30+ Best ARM Project Ideas for Final Year Electronics Students

Most ARM-embedded system projects currently use ARM microcontrollers and processors. Below is the list of the best 30 Latest ARM Project Ideas for ECE final-year students brought to you by Listyaan. ARM Project Ideas for B-Tech, M-Tech & Ph.D. students.

• Wireless Biomedical Parameter Monitoring System Using ARM9:

This project implements a health monitoring system to measure the physiological characteristics of ICU patients, such as heartbeat, body temperature, oxygen level, and blood pressure, using an ARM microcontroller and biosensors.

In this project, the patient’s health could be continuously tracked, and Zigbee WSNs could be used to relay the patient’s data to the microcontroller. The ARM processor analyses the patient data, which is then saved in the database.

A doctor can receive an SMS sent automatically by the GSM module if a patient in the ICU reports feeling ill.

• Postpaid and Prepaid Energy Meter Using ARM:

This project builds a prepaid energy meter using an ARM microcontroller to prevent electricity theft. The prepaid metering system and remote load control are combined via the GSM network.

This meter can be installed in each consumer unit, using a server unit provided by the service provider and an ARM7 microprocessor to measure the amount of energy utilized. These gadgets have an LCD and a GSM modem, with the GSM acting as an energy consumption display.

Power is immediately shut off when the meter’s balance reaches zero, and the user is notified by SMS to recharge the energy meter. The suggested approach, therefore, fights against electricity theft and illegal use of electricity.

• Temperature and Humidity Control System Using ARM and Graphical LCD:

This project offers a control system for monitoring and managing various environmental variables using ARM and LCD. The characteristics, which include humidity, temperature, fire, gas, and fire, are assessed and recorded in a data logger. An LCD monitor can be used to view this data.

• Voice-Based GPS Navigation System Using ARM:

In this project, GPS is used to pinpoint the precise location of sensor-collected data. Additionally, this idea employs GPS to develop a voice alarm system for blind people that notifies them when they reach their destination and reveals their current location.

• ARM and RFID-Based Security systems (Home, Office, Industrial):

This project builds an automotive security system using RFID and ARM to prevent auto theft. In this project, GPS, RFID, and GSM can all be used as two sensors. RFID is required when a vehicle door is opened.

This project also makes use of an accelerometer sensor to monitor the movement of the car and the breaking of the window. The fuel injector in the car can be turned off if the correct password is not entered and an SMS with the precise GPS location of the vehicle is sent to the concerned person’s phone.

• ARM-based Ear Recognition Embedded System:

This project uses PCA (Principal Component Analysis) and an ARM microcontroller to create an ear recognition system. PCA is the simplest technique to recognize the pattern in this case; nevertheless, it is rarely employed in many applications. However, it is possible to program and use this ear recognition system as an embedded system.

• Advanced Electronic Voting Machine (EVM) using ARM:

A simple electron machine can be used to conduct elections in India. However, there is a possibility of voting instead of an authorized person; any unauthorized person can vote.

To overcome this, an EVM is used to validate the voter, utilizing RFID and ARM7 to verify the voter’s fingerprint. In addition, RFID is used to send and receive basic information. As a result, the proposed approach adds to the level of safety.

• ARM7-based Drunken People Identification by Disabling Auto Ignition Function using ARM7:

This effort, which is based on ARM7, intends to lessen the number of accidents brought on by drunk driving. To avoid this, the suggested technique tracks drunk driving by drivers. This project can be accomplished with an ARM 7 CPU to automatically turn off the ignition in the car when the sensor’s data is received.

• DC Motor Speed Control & Direction through ARM7:

This project uses the ARM7 processor and the PWM method to control the direction and speed. This processor’s signal width is changed to maintain the required speed level of the motor.

• ARM-based Web Server Design & Development:

This project builds an embedded web server that offers users several services using an ARM 9 real-time CPU.

• Mobile Robot using PID Controller for Drive System of DC Motor:

The proposed method uses a particular motor drive technology for mobile robots in agriculture to reduce productivity and labor costs. In this project, an ARM 9 controller is used to construct the PID controller for the drive system.

• ARM-based Smart Shopping System:

This project develops a smart shopping system using an ARM CPU. Currently, shopping in major cities takes a lot of time, and the billing procedure makes us wait in line due to the enormous volume of visitors in malls. The recommended approach makes use of an RFID-based trolley to remedy this.

