F14: Team2-Self Driving Car - AUG

Self Driving Car

Abstract

Objective and Scope

Team Members & Responsibilities

• Sensor Controller
  • Amey Patil
  • Sujith Durgad
  • Arvind Allawadi

• Motor Controller and Power
  • Digvijay Patil (Master Documenation)
  • Rohan Jani
  • Mahesh Chudasama

• Display
  • Mradula Nayak
  • Karthik Govindaswamy

• Communication Bridge + Android
  • Siddhata Patil
  • Mohammed Raashid Kheruwala
  • Huzefa Siyamwala

• Geographical Controller
  • Yash Parulekar
  • Ajinkya Khasnis
  • Harsh Lavingia
  • Anand Dumbre

• Master Controller
  • Pradyumna Upadhya

Introduction

Schedule

Common Schedule

Sl. No	Start Date	End Date	Task	Status	Actual Completion Date
1	9/16/2014	10/7/2014	Finish Ordering project hardware parts	Completed.	11/10/2014
2	10/5/2014	10/21/2014	Fine tune subscriber code	Completed	10/28/2014
3	10/7/2014	10/21/2014	Finish Development of CAN Transceiver boards	Completed	10/25/2014
4	10/5/2014	11/4/2014	Sub teams finalize and implement dependency code(atleast single API per team)	Completed	10/28/2014
5	10/5/2014	10/28/2014	Finish hardware	Completed	10/27/2014
6	10/28/2014	12/2/2014	Start integration and testing.	Scheduled	12/19/2014

Master Team Schedule

Sl. No	Start Date	End Date	Task	Status	Actual Completion Date
1	9/30/2014	10/21/2014	Fine tune subscriber code and finalize CAN apis required from other boards	Completed	Completed on 10/21/2014
2	10/5/2014	10/21/2014	Fine tune subscriber code	Completed	Completed on 10/27/2014
3	10/5/2014	10/21/2014	Develop CAN Transceiver Board	Completed	Completed by 10/19/2014
4	10/5/2014	11/4/2014	Implement API co-ordination logic and test with other boards APIs	Completed	Completed by 11/20/2014
5	10/21/2014	10/28/2014	Test hardware with master code and motor code.	10/26/2014	Master and motor has been integrated.
6	10/21/2014	11/4/2014	Integrate master with motor and sensor.	Completed
7	10/28/2014	11/11/2014	Integrate master ,motor,sensor with andriod.	Completed	11/10/2014
8	10/28/2014	11/11/2014	Integrate master with display.	Completed	11/10/2014
9	10/4/2014	11/11/2014	Integrate master with compass and gps.	Completed	11/20/2014
10	11/4/2014	11/18/2014	Fix integration bugs and fine tune boards initialization and communication.	Completed	11/15/2014
11	11/11/2014	11/28/2014	Implement car movement logic as per GPS/COMPASS/Sensor data.	Ongoing	12/19/2014
12	11/28/2014	12/10/2014	Test hardware/software to remove bugs and fine tune algorithm.	Ongoing	12/19/2014

GEO Team Schedule

Sl. No	Start Date	End Date	Task	Status	Actual Completion Date
1	9/16/2014	9/23/2014	Decided and then ordered GPS modem Received Compass module	Completed	9/23/2014
2	9/23/2014	9/30/2014	Acquired GPS modem Interface Compass with SJOne Board via I2C	Completed	9/30/2014
3	9/30/2014	10/7/2014	Designing GPS driver Test code to get compass heading information	OnGoing Completed	TBD
4	10/7/2014	10/21/2014	Integration of GPS with the main board CAN RX task and subscription handling	In Progress	TBD
5	10/21/2014	11/04/2014	Test communication with the Master Determine final heading using GPS location and compass reading	Scheduled	TBD
6	11/04/2014	11/18/2014	Test and debug, Make necessary changes in the driver Compass Calibration	Scheduled	TBD

