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| == Hardware == | | == Hardware == |
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− | == Drone software ==
| + | Build on a hand-wired PCB as a prototype |
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− | There are two versions of the drone firmware, one for the motor test (mostly performance of a single motor) without the need of the prop-sheld and a full version to be used on the flying drone.
| + | [[Drone control hardware]] |
| + | <!-- [[File:schematic_rev0.png | 150px]] --> |
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− | To get the source code - see section "software and files" below.
| + | == Drone software == |
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− | === Motortes firmware ===
| + | [[Drone firmware]] |
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− | The motor test firmware is in the "motortest" directory.
| + | == Magnetometer calibration == |
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− | To compile the source for a Teensy 3.5 or 3.6 the Teensiduino needs to be installed first.
| + | Calibration is used using a calibration version of firmware and a calibration app from Prop Shield manufacturer. |
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− | Install Teensiduino, see https://www.pjrc.com/teensy/td_download.html .
| + | [[Drone compass calibration]] |
− | Start with installing the most recent supported version of Arduino, then overlay this by installing the Teensiduino.
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− | Once installed the directory needs to be prepared for compilation.
| + | == ESC calibration == |
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− | ====Linux====
| + | The drone control uses ESC pulse width from 1 to 2 ms, and all ESCs should be calibrated to use this range. |
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− | make shortcut links to libraries and compiler. The shourtcut described below assumes you have installed arduino version 1.8.9 (and Teensiduino) in your home directory, change as appropriate:
| + | [[ESC calibration]] |
− | | + | |
− | cd drone_ctrl/motortest
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− | ln -s ~/arduino-1.8.9/hardware/teensy/avr/libraries
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− | ln -s ~/arduino-1.8.9/hardware/teensy/avr/cores/teensy3
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− | ln -s ~/arduino-1.8.9/hardware/tools/
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− | ln -s tools/teensy
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− | | + | |
− | The last link is just to start the firmware upload app. make upload will work too.
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− | | + | |
− | The ma
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− | | + | |
− | ====Using arduino API====
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− | | + | |
− | If you prefer to use the Arduino programming interface, a few changes are needed
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− | | + | |
− | === Drone firmware ===
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− | | + | |
− | This is not ready yet.
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| == Propeller - motor performance == | | == Propeller - motor performance == |
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− | Measured with the app below, using the motor 3508-700KV Turnigy Multistar 14 Pole Brushless and a 14x5.5 carbon propeller.
| + | [[Drone motor performance]] |
− | The ESC is a Hobby-wing x-rotor 40A controller.
| + | [[File:3508-700-14x5.5-11v.png | 150px]] |
− | | + | |
− | === Time responce ===
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− | | + | |
− | [[File:3508-700-14x5.5-11v.png | 600px]] | + | |
− | | + | |
− | With 11 V supply (3 lipo cells).
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− | From 1.1ms to the ESC (idle) to 1.9ms almost full throttle. The ESC update frequency is 400 Hz.
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− | | + | |
− | [[File:3508-700-14x5.5-15v.png | 600px]] | + | |
− | | + | |
− | With 11 V supply (4 lipo cells). note that 30 amps is not sustainable, the motor gets hot fast.
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− | | + | |
− | === Trust 3508-700 14x5.5 ===
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− | | + | |
− | Transfer gain measurement from ESC pulse width to trust.
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− | The Hobby Wing controller is calibrated to 1ms=off, 2ms=full power.
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− | | + | |
− | [[File:trust-3508-700_14x5.5.png | 600px]]
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− | | + | |
− | Normal size propeller (14x5.5) for the motor. The translation for ESC pulse to trust is almost linear.
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− | The thrust increases with the square of the rotation speed, but drag increases with power 3 of the rotation speed, so the end result is almost linear.
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− | The maximum thrust is about 1kg (10N).
