Difference between revisions of "S22: Firebolt"

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(CAN Communication)
(Sensor ECU)
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== Sensor ECU ==
 
== Sensor ECU ==
<Picture and link to Gitlab>
 
Gitlab link to Sensor Node Firmware: https://gitlab.com/nimit.patel/roadster/-/tree/Main/Sensor_Node
 
  
The sensor controller node is responsible for interfacing with Ultrasonic sensors to know obstacles’ distance from the vehicle. We have used MaxBotix 1010 LV-EZ1 sensors for the right and left positions and MaxBotix 1000 LV-EZ0 sensor in the middle front position (To have a wider beam range of obstacle detection in blind spots).
 
  
 
[[File:Sensor_Node.png|center|800px|thumb|Sensor Controller Diagram]]
 
[[File:Sensor_Node.png|center|800px|thumb|Sensor Controller Diagram]]
  
Below is the beam pattern for both sensors.
 
 
[[File:Beam_Pattern_MB1000_EZ0.gif|left|500px|thumb|Beam Pattern MaxBotix MB1000 EZ0]]
 
[[File:Beam_Pattern_MB1010_EZ1.gif|center|500px|thumb|Beam Pattern MaxBotix MB1010 EZ1]]
 
  
  
Line 614: Line 607:
 
==== Sensor Controller Schematic ====
 
==== Sensor Controller Schematic ====
  
 
[[File:SensorSch.png|center|800px|thumb|Sensor Controller Node Schematic]]
 
  
  
Line 622: Line 613:
 
Sensors are interfaced with combination of GPIO, ADC Pins on SJTWo board. Below is the descriptive pin layout:
 
Sensors are interfaced with combination of GPIO, ADC Pins on SJTWo board. Below is the descriptive pin layout:
  
{| class="wikitable" style="text-align: center; width: 400px; height: 200px;"
+
 
|+ Sensors pin layout
 
|-
 
! Sr. No.
 
! SJTwo board Pin
 
! Maxbotix sensor Pin
 
! Function
 
|-
 
! 1
 
| ADC2-P0.25 || AN(Front sensor) || ADC input from front sensor
 
|-
 
! 2
 
| ADC3-P0.26 || AN(Rear Sensor) || ADC input from rear sensor
 
|-
 
! 3
 
| ADC4-P1.30 || AN(Left Sensor) || ADC input from left sensor
 
|-
 
! 4
 
| ADC5-P1.31 || AN(Right Sensor) || ADC input from right sensor
 
|-
 
! 5
 
| GPIO-P0.6 || RX(Left Sensor) || Trigger for left sensor
 
|-
 
! 6
 
| GPIO-P0.7 || RX(Front Sensor) || Trigger for front sensor
 
|-
 
! 7
 
| GPIO-P0.8 || RX(Right Sensor) || Trigger for right sensor
 
|-
 
! 8
 
| GPIO-P0.9 || RX(Rear Sensor) || Trigger for rear sensor
 
|}
 
  
 
=== <font color="0000FF">Software Design </font>===
 
=== <font color="0000FF">Software Design </font>===
Line 661: Line 621:
 
1. Read Sensor Values
 
1. Read Sensor Values
  
*  Sensors are mounted at four locations as mentioned below diagram. To read these sensor values, we initialized and configured 4 sensors using 4 ADCs viz ADC2, ADC3, ADC4, and ADC5. Considering the front 3 sensors' close proximity and possible beam interference, we decided to range extreme front sensors at a time and the middle front next in sequence while in a 20 Hz loop. And the rear sensor is triggered regularly. All the sensor values are digitally converted in the range of 0 to 4096 (12 bit ADC). These values are converted to distance format in centimeter unit using formula '''conv_val = (raw_val * 0.3182) - 0.3959'''.
 
[[File:Sensor_placement.png|center|400px|thumb|Sensors Placement location]]
 
  
*  Now, to avoid frequent noise pulses, we used a median filter. We created an array of 10 elements for each sensor and maintained a write index to track the current update position. Thus, all read values have been updated in the buffer which acts as a circular buffer as we start overwriting from the start index.
 
  
 
2.  Transmit obstacle distance over CAN bus:
 
2.  Transmit obstacle distance over CAN bus:
  
*  Sensor node is responsible for broadcasting all four sensor values in terms of distance in centimeter over CAN bus. To broadcast filtered values, it first sorts the existing values in the respective allocated sensor buffer. Then it takes the mean of five median values. It does the same thing for all four sensors. Finally, it transmits those values over CAN bus. Below flow chart gives the detailed flow of code at a high level.
 
 
[[File:Sensor_Node_flow_chart.png|center|600px|thumb|Sensor Node Controller Flow Chart]]
 
  
 
=== <font color="0000FF">Technical Challenges </font>===
 
=== <font color="0000FF">Technical Challenges </font>===
  
 
==== Neighboring Sensor Interference: ====
 
==== Neighboring Sensor Interference: ====
*  As explained above, we have mounted three ultrasonic sensors in the front, and those were configured to range in continuous mode, in which sensors were continuously measuring distance by transmitting beam. Out of 3, the middle sensor is of type with wider beam to detect blind spots ahead.
+
 
*  Most of the time, we observed that the obstacle in the middle sensor range used also gets detected by the left/right sensor, which disturbs driving logic. This used to happen due to sensor beam interference among three sensors.
 
*  To solve this problem, we decided to trigger sensor beams in such time intervals that they won’t interfere with neighboring ones. We used the Rx pin of the sensor to trigger ranging and scheduled to trigger left and right sensor at one time and middle sensor next time. This sequence helped us avoid interference altogether.
 
  
 
==== Frequent noisy measurements: ====
 
==== Frequent noisy measurements: ====
*  While reading the obstacle distance, it used to change suddenly to some random value, and that used to disturb driving logic. To get noise-free readings from sensors, we implemented a median filter. All the read values from sensors have been collected in the respective buffer of 10 elements. While sending obstacle distance on CAN bus, the median filter sort the buffer and takes an average of 5 median values. This way, it helped us to remove almost all noisy values.
+
 
  
  

Revision as of 14:57, 20 March 2022

FireBolt RC Car

Abstract

The Firebolt project is a path finding and obstacle avoiding RC car. The RC Car can interface with an Android application to get new coordinates to travel to, and will do so all while avoiding obstacles visible by ultrasonic sensors.

Objectives & Introduction

Objectives

  • RC car can communicate with an Android application to:
    • Receive new coordinates to travel to
    • Send diagnostic information to the application
    • Emergency stop and start driving
  • RC car can travel to received coordinates in an efficient path while avoiding obstacles
  • RC car can maintain speed when driving on sloped ground
  • Design printed circuit board (PCB) to neatly connect all SJ2 boards
  • Design and 3D print sensor mounts for the ultrasonic sensors
  • Design a simple and intuitive user interface for the Android application
  • Design a DBC file

Introduction

The Firebolt RC car uses 4 SJ2 boards as nodes on the CAN bus

  1. Driver and LCD
  2. GEO and path finding
  3. Sensors and bridge app
  4. Motor

Team Members & Responsibilities

Priyanka Rai

    • Geographical Controller
    • Master Controller

Ritu Patil

    • Android Application Developer
    • Communication Bridge Controller

Ritika Beniwal

    • Master Controller

Utsav Savaliya

    • Sensors Controller

Dhanush Babu

    • Hardware Integration
    • PCB Designing


Schedule

Week# Start Date End Date Task Actual Completion Status
1

03/01 to 03/07 Start of Phase 1

  • 03/01
  • 03/04
  • 03/05
  • 03/04
  • 03/07
  • 03/07
  • Study and discuss previous project reports
  • Brainstorm on the requirements for the project
  • Identify and order/purchase the required components
  • 03/04
  • 03/07
  • 03/09
  • Completed
  • Completed
  • Completed
2

03/08 to 03/14

  • 03/08
  • 03/08
  • 03/11
  • 03/12
  • 03/08
  • 03/08
  • 03/14
  • 03/14
  • Create and setup Gitlab Repository
  • Create and setup Confluence for document collaboration
  • Study the datasheets and manual of acquired components
  • Distribute initial roles among the team members
  • 03/04
  • 03/07
  • 03/17
  • 03/15
  • Completed
  • Completed
  • Completed
  • Completed
3

03/15 to 03/21

  • 03/15
  • 03/15
  • 03/19
  • 03/18
  • 03/15
  • 03/18
  • 03/18
  • 03/21
  • 03/21
  • 03/27
  • Interface ultrasonic sensors and test the functionality
  • Interface GPS and Compass and test the functionality
  • Analyze and decide the hardware placement of the RC Car
  • Create SENSOR and DRIVER nodes to transmit and receive data
  • Identify the Android app requirements and start studying the Android framework
  • 03/18
  • 03/22
  • 03/20
  • 03/21
  • 03/25
  • Completed
  • Completed
  • Completed
  • Completed
  • Completed
4