Motor Team Schedule

Sl. No	Start Date	End Date	Task	Status	Actual Completion Date
1	9/30/2014	10/7/2014	Understand the SERVO and DC motor controller signals	Completed	10/4/2014
2	10/4/2014	10/11/2014	Interface SJSU one board to SERVO and DC motor controller	Completed	10/10/2014
3	10/7/2014	10/18/2014	Develop CAN transceiver boards	Completed	10/12/2014
4	10/12/2014	10/26/2014	Design and Develop unified power distribution circuit and hardware structure for RC car	Ongoing	Power unit got burnt, working on new design
5	10/19/2014	11/03/2014	Interface motor SJSU board with master SJSU board for motion tuning	Ongoing	TBD
6	10/26/2014	11/07/2014	Redesign mechanical structure and fix wiring issue	Ongoing	TBD
7	10/19/2014	11/07/2014	Work on shaft encoder for motor speed feedback	Ongoing	TBD
8	11/01/2014	11/11/2014	Work with other teams to establish reliable CAN communication.	Scheduled	TBD
9	11/07/2014	11/30/2014	Fine tuning of turning curves, jerks, acceleration and deceleration algorithm.	Scheduled	TBD
10	11/07/2014	11/20/2014	Implement Zigbee communication for long range data logging.	Scheduled	TBD

I/O Team Schedule

Sl. No	Start Date	End Date	Task	Status	Actual Completion Date
1	9/16/2014	9/23/2014	Decided and then ordered display module	Completed	9/23/2014
2	9/24/2014	10/7/2014	Setting up the GIT	Completed	10/14/2014
3	10/7/2014	10/14/2014	Basic display on LCD with UART interface	Completed	10/23/2014
4	10/14/2014	10/28/2014	CAN communication between Master and I/O	Completed	10/28/2014
5	10/28/2014	10/31/2014	CAN communication between I/O and sensor	Completed	11/02/2014
6	10/31/2014	11/4/2014	CAN communication between I/O and GPS	Completed	11/02/2014
7	11/5/2014	11/9/2014	Logic for No. of CAN messages/sec, LED's for Start, CAN Tx,CAN Rx	Completed	11/18/2014
8	11/9/2014	11/15/2014	Mount LCD on board on CAR and Final testing	Completed	11/30/2014

Sensor Controller

Sl. No	Start Date	End Date	Task	Status	Actual Completion Date
1	10/3/2014	10/10/2014	Developing a Test code for sensors	Completed	10/14/2014
2	10/10/2014	10/17/2014	Finalizing on the sensors	Completed	10/14/2014
3	10/17/2014	10/24/2014	Transfer of sensor data via can bus to master	Completed	10/21/2014
4	10/24/2014	10/30/2014	Implementation with multiple sensors	Completed	10/30/2014
5	10/30/2014	11/24/2014	Testing the implementation for multiple sensors and debugging the issues.	Completed	11/30/2014
6	12/01/2014	12/17/2014	Optimizing the code and testing for stability and report.	Completed	12/19/2014

Communication Bridge + Android Team Schedule

Sl. No	Start Date	End Date	Task	Status	Actual Completion Date
1	9/16/2014	9/23/2014	Design UI of the Android App	Completed	9/23/2014
2	9/23/2014	9/30/2014	Interface and pairing the Android App with Bluetooth module	Completed	9/30/2014
3	9/30/2014	10/7/2014	Implementation of first stage of Android App (Frame 1: Sending data via Bluetooth to give directions for the car)	Completed	10/4/2014
4	10/7/2014	10/14/2014	Implementation of Bridge between Android and UART	Completed	10/16/2014
5	10/14/2014	10/28/2014	Implementation of second stage of Android App (Frame 2: Create on click function to give Start and End coordinates for the car)	Completed	10/28/2014
6	10/28/2014	11/11/2014	Implementation of third stage of Android App (Frame 3: Navigation path using markers and CLL coordinate system, START button and STOP button)	Completed	11/15/2014
7	11/11/2014	11/25/2014	Testing and improving the UI of to the App	Completed	11/25/2014

Parts List & Cost

Qty	Description	Manufacturer	Part Number	Total Cost
6	Ultra Sonic Sensor	Arduino	HC-SR04	12.58
1	Compass Module	Honeywell	HMC6352	Provided By Preet
1	GPS Receiver	MediaTek	LS20031 5Hz (66 Channel)	$59.95
1	RC car	Traxxas	1/10	$272
1	Bluetooth module	SunFounder	HC-05	$7.99

Backup Parts & cost

Qty	Description	Manufacturer	Part Number	Total Cost

Design & Implementation

Controller Communication Table

Controller ID Table

Controller ID	Controller
0x050	Master Controller
0x051	Geographical Controller
0x052	Motor Controller
0x053	Sensor Controller
0x054	IO Controller
0x055	App/Bridge Controller

