FPV
Flying electronic RC planes from the ground is fun. Piloting a FPV plane from First Person View is really cool. With the arrival of light and powerful video stream transmitters and long range remote RC transmitter modules , the range of flight has increased from line-of-sight to an order-of-magnitude wider.
Research
To build a reliable platform I want to begin with the fundamental basics and then extrapolate more specific products.
Electronics
- Lower frequency will allow greater range, longer wavelength requires larger antenna
- Higher frequencies, 2.4GHz or 5.8GHz, will quickly get attenuated by the atmosphere
- One energy-source, single set of batteries for motor, camera, OSD, VTx, Rx, servos
- Minimized weight, as batteries contribute as the heaviest component
- Receiver antenna diversity for maximum flexibility of the airplane, each antenna 90 degrees perpendicular
- Omni-directional antennas will have a radiation pattern much like a form of a doughnut, with dead-spots center, above and below
- Same radiation polarization on ground station and airplane where possible, alternatively circular polarized ground antenna
- Signal quality of same polarized electric fields can be many tens of dB different [1]
- Parallel 3S 11.1V Lithium-ion Polymer batteries, both on plane and ground station
- Prevents voltage drop if one cell is bad, might add reverse current protection (diode) to avoid 3S "charging" the then 2S battery
- Power- and signal-wiring separated as much as possible
- Noise from motor can degrade digital signals if coupled with signal-wires
- Shielded components, twisted wires, ferrite rings, and condensators will eliminate most noise and oscillation, PCB ground plate facing interference source
- Minimize both ambient noise and interference from nearby components, think of a long wire as an antenna that will pick up anything
- Video-transmitter on a higher frequency band than RC-transmitter, 1.3GHz VTx and 433MHz RCTx, 2.4GHz VTx and 433MHz RCTx
- Having the same frequency/band on VTx and RCRx will cause signal degradation
- Video-transmitter, as well as RC-receiver, powered by 5V voltage from main Lipo-batteries via BEC
- When the main engine batteries are drained or the ESC unexpectedly shut down, a separate BEC will continue to power the rest of the 5V system
- Split aileron servo signal to use twin ailron servos for each wing
- Prevent loss of control on servo failure, must be mounted close together to drive force-drive the dead servo, might drop this
- Proper cooling of video-transmitter using an appropriate heat-sink and thermal-adhesive
- Powerful video transmitter dissipate a lot of power in form of heat, prevent signal loss
Plane
- A wing for speed and stability
- Makes it possible to fly in windy condition and greater distances, less drag
- Batteries in front and electronics behind the batteries, suitable motor to create enough lift
- Front heavy for stable dives when motor is inactive and in up- or down-drift
- Find the center of gravity by temporarily putting everything where they're supposed to go
- Makes it easier to find where the sparing bars between the wings will go and position of the motor mount, leave the battery location to last for fine tuning CG
- Motor mount on or close to the center of gravity
- Easier to handle during acceleration and less wobbly when the force is pushing the center instead of the back end, imagine a horizontal axis over the wings as center of gravity
- Keep the servos, transmitters, and battery packs as near the center as possible
- Makes the flight more stable in windy conditions, instead of wobbling back and forth because of inertia
- Antenna for VTx mounted at the end and center of the left-wing, while the two RC-receiver antennas on the other right-wing, shifted 90 degree
- Minimize interference between the two radio systems, 90 degree angled to allow cross-polarization, both vertical and horizontal for better signal quality at different plane orientations
- Servo location as far forward as possible to put center of gravity back
- Push-rods on an angle does not affect the elevator action, might put but more pressure on the servo [2]
Gear
Use this as a guide to ballpark what is needed and then just pick whatever falls inside your needs and specifications.
Video system
Cameras
Preferred voltage is 5V to avoid boost/step-up converters and switching noise isolation.
Recording:
- GoPro HD Hero - High-definition on-board recording
- Contour HD - Another HD on-board recorder
Flying:
- Pixim PX540 - Resolution 540 lines, lower 1/3 brighter, 22 grams, 10-12V [3]
- DX201 DPS camera - 540 lines, excellent image quality, based on same Pixim sensor as above, 12V [4] [5] [6]
- Fatshark RCV922 camera - Resolution 420 lines, lower 1/3 brighter, unsaturated colors, 30 grams, 3.3-5V [7]
- Black Widow KX131 - 380 horizontal lines of resolution, nice colors, value, 23 grams, 5V [8] [9]
- FPVCAM-480 OSD - Resolution 480 lines, 12V [10]
- Sony SN555/VSN700 camera - 555 lines resolution, 12V
- DPC-161 - Cheap, resolution 380 lines, 5V [11]
- Sony SN777 - 555 lines resolution, 12V, RF noisy [12]
- KX-171 - 5V, too dark in sunlight [13]
Transmitters
Preferably use 2.4GHz band as it's safer, won't interfere with other, no high powered devices on band, 900MHz overpowered by mobile phones, 1.2GHz aviation communication [14]
- Lawmate 500mW 2.4GHz Tx - 5-5.5V, 10 grams, use ch5 2370MHz and ch8 2510MHz, outside regular band, noise-free [15] [16]
- IntelligentFlight GP-707 2.4GHz 10mW micro audio/video transmitter - 1.6 grams, comes with receiver [17] [18] [19]
- Sunsky 1.2GHz 400mW [20] [21]
- Sunsky 1.2GHz 800mW [22]
- BEV 1.3Ghz 800mW transmitter, 12V [23]
- Immersion RC 600mW 5.8GHz A/V transmitter - Built-in 5V regulator for camera, 6-16V
Receivers
- Lawmate 2.4GHz Portable receiver - 8 Channels, 5V DC in, small [24] [25] on-board battery [26] [27]
- RangeVideo 1.3GHz Deluxe receiver - RSSI 0-5V output
- EagleEyes FPV Station - Receiver with antenna diversity, antenna tracking
- Immersion RC Duo2400 diversity receiver
- Immersion RC Duo5800 diversity receiver
Diversity Controller
- Oracle Video Diversity Controller - Monitors video signal from two receivers (with different antennas), picks the better, opposite of RSSI-based selection [28] [29]
Antennas
A 14 dBi patch antenna has a narrower radiation beam than a 8 dBi patch antenna. A focused 14 dBi yagi for a focus beam in one direction.