03/22 to 03/28

  • 03/22
  • 03/22
  • 03/25
  • 03/27
  • 03/22
  • 03/25
  • 03/24
  • 03/28
  • 03/31
  • 03/28
  • Create the GEO node to get coordinates and cardinal directions from GPS and Compass
  • Interface the Bluetooth module to communicate with SJ-two board
  • Create the MOTOR node to drive the RC Car
  • Start designing the DBC file
  • Develop an initial version of the Android app
  • 03/24
  • 03/24
  • 03/28
  • 03/30
  • 03/28
  • Completed
  • Completed
  • Completed
  • Completed
  • Completed
5

03/29 to 04/04 End of Phase 1

  • 04/02
  • 03/29
  • 03/29
  • 03/29
  • 03/31
  • 04/03
  • 04/03
  • 04/01
  • 04/01
  • 04/01
  • 04/03
  • 04/04
  • Finalize the DBC file
  • Design obstacle avoidance and steering logic on the DRIVER node
  • Design motor driving logic on the MOTOR node with the encoder
  • Interface the LCD module with the DRIVER node to display messages
  • Integrate sensor data on the SENSOR node
  • Collective Test 1: Integrate all the completed modules and test on BusMaster
  • 04/05
  • 04/01
  • 04/01
  • 04/01
  • 04/04
  • 04/04
  • Completed
  • Completed
  • Completed
  • Completed
  • Completed
  • Completed
6

04/05 to 04/11 Start of Phase 2

  • 04/05
  • 04/05
  • 04/08
  • 04/10
  • 04/08
  • 04/08
  • 04/10
  • 04/11
  • Tune the SENSOR and DRIVER nodes to drive the RC car
  • Communicate to the DRIVER node over Bluetooth via Android app
  • Debug and revise the integrated modules with necessary improvements
  • Collective Test 2: Drive the car to a hardcoded GPS destination
  • 04/08
  • 04/08
  • 04/08
  • 04/08
  • Completed
  • Completed
  • Completed
  • Completed
7

04/12 to 04/18

  • 04/12
  • 04/15
  • 04/12
  • 04/17
  • 04/15
  • 04/18
  • 04/16
  • 04/18
  • Integrate GEO node to DRIVER node for navigation
  • Design driving decision logic based on the navigation data
  • Design a dashboard on the LCD to display the values
  • Collective Test 3: Test the car driving with navigation data from the Android app
  • 04/15
  • 04/18
  • 04/16
  • 04/18
  • Completed
  • Completed
  • Completed
  • Completed
8

04/19 to 04/25 End of Phase 2

  • 04/19
  • 04/19
  • 04/19
  • 04/19
  • 04/25
  • 04/25
  • 04/25
  • 04/25
  • Add functionalities to display various sensor data on the Android app
  • Design and 3D print the required components
  • Design and order PCB
  • Test and improve the RC car performance based on the changes
  • 04/25
  • 04/25
  • 04/25
  • Completed
  • Incomplete
  • Completed
  • Completed
9

04/26 to 05/02 Start of Phase 3

  • 04/26
  • 04/26
  • 04/26
  • 05/01
  • 04/30
  • 04/30
  • 04/30
  • 05/02
  • Design individual architecture diagrams and algorithms for documentation
  • Make any necessary improvements based on previous test results
  • Complete the final version of the Android app
  • Collective Test 4: Test car on various terrains and slopes
  • 04/30
  • 04/30
  • 04/30
  • 05/02
  • Completed
  • Completed
  • Completed
  • Completed
10

05/03 to 05/09

  • 05/03
  • 05/03
  • 05/03
  • 05/08
  • 05/07
  • 05/07
  • 05/07
  • 05/09
  • Replace the circuits with their corresponding PCBs and assemble
  • Complete the RC Car structure and assembly with the 3D printed parts - Prototype 1
  • Refactor the code modules with necessary improvements
  • Collective Test 5: Test the Prototype 1 with the aim of sending the car to return Preet's PCAN Dongle
  • 05/07
  • 05/07
  • 05/07
  • 05/09
  • Completed
  • Completed
  • Completed
  • Deferred
11

