F16: Autonomous Fire Extinguishing Vehicle

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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.

Autonomous FEV

Abstract

The Autonomous FEV is able to scan a room for fires through a focused IR sensor and navigate to each fire's location. Once the vehicle reaches a reasonable distance from the fire's location, the vehicle will spray water in the fire's general location and extinguish it.

Objectives & Introduction

The objectives of this project include:

  • Create a stand-by mode where vehicle would rotate in place and scan
  • Have vehicle detect a flame and traverse to its general location
  • Stop vehicle when flame is detected and activate water pump to spray in the fire's general location

Team Members & Responsibilities

  • Kevin Gadek
    • Sensor ADC Interface
    • Vehicle Assembly
    • Project Documentation
  • John Purkis
    • DC Motor Controller Interface
    • PWM Interface
    • Project Documentation
  • RuiQiang Yu
    • Vehicle Assembly
    • Project Documentation

Schedule

Week# Start Date End Data Task Status Actual Completion Date
1 10/21/2016 10/28/2016 Finalize Project Proposal Completed 10/28/2016
2 10/28/2016 11/04/2016 Compile Bill of Materials/Design Schematics Completed 11/04/2016
3 11/04/2016 11/11/2016 Order necessary parts Completed 11/15/2016
4 11/11/2016 11/18/2016 Disassemble prebuilt RC car/Develop initial IR sensor task Completed 11/21/16
5 11/18/2016 11/25/2016 Develop preliminary servo motor control task Completed 11/21/16
6 11/25/2016 12/2/2016 Assemble vehicle Completed 12/9/2016
7 12/2/2016 12/9/2016 Test/troubleshoot system setup Completed 12/11/2016
8 12/9/2016 12/16/2016 Fine-tune/Finalize of project Completed 12/18.16
9 12/16/2016 12/20/2016 Prepare for demo/presentation Completed 12/20/16

Parts List & Cost

Part Name Quantity Cost Notes
SJOne Board 1 $80 Main microcontroller
Infrared Sensor Module 2 $13.67 Placed around front of car to detect and approximate flame location
Actobactics Bogie Rover 1 $69.99 Main vehicle
Water pump 1 $25.77 Aubig 12V Brushless DC water pump
Water pump battery supply 2 $8.00 12V 8xAA battery pack w/ switch
System battery supply 2 $5.00 6V 4xAA battery pack w/ switch
Voltage Regulator 2 $2.00 5V Voltage Regulator (Approx. 1A output current)

Design & Implementation

Hardware Design

The overall system design diagram is shown below.

Figure 1. Overall System Diagram

Hardware Interface

SJOne Board

Figure 2: SJ-One Board Picture

As shown below, various pins from the SJOne Board were selected for the ADC and motor PWM interfaces used in this project.

Pin Connectivity Table

Item Port.Pin Direction Notes
1 P0.26 Input ADC
2 P0.0 Output DIR1
3 P0.1 Output DIR2
4 P2.3 Output PWM1
5 P2.4 Input PWM2
6 P1.20 Output Water Pump Enable

PWM Control

Figure 3. IrF3205 H-Bridge Motor Driver

The H-Bridge Motor Driver is powered by a 12V battery supply that has been regulated down to 5V with an LM7805. This allows both the 4.5V-7.4V voltage requirement of the Bogie Rover to be met while also ensuring enough current is being split among the six motors to adequately drive the Rover. The control signal bank is comprised of +5V, GND, DIR1, PWM1, DIR2 and PWM2 pins that allow motor control with either 3.3V or 5V logic. As shown in Figure 1, two GPIO pins are connected to the two DIR pins to allow easy GPIO switching to change motor direction. Two pins configured for PWM output are connected to the two PWM inputs, allowing for easy motor speed control. The output bank provides for two sets of motor control signals as well as external power input. In order to drive this specific Rover, the LM7805 output is connected to the POWER and GND pins on the driver's output bank, allowing approximately 5V and 2200 mA to be split among all six of the Rover's motors. The two MOTOR1 outputs are connected to the + and - inputs of the three motors on the left side of the Rover and the two MOTOR2 outputs are connected to the right side. This allows easy manipulation of either side of the Rover at once to allow for quick turning and movement.

Software Design

Figure 4. Basic Software State Diagram

The software logic follows the general flow shown in Figure 4. Various motor control functions are defined such as turn_left, turn_right, go_forward, and reverse that can be called on at will by the several tasks being used. Upon initialization, the state will be set to 0 and the pwm_task will make the Rover rotate in place while a separate flame_task will continually read sensor data. Because the sensor's base value is approximately 4095, conditions are set to check when the readings dip below a certain threshold. In this specific case, readings below 2000 indicate that a flame or flashlight has been detected. The flame_task will then set the system's state to 1 because it now knows that the flame is directly in front of the rover. The rover will then traverse towards the source of the flame while continually reading sensor data. If at any point, the sensor data indicates readings greater than 2000 while the state is still 1, then the system knows that it isn't correctly positioned to face the fire. In this case, the rover will re-enter state 0 and begin searching again. Once during traversal, readings indicate values less than 350, then a reasonable determination can be made that the fire is directly in front of the rover. In this case, all motors will stop and the water pump will start spraying.

Implementation

  • To implement IR interface
    • Configure ADC pin
    • Store reading
    • Check if reading meets a certain threshold indicating fire detection and change state
  • To implement PWM interface
    • Configure GPIO and PWM pins
    • Depending on which state, either spin in circle, go forward or stop

Testing & Technical Challenges

IR Sensor Calibration

Issue

Calibrating the IR sensor to focus on a specific source of IR waves rather than all the ambient light around it. ADC readings from the IR sensor were sporadic and unpredictable in areas with spotty lighting. Sensitivity calibration ended up not being as helpful as indicated in affecting the analog output of IR sensor.

Solution

This problem was somewhat mitigated by creating a makeshift apparatus with a film canister, forcing the sensor to focus its sensing in one specific direction at a time. The film canister prevents most outside IR waves from interfering with readings.

Motor Power

Issue

Control of the six different DC motors provided on the vehicle was sporadic at best. Because each motor required a peak supply current of approximately 220 mA, the peak output current of the LM7805 voltage regulator often wasn't enough to supply all six of them without either overheating and/or stopping some motors from functioning.

Solution

Attaching a 7805 with a heatsink mitigated many of the overheating issues. Installing a heatsink to the LM7805 instantly resolved power issues and the vehicle was able to traverse ground easily.

Conclusion

This project was ultimately successful at its goal. The RC Rover is able to detect IR light within a reasonable wavelength, detecting both certain flashlights as well as matches. The RC Rover is then able to transition between states according to readings that are being interpreted. These states allow the rover to traverse and navigate to several different fires within an enclosed area. The research done in learning how to interface the SJOne microcontroller over a variety of interfaces like ADC and PWM was a great learning experience. Creating a system with multiple tasks continually context switching and being able to predict the result was also a great lesson on designing with freeRTOS. With further work, this project could be improved both to increase reliability and accuracy.

Project Video

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Project Source Code

References

Acknowledgement

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References Used

Appendix

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