Master Controller MessageID Table

SubscribeID	Description	PublishID	Description
0x42A	Subscribe to new motor data to be set	0x52A	Publish motor data (Response of 0x42A )
0x44A	Subscribe to new input/output data	0x54A	Publish data to be displayed (Response of 0x44A )
0x45C	Subscribe to reliable sensor value (sensor data from sensor through master)	0x55C	Publish reliable sensor value (Response of 0x45C)
0x45D	Subscribe to current location data (GPS data from Master through GPS)	0x55D	Publish current location data (Response of 0x55D)
0x44A	Subscribe to display data (api to be used by display to get new display data)	0x54A	Publish new display data (Response of 0x54A)
Master Specific MessageID	Description	ResponseID	Description
0x312	Start (master specific command)
0x313	Stop (master specific command)

Geographical Controller MessageID Table

SubscribeID	Description	PublishID	Description
0x40C	Subscribe to Heading Data and Compass Data from GPS+Compass contrllero	0x50C	Publish Heading Data and Compass Data Data (Response of 0x40C )
0x44A	Subscribe to heading and bearing Data(I/O unit subscribes	0x54A	Publish heading and bearing Data (Sends data to I/O unit)

Motor Controller MessageID Table

SubscribeID	Description	PublishID	Description
0x40B	Subscribe to Motor Data	0x50B	Publish Motor data(Response of 0x40B)
0x44A	Subscribe to Motor Data(I/O unit subscribes	0x54A	Publish Motor Data (Sends data to I/O unit)

Sensor Controller MessageID Table

SubscribeID	Description	PublishID	Description
0x40A	Subscribe to Sensor Data	0x50A	Publish Sensor Data (Response of 0x40A)
0x44A	Subscribe to Sensor Data(I/O unit subscribes	0x54A	Publish Sensor Data (Sends data to I/O unit)

IO Controller

SubscribeID	Description	PublishID	Description
0x40A	Subscribe to IO Data	0x50A	Publish IO Data (Response of 0x40A)

Android and Bridge

SubscribeID	Description	PublishID	Description
0x45A	Subscribe Start/Stop command(IO data to Master)	0x55A	Publish "start" message (response of 0x312)
0x45B	Subscribe GPS longitude and latitude (Android GPS data to Master)	0x55B	Publish current location (response of 0x45D)

Master controller

Android and Bridge

System Diagram

The above System Diagram shows the overall connection of the SJOne board and the HC05 bluetooth module. The module has 4 pins labeled on the back, VCC, GND, TXD and RXD. You might buy a module with two more pins KEY and STATE but it won't matter if you leave them open. The communication for configuration of the module is based on AT commands. There is one command for every thing, to set the device name, set the pin, set the baud rate and much more. All you have to do is to save these AT commands in the form of string and send each byte serially to the module using a simple for loop. Initially the baud rate is set to 9600. Following table shows few of the AT commands which you may require.

Command	Response	Use
AT	OK	Used to verify communication
AT+NAMExyz	OKsetname	Sets the module name to “xyz”
AT+PIN1234	OKsetPIN	Sets the module PIN to 1234
AT+BAUD1	OK1200	Sets the baud rate to 1200
AT+BAUD2	OK2400	Sets the baud rate to 2400
AT+BAUD3	OK4800	Sets the baud rate to 4800
AT+BAUD4	OK9600	Sets the baud rate to 9600
AT+BAUD5	OK19200	Sets the baud rate to 19200
AT+BAUD6	OK38400	Sets the baud rate to 38400
AT+BAUD3	OK4800	Sets the baud rate to 4800
AT+BAUD4	OK9600	Sets the baud rate to 9600

This bluetooth module requires 5V. Its Rx is connected to Tx of SJOne board and its Tx is connected to Rx of SJOne board with a common ground. We need bluetooth module in order to establish communication between the SJOne board and the Android Phone. In order to do this, code for bluetooth pairing, connecting and transmitting was thus written on Android SDK. There are three main tasks on the Android side :

1. To send location coordinates (latitude and longitude) to GPS.
2. To transmit "START" signal to the master.
3. To transmit "STOP" signal to the master.

At the receiver, this data will be received by the Bluetooth Module and provided to SJOne(Android board) via UART. Then via CAN communication its passed on to the Master and GPS boards.

