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ABES Engineering College, Ghaziabad

Department of Electrical & Computer Engineering

Project Title Proposal

1. Project Title (in CAPITAL letters)

IOT Based Smart Electricity Energy Meter

2. Particulars of PROPOSED Guide(s) [Maximum. 2 guides per project.]

NAME FIELD OF SPECIALIZATION

GUIDE Mr. Abhishek Kumar Gupta Power Electronics System

CO-GUIDE (Optional) Mr. Vivek kr. Verma Embedded System

3. Particular of Student(s) [maximum 4 students per project]:

S.NO NAME UNIV ROLL NO %AGE upto Technical Skill

previous Sets
Semester

Group GANESH Embedded

Leader 2300320239002 70.18 System

2 VISHAL Embedded
2300320239005 74.906 System

3 MAYANK 2300320239004 69.00 Embedded

SINGHAL System

4 ABHISHEK 2300320239001 61.00 Embedded

TIWARI System

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4. Objectives of the proposed project

(Maximum 2000 characters)

The primary objective of this project is to design and develop an IoT-based Smart Electricity Energy
Meter system that enhances the monitoring, management, and billing of electrical energy consumption.
This system will leverage real-time data acquisition, wireless communication, and cloud integration to
provide an efficient and user-friendly alternative to traditional energy meters

5. Motivation/ Literature Survey for the Project

(Maximum 1000 characters)

Traditional electricity meters lack real-time monitoring, remote access, and automation, leading to
inefficient energy management, manual billing errors, and delayed fault detection. With the growing
demand for smarter infrastructure, IoT-based energy meters have gained attention for their ability to
provide real-time data, automated readings, and remote access. Literature shows successful
implementations using microcontrollers like Arduino/ESP8266 and communication modules such as
GSM or Wi-Fi for live monitoring. Studies highlight benefits such as improved billing accuracy, energy
theft prevention, and user awareness of consumption patterns. Motivated by these advantages, this
project aims to design a cost-effective, reliable, and user-friendly IoT-enabled smart energy meter to
bridge the gap between consumers and utility providers, contributing to smarter and more sustainable
energy systems.

6. Project Duration (in months): 8

7. Work plan (including detailed methodology and time schedule in form of Gantt Chart)

(Max 5000 characters for methodology)

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Phase 1: Requirement Analysis and Planning (July)

• Objective: Define the scope, technical requirements, and design goals of the project.
• Activities:
o Identify end-user and utility provider requirements.
o Choose appropriate microcontroller (e.g., ESP32/Arduino) and sensors (current,
voltage).
o Outline system architecture (sensing, data processing, transmission, and
display).
o Prepare a bill of materials (BoM) and cost estimation.
o Create risk assessment and mitigation strategies.

Phase 2: Hardware Development and Setup (August)

• Objective: Build the physical layer of the smart meter using selected hardware.
• Activities:
o Circuit design using Proteus or Fritzing.
o Interface current and voltage sensors with microcontroller.
o Assemble components on breadboard or PCB.
o Ensure safe voltage handling using isolation components (e.g., opto-isolators).
o Calibrate sensors for accuracy in measurement.

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Phase 3: IoT Integration and Backend Setup (September)

• Objective: Enable wireless communication and backend data logging.

• Activities:
o Integrate Wi-Fi/GSM modules for IoT communication.
o Design and develop backend using Firebase, AWS, or custom server with REST
API.
o Implement data logging and timestamping of energy consumption.
o Secure data transmission using encryption or authentication tokens.
o Store user profiles, energy logs, and billing info.

Phase 4: Dashboard and User Interface Development (October)

• Objective: Provide users and utility providers a platform for real-time monitoring.
• Activities:
o Design a web/mobile dashboard using React/Flutter or HTML/CSS.
o Visualize energy usage in kWh, units consumed, cost, and consumption history.
o Add login authentication and access control.
o Display live alerts (e.g., high consumption, outages, low balance).
o Ensure responsive and user-friendly UI/UX.

Phase 5: Advanced Features and System Testing (November)

• Objective: Implement core functionalities and ensure system robustness.

• Activities:
o Enable prepaid energy metering and online recharging.
o Add logic for abnormal usage or energy theft detection.
o Perform unit, integration, and system testing.
o Use test loads to validate sensor accuracy and system stability.
o Log bug reports and perform debugging iterations.

Phase 6: Finalization, Deployment, and Documentation (December)

• Objective: Complete the project and prepare final deliverables.

• Activities:
o Perform final validation and calibration.

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o Prepare user manual and technical documentation.

o Deploy system in simulated environment or real premises.
o Compile project report with results, code, schematics, and screenshots.
o Present findings, challenges, and future scope.

8. Technical Skills involved in the Project

S. No. Skill required

1 Knowledge of microcontrollers (e.g., ESP32, Arduino)

2 Circuit design and PCB/breadboard prototyping

3 Power management and electrical safety

4 Sensor interfacing

9. Relevance to the POs & PSOs

S. No. PO/ PSO

1 PO1:ENGINEERING KNOWLEDGE

2 PO2:PROBLEM ANALYSIS

3 PO3:DESIGN AND DEVELOPMENT SOLUTION

4 PO4:USE OF MODERN TOOLS

10. Expected Outcomes of the Project

S.No. Outcome of the project

1 EFFICIENT SESSIONAL AND INTERNAL MARKS MANAGEMENT

2 REAL-TIME PERFORMANCE TRACKING

3 ENHANCED TRANSPARENCY AND ACCESSIBILTY

4 DATA-DRIVEN REPORTS

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Signature of Project Supervisor

Name: GANESH KASHYAP

Date: 17-06-2025