Commonality Evaluation and Prediction Study of Light and Small Multi-Rotor UAVs
Abstract
:1. Introduction
2. Commonality Quantification Method
3. Light and Small Multi-Rotor UAV Commonality Evaluation Model
3.1. Light and Small Multi-Rotor UAV Product Breakdown Structure
3.2. UAV Design Structure Matrix
3.3. UAV Commonality Evaluation Indexes
3.4. UAV Commonality Calculation
3.5. Case Calculation
4. The Prediction Model Based on Convolutional Neural Networks for the Commonality of Light and Small Multi-Rotor UAVs
4.1. Data Collection and Cleaning
4.2. Constructing the Dataset
4.3. Convolutional Neural Network Model Building
4.4. Experimental Results and Analysis
4.5. Test Cases
5. Summary and Outlook
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
Nomenclature
X, Y | data of a set of comparison samples |
Minkowski distance | |
maximum possible Minkowski distance between X and Y | |
Cosine similarity | |
value of commonality evaluation | |
DSM | design structure matrix |
comprehensive connection strength of the DSM cell (i, j) | |
spatial connection strength of the DSM cell (i, j) | |
energy connection strength of the DSM cell (i, j) | |
information connection strength of the DSM cell (i, j) | |
material connection strength of the DSM cell (i, j) | |
CNN | convolutional neural network |
MRE | mean relative error |
RMSE | root mean square error |
R2 | goodness of fit |
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Graduations | Representation | Meaning |
---|---|---|
3 | High | High connection strength |
2 | Medium | Medium connection strength |
1 | Low | Low connection strength |
0 | None | No connection |
Level 1 Indexes | Level 2 Indexes | Evaluation of Characteristic Variables | |
---|---|---|---|
The commonality of UAV performance parameters | Weight | Body weight (g) | |
Maximum load weight (g) | |||
Speed | Ascent speed | Maximum ascent speed in sports gear (m/s) | |
Maximum ascent speed in normal gear (m/s) | |||
Maximum ascent speed in smooth gear (m/s) | |||
Descent rate | Maximum descent speed in sports gear (m/s) | ||
Maximum descent speed in normal gear (m/s) | |||
Maximum descent speed in smooth gear (m/s) | |||
Horizontal flight speed | Maximum horizontal flight speed in sports gear (m/s) | ||
Maximum horizontal flight speed in normal gear (m/s) | |||
Maximum horizontal flight speed in smooth gear (m/s) | |||
Tilt angle | Maximum tilt angle of sports gear (°) | ||
Maximum tilt angle of normal gear (°) | |||
Maximum tilt angle of smooth gear (°) | |||
Flight time | Maximum endurance (min) | ||
Maximum take-off altitude | Altitude (km) | ||
Wind resistance | Wind resistance class | ||
Temperature | Minimum temperature (°C) | ||
Maximum temperature (°C) |
Level 1 Indexes | Level 2 Indexes | Level 3 Indexes | Evaluation of Characteristic Variables | |
---|---|---|---|---|
The commonality of UAV structural system parameters | UAV rack system commonality | Fuselage | Length of fuselage unfolding (mm) | |
Width of fuselage unfolding (mm) | ||||
Height of fuselage unfolding (mm) | ||||
Wheelbase (mm) | ||||
Length of fuselage folding (mm) | ||||
Width of fuselage folding (mm) | ||||
Height of fuselage folding (mm) | ||||
UAV arm and landing gear | Number of arms | |||
Arm Mounting | Foldable | |||
Non-foldable | ||||
Landing gear layout | Bottom support layout | |||
Connection arm layout | ||||
Power system commonality | Battery | Battery Capacity (mAh) | ||
Voltage (V) | ||||
Energy (Wh) | ||||
Weight (g) | ||||
Charging power (W) | ||||
Motors and ESCs | Maximum ascent speed (m/s) | |||
Maximum descent speed (m/s) | ||||
Maximum horizontal flight speed (m/s) | ||||
Maximum take-off altitude (km) | ||||
Propeller | Number of propeller blades | |||
Total number of propellers | ||||
Propeller mounting position | Upward | |||
Downward | ||||
Flight control system commonality | Flight control, IUM, perception system | Perception system arrangement | Front-end Perception | |
Rear Perception | ||||
Lower Perception | ||||
Upper Perception | ||||
Lateral Perception | ||||
Hovering accuracy | Vertical direction (m) | |||
Horizontal direction (m) | ||||
Maximum tilt angle (°) | ||||
Maximum wind resistance class | ||||
Navigation and remote control systems commonality | GNSS | GPS | ||
GLONASS | ||||
Galileo | ||||
BeiDou | ||||
Navigation and remote control systems commonality | Graphical/Digital transmission/Receiver | Operating frequency | 2.4 GHz | |
