S15: Connect Four - Robotic Player

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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.

Artificially-Intelligent Connect Four Robot

Robo Dance: Robots have feelings too.

Abstract

Connect Four - Four in a Row, Column, or Diagonal

Play Connect Four against an Artificially Intelligent robot with variable difficulty. Prepare to test your ability to think into the future and your proficiency at connecting your pieces against an ideal player. Connect Four

Objectives & Introduction

The objectives of this project is to implement a robotic connect four player with the same capabilities as a human being with respect to the task of connecting pieces by inserting them into one of seven columns at the top of the board. Just as a human can see where his opponent has played his move and can insert his next move into the board, this robot will implement imitations of these basic human abilities.

Team Members & Responsibilities

   Matthew Carlis   (Jack of all Trades) - Hardware/Mechanical, 
                                           Artificial Intelligence,
                                           System Architect,
                                           Technical Writer.
                                                                
   Alexander Koumis (Image/Driver Guru)  - Drivers,
                                           Image Processing,
                                           Software Interfaces.

Status Video: https://www.youtube.com/watch?v=txRglMCjcsI&feature=youtu.be

Schedule

Project - Agile Parameters. Total Story Points = 100. Estimation of time investment ratio.
Story# Points Task Description
1 15 Motor Controller Write a Stepper motor driver with variable frequency capabilities with constant linear acceleration. This driver should slowly speed up the motor and slowly bring it down while being capable of mapping PWM frequency to pulley frequency.
2 10 Bluetooth Socket. The micro-controller will be run in combination with a workstation using Bluetooth message passing. The workstation will implement the AI programming where the micro-controller simply tells the workstation through Bluetooth where each move is made by the human and is returned the column number of where to insert the robots next piece. The workstation will implement a Python program interface.
3 20 AI Brain. (It's alive!) A Python program running on an workstation will implement the "Brain" of the robot where messages are passed between the micro-controller and workstation through Bluetooth. This program will determine where the robot will insert his next move based on which column the human inserts into as reported through the Bluetooth message protocol.
4 30 Mechanical System. The mechanical system be capable of inserting it's own pieces using linear motion and a stepper motor. The robot will drop his piece into a funnel device which is driven over the column for which the robot wishes to play. After his human opponent has inserted his piece the robots eyes will detect the location of the humans insertion and reply by inserting his next piece.
5 25 The Eyes. Using the pixy camera to determine the current configuration of the Connect Four board for the robotic player. Using statistical filtering by oversampling the frames the robot will be see each piece as it is inserted.
Burn Down Versus Time.
Story# Points Story Burn-down Time Invested Actual
1 15 Motor Controller 10 15 Hours 22.7%
2 10 Bluetooth Socket. 5 3 Hours 4.5%
3 20 AI Brain. (It's alive!) 15 18 Hours 27.3%
4 30 Mechanical System. 18 20+ Hours 30.3%
5 25 The Eyes. 10 10+ Hours 15.2%
Completion Dates.
Event# Date Task Actual
1 3/1 Spec out Design Completed: Started the system hardware/mechanical specs and materials ordering. Software interfaces are well defined, but not implemented.
2 3/18 Ordered Materials Completed: Completed mechanical design/research and ordered the majority of the significant materials. (Stepper motor, timing belt/pulleys, liner motion accessories)
3 4/1 Structure Materials Completed: Received and obtained the majority of the significant materials for the mechanical structure.
4 4/20 Major Milestone Completed: Bluetooth interface, Stepper Motor Driver, Mechanical specs/ordered, AI implementation.
5 4/27 Projected ToDo: Finish assembling the mechanical, add linear acceleration to motor driver.

Parts List & Cost

Give a simple list of the cost of your project broken down by components. Do not write long stories here.

Driving a Stepper Motor
Qty (Extra) Description Manufacturer Cost
1 Stepper Motor Driver 3A SmartSain $19.99
1 Stepper Motor Lin Engineering $45.90
1 24V-40W PSU. CircuitSpecialists $14.79
1 Pixy Camera CMUcam5 Pixy $69.99
1 XBee Bluetooth XBee $27.95
2 Timing Pulley's N/A $11.95 (each)
1 Timing Belt N/A $9.95
4 Linear Rail Guide N/A $3.95 (each)
2 Linear Bearing w/Platform N/A $6.95 (each)
2 8mm Linear Motion Rail/Shaft Steel N/A $15.25 (each)

Design & Implementation

System Diagram

The following graphic provides a high-level representation of the system's various software/hardware/human interfaces:

Hardware Design

Discuss your hardware design here. Show detailed schematics, and the interface here.

