S14: Wireless Control Car
Contents
Grading Criteria
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- Code Quality
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- Software Block Diagrams
- Hardware Block Diagrams
- Schematic Quality
- Quality of technical challenges and solutions adopted.
Project Title
Wireless Control Car
Abstract
This project is about the development of a robotic car which can be controlled wirelessly. A robotic car has two front and back motors which are controlled independently. Both the motors are attached to a wireless module in built in the microcontroller so that it can be controlled wirelessly. This car also has three ultrasonic sensors which are attached to front, left and right side of the car. These three sensors help in avoiding any collision with the obstacle. This car also has an auto mode which enables the car to run without the user's help.
Objectives & Introduction
The objective of this project is to build a wireless robotic car. This car is designed so that it can be controlled wirelessly. This car has two DC motors to control front and back tires, an H bridge dual motor controller to control the speed and direction of the motor, three ultrasonic sensors for obstacle avoidance, an Accelerometer sensor to detect the direction of board rotation and a wireless module to control the car wirelessly.
The project is divided into following objectives:
- Design the circuit and algorithm for motor controller to control both front and back motor independently.
- Write the driver to control in build accelerometer sensor on the microcontroller.
- Write the wireless driver to send and receive commands between two microcontroller boards.
Team Members & Responsibilities
- Deepak Yadav
- Project Design and Testing
Schedule
Week# | Date | Task | Actual |
---|---|---|---|
1 | 02/24 | Project Planning | Completed on Time |
1 | 03/06 | Order Parts | Completed on Time |
1 | 03/10 | Reviewing part's user manual and datasheet | Completed on Time |
3 | 03/24 | PWM Driver | Understanding PWM took more time than I was expecting. It's Completed on (04/6) |
3 | 03/24 | Wireless Driver | Completed on Time |
3 | 04/1 | Acceloremoter Driver | Completed on Time |
3 | 04/12 | Design Integration | Completed on Time |
2 | 04/14 | Testing and Debug-Phase 1 | Completed on Time |
2 | 04/21 | Testing and Debug-Phase 2 | Partially Completed. Found some software bugs that needs to be fixed. |
1 | 05/08 | Project Demo | Pending |
Parts List & Cost
Item# | Part Desciption | Vendor | Qty | Cost |
---|---|---|---|---|
1 | SJOne Board (LPC1758) | One board from SJSU CmpE and one board by Preet | 2 | $80.00 |
2 | Toy car(including two DC Motors) | Grocery Outlet (Any toy store/grocery store such as Walmart) | 1 | $15.00 |
3 | Ultrasonic Sensor | Amazone | 1 | $5:00 |
4 | 9V Battery | Frys | 1 | $12:00 |
5 | Accessories (Jumper Wires, prototype board and battery charger) | Frys | 1 | $20:00 |
Total Cost | $132:00 |
Design & Implementation
Hardware Design
The hardware is designed by going through each project part's datasheet and LPC1758 microcontroller. After understanding the pin connections and the design, all the parts are connected by jumper wires. The Power to the microcontroller is supplied by USB cable which is spliced so that one end is connected to the 5V power supply. The Power source used for this project is rechargeable 9V battery, which is then connected to a power distribution circuit. A Power distribution circuit takes 9V from rechargeable battery converts to 5V. The Following block diagram shows the overall connection between the project parts:
Hardware Interface
The Transmitting Module used the following interfaces:
- I2C Bus
- Used to read the board orientation from Accelerometer sensor
- SPI Bus
- Used to transmit commands from Nordic wireless from receiving board
- GPIO
- Control Motor direction and speed, read ultrasonic sensor and Switches for start and stop
The Receiving Module board used the following interfaces:
- SPI Bus
- Used for receiving commands from a Nordic wireless from transmitting board
- GPIO
- PWM interface for front and back motor
- Direction control for front and back motor
- Send Trigger to Ultrasonic sensor
- Detect Echo back pulse from Ultrasonic sensor
Software Design
The Software is implemented by following the below flowchart:
Transmitting module
Receiving module
Implementation
Accelerometer Sensor
Ultrasonic Sensor
Motor Controller
Power Distribution Circuit
Nordic Wireless Sensor
Testing & Technical Challenges
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My Issue #1
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Conclusion
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Project Video
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Project Source Code
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References
Acknowledgement
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References Used
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Appendix
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