Software Developing Environment

The software developing Environment used for Android was Android SDK and for bridge we used Free RTOS. To develop an Android App for our self driving car, the first thing we needed was a proper connection between the Bluetooth module and our Android phone. For this we used the Bluetooth APIs available like Bluetooth Adapter, Bluetooth Device etc. Here the Bluetooth Adapter is used as the first step to setup the Bluetooth connection and to verify if the bluetooth is supported or not. The Bluetooth Adapter is returned when we call static BluetoothAdapter.getDefaultAdapter(). Secondly, it is very important that you enable the Bluetooth and this is done by calling startActivityForResult(). According to your requirement you can either use BluetoothAdapter.ACTION_REQUEST_ENABLE or BluetoothAdapter.ACTION_STATE_CHANGED. Third Task is the Discovery, for this we have to call startbtAdapter.startDiscovery(). Next Task is to scan the devices available for Pairing. This is done by BluetoothAdapter.ACTION_DISCOVERY_STARTED and BluetoothAdapter.ACTION_DISCOVERY_FINISHED. And if nothing is happening check if the Bluetooth is ON if not turnOnBT(). Next task is to pair the Devices. This is done by calling btAdapter.getBondedDevices(). This will return already paired devices with the Android Device you using. Next step is to connect the devices which are not already paired. These devices are paired by entering the password for the device. Next step is to initiate a Bluetooth Connection for sending the data. For this simply copy the code for "private class ConnectThread extends Thread" from the Bluetooth|Android Developer site. Final task is set the UUID to "00001101-0000-1000-8000-00805F9B34FB" and you are good to go. It is very important that you add Permissions in the Android Manifest.xml. The permissions that we used were:

   <uses-permission android:name="android.permission.INTERNET" />
   <uses-permission android:name="android.permission.ACCESS_NETWORK_STATE" />
   <uses-permission android:name="android.permission.WRITE_EXTERNAL_STORAGE" />
   <uses-permission android:name="com.google.android.providers.gsf.permission.READ_GSERVICES" />
   <uses-permission android:name="android.permission.BLUETOOTH_ADMIN"/>
   <uses-permission android:name="android.permission.BLUETOOTH"/>

Developing an Android App

The very first stage was to create a Map fragment. For this we decided to go with the Google Map API V2. For this we need the "Google Play services" . To install this package go to Android SDK Manager, click on Google play services and click on install package. Once the package is installed, we have to import this library. After this we need to add the googleplay_services_lib to our project. To do this, goto Properties -> Android -> Click on the googleplay_services_lib -> Click on Add. In MainActivity.java import the following:

    import com.google.android.gms.maps.GoogleMap;
    import com.google.android.gms.maps.MapFragment;

Now add all the required permissions to your project

   <uses-permission android:name="android.permission.ACCESS_COARSE_LOCATION" />
   <uses-permission android:name="android.permission.ACCESS_FINE_LOCATION" />
   <permission
       android:name="siddhata.patil.sdc243.permission.MAPS_RECEIVE"
       android:protectionLevel="signature" />

Next step is the SHA1 fingerprint key. Goto Mac / Windows -> Preferences -> Android -> Build -> Copy the given SHA1 fingerprint key. Now go on the Internet and search for API Console - Google code. This is Google Developers Console. On left hand side you will see Services -> turn the tab ON for Google Maps Android API v2. Now again go on the left hand side and you will find API Access. Click on that. Generate new key -> Paste the copied SHA1 key ; "your package name" -> Click on Create. Your API key will be generated. Now copy this API key and paste this in your AndroidManifest.xml.

         <meta-data
           android:name="com.google.android.gms.version"
           android:value="@integer/google_play_services_version" />
         <meta-data
           android:name="com.google.android.maps.v2.API_KEY"
           android:value="Paste you API key" />

Now for the UI, under Activity_main.xml, we need to create a map fragment in Relative layout.

