Location: Lombok
Relevant Fields: Embedded System& Edge Computing, Cloud Infrastructure & Web Analytics

Organisation Overview

The Computer Networks and Embedded Systems Laboratory serve as a strategic research hub dedicated to the advancement of the Internet of Things (IoT), bridging the gap between intelligent hardware and digital communication infrastructure. The facility focuses on the end-to-end development of smart systems, ranging from low-level firmware optimization using C++ and MicroPython for real-time sensor integration to the deployment of robust cloud architectures via Python Flask. By synthesizing expertise in network protocols, energy-efficient embedded design, and data analytics, the lab provides an essential environment for engineering students to transform conceptual waste management solutions into scalable, autonomous technologies that support sustainable urban development.

Project Background

As urbanization accelerates globally, municipal solid waste management has become a critical environmental challenge. Organic waste, primarily consisting of food scraps and green waste, accounts for approximately 40% to 50% of total urban waste. In many developed nations, a significant portion of this waste ends up in landfills, where anaerobic decomposition releases methane (CH_4)—a greenhouse gas significantly more potent than carbon dioxide (CO_2). For urban households, the lack of space and the unpleasant odors associated with traditional composting methods make home-based waste processing impractical.

Traditional composting is a labor-intensive and slow process. It requires manual turning to ensure aeration and precise moisture control to maintain the ideal environment for aerobic microbes. In an urban setting, where residents have limited time and expertise, these systems often fail due to:

• Improper Moisture Levels: Leading to foul odors or stagnant decomposition.
• Temperature Fluctuations: Preventing the system from reaching the thermophilic stage required to kill pathogens.
• Lack of Monitoring: Users have no visibility into the “health” of the compost, leading to guesswork and abandonment of the practice

Project Objectives

To design and develop an Autonomous In-Vessel Composting System that integrates Internet of Things (IoT) technology and cloud computing to automate and optimize the composting process. The system will self-regulate critical parameters such as temperature, moisture, and aeration, while utilizing cloud-based analytics to enhance efficiency, monitoring, and scalability for decentralized waste management applications.

Project Outcomes

The primary output of this project is an Autonomous Smart Composting Ecosystem that integrates hardware engineering, IoT technology, and cloud computing into a single intelligent waste management solution.

1. Smart Composting Ecosystem (Three Integrated Layers)

• The Smart Vessel (Hardware Layer)
  An enclosed in-vessel composting unit equipped with integrated sensors and actuators, programmed using C++ and MicroPython. The system automatically regulates temperature, moisture, and aeration to maintain optimal aerobic decomposition without manual intervention.
• The Cloud Engine (Back-End Layer)
  A centralized server powered by Python Flask that receives real-time data from the vessel. It performs analytics to monitor compost “health,” track decomposition progress, and predict compost maturity using historical data modeling.
• The User Dashboard (Front-End Layer)
  A responsive web interface built with HTML5 and CSS that visualizes real-time system performance. Users can monitor decomposition stages, environmental parameters, and receive system notifications via mobile or web access.

2. Intelligent Monitoring & Optimization System

• Real-time visualization of composting parameters
• Predictive analytics to optimize decomposition cycles
• Automated system regulation and safety monitoring
• Data-driven estimation of fertilizer readiness

3. Key System Parameter

Skills Required

• C++ Programming: Utilized for low-level firmware optimization on microcontrollers (e.g., ESP32 or Arduino). It ensures high-speed sensor interrupts and precise timing for hardware control.
• MicroPython: Employed for rapid prototyping of edge logic, such as the automated irrigation algorithm that triggers water pumps when moisture levels drop below the optimal threshold.
• Python Flask: This serves as the robust back-end framework. It manages the API endpoints that receive data from the IoT devices, handles database transactions, and runs analytical scripts to predict compost maturity.
• HTML5 & CSS: These technologies are used to craft a responsive, user-centric Dashboard. Residents can monitor temperature curves, humidity levels, and system health through an intuitive interface on any web-connected device.
• In-Vessel Structural Design: Focuses on the physical durability of the composting unit, ensuring it is leak-proof, odor-contained, and fits the aesthetic and spatial requirements of modern urban housing.
• Decentralized Waste Management: Analyzes the system’s impact on municipal infrastructure, aiming to reduce the logistical load on city waste collection services and promote local nutrient recycling.

Note: This project is being revised by the RMIT academic supervisor and the scope may be split among different teams or reduced. Further details on the project and its outcomes will be provided closer to the start date.