROBLEM:

RESOLUTION:

FUTURE RECOMMENDATIONS:

Geographical Controller Issues

Geographical Controller #1

PROBLEM: Received a blend of multiple formats from the GPS module.

RESOLUTION:

FUTURE RECOMMENDATIONS:

Geographical Controller #2

PROBLEM: Values from the accelerometer were not stable.

RESOLUTION: Implemented functions to calibrate. Upon boot, offsets are calculated by polling and averaging the values of x,y, and z at standstill and subtracting all those values from 0 (because 0 is the supposed values for x,y, and z during standstill). Whenever the accelerometer task grabs the values from the registers in the gps module, it will add the value of the corresponding offset to it, producing calibrated values.

FUTURE RECOMMENDATIONS:

Master Controller Team Issues

Master Controller Issue #1

PROBLEM:

RESOLUTION:

FUTURE RECOMMENDATIONS:

Master Controller#2

PROBLEM:

RESOLUTION:

FUTURE RECOMMENDATIONS:

Conclusion

Conclude your project here. You can recap your testing and problems. You should address the "so what" part here to indicate what you ultimately learnt from this project. How has this project increased your knowledge?

Project Video

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Project Source Code

• Sourceforge Source Code Link

References

Acknowledgement

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References Used

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Appendix

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