Forwarded from Fireworks Daily Team 2.0 (Stella)
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✨💫Good Night Doomsday💫✨
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Standby for Drone Engineering (UAV Systems Design & Operation) ✈️
Click the link and scroll down ⬇️
https://t.me/AzazelNews/977395
Click the link and scroll down ⬇️
https://t.me/AzazelNews/977395
🔥3❤1
Forwarded from Mythic
This class focuses on how drones actually work at a systems level — including electronics, control, power, and real-world applications. This is critical for surveillance, mapping, logistics, and infrastructure support in any advanced or rebuild scenario.
Forwarded from Mythic
What Is a Drone (UAV)?
A drone (Unmanned Aerial Vehicle) is a system made of:
• propulsion (motors + propellers)
• control systems (flight controller)
• sensors (orientation, GPS, cameras)
• communication systems
• power system
Modern drones are essentially flying computers with real-time control systems.
A drone (Unmanned Aerial Vehicle) is a system made of:
• propulsion (motors + propellers)
• control systems (flight controller)
• sensors (orientation, GPS, cameras)
• communication systems
• power system
Modern drones are essentially flying computers with real-time control systems.
Forwarded from Mythic
Flight Control System (The “Brain”)
Core Electronics
• microcontroller / embedded processor
• IMU (Inertial Measurement Unit)
• gyroscope + accelerometer
• sometimes magnetometer
What It Does
• stabilizes the drone in real time
• adjusts motor speeds continuously
• processes sensor data hundreds of times per second
Core Electronics
• microcontroller / embedded processor
• IMU (Inertial Measurement Unit)
• gyroscope + accelerometer
• sometimes magnetometer
What It Does
• stabilizes the drone in real time
• adjusts motor speeds continuously
• processes sensor data hundreds of times per second
Forwarded from Mythic
Propulsion System
Components
• brushless DC motors (BLDC)
• propellers
• Electronic Speed Controllers (ESCs)
How It Works
• ESCs convert battery power into controlled signals
• motors spin at different speeds
• thrust is adjusted to control movement
⸻
Motor Control Electronics
• MOSFET switching circuits
• PWM (Pulse Width Modulation) signals
• high-frequency switching controllers
Components
• brushless DC motors (BLDC)
• propellers
• Electronic Speed Controllers (ESCs)
How It Works
• ESCs convert battery power into controlled signals
• motors spin at different speeds
• thrust is adjusted to control movement
⸻
Motor Control Electronics
• MOSFET switching circuits
• PWM (Pulse Width Modulation) signals
• high-frequency switching controllers
Forwarded from Mythic
Power System
Typical Power Sources
• lithium-polymer (LiPo) batteries
• lithium-ion packs
Supporting Electronics
• Battery Management System (BMS)
• voltage regulators
• power distribution board (PDB)
Typical Power Sources
• lithium-polymer (LiPo) batteries
• lithium-ion packs
Supporting Electronics
• Battery Management System (BMS)
• voltage regulators
• power distribution board (PDB)
Forwarded from Mythic
Navigation & Sensors
Core Sensors
• GPS module
• barometer (altitude)
• IMU (orientation)
• optical flow sensors
• LiDAR (advanced systems)
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What They Enable
• position hold
• autonomous flight
• obstacle avoidance
• terrain mapping
Core Sensors
• GPS module
• barometer (altitude)
• IMU (orientation)
• optical flow sensors
• LiDAR (advanced systems)
⸻
What They Enable
• position hold
• autonomous flight
• obstacle avoidance
• terrain mapping
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Forwarded from Mythic
Communication Systems
Types
• radio control (RC link)
• telemetry systems
• video transmission (FPV)
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Electronics Involved
• RF transmitters/receivers
• antennas
• signal processors
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Frequencies Commonly Used
• 2.4 GHz (control)
• 5.8 GHz (video)
Types
• radio control (RC link)
• telemetry systems
• video transmission (FPV)
⸻
Electronics Involved
• RF transmitters/receivers
• antennas
• signal processors
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Frequencies Commonly Used
• 2.4 GHz (control)
• 5.8 GHz (video)
Forwarded from Mythic
Payload Systems
Drones often carry additional systems:
• cameras
• thermal sensors
• mapping equipment
• delivery payloads
Payloads require:
• stabilized mounts (gimbals)
• dedicated power circuits
• data transmission systems
Drones often carry additional systems:
• cameras
• thermal sensors
• mapping equipment
• delivery payloads
Payloads require:
• stabilized mounts (gimbals)
• dedicated power circuits
• data transmission systems
Forwarded from Mythic
Multirotor (Most Common)
• quadcopters (4 motors)
• hexacopters (6 motors)
Pros:
• stable
• easy to control
Cons:
• limited flight time
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Fixed-Wing Drones
• airplane-style
Pros:
• long range
• energy efficient
Cons:
• need space to launch/land
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Hybrid VTOL (Vertical Takeoff + Fixed Wing)
• combine both systems
Used in advanced mapping and military drones.
