Centre for Skill and Entrepreneurship Development

3D SMART FACE ATTENDANCE

The 3D Face Attendance Device integrates advanced deep learning technology for 3D live face recognition, powered by Python and Raspberry Pi 4 with a Raspi CAM. It features a React JS front-end and Python Flask back-end for a seamless user experience and connects with Zoho People via API for automated attendance tracking. Smart functionalities include OTA firmware updates, remote troubleshooting, Wi-Fi connectivity, and real-time device monitoring. Designed for diverse applications such as universities, offices, gated communities, and R&D centers, the device is housed in a durable, wall-mounted enclosure crafted with CATIA 3D Experience and 3D-printed using ABS material, making it a robust and efficient solution for attendance and access management.

THREE-PHASE ENERGY METER (MFM)

The Three-Phase Energy Meter, also known as a Multi-Function Meter (MFM), is designed to measure and monitor electrical parameters in three-phase power systems. It provides real-time data on voltage, current, power factor, frequency, and energy consumption across all three phases.

This meter is essential for applications in industrial settings, commercial buildings, and power distribution systems where accurate monitoring and analysis of energy usage are critical. The MFM also supports load balancing, efficiency optimization, and fault detection, ensuring reliable operation of electrical systems. Its advanced features make it a key tool in energy management and cost-saving strategies for high-demand environments.

SMART AUTONOMOUS EV

The Smart Autonomous EV integrates advanced technologies such as a Battery Management System, RFID security, location tracking with geofencing, driving pattern analytics, and EV range predictions, along with autonomous driving capabilities and a dedicated mobile application for easy control and monitoring. It is ideal for applications such as in-campus rides at colleges, transportation in parks and public places, and short tourist rides. The internship involved in the development of this project provided proficiency in autonomous technology, as well as industry-ready skills in IoT, embedded systems, and IoT cloud solutions, along with application development expertise. This project offers an innovative, secure, and eco-friendly solution for modern electric mobility.

CROP YIELD PREDICTION

The Crop Yield Prediction system uses historical agricultural data and environmental factors such as soil conditions, weather patterns, and the impact of pests and diseases to predict crop yields. It helps optimize farming practices through precision agriculture, improves irrigation strategies by incorporating water usage data, and predicts the best harvest time for crops. Additionally, it offers automated market predictions to guide farmers in making informed decisions. Students involved in this project gained expertise in predictive analytics, learned sustainable farming practices, developed skills in interdisciplinary collaboration, and gained real-world project management experience, preparing them to apply data-driven solutions in agriculture.

SMART INDUSTRY METER

The Smart Industry Meter is designed for real-time monitoring of industrial machinery performance, focusing on energy consumption, live billing, and operational metrics. Equipped with a 4G IoT Gateway, it provides seamless connectivity for data transmission and integrates with a custom mobile app for easy access to reports and alerts. The device delivers critical insights such as power factor (PF) and operation matrices, tailored for industries like the forging sector in Pune. Enclosed in a DIN-rail mountable structure, the device is engineered with CATIA 3D Experience and 3D-printed ABS material, ensuring durability and compatibility with industrial panels. This innovative solution enhances efficiency and productivity with actionable data and alerts.

SMART GENSET MONITORING KIT

The Smart Genset Monitoring Kit is a comprehensive solution designed to monitor essential diesel engine parameters, fuel consumption, and generated energy. With IoT cloud integration and mobile app connectivity, it enables real-time monitoring and management, making it ideal for applications in smart homes, hospitals, commercial spaces, and carbon footprint management. The system allows for remote monitoring and optimization of genset performance, ensuring efficient energy usage. The internship experience provided hands-on coding skills with live projects and exposure to IoT, Data Analytics (DA), and Machine Learning (ML) technologies, preparing interns for industry-standard product development and equipping them with valuable experience for future tech roles.

VIRTUAL REALITY SYSTEM

A Virtual Reality (VR) System creates immersive, computer-generated environments that allow users to interact with virtual worlds in a highly realistic way. Using specialized hardware such as VR headsets, motion sensors, and haptic feedback, users can engage with and explore 3D simulations in real time. VR has applications across various fields, including education and training (e.g., medical, aviation, and engineering simulations), entertainment (such as gaming and immersive cinematic experiences), and design & visualization (helping architects and engineers visualize projects in 3D before execution). This technology is revolutionizing industries by providing hands-on experiences and interactive solutions that were previously impossible in traditional environments.

SMART STREET LIGHTS

The Smart Street Lights system integrates PIR sensors to detect motion and ambient light sensors to activate the lights only when needed, ensuring energy efficiency. This adaptive lighting system is ideal for smart homes, parking management, public park lighting, and smart campus lighting, where lights automatically adjust brightness based on activity and surrounding light conditions. Students working on this project gained hands-on experience in designing, programming, and deploying IoT solutions while developing an energy-efficient system. The project also fostered interdisciplinary collaboration, combining knowledge from engineering, technology, and energy management to create a practical, sustainable solution.