• Wireless Electric Board using ARM:

In this project, an electronic board with a pen substitutes the traditional blackboard with a chalkboard. Using this hardware, the handwriting can be turned into an electrical signal and sent to a computer for projection on a big screen.

This concept can be implemented for portable devices using an ARM 9 board and an RTOS.

• Wireless Network & ARM9-based Safety System for Mines:

This project uses continuous environmental monitoring of variables like humidity, gas, temperature, and others to protect subterranean workers. This project may be made with an ARM 9 CPU and a Zigbee sensor.

• EVM based on Biometric System:

This project creates a fingerprint-based EVM machine that collects, stores, and processes voting data using an ARM9 microcontroller. This project is easy to design, affordable, and adaptable.

• Monitoring and Controlling System for Power Factor using ARM Cortex:

With a microcontroller such as the ARM Cortex, a relay driver, and a zero-crossing detecting circuit, this project is utilized to construct an autonomous PF monitoring and controlling system.

• AES Algorithm-based Encryption:

This project uses ARM7 to design an encryption method for military data protection. The major goal of this AEC algorithm-based encryption project is to keep storage devices secure.

• MEMS-based Self-Balancing Robot:

The main concept of this project is to design a robotic vehicle to control through a MEMS sensor. This sensor is a highly sensitive type that is capable of detecting tilt.

This robot is used to detect tilt, so used in the construction field to detect the slopes within the floors, beamers, etc. By using this robot, manual operation can be reduced.

• Raspberry Pi-based Monitoring System for Weather:

The proposed approach is used to construct a system that makes use of both a DHT sensor and a Raspberry Pi. This technology is used to monitor and record the temperature and humidity in a certain area.

You will build a device to monitor, record, and transmit the temperature and humidity of a specific area in this mini-project using a Raspberry Pi and a DHT sensor.

With the addition of a special feature, the system can trigger an alarm by sending an email or SMS if the temperature rises above a predetermined level. Data analysis can be done using the cloud platform utilizing this project.

• Surveillance System for Smart Security with Labview & ARM Cortex M0:

A smart security surveillance system that overcomes the limitations of existing IP (Internet Protocol) cameras monitors and records human detection using the ARM Cortex M0 Processor and a Labview interface.

• Detection System of Collision using ARM Cortex M3:

This project constructs an accident detection and airbag deployment system using the ADXL sensor and modules like GPS and GSM that are properly interfaced through the ARM CPU.

• Implementation of Intelligent Substation through Web & Monitoring and Controlling of Power Equipment:

This ARM-based project builds a control system for tracking the current, temperature, and voltage of a substation using the internet. This system also offers safety when these parameter values are higher than the threshold. The entire machine can be turned off to protect this system.

• Digital Nameplate with Visitor Sensing:

An Atmega 328 microcontroller, an ultrasonic sensor, an LED display board, a buzzer, buttons for operation, some basic electronic parts, and a PCB board are all used to create the system. The input message that will be shown on the LED board is saved in the controller.

The family or workplace name could be in the message. Along with the firm name, this could also include the names of any family members or the company tagline. On the system, the message and user name are displayed in a scrolling display.

This makes it possible for an exterior LED nameplate to be brilliant and move about. An integrated ultrasonic sensor is another component of the system. Unless an object is within one meter of the ultrasonic sensor, the ultrasonic frequency it sends does not return to it.

The ultrasonic waves are reflected by the user and are first detected by the sensor when a visitor approaches and stands in front of it. The microcontroller notices this sensor trigger. Now the microcontroller shows the welcome message it has stored.

• Medical Supplies Delivery Drone:

Six high-torque quadcopter motors are used by the system to produce the necessary lift for the supply mission. The motors are appropriately outfitted with complementary propellers.

The basket’s one-side-opening flap is utilized to make it simple to add and remove items. Here, we communicate flying instructions to the drone via an RF controller remote. The onboard controller continuously reads these signals using an rf receiver to regulate the drone motors accordingly.

Using a wireless remote controller, the drone flies in response to user commands. The drone’s camera is utilized to relay real-time video to the user, enabling remote control operation of the aircraft. Rooftops can be reached by drone.

• DIY Oxygen Concentrator Generator Using PSA With Leakage Detection For Covid 19:

Here, we create a homemade oxygen concentrator that uses a pneumatic supply to produce oxygen from ambient air. To construct this system, our machine uses pneumatic pressure, zeolite containers, a separate pressure vessel, pressure sensors, oxygen sensors, and leakage sensors.