  <RelativeLayout xmlns:android="http://schemas.android.com/apk/res/android"
   xmlns:tools="http://schemas.android.com/tools"
   xmlns:map="http://schemas.android.com/apk/res-auto"
   android:id="@+id/LinearLayout1"
   android:layout_width="wrap_content"
   android:layout_height="wrap_content"
   android:orientation="vertical" >
   <fragment  
         android:id="@+id/map"
         android:layout_width="match_parent"
         android:layout_height="match_parent"
         android:name="com.google.android.gms.maps.MapFragment"
         />

Now, for the second stage of our Android App, we had to create an On click function to select the Start and End coordinates for our car.

   public void onMapLongClick(LatLng point) 
   {
    AlertDialog.Builder setPasswordDialog = new AlertDialog.Builder(this);
    setPasswordDialog.setTitle("243SDC_Team 2");
    setPasswordDialog.setMessage("Coordinates for the car:"+ String.valueOf(point.latitude) + " , "
    + String.valueOf(point.longitude));
    setPasswordDialog.show();
      if(isStartDone==0)
      {
      SANJOSE1 = new LatLng(point.latitude, point.longitude);
      Log.d("ADebugTag", "Setting Start Point");
      isStartDone=1;
      }
      else
      {
      Log.d("ADebugTag", "Setting End Point");
      SANJOSE2 = new LatLng(point.latitude, point.longitude); 
      }
    }

Now for the third and the last stage of our Android Application, we had to add three buttons for the UI.

1. Navigation Button - This button gives us a red color path between the selected Start and End coordinates.
2. Start Button - Once the Start button is pressed, all the coordinates of the desired path are sent to the GPS board a character "a" is sent to the Master board indicating a start signal.
3. Stop Button - Stop button sends character "z" to the Master board indicating a stop signal.

Sensor Controller

HC-SR04 Ultrasonic Sensor Features

• It is a four pin ultrasonic sensor. Four pins being; supply, ground, trigger and echo.
• The module is composed of; ultrasonic transmitter, ultrasonic receiver, and control circuit.
• It is a non-contact obstacle detector.
• Range of obstacle detection is from 2cm to 400cm.
• Requires, 5V 15mA supply.
• 15 degrees of measuring angle.

HC-SR04 Working Principle

• When a short 10uS pulse is provided to the trigger input, the module will send out an 8 cycle burst of ultrasound at 40 kHz and make its echo pin a logic high.
• The Echo pin is lowered to logic low when the ultrasound burst is reflected off a distant object.
• Now, the width of this pulse on the echo pin is in direct proportion with the distance of the obstacle.
• Timing diagram for all these signals is shown in the above figure.

HC-SR04 Distance Calculation

• We know, speed of sound is 340m/s.
• In our sensor, ultrasonic sound waves needs to travel twice the distance of the obstacle as shown in the above diagram.
• From the pulse width, we know the time required to get an echo.
• For example, let us assume the time required to get an echo is 10msec, the following image shows how the distance is calculated.

Hardware Implementation

• As shown in the image below, we are connecting six such ultrasonic sensors.
• The front three and rear sensors are for obstacle detection, while the middle two sensors are for edge detection.
• All trigger and echo pins are directly connected to the hardware pins of SJ-One board.

Software Implementation

• We are using hardware timer 0 for calculating time between trigger and echo of all six sensors.
• All the sensors are triggered in sequential order to avoid interference from one another.
• The flowchart of our implementation is as shown in the figure below.

• As shown above each sensor will wait for the echo for 10msec. If it gets an echo within 10msec then it will calculate the distance proportional to that echo. If it doesn't get an echo within 10msec then it will assume the distance is greater than or equal to 170cms.
• Hardware timer is programmed to run continuously from the moment it is initialized.
• As shown below, we save the timer value in a variable when trigger is provided to a sensor.

   LPC_GPIO2->FIOPIN &= ~(1 << pin_number);
   LPC_GPIO2->FIOPIN |= (1 << pin_number);
   delay_us(10);
   LPC_GPIO2->FIOPIN &= ~(1 << pin_number);
   sensor0_trigger_time = lpc_timer_get_value(lpc_timer0);

• When echo is received, we subtract the saved timer value from the current timer value to calculate the time required for the ultrasonic wave to return. This distance calculation code is defined in ISR.
• As we have seen earlier, the echo pin makes a transition from high to low when echo is received. Hence, the ISR is called when there is a falling edge on the echo pin.
• The ISR code is as shown below.

   void sensor0_echo_function()
   {
       temp0 = lpc_timer_get_value(lpc_timer0) - sensor0_trigger_time;
       distance[0] = ((temp0) * 0.017) - 10;
   }

