HackRover: Cyber Security in HackRover: Cyber Security in Motion Motion Josaiah Clark Josaiah Clark [email protected] [email protected] Gary Nguyen Gary Nguyen [email protected] [email protected] Mat Pearce Mat Pearce [email protected] [email protected] Dalton Wiebe Dalton Wiebe [email protected] [email protected] Chase Sutton Chase Sutton [email protected] [email protected] Special thanks to: Professor Mark Kochanski, Geoffrey Powell-Isom, Silver Lucoris, Victor Suciu, Justin Heinzig, Mohammad Dabbagh, Anwar Aminnudin, Kassim Shaibi, Yang Zhou, Taylor Johnston, Connor Lauerman, Matthew Lauerman, Long Ly, Daniel Zhuge Special thanks to: Professor Mark Kochanski, Geoffrey Powell-Isom, Silver Lucoris, Victor Suciu, Justin Heinzig, Mohammad Dabbagh, Anwar Aminnudin, Kassim Shaibi, Yang Zhou, Taylor Johnston, Connor Lauerman, Matthew Lauerman, Long Ly, Daniel Zhuge Why Solution Data Analysis & Testing Results All technology-reliant companies are interested in leveraging big data to make better decisions about products and services. The way that industry is supporting the shift toward big data is by collecting diagnostics and other info in real time from sensors. This trend toward leveraging the Internet of Things is what many are calling “Industry 4.0.” The aim of this capstone was to develop a model for exploring ethical hacking of self-driving cars and autonomous manufacturing equipment. This model would use technology similar to both, mainly through the use of embedded systems and sensors. Client: Pierre Mourad, PhD Client: Pierre Mourad, PhD Advisor: Imen Elloumi-Hannachi, PhD Advisor: Imen Elloumi-Hannachi, PhD A mecanum wheel- based drivetrain was designed to better suit the mobility needs of an indoor rover. The system architecture for a semi-autonomous rover was laid out in a flowchart. A printed circuit board was designed in collaboration with an Electrical Engineering capstone in order to enhance the integrity and repeatibility of our rover’s electrical system. Root cause analysis was used to find the reason for permanent marring and bending in all of the drivetrain’s 6mm 2101 stainless steel shafts. 8mm carbon steel keyed shafts were used in the newest iteration for easy maintenance and greater dynamic loading capacity. To facilitate remote software testing of the arm, a simplified model was made in SolidWorks with accurate link dimensions and weight distribution. Motor power wires were burnt during a Winter demonstration. Investigation revealed that drivetrain motors were exceeding allowable current draw of their power wires while the rovers were driving on carpet. Wire sizes were increased from 22AWG to 16AWG. IMU Data Filtered IMU Data Odometry Data Filtered Odometry Data Motor movement commands Motor movement commands ROS Master Node Raspberry Pi Authorized User Network Hacker xbox event commands,... Camera feed,... Hacker Using VM Network Adapter Client Virtual Machine User Interface Virtual Machines Hacking VM Arm Movement Commands Jetson Nano LattePanda ROS Motor... Motor Commands... IBT-2 Motor Controller Robotic Arm Intel Realsense D435i USB Camera Camera ROS Node Motor Commands... Ultrasonic Sensor Array Status Signals Motor Commands... Encoder Data Status Signals Wheel Odometry Data ROS Sonar... Trig Echo... Distance Data... Status Signals Magnetometer & Accelerometer Firewall NAT Magnetic Orientation... ROS .bag File... Xbox Controller Wheel Odometry Data... SSH... Camera Feed Feed Requests... Camera feed,... Camera feed,... xbox event commands,... xbox event commands... OUTPUT INPUT OUTPUT INPUT OUTPUT INPUT Encoder Translation... Magnetometer/ Accelerometer ROS Node Firewall Embedded LAN Xbox Input / Output... Legend Completely New Code Reconfigured Code COTS Code Arm Position IMU Fusion/Filtering... Motor Position... Accelerometer/... robot_localization... Visual Odometry... 3D Map Wheel Odometry Data Motor Encoder realsense2_camera node Raspberry Pi Zero W Xbox Controller... Xbox Movement Commands Xbox movement commands Joystick Events... Arm movement commands Arm Movement... Camera Feed Magnetic Orientation... Arm ROS Node Wheel Odometry Data... The project sparked enough interest to start a HackRover club, the purpose of which is the same as this capstone project: to promote cyber awareness in IoT/IIoT. For more information, visit hackrover.com or email [email protected]. With the new frame built, the rover is ready for integration of electrical, mechanical, and software elements. Conclusion & Future Work The project still has not achieved autonomy, which is crucial for our hacking functions. In the next iteration of the project, the following topics should be explored: 1. ROS drivetrain control development 2. Simultaneous Localization and Mapping (SLAM) 3. One-shot learning for arm articulation tasks We have implemented drivetrain and arm controls with an Xbox controller. Follow our Github page to see the codebase and new feature projects: