The Smart Parking System is a forward-thinking approach to urban mobility, providing a holistic solution to the difficulties of parking congestion in modern cities. We want to make parking more sustainable, efficient, and user-friendly for everyone by combining sophisticated technology and data-driven insights.


Empowered and Driven:
Delivering Solutions for Global Issues

Goal 11: Sustainable Cities and Communities: The Smart Parking System contributes to creating sustainable cities and communities by promoting efficient land use, reducing traffic congestion, and minimizing environmental impact through reduced emissions from circling vehicles.
Goal 9: Industry, Innovation, and Infrastructure: By integrating advanced technologies such as the Internet of Things (IoT) and real-time data analytics, the Smart Parking System fosters innovation in urban infrastructure, enhancing the efficiency and effectiveness of parking management.
Goal 13: Climate Action: The Smart Parking System helps combat climate change by reducing greenhouse gas emissions associated with urban transportation. By optimizing parking and reducing traffic congestion, the system contributes to a cleaner and greener urban environment.
Goal 12: Responsible Consumption and Production: Through dynamic pricing and efficient resource allocation, the Smart Parking System promotes responsible consumption and production practices in urban mobility, optimizing the utilization of parking spaces and reducing waste.
Goal 17: Partnerships for the Goals: The implementation of the Smart Parking System encourages collaboration and partnerships between various stakeholders, including government agencies, private sector entities, and community organizations, to achieve shared objectives related to sustainable urban development and transportation.


Technological Complexity: Combining several technologies was difficult. Data Privacy and Security: Handling sensitive data necessitates strong safeguards. Infrastructure limitations may impede deployment. User Adoption: Motivating users to embrace new systems can be tough. Financial viability: It is critical to ensure long-term viability in the face of significant initial investment. Regulatory Obstacles: Navigating rules and securing licences may be challenging. Poor Team collaboration and effective planning
Technology: Ensure a wide range of knowledge and rigors testing for easy integration. Data security should include encryption, access limits, and frequent audits. Infrastructure: Prioritise locations with superior infrastructure and invest in improvements. Encourage user adoption with incentives, user-friendly interfaces, and outreach activities. Financial viability entails creating a sustainable business plan and exploring financial possibilities. Regulatory Compliance: Communicate with authorities early, remain up to current on rules, and obtain legal counsel. Stakeholder Engagement: Encourage open communication, respond to concerns, and include stakeholders in decision-making. Team collaboration and effective planning
Use Case
Use Case: Smart Parking System Scenario: Sarah uses a Smart Parking System to quickly find,and pay for a parking spot in a busy urban area. Steps: Sarah accesses to our parking location. She enters available parking spots and chooses one. Sarah navigates to the spot Upon arrival, she parks and and its record is in membership plan. After her visit, Sarah exits the parking facility seamlessly. Benefits: Time-saving, hassle-free parking experience. Reduced congestion and emissions. Data insights for city planning.


List of Essential Tools and Technologies



This project aims to develop a smart parking system using a Raspberry Pi to optimize parking space utilization and improve driver experience. Hardware Components: Raspberry Pi: This will be the core unit, processing sensor data and controlling functionalities. Ultrasonic Sensors (or alternative): Sensors will detect the presence or absence of a vehicle in a parking space. Camera : A camera can be used for additional functionalities like license plate recognition. Server : A server can be used for central data storage, remote access, and integration with mobile apps (if desired). Motorized Gate : A motorized gate can be integrated for automated parking space access control. Display: A display will show real-time parking availability information. Power Supply: The system will be powered by an adapter. Software Development: Programming Language: Python will be used for coding due to its ease of use and extensive libraries. Functionality: Parking Space Detection: The ultrasonic sensors will continuously detect vehicles in designated parking spaces. Real-time Availability Display: The display will show which parking spaces are free or occupied. Data Logging (Optional): Parking data can be logged on the Raspberry Pi or a server for analysis of parking patterns and optimization. Camera Integration : Utilize the camera for license plate recognition, allowing for automated access control or parking fee management. Mobile App Integration (Optional): Develop a mobile app to display real-time parking availability and potentially reserve parking spaces. Prototype Development: Start with a basic setup using the Raspberry Pi, ultrasonic sensors, and display. Develop core functionalities like parking space detection and displaying availability. Integrate the camera for license plate recognition (optional). Test and refine the system for sensor accuracy and display clarity. Future Enhancements: Motorized Gate Integration: Integrate a motorized gate for automated parking access control based on license plate recognition or pre-booking through a mobile app. Advanced Sensor Integration: Explore alternative sensors like magnetic loop detectors for increased reliability in parking space detection. Cloud Integration: Implement cloud connectivity for centralized data storage, remote system management, and potential integration with smart city infrastructure.

Online Marketing
Creative agency
Web development


Impact on the market

``Our Smart Parking System's market launch promises to improve parking management, urban mobility, and customer experience. By optimising parking space utilisation, decreasing congestion, and offering data-driven insights, our technology solves critical difficulties in urban contexts, paving the way for more efficient, sustainable, and user-friendly parking solutions.




“Smart Parking System Process Overview:

Planning and Requirements: Determine objectives and acquire requirements.
Design and development include the creation of system architecture and software components.
Deployment & Installation: Install hardware and software, then test.
User Onboarding: Provide users with training and support resources.
Operation and maintenance include monitoring performance, updating software, and maintaining hardware.
Data Analysis & Optimisation: Use data to get insights and improve system performance.
Stakeholder Engagement: Gather feedback from stakeholders and iterate accordingly.
Scaling & Expansion: Move the system to new sites and investigate new features or services.”

The Team

Meet the team of ``Project name``

Team Member Team Member; ?> Team Member
Prabesh Chapai
Team Member
Team Member Team Member; ?> Team Member
Om Revalia
Team Member
Team Member Team Member; ?> Team Member
Wasiq Ali
Team Member
Team Member Team Member; ?> Team Member
Mahdi Hussain
Team Member