Difference between revisions of "F19: Space Impact"

From Embedded Systems Learning Academy
Jump to: navigation, search
(Accelerometer Input)
(Implementation)
Line 366: Line 366:
 
#Reading only the x direction accelerometer data for spaceship movement
 
#Reading only the x direction accelerometer data for spaceship movement
 
#Using simple math to calibrate the accelerometer data to corresponding position of the spaceship
 
#Using simple math to calibrate the accelerometer data to corresponding position of the spaceship
 +
<source lang="cpp">
 +
int getSpaceshipPos() {
 +
  acc = acceleration__get_data();
 +
  if (abs(acc.x - prev_acc) > 30) {
 +
    prev_acc = acc.x;
 +
    if ((acc.x < 3400) && (acc.x > 2048)) {
 +
      sp = 10;
 +
    } else if ((acc.x >= 3400) && (acc.x <= 4096)) {
 +
      sp = 10 + (acc.x - 3400) / 29;
 +
    }
 +
    if ((acc.x >= 0) && (acc.x <= 700)) {
 +
      sp = 35 + (acc.x / 29);
 +
    } else if ((acc.x > 700) && (acc.x < 2048)) {
 +
      sp = 59;
 +
    }
 +
  }
 +
  return sp;
 +
}
 +
</source>
  
 
== Testing & Technical Challenges ==
 
== Testing & Technical Challenges ==

Revision as of 09:20, 18 December 2019

Space Impact.png

Abstract

Space Impact is a classic game from the days of the Nokia era. Our objective is to design a game in which a player is prompted to protect a spaceship from incoming missiles by moving the ship up and down. The player will also have the ability to fire back at the incoming enemies. Taking damage from the enemy will reduce the health of the spaceship and zero health will lead to the game over screen.

Example Link: https://www.youtube.com/watch?v=jh49RWFnZHk

Objectives & Introduction

Introduction:

We intended to design an embedded system whose sole purpose is to run an arcade game with just an RGB LED Matrix and a microcontroller. The game itself involves a user controlling a spaceship through an accelerometer, guiding the spaceship across many enemy spacecraft and obstacles. These obstacles are generated randomly and appear from the right-hand side of the screen. The player shoots the obstacles with bullets by pressing a button clearing a path for him or herself. The game starts on the press of the button and ends when the players runs out of health by taking too many hits. The objective of the game is to survive as long as possible acquiring as many points as he or she can.

Objectives:

  • Interfacing the RGB LED Matrix with SJTwo Microcontroller
  • Coding simple to use display functions for displaying spacecraft, bullets, enemies at any given position
  • Randomizer to generate random locations for enemies
  • Tasks that can move the spacecraft and detect collisions between:
    • Bullet to Bullet (Cancels out)
    • Bullet to Enemy (Clears enemy and increments score)
    • Enemy bullet to ship (Damage to ship and decrements energy bar)
    • Ship to Ship (Extra damage to energy bar)
  • Interrupt to be generated on press of button to start game/fire bullets
  • Score Counter and Energy Counter to be displayed at the top and updated in real time as the game progresses
  • Title Screen and Game Over screens
  • MP3 driver for playing audio

Team Members & Responsibilities:

Schedule

Week# Date Task Current Progress Actual Completion Date
1 10/01/2019
  • Project Proposal Submission.
  • Completed
  • 10/01/2019
2 10/15/2019
  • Create our own Wiki page of Space Impact.
  • Discuss the various challenges that might come up with during the design phase and report it as top questions.
  • Discuss what kind of components would be needed for our design.
  • Completed
  • Completed
  • Completed
  • 10/15/2019
  • 10/15/2019
  • 10/15/2019
3 10/22/2019
  • Finalize the Bill of Materials.
  • Place order for Hardware components.
  • Downloading All the Software and Document(Datasheet) required for designing and field testing.
  • Completed
  • Completed
  • Completed
  • 10/22/2019
  • 10/22/2019
  • 10/22/2019
4 10/29/2019
  • Delegation of tasks to each team member.
  • Reading the 64x64 LED-Matrix datasheet.
  • Completed
  • Completed
  • 10/29/2019
  • 10/29/2019
5 11/05/2019
  • Test LED Matrix by writing GPIO driver
  • Completed
  • 11/08/2019
6 11/12/2019
  • Implement Drivers for input controls.
  • Display the spaceship and control its movement using input buttons.
  • Generate projectiles from the spaceship on user input.
  • Completed
  • Completed
  • Completed
  • 11/11/2019
  • 11/12/2019
  • 11/12/2019
7 11/19/2019
  • Use Accelerometer as input controls for spaceship instead of buttons.
  • Randomizer to generate enemies at random locations at end of the screen.
  • Move the enemies towards space ship and generate enemy bullets.
  • Completed
  • 11/19/2019
8 11/26/2019
  • Implement collision detection between
    • 1) Spaceship and enemy (Game Over)
    • 2) Spaceship's bullets and enemies (Kill enemies)
    • 3) Spaceship and enemies' bullets (Reduce health of spaceship)
    • 4) Spaceship's bullets and enemies' bullets (The bullets should cancel out each other)
  • Completed
  • 11/26/2019
9 12/03/2019
  • Add Score counter and health meter.
  • Completed
  • 12/03/2019
10 12/10/2019
  • Final testing and Fine-tuning.
  • Completed
  • 12/10/2019

