Here is the list of the top 30 Best Drone & Robotics Based Project Ideas for Engineering Students brought to you by Listyaan. Drone & Robotics Project Ideas for B-Tech, M-Tech & Ph.D. students.
Robotic and drone technologies can be utilized to increase the reliability and efficiency of power grid maintenance. Although they are presently controlled, drones can fly independently thanks to GPS self-positioning.
Birds are intelligent enough to recognize scarecrows as fake humans since they don’t move, hence scarecrows have rarely been successful in keeping them away from fields. The system uses a CONTROLLER, a DC motor, a battery, solar panels, gears, linkage joints, a microphone for sound detection, a pole, and a model frame to construct the system.
On a metal pole in a field, the scarecrow is positioned. Due to the lack of a need for an external power source, it may be installed anyplace outside. During the day, the system’s battery is continually charged by the solar panels.
The robotic vehicle achieves this process using a set of geared motors with wheels, a metal robotic frame, ultrasonic sensors, controller circuitry, batteries, and solar panel. The technology employs ultrasonic motors with control electronics to travel across gardens and lawns with ease.
The robotic vehicle has four-gear motors attached to it to provide the necessary torque for navigating gardens and lawns. We attach four substantial rubber wheels to the motor shafts so they won’t get caught in weeds and grass.
Theo Jansen connections control the kinematic motion used by the spider robot. This makes it possible to convert a DC motor’s rotating motion into an animal-like step motion. Two DC motors are used by the robot to drive the mechanism. The robotic chassis, or mainframe, has motors situated on two opposing sides.
Using Jansen connections, the gear action is changed into a stepping motion. This connection arrangement enables the eight legs combined to move in any direction. The robot can spin in addition to moving forward and backward. A microcontroller-based circuitry is used to create the spider controller.
The robotic vehicle utilizes a motorized tracked setup together with a Gripper setup that is controlled by a wireless remote controller. User movement orders are sent to the tracked robot via the wireless remote.
An rf receiver and an Atmega328 microprocessor are coupled in the robot receiving circuitry. The microcontroller was given the movement orders that the rf receiver had picked up. This data is processed by the controller, which then controls 4 Motors to provide the required movement.
This project creates a little RC drone boat that separates oil from water by acting as an oil skimmer. Working together, a swarm of these tiny drones can clean up oil spills and save the oil itself.
The user uses an RC remote control to steer the boat, which is driven by a DC engine and has two rudders. A built-in oil skimmer mechanism on the RC boat separates the oil from the water and collects it in a different tank. This makes it possible to collect oil from the water in addition to cleaning it.
The controller, a wireless joystick, responds to human inputs and enables remote control of robotic equipment. Here, we employ a joystick to send steering-type signals from the user, and four push buttons to receive button press commands from the user.
The user has a choice of communication methods, including Bluetooth and RF frequency. An internal switch on the controller remote lets the user choose their preferred communication method. An atmega 328 controller controls the controller, which is powered by tiny battery.
This robot’s straightforward mechanism makes it simple to use and maintain. This Robot’s batteries, microcontrollers, and circuits are protected from the elements by a closed, heavy-duty metal chassis, allowing it to function even in the worst conditions. It can even film and follow your off-road escapades in the first person with this Robot’s action camera mount.
Most drones suffer from this deadly fault, which renders them useless during downpours and thunderstorms. The fragility of traditional drones is something that our waterproof action camera drone seeks to address.
This drone, which has a range of up to a kilometer, may be used for both scouting and firing. This drone can easily hold any type of action camera because of its payload capacity of up to 500 grams.
Water is kept away from the device’s core electronics and functions thanks to its waterproof body. Consequently, the drone can continue to operate and you may get beautiful, natural footage even if it is pouring rain.
By ensuring the solar panels are maintained clean without endangering people, this solar panel cleaning robot intends to preserve the effectiveness of solar energy generation. This robot has a water sprayer and a roller brush to wipe the panels’ surface off any dirt and grime.
Through an onboard tank, the sprayer receives its water supply. The rubber caterpillar tracks make it possible for this robot to stick to the slippery solar panel surface. This robot is wirelessly and remotely controlled.
With this approach, large water bodies’ water quality may be easily checked. This RC water pollution monitor boat enables the collection and online transmission of data regarding water quality.