05/10 to 05/16 End of Phase 3

  • 05/10
  • 05/10
  • 05/10
  • 05/15
  • 05/16
  • 05/16
  • 05/16
  • 05/16
  • Revise and improve the wiki report to cover all the aspects of design and implementation
  • Fix all the errors and make improvements
  • Final testing of all the modules and car
  • Collective Test 6: Have the final version of the project tested with all the functionalities
  • 05/16
  • 05/16
  • 05/16
  • 05/16
  • Completed
  • Completed
  • Completed
  • Completed


Parts List & Cost

Item# Part Desciption Vendor Qty Cost
1 RC Car Traxxas [1] 1 $250.00
2 CAN Transceivers MCP2551-I/P Comimark [2] 5 $7.00
3 Ultrasonic Sensors Max Botix[3] 5 $150.00
4 GPS and Antenna Adafruit[4] 1 $60.00
5 HC05 bluetooth RF Transreceiver HiLetgo[5] 1 $12.59
6 Triple-axis Accelerometer Adafruit[6] 1 $21.40
7 Traxxas RPM Sensor Traxxas[7] 1 $12
8 Discrete Electronic Components Generic[8] 1 $28.75
9 Buck-Boost Voltage Regulator Generic[9] 1 $11.99
10 Traxxas Telemetry Trigger magnet & holder Traxxas[10] 1 $6.35
11 Acrylic Sheet Tap Plastic 1 $12
12 Battery Amazon[11] 1 $26.99
13 Traxxas Battery and Charger Amazon[12] 1 $55.94


Printed Circuit Board

PCB Schematic

PCB Design

CAN Communication

We use controller area network to broadcast data between the 4 nodes. All nodes are connected to each other through a physically conventional two wire bus. The wires are a twisted pair with 120 Ω resistors at each ends of the bus. 1s and 0s are transmitted as CAN High(0V difference) and Can Low(2v difference). A CAN frame has the following contents:

  • Data Length Code (4bits)
  • Remote Transmission Request.
  • ID extend bit.
  • Message ID (11 bit or 29 bit)
  • Data bytes( depends on DLC)
  • CRC


Arbitration: No two nodes will transmit at the same time because if arbitration. A lower Message-ID has a Higher priority on the CAN bus since 0 is the dominant bit.

Bit Stuffing: CAN bus stuffs extra bits when a long chain of multiple 1's or 0's occur to improve CAN integrity.

Sr. No Message ID Message function Receivers
Driver Controller
1 300 speed and steering direction for the motor. Motor
2 310 Destination reached Sensor
Sensor Controller
1 200 Sensor sonars from front, back, left ,right sensor Driver
Motor Controller
8 700 motor speed, motor direction Driver
Geo and Bridge Controller
1 400 Bearing, Heading and Distance Driver
Debug messages
1 851 Driver Debug SENSOR,MOTOR,GEO_AND_BRIDGE
1 811 Motor Debug SENSOR,MOTOR,GEO_AND_BRIDGE
1 801 Sensor Debug SENSOR,MOTOR,GEO_AND_BRIDGE


Hardware Design


DBC File



Sensor ECU

Sensor Controller Diagram


Hardware Design

Sensor Controller Schematic

Board Pin Connections

Sensors are interfaced with combination of GPIO, ADC Pins on SJTWo board. Below is the descriptive pin layout:


Software Design

The sensor node mainly does two activity viz. 1) Read sensor values, 2) Transmit obstacle distance over CAN bus. Both of these activities happen in a 20Hz periodic callback.

1. Read Sensor Values


2. Transmit obstacle distance over CAN bus:


Technical Challenges

Neighboring Sensor Interference:

Frequent noisy measurements:



Motor ECU

Motor Node Schematic

Hardware Design

Traxass ESC XL5
Traxass Servo Motor
Traxass RPM Sensor


The motor node(SJ-2) interfaces primarily interfaces with:

  • Traxass Motor ESC over PWM
  • Traxass RPM Sensor over GPIO Interrupt
  • Traxass Servo Motor over PWM

All these three components have 3 pins each. The functionalities of these pins are mentioned in the table below.

Module Black Red White
ESC Ground Vout : 6 V PWM Input
Servo Ground Vin : 6 V PWM Input
RPM Sensor Ground Vin : 6 V Pulse Output

Software Design

The motor node acts based on the speed and direction received over CAN bus from the Driver Node. The positive speed values are treated as forward motion and the negative speed values are considered to be the reverse motion of the RC car.