Algorithm

1. . Trigger sensor 0.
2. . If echo is not received within 10msec, make distance 0 = 170cm and skip next step.
3. . If echo is received within 10msec, calculate distance 0.
4. . Trigger sensor 1.
5. . If echo is not received within 10msec, make distance 1 = 170cm and skip next step.
6. . If echo is received within 10msec, calculate distance 1.
7. . Trigger sensor 2
8. . If echo is not received within 10msec, make distance 2 = 170cm and skip next step.
9. . If echo is received within 10msec, calculate distance 2.
10. . Trigger sensor 3.
11. . If echo is not received within 10msec, make distance 3 = 170cm and skip next step.
12. . If echo is received within 10msec, calculate distance 3.
13. . Trigger sensor 4.
14. . If echo is not received within 10msec, make distance 4 = 170cm and skip next step.
15. . If echo is received within 10msec, calculate distance 4.
16. . Trigger sensor 5.
17. . If echo is not received within 10msec, make distance 5 = 170cm and skip next step.
18. . If echo is received within 10msec, calculate distance 5.

I/O Unit

The I/O Unit consists of an LCD display to report the status of the car such as sensor values, heading and the current degree for the compass. It also displays the CAN messages received per second. The LCD display that is being used in the car is SJONE Serial LCD display which runs on UART.
It is a 20x4 LCD display with a LCD driver which converts the UART characters to data and command signals for the LCD display.

The LCD has two modes of operation:
1. User Control mode
In this mode, the user controls the placing of LCD characters according to row and column by using GOTO command and $ character.
2. Smart LCD mode
In this mode, the user has to maintain a buffer for each line and print it on the line directly with scrolling enabled.

Pin Configuration

LCD Pin	SJONE Pin
Rx	P0.10(TXD2)
Vcc	5 V
GND	Ground

LCD initialization:

Geographical Controller

To Do: Harsh - 12/18/2014

Compass

- Heading
- Bearing Calculation
- what is magnetic declination?

GPS

- Steps to change frequency to 10Hz using binary commands
- Parse NMEA message to get current longitude and latitude
- Distance calculation

Received Android Data and related CAN subscription - CAN subscription Navigation, Destination Reached

- Navigate through received coordinates
- Destination reached command 4000 to master

Testing & Technical Challenges

Sl. No	Test Case	Test Description	Result

Android Testing

Command Log.d("ADebugTag", "Debugging!!!!") was used a lot of times. There was lot of debugging carried out since, one change in Android SDK would make us do change in the CAN communication in Free RTOS. The very first test carried out was the transmission of the data via bluetooth from Android phone to SJOne board. This was done by sending dummy coordinates to the SJOne board. Second test was carried out for the START and STOP buttons. This was tested by receiving the respective characters on the console. Third and final test was carried out for navigation. This test was done using actual App with the car thus involving GPS as well as Master.

Sensor Testing

HCSR04 Sensor Testing

LV-MaxSonar Sensor Testing

Sensor Decision

Hardware Timer

Sequentially Triggering of Sensors

• Triggering of multiple sensor together would cause sensor interfering with other sensors.
• This interfering with other sensors resulted in populating inaccurate readings, due to which the sensor was values were not reliable.
• Thus to solve the issue in sensor interfering with other sensor, triggering each sensor after the previous sensor value has been populated would resolve the issue.
• The cycle, i.e sequentially triggering of each sensor after calculating the previous value of sensor, for all the 6 sensors would be completed in 138 msec.

Limiting Max Distance

• For proper obstacle avoidance, we need to provide the sensor data to the master atleast 20 times per second, i.e. at 20Hz.
• Which means data from all six sensors must be calculated in 50msec.
• If we consider maximum distance (400cms) calculation for all sensors, we will require 23.5msec each sensor i.e. 141msec for all six sensors.

Challenges and Learning

Challenges in Android

There are two activities in Android. One is the bluetooth activity and other is the navigation activity. Switching from bluetooth activity to navigation activity would disconnect the bluetooth activity. This was one of the early challenges faced by us. We overcame this by changing the layout of our App. Then we combined the two activities in one activity itself by adjusting the dimensions. One more challenge faced by us was to differentiate latitude and longitude and give them separately to the GPS team. This was done by inserting one distinguishing character after each latitude and longitude so that the SJOne board could do the parsing and send it to the GPS board accordingly.

Future Enhancement

Conclusion

Project Video

Project Source Code

References

Acknowledgement

References Used

1. Preetpal Kang, Lecture notes of CMPE 243, Computer Engineering, Charles W. Davidson College of Engineering, San Jose State University, Aug-Dec 2014.
2. en.wikipedia.org/