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.

  • Physical Layer Interfaces
    • SPI - Pixy Camera
    • Bluetooth - Laptop Communication
    • PWM (stepper) - 1 Wire PWM with 2 Control Signals.
    • PWM (servo) - 2 Wire PWM.

Software Design

The system's software interfaces are comprised of the following components (organized by their respective hardware hosts):


Bluetooth Socket Interface

Connect 4 AI

GameTask

MotorTask

PixyTask

Drivers for the Pixy were designed using Ozmekian system principles (every machine characteristic/action has a corresponding human analogue). The Pixy's primary tasks as part of Konnector is to send the location and coordinates of human-inserted Connect 4 game chips to the SJSU One board. This involves recording location/coordinate information of incoming blobs, performing statistical analysis on said blobs, and subsequently notifying other system components once a human chip-insertion has been detected. The Pixy's software interface is therefore comprised of the classes PixyBrain, PixyEyes, and PixyMouth, each one encompassing the corresponding facilities that would be required of a human assuming the same role.

Following the same analogy, PixyTask can be thought of as the "consciousness" of the system, interfacing directly only with the 'Pixy' class, which defines actions for the individual components to take in response to recorded state/external input.

{

 using namespace std; // Never use globally scoped 'using' namespaces!
 template<typename KEY_T, typename FUN_T, typename ... ARG_T>
 struct FuncMap_t
 {
   map<KEY_T, function<FUN_T(ARG_T ... xArgs)>> fpMap;
   void vSetHandler(KEY_T xElem, function<FUN_T(ARG_T ... xArgs)> fnHandler)
   {
       fpMap[xElem] = fnHandler;
   }
   function<FUN_T(ARG_T ... xArgs)>& vResponse(KEY_T xElem)
   {
       return fpMap[xElem];
   }
 };

} </codeblock>

with states to respond to as: (Github), defined as:

       enum State_t
       {
           RESET=0x01,                        // SW(1)
           EMA_ALPHA_UP=0x02,        // SW(2)
           EMA_ALPHA_DOWN=0x04,  // SW(3)
           SW_4=0x08,                         // SW(4)
           CALIB=16,
           WAITING_FOR_HUMAN=17,
           WAITING_FOR_BOT=18,
           ERROR=19
       } eState, eLastState;


During normal execution, the Pixy system's universal state, 'eState' (and 'eLastState'), alternate between 'WAITING_FOR_HUMAN' and 'WAITING_FOR_BOT'. These systems are set by the following (pseudo-code functions):

           xFuncMap->vSetHandler(WAITING_FOR_HUMAN, [&] ()
           {
               int lHumanCol = pPixyBrain->lSampleChips(pPixyEyes.get());
               if (lHumanCol > 0)
               {
                   pPixyBrain->vPrintChips(Board_t::COLOR, true);
                   eState = WAITING_FOR_BOT;
               }
               else
               {
                   eState = WAITING_FOR_HUMAN;
               }
               pPixyBrain->vPrintCorners(Board_t::COLOR);
           });


lambda function dictating the flow of data after each of FreeRTOS' successive calls to the 'Run' function.  
PixyBrain
PixyEyes
PixyMouth

Implementation

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.

Relationship between PWM frequency and wheel velocity. i.e lateral translation.

Testing & Technical Challenges

Describe the challenges of your project. What advise would you give yourself or someone else if your project can be started from scratch again? Make a smooth transition to testing section and described what it took to test your project.

Include sub-sections that list out a problem and solution, such as:

My Issue #1

Discuss the issue and resolution.

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

Upload a video of your project and post the link here.

Project Source Code

References

Acknowledgement

Any acknowledgement that you may wish to provide can be included here.

References Used

List any references used in project.

Appendix

You can list the references you used.