The steering angles are divided into 5-degree segments and the motor node sends the pre-defined pwm duty cycle of the particular segment to the servo motor depending on the angle value received from the driver node.

Motor Node - Software Flowchart

Technical Challenges

  • Firstly, the Traxxas motor ESC and other Traxass parts are members of the Traxxas Hobby Parts family, and they are not intended for development purposes. This is why there are no technical specification documents or any program/development guides available. One needs to test the motor ESC by feeding the PWM duty cycles in various sequences at various duty cycle percentages. We used the Remote control to reproduce some scenarios where the ESC was behaving unexpectedly.
  • The ESC configuration changes to the Lipo battery state if the Lipo battery is used. If one switches back to the NiMH battery, then the ESC starts flashing the led in a green-red repeated sequence, and the ESC power button stops working. In this scenario, there is a calibration process that can save your boat and can make the ESC function normally again. Follow this procedure : ESC Calibration
  • Another challenge with the motor node program development is that you cannot rely on unit testing. Whoever works on the motor node, should make sure that the sequence of the duty cycles being fed to the ESC produces the expected results on the motor as well. The forward-reverse transitioning and the speed controlling both can be a bit tricky. Also, the hard brake logic can take a while to get working properly.
  • Some useful reference values for the ESC are : 15% -> Neutral; 15.8%-> Minimum forward speed, 10%->Full reverse speed.


Geographical And Bridge Controller

Repository link for Geo Controller

Hardware Design

Geo Node Schematic


Bluetooth Trans-receiver
GPS Module
3 Axis Magnetometer (eCompass)


Battery Monitoring



The SJ2 board communicates with:

  • Bluettoth transreceiver over UART
  • LSM303DLHC over I2C
  • GPS model over UART
  • Battery monitoring

Considering the orientation of the car changes as it travel along the land, tilt compensation logic for heading calculation using the magnetometer is a must for accurate measurement. Without the tilt compensation algorithm which uses the onboard accelorometer, the heading computation can have error up to 60 degrees, which has the potential to send the car off course.

For battery monitoring, the values for the voltage divider should be chosen such that the full range of the onboard ADC can be efficiently used. Depending one the cell type of the battery, the discharge curve can be use to map the charge state corresponding to voltage level. This method has its flaws and sophisticated techniques involving Coulomb count yields far better results, however, the technique discussed above suffices the needs of our project. Charge state of battery transmitted over Mobile app, greatly facilitates the charging schedule while testing and final demo day.



Software Design

The periodic scheduler for Geo Controller Node does the following functionalities:

  • In 10Hz periodic callback:
    • gps__update() : Fetch GPS data from GPS controller.
    • geo_compass__periodic_send() : Reads the Magnetometer and accelerometer values from Compass controller and convert those to current heading data.
  • In 100Hz periodic callback:
    • bluetooth__run_once() : Send specified data to android application via Bluetooth.

The GEO controller is divided into 5 parts.

  • The current location of the car is determined using the GPS.
  • The current magnetic heading of car is determined using the on board compass.
  • The way point calculation determines the nearest way point continuously by computing the distance using Haversine formula and current location using GPS.
  • The heading is also computed using the Haversine formula and the difference between the actual and required is sent over the CAN bus for heading correction.
  • Alternatively, once the car is within the threshold distance, next way point is selected and the car heads to the next way point.


Heading computation from geographical (Geo) controller

Technical Challenges

  • The GPS module sends data at 9600 baud rate, updating the data every one second. The data update rate needs to be updated to 10Hz for fast maneuvering and course correction of the car. If the update frequency is updated, the data sent over the UART is higher than it can handle in 10Hz periodic function. Hence, only GPGGA messages should be enabled to extract the required data and reduce the time spent in parsing the incoming string. NEMA (PMTK) messages should be correctly configured on the module for desired functioning.
  • Heading calculation without the tilt compensation logic using the onboard accelorometer of LSM303 is in accurate. Reading accelorometer values requires and offset of 0x80 to the byte addressing of the accelorometer read. Magnetometer need no such offset. This is weird, considering both the I2C devices reside on the same physical chip.
  • Using data type as float as opposed to double, utilizes the onboard FPU, which is faster. Double utilizes software implementation, which takes more clock cycle. Considering extensive use of math library in distance/heading measurement and tilt compensation algorithm, completing the task with the periodic is of at most importance.
  • GPS fix is best when when there are no obstruction above the module. Module requires clear wide view of sky for a fast fix and error free location detection.
  • LSM303DLHC is sensitive to even weak magnetic field interference. Place the chip devoid of such active/passive magnetic fields.
  • Calibrating LSM303 is a must to get accurate heading values. 2-point calibration worked just fine for our team. More sophisticated methods are available too.

Driver Node

https://gitlab.com/nimit.patel/roadster/-/tree/Main/Driver_Node

Hardware Design

The Driver Node has one peripheral connected to it and that is the LCD screen.

Driver Node Schematic
Driver Node Schematic

Software Design

The driver node controls the logic of steering the car in the right direction based on the data received from the Sensor and Geo Nodes. The following flowchart describes that process.

  • Driver Node Flow Chart
Driver Node Flow Chart

In case there are obstacles in the path where the car wants to move to, the following obstacle avoid logic would kick in.

  • Driver Node Obstacle Avoidance Logic
Driver Node Obstacle Avoidance Logic

The work in the Driver Node is done using two different periodic tasks. Here is a description of those periodic tasks and what they do.

  • 1 Hz Loop:
    • Transmit debug messages over the CAN bus
    • Transmit messages on the LCD
    • Transmit destination reached flag over the CAN Bus
  • 20 Hz Loop:
    • Receive Sensor Data
    • Receive Geo Data
    • Process and Transmit Data(Motor Direction and Speed) to Motor Node
  • LCD Interface

The LCD interface on the Driver is used to print some important information about the car. This is what it prints.

    • Car Speed
    • Distance from the Destination
    • Car State (Car Stopped from the App, Car Moving, Destination Reached)

Technical Challenges

  • The Driver Node did not have much hardware interfaced on it apart from LCD. So from the hardware side there were no technical challenges. On the software front as well there were not many challenges as unit tests helped debug most of the issues then and there.
  • We initially used GLCD which was configured via GPIOs and it was working perfectly. Hence we created our PCB as per this LCD. But, while testing our car with various speeds and PID logic, it got toppled and damaged the LCD. So, we had to change to SJ Valley LCD, which was configured via the UART interface, at the last moment. So, we used the same location on the PCB to place the LCD and soldered wires below PCB. Hence, this correction was not visible on our end product.


Mobile Application

Gitlab We created a lightweight mobile app to navigate our car, It can communicate with the car via Bluetooth and is capable of sending Destination co-ordinates along with checkpoints. Receive and Update live location on Google Maps, send Start, Stop and Clear commands, Receive and Display Debug Data.

  • Splash screen
  • Data from roadster
  • Checkpoints

User Interface

The app has minimal buttons on the same screen as Google Maps View to confirm the cars current state and location before sending the commands.

       connect_Btn.setOnClickListener(new View.OnClickListener() {
           @Override
           public void onClick(View v) {
               listPairedDevices(v);
           }
       });
       clear.setOnClickListener(new View.OnClickListener() {
           @Override
           public void onClick(View v) {
               try {
                   if(!state) {
                       mConnectedThread.write("--,\n");
                       mMap.clear();
                       checkpoints.clear();
                       sending_status.setText("Waiting");
                   }
                   else{
                       Toast.makeText(getApplicationContext(),"Stop the car First",Toast.LENGTH_SHORT).show();
                   }
               }
               catch (Exception e)
               {
                   Toast.makeText(getApplicationContext(),"Connect to Roadster First",Toast.LENGTH_SHORT).show();
               }
           }
       });
       stop.setOnClickListener(new View.OnClickListener() {
           @Override
           public void onClick(View v) {
               try {
                   mConnectedThread.write("!!,\n");
                   state=false;
                   move_camera=false;
                   car_status.setText("   stopped");
               }
               catch (Exception e)
               {
                   Toast.makeText(getApplicationContext(),"Connect to Roadster First",Toast.LENGTH_SHORT).show();
               }
           }
       });
       start.setOnClickListener(new View.OnClickListener() {
           @Override
           public void onClick(View v) {
               try {
                   mConnectedThread.write("##,\n");
                   state=true;
                   move_camera=true;
                   car_status.setText("   started");
               }
               catch (Exception e)
               {
                   Toast.makeText(getApplicationContext(),"Connect to Roadster First",Toast.LENGTH_SHORT).show();
               }
           }
       });
       send_cpts.setOnClickListener(new View.OnClickListener() {
           @Override
           public void onClick(View v) {
               try {
                   sending_status.setText("....");
               for(int i=0;i<checkpoints.size();i++) {
                   String cpt="GPS,"+checkpoints.get(i).latitude+","+checkpoints.get(i).longitude+"\n";
                   mConnectedThread.write(cpt);
               }
               sending_status.setText("Sent");
               }
               catch (Exception e)
               {
                   Toast.makeText(getApplicationContext(),"Connect to Roadster First",Toast.LENGTH_SHORT).show();
               }
           }
       });

Software Design

This app has mainly two activities, The main activity and maps activity.