PARTS ON CNC MACHINE

The Parts on CNC Machine project involves the use of Computer Numerical Control (CNC) machines to manufacture precise and complex parts. These machines are programmed to follow specific design patterns, allowing for efficient, high-precision production of parts used in various industries. This technology ensures consistency and accuracy in manufacturing, reducing human error and optimizing production speed. CNC machines are widely used in sectors like automotive, aerospace, and electronics to create custom components with intricate designs.

3D SCANNER

A 3D scanner is a device that captures the physical dimensions of an object and creates a digital 3D model. It works by emitting a light source, usually laser, to scan the surface of an object and record the reflected data. This technology is commonly used in design, reverse engineering, quality control, and prototyping. 3D scanners are essential in industries such as manufacturing, healthcare, and entertainment, as they allow for accurate digital representations of real-world objects for further analysis or modification.

PARKING AREA MANAGEMENT

Parking Area Management systems use technology to optimize the usage of parking spaces in busy environments such as malls, offices, and urban centers. These systems typically involve real-time monitoring of parking spaces through sensors or cameras that track availability and guide drivers to open spots. Parking management software can also integrate payment solutions, reservations, and usage analytics to streamline operations. This reduces traffic congestion, enhances user experience, and improves the overall efficiency of parking spaces, especially in high-demand areas

SINGLE-PHASE ENERGY METER

A Single-Phase Energy Meter is a device designed to measure and monitor electrical energy consumption in single-phase power systems, commonly used in residential and small commercial setups. It accurately records parameters like voltage, current, and power consumption, enabling users to track energy usage effectively.

Modern single-phase energy meters often include features like digital displays, remote monitoring via IoT integration, and prepaid or smart billing options. They are essential for efficient energy management, allowing users to monitor their power usage, detect inefficiencies, and reduce electricity costs while contributing to overall energy conservation.

INDOOR AIR QUALITY MONITORING

Indoor Air Quality (IAQ) Monitoring involves the use of sensors to detect and analyze key air quality parameters such as CO2 levels, humidity, temperature, volatile organic compounds (VOCs), and particulate matter (PM2.5 and PM10). These systems provide real-time data, often integrated with cloud platforms for continuous monitoring and mobile app connectivity for user convenience.

IAQ monitoring is crucial for applications in smart homes, offices, elderly care, ICUs, and smart HVAC systems, helping to identify and mitigate potential health risks caused by poor air quality. By automating appliance control based on air quality data, these systems enhance comfort, health, and energy efficiency. They are a cornerstone of modern sustainable and health-focused living spaces.

Smart Car Parking System

In these modern days finding car parking is a big issue in congested cities. There are too many vehicles on the road but not enough parking spaces. One of the biggest problems is when we enter a parking area then we realize that there are no empty parking slots to park our cars. Important time. Another biggest problem is after entering in a big parking area we confused to find the empty parking slot to park our car. Sometimes maybe we all have been facing these two problems that wasted our important time. That’s why we need efficient parking management systems in all parking areas that will provide confusion-free and easy parking.

Smart Door Automation

Security describes protection of life and property. The safety in the house is very important. Besides the traditional method door that used a key can be easily open by not authorized person or burglar if they have the right. This will allow them to steal the entire valuable thing in the house. Nowadays the technologies become wider and features exist to make human life better. This project uses a technology that opens the door automatically after providing password.

Arduino Based Pulse Oximeter

The objective of a pulse oximeter in IoT (internet of things) is to monitor and measure the oxygen saturation (spo2) and heart rate of an individual remotely and in real time using a connecting device. pulse oximeters are small, non -invasive medical devices that are typically attached to a fingertip or other part of the body, and they use infrared light to measure the amount of oxygen carried by haemoglobin in the blood.

Wi-Fi Based Light Automation

The objective of the project is to design and implement a home automation system using ESP8266 Wi-Fi module to control and automate the lighting system. The aim is to provide convenience, energy efficiency, and remote-control capabilities to the users.

Bluetooth Controlled Car

The objective of the project is to design and build a car that can be controlled remotely using an Arduino microcontroller and Bluetooth communication. The aim is to demonstrate the use of wireless technology for remote control applications.

Obstacle Avoidance Robotic Vehicle

Obstacle avoidance is one of the most important aspects of mobile robotics. Without it, robot movement would be very restrictive and fragile. This project proposes robotic vehicle that has an intelligence built in it such that it directs itself whenever an obstacle comes in its path. So, to protect the robot from any physical damages.

Smart Door

Develop a smart door system using IoT and Arduino Uno R3 to provide secure access control to a building or room. Enable authorized individuals to unlock the door using a keypad or mobile application. Utilize a servo motor to actuate the door lock mechanism upon successful authentication. Develop code to control the servo motor's position, enabling the door to unlock or lock accordingly. Incorporate an ultrasonic sensor to detect the presence of a person in front of the door.