Difference between revisions of "Cordova"
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Revision as of 15:40, 28 July 2010
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Creator: |
Contents
[hide]Overview
Cordova is the current code name for a two person quadrotorcraft with an estimated lifting capacity of 500lbs. This should be enough power for two people plus some stuff. There will be four rotors, one on each corner of the craft. The seats will be back to back so the two passengers can see everything around them. The rotors will be powered by electric motors, but there will be a diesel generator to provide power to the motors and a backup battery for emergency landings and to maintain flight control in the event of power loss. The choice of diesel is mostly because of energy density when compared to batteries. We don't plan to fly this very high.
Flight Equations
Motors: The cross shape is aligned along the pitch and roll axes. Motors are M1 through M4 with M1 at the front of the aircraft and M2, M3, and M4 arranged clockwise from the front. M1 and M3 spin clockwise while M2 and M4 spin counter clockwise.
Controls consist of a joystick comprising the X and Y input variables. A throttle comprises the Z input variable. A left/right joystick component comprises the yaw input component W. W, X, and Y need modification on input to scale from 0-255 to -128-127.
M1 = Z - W + Y
M2 = Z + W + X
M3 = Z - W - Y
M4 = Z + W - X
Proof of Concept
The PoC will be created using standard model aircraft speed controllers, motors, and propellers. It will be battery powered and have a IMU for stabilization.
Parts Required
- 2 matched blade pairs
- $4.95 for 8" blade pairs
- $6.95 for 10" blade pairs
- $7.95 for 12" blade pairs
- 4 rc airplane motors
- $7.88 for 3800rpm/V motor
- 4 rc airplane speed controllers
- $16.00 for 40A speed controller
- frame material (balsa?)
- LiPo batteries
- atmel/arduino for channel mixing and motor control
- flight control system
- standard 4-6 channel remote
- something more microprocessor friendly (xbee?) need a good range
Stage 1 - Basic Flight
exclusively remote control, direct control input, mixing of controls based on equations above in the microprocessor
Stage 2 - Assisted Manual Flight
Add a gyro
The atmel will take in raw input channels and mix them according to the equations above like before, but will correct pitch, roll, and overall thrust based on gyro data.
Stage 3 - Automated Stabilization, Hover, and Movement
Legalese
How high can we go without telling anyone what we're doing? Do we have to file flight plans?