Maps Activity

This is the only functional activity for the app and is responsible for the Google Maps and Bluetooth related Tasks. User can also dynamically select multiple checkpoints and send them to the bridge node. This is achieved using java vector and OnMapclickListener setup to read each marker placed by the user.

mMap.setOnMapClickListener(new GoogleMap.OnMapClickListener() {

           @Override
           public void onMapClick(LatLng latLng) {
               int precision = (int) Math.pow(10,6);
               double new_latitude = (double)((int)(precision*latLng.latitude))/precision;
               double new_longitude = (double)((int)(precision*latLng.longitude))/precision;
               LatLng myloc = new LatLng(latLng.latitude, latLng.longitude);
               mMap.addMarker(new MarkerOptions().position(myloc).title("Destination"));
               mMap.moveCamera(CameraUpdateFactory.newLatLngZoom(myloc,20));
               checkpoints.add(new LatLng(new_latitude,new_longitude));
               destination_coordinates = "GPS," + new_latitude + "," + new_longitude +"\n";
           }
       });

Bluetooth

The Bluetooth connection is initially set up by reading the id and MAC addresses of the selected device, The available devices are displayed on a listView under the connect button. Once the socket is established, Bluetooth module provides read() and write() API used to communicate.


           if(!mBTAdapter.isEnabled()) {
               Toast.makeText(getBaseContext(), "Bluetooth not on", Toast.LENGTH_SHORT).show();
               return;
           }
           mBluetoothStatus.setText("Connecting...");
           // Get the device MAC address, which is the last 17 chars in the View
           String info = ((TextView) v).getText().toString();
           final String address = info.substring(info.length() - 17);
           final String name = info.substring(0,info.length() - 17);
           new Thread()
           {
               public void run() {
                   boolean fail = false;
                   BluetoothDevice device = mBTAdapter.getRemoteDevice(address);
                   try {
                       mBTSocket = createBluetoothSocket(device);
                   } catch (IOException e) {
                       fail = true;
                       Toast.makeText(getBaseContext(), "Socket creation failed", Toast.LENGTH_SHORT).show();
                   }
                   // Establish the Bluetooth socket connection.
                   try {
                       mBTSocket.connect();
                   } catch (IOException e) {
                       try {
                           fail = true;
                           mBTSocket.close();
                           mHandler.obtainMessage(CONNECTING_STATUS, -1, -1)
                                   .sendToTarget();
                       } catch (IOException e2) {
                           Toast.makeText(getBaseContext(), "Socket creation failed", Toast.LENGTH_SHORT).show();
                       }
                   }
                   if(fail == false) {
                       mConnectedThread = new ConnectedThread(mBTSocket);
                       mConnectedThread.start();
                       mHandler.obtainMessage(CONNECTING_STATUS, 1, -1, name)
                               .sendToTarget();
                   }


The Bridge node sends data in string format with end of line chars, The Bluetooth handler concatenates the received data and waits for the "end of line" before trying to parse it. Below is the code snippet that parses the incoming stream with location and debug data sent by the bridge node.