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− | | + | |
− | Data for the graph above is
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− | % Measurement from esc,motor,propeller test
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− | % file created 2020-10-04 17:49:57.982360
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− | % 1: esc value (motor 1) 0=1ms, 1024 = 2ms
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− | % 2: rps (motor 1) a rotations per second)
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− | % 3: rps (motor 1) b rotations per second)
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− | % 4: Motor voltage (volt)
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− | % 5: total current (amps)
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− | % 6: thrust force (gram force)
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− | % 7: CCV (rotation direction)
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− | % 8: Temperature motor (deg C)
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− | % 9: Temperature ESC (deg C)
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− | 100 8.27 8.27 11.3 0.1 10 0 38.8 33.3
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− | 200 18.89 18.91 11.3 0.4 54 0 28.8 27.9
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− | 250 24.78 24.78 11.3 0.7 92 0 27.2 28.0
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− | 300 30.11 30.16 11.3 1.2 136 0 27.8 27.6
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− | 350 35.65 35.65 11.1 1.7 192 0 27.2 28.2
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− | 400 40.33 40.54 11.2 2.5 246 0 26.3 28.7
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− | 450 44.49 44.47 11.3 3.6 300 0 27.4 28.4
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− | 500 49.34 49.33 11.3 4.5 371 0 26.8 28.5
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− | 550 54.00 54.01 11.4 5.8 440 0 27.9 29.2
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− | 600 58.11 58.07 11.2 7.2 523 0 27.0 29.3
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− | 650 61.94 61.71 11.0 9.0 600 0 27.0 30.0
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− | 700 65.24 65.20 11.0 10.3 660 0 27.6 29.8
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− | 750 68.22 68.67 11.2 12.5 730 0 29.2 30.6
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− | 800 71.01 71.14 11.3 14.4 806 0 31.7 30.3
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− | 850 73.87 73.89 11.5 16.7 870 0 32.1 29.1
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− | 900 76.76 76.62 10.8 18.7 930 0 33.0 31.3
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− | | + | |
− | === Trust 3508-700 18x5.5 ===
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− | | + | |
− | [[File:trust-3508-700_18x5.5.png | 600px]]
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− | | + | |
− | Oversize propeller (18x5.5). The translation for ESC pulse to thrust is almost linear here, with lower RPM and higher motor current.
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− | | + | |
− | Data for the graph above with 18" propeller is
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− | % Measurement from esc,motor,propeller test
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− | % file created 2020-10-04 17:40:42.147504
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− | % 1: esc value (motor 1) 0=1ms, 1024 = 2ms
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− | % 2: rps (motor 1) a rotations per second)
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− | % 3: rps (motor 1) b rotations per second)
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− | % 4: Motor voltage (volt)
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− | % 5: total current (amps)
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− | % 6: thrust force (gram force)
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− | % 7: CCV (rotation direction)
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− | % 8: Temperature motor (deg C)
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− | % 9: Temperature ESC (deg C)
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− | 100 5.95 5.95 11.3 0.2 12 0 24.7 28.3
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− | 200 16.19 16.18 11.2 0.8 112 0 24.7 28.2
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− | 300 24.77 24.76 11.2 2.2 270 0 24.7 28.8
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− | 400 31.39 31.42 11.0 4.7 440 0 23.9 29.5
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− | 500 36.94 36.98 11.2 9.0 640 0 25.1 30.0
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− | 550 38.70 38.70 11.3 10.5 700 0 25.8 31.4
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− | 600 40.72 40.56 11.0 12.5 770 0 28.4 32.4
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− | 650 41.95 42.14 10.7 14.6 840 0 29.1 35.4
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− | 700 43.73 43.73 11.1 18.5 890 0 33.1 37.1
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− | 750 44.79 44.83 10.8 20.2 960 0 35.0 37.9
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− | 800 45.53 45.56 11.8 22.3 1000 0 39.6 39.0
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− | | + | |
− | === Software and files ===
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− | | + | |
− | The files for these results is in our subversion repository:
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− | | + | |
− | Install subversion - https://subversion.apache.org/packages.html - and from a command line
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− | | + | |
− | svn checkout svn://repos.gbar.dtu.dk/jcan/mobotware/drone_ctrl
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− | cd drone_ctrl/trunk/motortest_gui
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− | ls
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− | - motortest_gui.py is the application below.
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− | - plot_rpm_sensor.m is the Matlab script to make the plots above.
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− | ... other support and data files.
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− | cd drone_ctrl/trunk/doc/Matlab
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− | - Simulink version of hexacopter drone
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| == Motor test app == | | == Motor test app == |
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− | [[File:motortest_gui.png | 600px]] | + | [[Drone motor test app]] |
− | | + | [[File:motortest_gui.png | 120px]] |
− | == MATLAB simulation ==
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− | | + | |
− | [[File:drone_ctrl_simulink.png | 800px]] | + | |
− | | + | |
− | Simulink model of hexacopter.
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− | [[File:drone_ctrl_sim_hex.png | 600px]]
| + | ==Matlab simulation== |
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− | Sim mechanics simulated hex-drone hoovering.
| + | [[Drone MATLAB simulation]] |
| + | [[File:drone_ctrl_sim_hex.png | 120px]] |
This project is intended to be a rather simple core drone stabilizer application based on Teensy and the prop shield.
Intended to be expanded with an outer control loop with a non-realtime sensor, e.g. GNSS, camera or laser scanner.
Calibration is used using a calibration version of firmware and a calibration app from Prop Shield manufacturer.
The drone control uses ESC pulse width from 1 to 2 ms, and all ESCs should be calibrated to use this range.