We first force air through our system’s valves using ambient air through an external compressor. Air is pushed through the zeolite vessels via the valves. To ensure that the atmospheric N2 undergoes a quadruple moment and that the oxygen and other gases are at least free to travel, we hold the compressed air here through the zeolite containers.

The oxygen-rich air will then be forced into the second pressure vessel by opening the vessel’s outflow valves. We simultaneously keep an eye out for leaks because combustion can be fueled by high oxygen levels.

When a leak is found, the system automatically shuts off and a bell sounds. The second pressure vessel’s oxygen-rich air is then regulated and pushed through to the patient or supplied to the ventilator as needed. Together, the pressure sensors and valves produce the desired result.

To maintain track, a panel simultaneously displays the created air’s pressure and oxygen concentration. A microcontroller controls the entire system to ensure seamless operation.

• Public Property Violation and Anti-Littering Drone:

Litter that has fallen into the roadside ditch, the street, or the bushland can be swept or blown into the streets. It is regarded as a widespread issue with detrimental impacts on both human health and the environment. Our idea intends to use a drone to address this problem.

The authorities will use this drone’s wireless camera for surveillance to keep an eye on the region. When they spot a miscreant littering, they can maneuver the drone closer to the offenders and use an onboard speaker assembly to broadcast a pre-recorded message to inform them and stop them from littering.

This will allow us to keep an eye on the region and contribute to its upkeep.

• Waste and Garbage Recycling Vending Machine Project:

Our waste recycling system will assist in separating recyclable waste from non-recyclable waste and also offer financial benefits to the individual. In this waste management vending machine, rubbish bags would be marked with barcodes that would indicate whether the waste was recyclable or needed to be disposed of.

Then, these bags are put on a conveyor, where a barcode reader scans them along the way to identify the type of garbage they contain.

At the end of the conveyor, a servo motor arrangement pushes the bags into the appropriate bins, where the non-recyclable waste is disposed of, the recyclable waste’s weight is calculated, and the user is given a sum corresponding to that weight.

• Mini Windmill Power Generation Project:

In this project, a Windmill prototype that rotates horizontally is being employed. A 12V battery is charged using a windmill, or wind turbine generator, in the Mini Windmill Power Generation Project.

The Atmega328 microprocessor, on which the system is built, cleverly senses and charges the battery while showing the voltage on the LCD. The windmill can provide enough power to charge a battery when there is sufficient wind to propel it.

It can automatically charge the battery without emitting any hazardous pollutants because it can operate under ideal natural conditions without requiring fossil fuel. Thus, this project serves as an illustration of how renewable natural resources, such as wind energy, can be effectively exploited to provide electricity while preserving the environment.

• Fingerprint Vehicle Starter Project:

To start the vehicle, the user only needs to scan their finger; a key is not required. The car can only be started by those who are authorized by the system. By scanning their fingerprints, users can first register on the system. Multiple people can register as authorized users on the system.

The system looks for users to scan when in monitoring mode. When a user is scanned, the system determines whether they are an authorized user and only allows them to start the vehicle. An Atmega 32 microcontroller is used in this case.

The microcontroller is attached to the fingerprint sensor, and there is also an LCD, push buttons, and a starter motor. The motor is used to show how to start a car. This system uses a fingerprint-based approach to automate both vehicle security and access control.

• Hovercraft Controlled By Android:

In this article, we suggest a sophisticated hovercraft that combines high-rpm motors with an AVR family microcontroller to accomplish the needed functionality.

Low friction is achieved by the hovercraft’s motor rotating at a high RPM, which enables it to generate a force sufficient to cause it to hover on the surface. The hovercraft is then propelled forward using the engine propeller situated behind it.

To propel the hovercraft in the proper direction, we must now also employ a servo motor that is attached to the rudder. This device bends the air at precise angles to assist in the movement of the hovercraft.

The system functions as a whole to hover while continuously controlling the servo and propeller motor to move the hovercraft in the desired direction. Now, we utilize an Android app to control the hovercraft. The hovercraft circuit receives movement instructions from the android application.

A Bluetooth receiver is part of the circuit, which will take these commands and process them. Now that the microcontroller has analyzed the commands the receiver has received, it is operating all three motors by the user’s instructions