                   if(readMessage.indexOf("\n")>0) {
                       message = new StringTokenizer(readMessage, "\n");
                       StringTokenizer st;
                       while (message.hasMoreTokens()) {
                           st = null;
                           received_line = message.nextToken();
                           st = new StringTokenizer(received_line, ",");
                           try {
                               read = st.nextToken();
                           } catch (Exception e) {
                               continue;
                           }
                           if (read.compareTo("GPS") == 0) {
                               try {
                                   LatLng current_location = new LatLng(Double.parseDouble(st.nextToken()), Double.parseDouble(st.nextToken()));
                                   waypoint.setText(st.nextToken("\n").replace(",", ""));
                                   prev.remove();
                                   prev = mMap.addMarker(new 
                                          MarkerOptions().position(current_location).anchor(0.5f,0.5f).rotation(compass_value).title("Roadster")
                                          .icon(BitmapFromVector(getApplicationContext(), R.drawable.ic_baseline_directions_car_filled_24)));
                            if (state || init) {
                                       mMap.moveCamera(CameraUpdateFactory.newLatLng(current_location));
                                       if (current_location.latitude != 0) init = false;
                                   }
                               } catch (Exception e) {
                               }
                           } else if (read.compareTo("speed") == 0) {
                               try {
                                   speed.setText(st.nextToken("\n").replace(",", "") + "m/s");
                               } catch (Exception e) {
                               }
                           } else if (read.compareTo("sens") == 0) {
                               try {
                                   left.setText(st.nextToken() + "cm");
                                   right.setText(st.nextToken() + "cm");
                                   center.setText(st.nextToken() + "cm");
                                   back.setText(st.nextToken("\n").replace(",", "") + "cm");
                               } catch (Exception e) {
                               }
                           } else if (read.compareTo("comp") == 0) {
                               try {
                                   compass.setText(st.nextToken());
                                   String compass_s=st.nextToken("\n").replace(",", "");
                                   compass_raw.setText(compass_s);
                                   compass_value =Integer.parseInt(compass_s);
                                   prev.setAnchor(0.5f,0.5f);
                                   prev.setRotation(compass_value);
                               } catch (Exception e) {
                               }
                           } else if (read.compareTo("dist") == 0) {
                               try {
                                   String dis=st.nextToken("\n").replace(",", "");
                                   distance.setText(dis+"m");
                                   //int prog=(int)Float.parseFloat(dis)%200;
                                   //progress.setProgress(prog);
                               } catch (Exception e) {
                               }
                           } else if (read.compareTo("mot") == 0) {
                               try {
                                   rps.setText(st.nextToken());
                                   pwm.setText(st.nextToken("\n").replace(",", ""));
                               } catch (Exception e) {
                               }
                           }
                           else if(read.compareTo("bat")==0){
                               try{
                                   battery.setText(st.nextToken("\n").replace(",", "")+"%");
                               }catch (Exception e){
                               }
                           }
                      }
                       readMessage="";

Technical Challenges

Given no experience in Android Development, we had to start from the basics about the activities, message passing etc. The initial challenge was to understand the google maps API and generate the API key to access google cloud to implement the map view and markers. Implementing Bluetooth communication required scanning the list of paired devices and acquire the MAC address required to open a socket using the provided API. Fortunately, there are many example implementations to go through. We decided to use a similar line buffer that is used in the Geo node to read the debug data sent from the app, this helped solve the challenge of parsing the group of variables sent by the bridge node by reading from the CAN bus.






Conclusion

  • Embedded project are generally single board projects. The mandatory use of CAN bus required a great deal of collaboration, where all board are interdependent and the system design should be robust to make it work every single time, the car is used for its intended purpose.
  • Unit testing helps in early phase of the project, where the hardware setup is not ready yet, but one needs to start coding to get ahead of the curve and start building logic. This helps in troubleshooting the hardware as well.

Project Video

https://youtu.be/Q24ghJRe9VM

Project Source Code

Repository link for Autonomous RC Car Repository for Android App

Advise for Future Students

  • Get the hardware modules and test the same with SJ2 (Before the Mid Semester exams). Once this is done, create a PCB and mount devices and then start the extensive software testing. Considering the car is moving object, temporary connections over bread board and zero PCB might work, but reliability will remain a doubt at the back of the head. Eliminate the same by creating the PCB early. You might even want to iterate to a second PCB, once you are a few weeks into testing and want to change amend previous mistakes/improve existing layout and placements. The time and effort this will save is worth it.
  • Once the hardware is nearing its completion, the Mobile app should be ready in its rudimentary form. Having a hand held debug device is more useful, compared to using PCAN dongle which is great for static testing.
  • The software will take multiple iteration by testing your car in various field scenarios. This is not a project which can be completed a night before demo. Keep a healthy amount of time for testing.
  • The sole working power socket available in university outside of the university buildings is available on the top floor of the tenth street car garage. This is especially useful when testing in field.

Acknowledgement

  • Building a hardware project without the availability of a electronics lab of the university which had been shut, due to COVID-19 pandemic tested our resourcefulness to our extremes.Considering the remote nature of course work, resource availability in any shape or form from university was sadly non existent. All the team members should be appreciated for their unwavering enthusiasm to make this a success story.
  • Preet's advice for buying quality hardware parts should be followed to the line.

References

http://socialledge.com/sjsu/index.php/Industrial_Application_using_CAN_Bus