Embedded System based Independent Scientist Satellite Payload
Objective
The main objective of this project is to create an embedded system-based independent scientist satellite payload, enabling scientific research and data collection in space with a focus on autonomy, versatility, and accessibility for independent scientists and researchers.
Abstract
The Embedded System based Independent Scientist Satellite Payload (ESSP) is a sophisticated technology designed for autonomous scientific data collection and transmission in satellite missions. In this innovative system, separate transmitter and receiver components are utilized to optimize functionality. The receiver, housed within a ground station, integrates a Raspberry Pi and Zigbee receiver module. Data received by the ground station is seamlessly transmitted to a web server, ensuring accessibility and analysis. On the transmitter side, an Arduino microcontroller serves as the central processing unit, supported by a GPS module for location tracking, a DHT11 sensor for monitoring temperature and humidity, and a BMP180 sensor for pressure measurements. Additionally, an LCD display is incorporated to provide essential data visualization. The communication between the transmitter and receiver is facilitated by Zigbee modules, enabling efficient data transmission and reception. This integrated ESSP system demonstrates a robust approach to satellite-based scientific exploration, offering a versatile platform for independent researchers and scientists to conduct diverse experiments and gather valuable data from remote locations.
Keywords: Raspberry pi, Zigbee (Transmitter and Receiver), Arduino, GPS, DHT 11, BMP180, LCD, Webserver.
NOTE: Without the concern of our team, please don't submit to the college. This Abstract varies based on student requirements.
Block Diagram
Specifications
Hardware components:
- Power supply
- Raspberry pi
- Zigbee (Transmitter and Receiver)
- Arduino
- GPS
- DHT 11
- BMP180
- LCD
Software components:
- Raspbian
- Python
- Arduino IDE software
- Embedded C language
Learning Outcomes
- Raspberry pi pin diagram and architecture
- How to install Raspberry pi IDE software
- Setting up and installation procedure for Raspbian
- Basic coding in Raspbian
- Basic of python language
- Working of power supply
- Arduino Uno pin diagram and architecture
- How to install Arduino IDE software
- Setting up and installation procedure for Arduino
- Introduction to Arduino IDE
- Basic coding in Arduino IDE
- Basic of Embedded C language
- Basics of IoT platforms
- Working of Zigbee (Transmitter and Receiver)
- GPS working
- DHT 11 working
- BMP180 working
- Working of LCD
- Interface LCD with Arduino?
- Working of power supply
- About Project Development Life Cycle:
- Planning and Requirement Gathering( software’s, Tools, Hardware components, etc.,)
- Schematic preparation
- Code development and debugging
- Hardware development and debugging
- Development of the Project and Output testing
- Practical exposure to:
- Hardware and software tools.
- Solution providing for real time problems.
- Working with team/ individual.
- Work on Creative ideas.
- Project development Skills
- Problem analyzing skills
- Problem solving skills
- Creativity and imaginary skills
- Programming skills
- Deployment
- Testing skills
- Debugging skills
- Project presentation skills
- Thesis writing skillS
Paper Publishing
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Disclaimer - Takeoff Edu Group Projects are not associated or affiliated with IEEE in any way. The IEEE Projects mentioned here are mentioned in the context of student projects, whose ideas are derived from IEEE publications, not projects of or by IEEE.