Parts List & Cost

S.No. Parts Seller Quantity Price
1 SJTwo Microcontroller Preetpal Kang 1 $50
2 RGB LED Matrix Panel - 64x64 Sparkfun 1 $85
3 Serial MP3 Player Aideepen 1 $8

Design & Implementation

Hardware Design

The hardware design in this project involved an LED Matrix, MP3 Audio Decoder, SJTwo Board along with its on-board accelerometer.

LED Matrix

The main component in our hardware design is the 64x64 LED Matrix. It uses 5 data lines (A,B,C,D,E) which is used for row selection of LED Matrix. R1,G1,B1 control the colors of the upper half of the LED Matrix and R2,G2,B2 control the lower half the matrix.The CLK signal is used to indicate the arrival of a bit of data. Each time the clock goes high, a bit of data is clocked in for the current row. OE (output enable) switches the LEDs off when transitioning from one row to the next. The LAT (latch) signal marks the end of a row of data.The following are its technical specifications:

  • Module size: 192 x 192mm
  • Pixel pitch: 3mm
  • Pixel density: 111,111 pixels/ sqm
  • Pixel resolution: 64 pixels (W) x 64 (H) pixels
  • Max power consumption: 18W
  • Module thickness: 14.66mm (without magnet), 26.55mm (with magnet)
  • Weight: 0.31kg
  • Scan mode: 1/ 16 scan
  • Power Supply: 5V regulated power input, 4A max
LED Matrix
LED Matrix Backpanel
Spade Connectors, Ribbon Cables and Magnets


MP3 Audio Decoder

We also used an audio decoder for the in-game sound effects. This module is a simple MP3 player device based on high quality MP3 audio chip MH3028M. It has 4 pins namely Vcc, GND, Rx, and Tx. MCU can send commands to module through UART port to control MP3 playback.

Aideepen YX5300 UART Control Serial MP3 Music Player Module


Accelerometer

The SJTwo board has its own accelerometer on-board. It has the MMA8452Q, 3-axis, 12-bit/8-bit digital accelerometer. It has an I2C digital output interface.

On-board accelerometer


Hardware Interface

Our design for LED control was based on the below simplified block diagram. We are using the SJTwo board GPIO pins for turning on and off an LED in the LED matrix. R1 G1 B1 is used to control the colors of LEDs in the top half of the matrix (0-31 rows) and R2 G2 B2 in the bottom half of the matrix (32-63 rows). GPIO were also selected for the CLK, LAT and OE purposes. ABCDE pins are used for row selection. Each pin is made high or low based on the requirement. Using these pins we can form our LED animation based on transmission pattern.

CmpE244 F19 T4 BlockDiagram.PNG


Software Design

Our approach to the software design involved the use of eight different tasks for the various moving elements of our gameplay. Seven of these tasks are dedicated to updating the matrix buffer of size 32x64 which is just a two-dimensional array holding the R2, G2, B2 and R1, G1, B1 values. The ninth task has the highest priority which is used to refresh the display. This task get the latest values from the matrix buffer and is used to display a frame of the game on the LED Matrix display. The matrix buffer is constantly updated in real-time by the other seven tasks such as:

  1. Title Screen:
    • Used to initially display the title screen
    • Waits for a button press to launch the game and then suspends itself
  2. Life Display:
    • Displays the health bar of the spaceship
    • When health runs out, suspends all other tasks and displays end screen (Game Over)
  3. Move Spaceship:
    • Used to display the spaceship at a location based on input from accelerometer
    • Collision detection between the Enemy ships and User Spaceship
    • On detection, changes the color of spaceship temporarily indicating damage
  4. Spaceship Bullet
    • Displays bullet on button press
    • Displays super-weapon on button press
    • Checks for collision between bullet and enemy bullet along with bullet with enemy ship
  5. Enemy Bullet
    • Displays enemy bullets
    • Checks for collision between bullet and enemy bullet along with bullet with user’s spaceship
  6. Kill Animation Task
    • Used to display explosions on collision between bullet and enemy
  7. Moving Enemy ship
    • Generates the enemies at random positions from the end of the screen
    • Moves the enemies in right to left direction towards the user
  8. Boss Enemy Task
    • Create a boss to fight every 12 seconds


The last task is the refresh display task mentioned above. This task includes a display function that controls the Latch, Clock, Output Enable pins of the LED Matrix display. This function reads the matrix buffer and extracts the R2, G2, B2, R1, G1, B1 values using shift operators.