This will aid us in keeping the water clean even more. This project has a motorized propeller system to offer forward propulsion and a servo motor arrangement to provide steering using a rudder. It is remote-operated and controlled by an RC remote with which it can be maneuvered suitably.
Four drone motors and propellers, an Arduino Pro Little F3 EVO controller, buzzer, and a lidar sensor make up the mini drone. To identify any impediments in front of it, the lidar sensor employs infrared technology.
If an obstacle is found, the controller decodes the lidar signal and activates a buzzer and light to warn the user of the closeness of the obstacle. By altering the frequency of the buzzer and leading according to proximity, the operator is continually informed of nearby objects so that the drone may be maneuvered safely without colliding.
To achieve the required flying movement, the RC controller commands are translated and used by the flight controller through the rf receiver.
A single motor is used for depth/direction control in addition to two motors for propulsion in the RC drone. To do this, propellers are affixed to both motors. This method uses a special rudderless mechanism with motor drives to control the drone’s 360-degree movement.
Ballast tanks are not used in this system to regulate buoyancy. The drone currently records underwater video using a camera. The user may connect through wifi to the floating buoy unit to see the footage when it has received the transmission. The setup uses a raspberry pi controller for wifi transmission and the transfer of video.
The caged constructions made of aluminum used by the RC boat drone are designed to fit the size of the intended fish. Sea turtles, sharks, and whales are not caught because the cages are too small. Furthermore, the mesh size is designed to capture the intended fish while releasing smaller bycatch fish that weren’t intended to be captured.
A camera attachment on the RC drone enables the operator to see fish shoals underwater. With the use of this vision, the user may direct the floating drone to go into fish shoals and catch fish as desired. To launch the cages toward fish shoals at the high speeds required to catch them, the RC drone features two propellers.
The drone has four rotating blades and uses four high-powered drone motors with propellers to give it the lift it needs. Solar panels built inside the drone’s fuselage allow for high-efficiency charging both when the aircraft is stationary and while it is in flight, extending flight periods.
The drone includes a wifi camera that can be viewed over a wifi connection on an Android smartphone. It uses an RC remote controller to accept user control commands. The onboard RC receiver of the drone is utilized to receive control commands from the operator and to drive the drone motors to accomplish the desired flying.
The technology uses six motors to hoist the pesticide/sanitizer chemical tank while flying the hexacopter drone. An RC remote control is used to control the drone and send orders over the RF spectrum to the drone controller.
An RC receiver connected to the drone controller receives orders from remote control transmitter to operate the drone. The controller controls the sprayer motors after receiving the sprayer control inputs to regulate the drone spraying. The drone’s ability to spray at medium or full range lets the operator regulate how much liquid is spread throughout the area.
The thermal camera and the night vision camera are both used by the RC-tracked robot to give dual-viewpoint viewing of the environment. This is useful for spying, detecting wildlife, and doing inspections. Metal wheels and connections are used to create the tank robot’s tracked tank movements.
The tracked system on the tank is propelled by two DC motors. A joystick-based transmitter is used by the user to send the control commands. The tank’s onboard receiver module picks up the orders. A raspberry pi controller is used by the tank to manage its functions.
The Bluetooth receiver picks up the programming commands sent by the app and transfers them to the Arduino controller. Each servo step’s movement orders are saved and recorded by the controller.
Now that the series of stages have been completed, the controller may repeatedly complete the program by executing the whole movement instruction in the proper coordination with each servo. In light of this, the system offers a clever technique for using a 360° programmable robotic arm with a smartphone-operated system.
For simple navigation, the system uses a robotic car with four-wheel drive. The robot also has a controlling box for the electronics as well as a mounting for a tablet or phone. Live video calls are held on a mobile device or tablet. The robot may be controlled by the doctor via an IOT-based panel.
The robot controller receives the control commands given online. The robot controller uses wifi internet to function. Real-time commands are sent, and the robot motors are activated to carry out the requested movement instructions. Additional features of the root include a battery status indicator that serves as a reminder to charge batteries on schedule.
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.
The drone receives flying instructions from an RF controller remote. The onboard controller continuously reads these signals using an rf receiver to regulate the drone motors accordingly.
To move air into and out of the compressed air tank, the system uses pressurized helium tank with two valves. To manage the zeppelin height, pressurized helium is pumped into the air balloon and then reverse-compressed into the tank as needed.
Pressure, temperature, humidity, wind direction, and wind speed are all monitored via onboard sensors. The sensors and a GPS sensor broadcast this information via the internet back to the user, who may log it and examine real-time figures.