- Active Robots 433 MHz 1/4 wavelength straight and angled - On the plane
- Maker your own Sander-style omni-directional SMA antenna - Lighter than any purchased item, can be tuned to exact wavelength of frequency
On-Screen Display
- ImmersionRC EzOSD - Uncluttered display, GPS on-board, signal strength indicator via I2C, current/voltage sensor with Deans
- Eagle Tree OSD Pro
- DOSD
Goggles
- Fatshark RCV922 V2 Base Edition - 640x480, only the bare minimum video and power inputs required, FPV ground station friendly, 6-12V
- HeadPlay Googles - 800x600 resolution, requires exactly 12V
- Fatshark RCV230T/922T Teleporter - All-in-one, limited 320x240 resolution and range [30]
- Fatshard RCV922 Aviator - Video input, 640x480 resolution, Vin 6-12V [31]
Misc
- Immersion RC PowerBox - Groundstation video and power filtering box
- Archos 604 - Video recorder [32]
- Pinnacle Video Transfer - Video recorder [33]
Control system
Radios
The 35/72MHz radio will not be used, the PPM signal is feed to the long range transmitters.
Transmitters
Connects to any PPM radio via trainer-port.
- ImmersionRC EzUHF transmitter - 433 MHz frequency band, 200mW or 600mW power-mode, 9-12V prototype model
- Dragon Link transmitter - Transmits at 433MHz, 500mW [36]
- Thomas Scherrer OZ2CPU UHF system - Many hardware revisions, hard to keep track
Receivers
- ImmersionRC EzUHF receiver - 8-channel receiver, signal diversity, 50A current-sensor, 10 Hz GPS
- Dragon Link receiver
- Futaba R149DP 72 MHz [37]
- Corona RP8D1 35 MHz, 4 meter antenna [38] [39] [40] [41]
- Corona RP6D1 35 MHz [42] [43]
Other
- ImmersionRC EzAntennaTracker - Uses GPS-coordinates from EzOSD inserted in the right audio channel
Plane
Airplanes
- Ritewing Zephyr - Foam wing base, glass fiber rods, and winglets [44] [45]
- Multiplex Easystar - Simple glider-plane [46]
- ParkZone Radian PNP - Glider, prop in front, huge easy to spot [47]
- EasyStar - Cross between glider and sport plane, 3-channel, easy to modify [48]
Motor
- Hacker A30-10L V2 [49]
- Turnigy 35-36B 1300Kv Outrunner [50] - Great for Maxi Swift [51]
- Turnigy AerodriveXp SK Series 35-36 1400Kv 550w [52] [53]
ESC
- Hacker X-55 SB Pro Brushless Motor Speed Controller ESC 55A
- Turnigy Plush 60A ESC [54] - Great for 4S
- Turnigy Plush 40A Speed Controller [55] - Great for 3S
Blades
- Turnigy 10x6 folding blades
- Aeronaut CAM foldering carbon propellers
- Aeronaut CAMcarbon Power-Prop 10"x7
- TGS 10x6F Precision Folding propeller [56] [57]
- Aeronaut CAMcarbon 9"x7 folding prop blades [58]
Spinner
Servos
- Hitec HS-645MG [59]
- Gaupner Servo DES 708 BB MG [60]
- Turnigy 380MAX Micro Servo [61]
- Blue Bird BMS-661DMG+HS Super Fast Digital Servo (MG) 6.4kg .08sec 46.5g [62] [63]
Batteries
- Turnigy S3 2200 mAh
- Zippy S3 2200 mAH - Cheap Hobbyking packs
- Flightmax S3 2200 mAh [64]
Charger
- Bantam BC-6 - Korean, high quality
Materials
- Laminate - Apply to foam wing to give it a outer strength and cover for paint
- Riteweave - Flass fiber mesh to add strength over open cuts in the foam [65]
Glue
- 3M 90 adhesive - Spray adhesive for base to add laminate
- Zap-a-Gap CA glue - For sparing bars in wings, or Gorilla glue
- Gorilla glue brown - Glue for wing and sparing bars, activates by adding water
- Goop - Fasten winglets
- Epoxy adhesive - Properly fasten the motor mount plate to the surrounding foam
Tape
- 3M Mailing & Storage tape - Mount elevons to the airframe, 1/3 on the elevon, UV resistant [66]
Shops
- readymaderc.com - Offer a range of products from the main FPV manufacturers
- nghobbies.com - FPV gear
- rangevideo.com - FPV gear
- hobbyking.com - All-around-supplier of batteries, servos, motors, cables, wires, rods
- hobbywireless.com - Everything cameras and transmitters
- der-schweighofer.at - Austrian shop