Implementation

LED Driver

  1. Initialize all the pins and construct as output pins
  2. Create a matrix buffer of size 32x64 to hold the color values for the display
  3. Loop through matrix buffer from 0 to 31 rows and 0 to 63 columns
  4. Check if the R1,G1,B1 or R2,G2,B2 bits are set
  5. After every column the clock is set and then reset
  6. After every row the OE and LAT is set
  7. On clearing all the ABCDE bits, we extract each address bit and set the pin accordingly
  8. The LAT and OE is cleared, marking the completion of a row
  9. Refresh display task calls the display function and has highest priority
void display() {
  for (uint8_t row = 0; row < 32; row++) {
    for (uint8_t col = 0; col < 64; col++) {
      if (matrixbuff[row][col] & 0x1) {
        gpio__set(B1);
      } else {
        gpio__reset(B1);
      }
      if (matrixbuff[row][col] & 0x2) {
        gpio__set(G1);
      } else {
        gpio__reset(G1);
      }
      if (matrixbuff[row][col] & 0x4) {
        gpio__set(R1);
      } else {
        gpio__reset(R1);
      }
      if (matrixbuff[row][col] & 0x8) {
        gpio__set(B2);
      } else {
        gpio__reset(B2);
      }
      if (matrixbuff[row][col] & 0x10) {
        gpio__set(G2);
      } else {
        gpio__reset(G2);
      }
      if (matrixbuff[row][col] & 0x20) {
        gpio__set(R2);
      } else {
        gpio__reset(R2);
      }

      gpio__set(CLK);
      gpio__reset(CLK);
    }

    gpio__set(OE);
    gpio__set(LAT);

    gpio__reset(A);
    gpio__reset(B);
    gpio__reset(C);
    gpio__reset(D);
    gpio__reset(E);

    if (row & 0x1) {
      gpio__set(A);
    }

    if (row & 0x2) {
      gpio__set(B);
    }

    if (row & 0x4) {
      gpio__set(C);
    }

    if (row & 0x8) {
      gpio__set(D);
    }

    if (row & 0x10) {
      gpio__set(E);
    }

    gpio__reset(LAT);
    gpio__reset(OE);
  }
}

void refreshdisplay(void *p) {
  while (1) {
    display();
    vTaskDelay(2);
  }
}

Accelerometer Input

  1. I2C protocol to communicate with on-board accelometer
  2. Reading only the x direction accelerometer data for spaceship movement
  3. Using simple math to calibrate the accelerometer data to corresponding position of the spaceship
int getSpaceshipPos() {
  acc = acceleration__get_data();
  if (abs(acc.x - prev_acc) > 30) {
    prev_acc = acc.x;
    if ((acc.x < 3400) && (acc.x > 2048)) {
      sp = 10;
    } else if ((acc.x >= 3400) && (acc.x <= 4096)) {
      sp = 10 + (acc.x - 3400) / 29;
    }
    if ((acc.x >= 0) && (acc.x <= 700)) {
      sp = 35 + (acc.x / 29);
    } else if ((acc.x > 700) && (acc.x < 2048)) {
      sp = 59;
    }
  }
  return sp;
}

Testing & Technical Challenges

Title Screen and Game Over Screen

When we tried to write the code for the title and game over screens, we wanted to make the design/font more eye-catching like most arcade-games are. However, coding each letter with the fancy font proved to be challenging and lengthy. Initially, we were having a function that would take the starting coordinate of where the letter should appear. To display the rest of the letter, we would have had to code the exact position of every pixel we wanted to turn on. This approach worked fine for small designs such as our spaceship, bullets, enemy ships and other minimal moving elements of the game. For gigantic letters with fancy fonts, we used 2-Dimensional array of size 64x64, and input the values using Notepad++ and its handy column selection feature. Then it was just a matter of reading from this array to display the letters.

Testing and Results

Start Screen
Gameplay
Game Over Screen


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?

This project was completely successfully after a period of two months. Although we faced initial hiccups due to a lack of datasheets for the LED Matrix, the project went smoothly afterwards. Working on this project has given us so much confidence in using the FreeRTOS API and sharpened our embedded software skills. We also followed a strict schedule which helped us deliver the project on time and improved our time management skills. Working in a team of 3 has also boosted our teamwork skills.

Project Video

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

Project Source Code

References

Acknowledgement

Firstly, we would like to thank our professor Preetpal Kang gave us this opportunity to challenge ourselves and master the concepts of FreeRTOS. We would also like to thank the ISA members for their unwavering support and guidance throughout the semester. This project was successful, thanks to all three of our team members and all the hard work each of us put in.

References Used