• quadcopters (4 motors)
• hexacopters (6 motors)
Pros:
• stable
• easy to control
Cons:
• limited flight time
⸻
Fixed-Wing Drones
• airplane-style
Pros:
• long range
• energy efficient
Cons:
• need space to launch/land
⸻
Hybrid VTOL (Vertical Takeoff + Fixed Wing)
• combine both systems
Used in advanced mapping and military drones.
Forwarded from Mythic
Autonomous Navigation
Using:
• onboard AI
• GPS waypoints
• real-time obstacle avoidance
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Swarm Technology
Multiple drones coordinated together.
Used in:
• mapping
• agriculture
• research
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Counter-Drone Systems
Drones are also part of defense systems.
They can be:
• detected
• jammed
• disabled
⸻
🤖 Relation to Directed Energy Systems
Drone defense often uses:
• microwave systems (disable electronics)
• laser systems (physical damage)
• electronic warfare (signal jamming)
Using:
• onboard AI
• GPS waypoints
• real-time obstacle avoidance
⸻
Swarm Technology
Multiple drones coordinated together.
Used in:
• mapping
• agriculture
• research
⸻
Counter-Drone Systems
Drones are also part of defense systems.
They can be:
• detected
• jammed
• disabled
⸻
🤖 Relation to Directed Energy Systems
Drone defense often uses:
• microwave systems (disable electronics)
• laser systems (physical damage)
• electronic warfare (signal jamming)
Forwarded from Mythic
Energy Constraints
Drone capability is limited by:
• battery energy density
• motor efficiency
• payload weight
This is why drones typically have:
• 20–60 minute flight times
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🌐 Real-World Applications
Drones are used by organizations like:
• NASA
• DJI (commercial drones)
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Major Uses
• aerial mapping
• surveillance
• search and rescue
• infrastructure inspection
• delivery systems
Drone capability is limited by:
• battery energy density
• motor efficiency
• payload weight
This is why drones typically have:
• 20–60 minute flight times
⸻
🌐 Real-World Applications
Drones are used by organizations like:
• NASA
• DJI (commercial drones)
⸻
Major Uses
• aerial mapping
• surveillance
• search and rescue
• infrastructure inspection
• delivery systems
Forwarded from Mythic
Engineering Fields Involved
Drone engineering combines:
• electrical engineering
• control systems engineering
• aerodynamics
• embedded systems
• RF communications
• software engineering
Drone engineering combines:
• electrical engineering
• control systems engineering
• aerodynamics
• embedded systems
• RF communications
• software engineering
Forwarded from Mythic
Capabilities
• manual control (RC)
• basic stabilization
• short-range flight
• visual observation
Core Tech
• flight controllers (ArduPilot / PX4 Autopilot)
• ESCs + brushless motors
• LiPo batteries
• radio transmitters
Use Cases
• scouting
• perimeter checks
• basic mapping
• manual control (RC)
• basic stabilization
• short-range flight
• visual observation
Core Tech
• flight controllers (ArduPilot / PX4 Autopilot)
• ESCs + brushless motors
• LiPo batteries
• radio transmitters
Use Cases
• scouting
• perimeter checks
• basic mapping