The drone is equipped with a wireless camera that enables the user to take selfies from a broad range of perspectives, such as from above and in all directions, from a distance and up close, zooming films, family selfies, group selfies, and more. So, we start with a drone frame to construct this system.
The frame has three sides so that we may attach three arms to it. A BLDC high torque motor and propeller are mounted on each arm. The user may see the recorded video and use his or her Android phone to take images and films using the drone camera. Thus, the idea enables a remotely operated, completely automated selfie drone tricopter.
The drone receives input from two remote controllers; one remote controls the drone’s motions, and the second remote controls the action camera’s movements. Filmmakers now can record professional footage with an affordable camera setup thanks to the ability to capture high-quality video footage from a range of video angles.
We utilize a drone with a remote-controlled transmitter for this. The drone receiver receives the movement orders that are transmitted by the transmitter. To make the necessary movement, the controller receives them from the receiver.
To fly the drone steadily, this system combines 4 drone motors with a drone frame under the supervision of a flight controller. Drone control instructions are sent to the drone via a long-range remote and receiver pair.
Additionally, the drone has a tiny drone camera that allows the user to see real-time video. A three-arm gripper construction is being used with an Atmega-based circuitry to retain the ball. When a trigger is pulled, a servo motor is activated, releasing a gripper arm and dumping the ball into the flames.
This drone combines a video camera and a thermal camera to capture images of close-up solar panels, electrical towers, and thermal scans. A controller is used by the drone to regulate flight and provide long-range control.
To broadcast and receive control orders from the user’s RC remote, it uses an RF transmitter and receiver frequency. The thermal sensor, which has limited resolution, can be used to detect thermal heating problems near items. Raspberry Pi is used to record the thermal sensor video for subsequent viewing. The process of heat screening is therefore automated, and safety is increased.
To find infractions, the robotic moves along the line while using IR sensors. The robot now has an ultrasonic obstacle-detection sensor to help it identify impediments in its path. Another ultrasonic sensor is used by the robotic vehicle to measure the separation between two people standing in a line.
Additionally, it notifies the higher authorities/head office of these offenses and transmits a camera image through IoT utilizing wifi to provide them with documentation so immediate disciplinary action may be performed. This technique enables lines to automatically maintain social distance to stop the virus from spreading.
To verify that the entire robot functions, a raspberry pi board was used in the creation of the robot. A 4-wheel drive and an RF remote are used to remotely operate the robot. This anti-theft device removes the possibility of any robot thefts and guarantees delivery that is human-like.
The robot also has an ultrasonic sensor to prevent collisions with humans or objects. To help the robot navigate, the control team uses a remote camera to monitor the robot’s direction. A speaker on the robot allows it to converse with customers and emits a sound when it approaches a door. Along with a siren system, the speaker is also used to create noise in the event of a theft attempt.
For simple navigation and control, this specifically built drone uses a controller-based circuit system in conjunction with 4x High RPM quadcopter motors. To assure long-range flight, use RC control and an FP camera with transmitter for live video transmission. A speech receiver and loudspeaker for drone-based remote warning/reprimanding offenders.
The drone may be used to remotely sound warnings through loudspeakers and check for Covid 19 limit breaches. This will make it simpler for drones to monitor and police wide regions and lengthy roadways.
The second pressure vessel’s oxygen-rich air is then regularly pushed through to the patient or supplied to the ventilator as needed. Together, the pressure sensors and valves provide 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 smooth operation. To help patients in the COVID pandemic and other emergency scenarios, an oxygen concentrator generator was successfully constructed.
This technology uses a sensitive pressure sensor and a blood oxygen sensor to track the patient’s vital signs and show them on a small screen. Additionally, the system is equipped with an emergency buzzer alert that will sound a warning once an abnormality is found.
To accomplish the intended outcomes and to help patients in the COVID pandemic and other emergency scenarios, the complete system is controlled by an Arduino board.
This project’s main goal is to survey a big region from a single location without the need for a safety officer to personally watch it. A camera and sidelights will be added to the drone so that it can be seen in the dark.
Additionally, the drone would have floatable material attached to its legs, enabling it to float on water and perform takeoffs and landings from and into bodies of water. This might also aid in preventing robberies, and the military could use it to keep an eye on hostile areas that would be difficult to physically inspect due to tough terrain or other factors.
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