5 GHz | ||||
Data interface type | Lightning | |||
Micro USB | ||||
Type-C | ||||
HDMI | ||||
Signal effective distance (km) | FCC Distance | |||
CE Distance | ||||
MIC Distance | ||||
SRRC distance | ||||
Maximum bit rate (Mbps) | ||||
Delay (ms) | ||||
Remote control | Battery capacity (mAh) | |||
Operating current (mA) | ||||
Operating voltage (V) | ||||
Mission load system commonality | Cloud terrace | Stabilization system (number of axes) | ||
Maximum control speed (°/s) | ||||
Amount of angular jitter (°) | ||||
Head structure design range (°) | Pitch angle | |||
Rolling angle | ||||
Yaw angle | ||||
Controllable rotation range (°) | Pitch angle | |||
Rolling angle | ||||
Yaw angle | ||||
Camera | Pixel size (million) | |||
Maximum video bit rate (Mb/s) | ||||
Lens angle of view (°) | ||||
Lens focal length (mm) | ||||
Lens aperture (f/X) | ||||
Maximum photo size | Long (PX) | |||
Width (PX) | ||||
Video resolution | HD | |||
FHD | ||||
2.7 K | ||||
4 K | ||||
Larger than 4 K | ||||
Mounting device | Presence of mountings | |||
No mountings |
Evaluation of Characteristic Variables | Model 1 | Model 2 | Formula 4 Calculation | Formula 6 Calculation | Commonality |
---|---|---|---|---|---|
Pixel size (million) | 2000 | 2000 | 0.998 | \ | 0.874 |
Maximum video bit rate (Mb/s) | 120 | 100 | |||
Lens angle of view (°) | 82 | 77 | |||
Lens focal length (mm) | 28.6 | 28 | |||
Lens aperture (f/X) | 11 | 11 | |||
Long | 5472 | 5472 | |||
wide | 3648 | 3648 | |||
HD | 0 | 0 | \ | 0.750 | |
FHD | 1 | 1 | |||
2.7 K | 1 | 1 | |||
4 K | 1 | 1 | |||
Larger than 4 K | 1 | 0 |
Weight | Speed | Tilt Angle | Endurance Time | Take-Off Altitude | Wind Resistance | Operating Temperature | |
---|---|---|---|---|---|---|---|
Fuselage | 3 | 1 | 1 | ||||
Arm | 2 | 1 | 1 | ||||
Landing gear | 2 | ||||||
Battery | 3 | 1 | 3 | 2 | 3 | ||
Motor | 2 | 3 | 2 | ||||
ESC | 1 | 2 | 1 | ||||
Propeller | 1 | 3 | 2 | 2 | |||
Flight Control | 1 | 2 | 3 | 3 | |||
IMU | 1 | 3 | 2 | ||||
Perception System | 1 | ||||||
GNSS | 1 | ||||||
Graphical/Digital transmission | 1 | ||||||
Receiver | 1 | ||||||
Remote Control | |||||||
Cloud Terrace | 1 | 1 | |||||
Camera | 1 | 1 | |||||
Σ | 23 | 11 | 9 | 7 | 6 | 7 | 4 |
Weights | 0.343 | 0.164 | 0.134 | 0.105 | 0.09 | 0.104 | 0.06 |
Performance Commonality (0.4) | Structural System Commonality (0.6) | ||||
---|---|---|---|---|---|
Weight (0.343) Speed (0.164) Tilt angle (0.134) Endurance time (0.105) Take-off altitude (0.09) Wind resistance (0.104) Operating temperature (0.06) | UAV rack system (0.186) | Power system (0.245) | Flight control system (0.212) | Navigation and remote control system (0.268) | Mission load system (0.088) |
Fuselage (0.614) Arm and landing gear (0.386) | Battery (0.400) Motor and ESC (0.520) Propeller (0.080) | Flight control, IUM, Perception system (1) | GNSS (0.146) Graphical/Digital transmission/Receiver (0.561) Remote control (0.293) | Cloud terrace (0.370) Camera (0.519) Mounted devices (0.013) |
UAV Brands | DJI | Autel | Hubsan | Parrot |
---|---|---|---|---|
Number of models | 16 | 3 | 3 | 2 |
General Design Features of UAV | UAV Performance Characteristics |
---|---|
Body weight Number of arms Fuselage spread length Width of fuselage spread Fuselage unfolded high Wheelbase | Maximum ascent speed Maximum descent speed Maximum horizontal flight speed Maximum tilt angle Maximum flight time Maximum takeoff altitude Wind resistance class Battery capacity Longest data transmission distance Camera pixels |
Layer | Type | Parameters | Neurons | Output |
---|---|---|---|---|
1 | Input layer | 16 × 2 × 1 | ||
2 | Convolutional layer | 2 × 2 convolution kernel | 256 | 15 × 1 × 256 |
3 | Batch normalization layer | 15 × 1 × 256 | ||
4 | Relu layer | 15 × 1 × 256 | ||
5 | Convolutional layer | 3 × 1 convolution kernel | 128 | 13 × 1 × 128 |
6 | Batch normalization layer | 13 × 1 × 128 | ||
7 | Relu layer | 13 × 1 × 128 | ||
8 | Convolutional layer | 3 × 1 convolution kernel | 128 | 11 × 1 × 128 |
9 | Batch normalization layer | 11 × 1 × 128 | ||
10 | Relu layer | 11 × 1 × 128 | ||
11 | Dropout layer | 0.2 | 11 × 1 × 128 | |
12 | Fully connected layer | 1 × 1 × 1 | ||
13 | Regression output layer | 1 × 1 × 1 |
Optimization Algorithm | Adam |
---|---|
MiniBatchSize | 100 |
MaxEpochs | 800 |
InitialLearnRate | 0.001 |
LearnRateDropFactor | 0.1 |
Shuffle | Yes |
Training Set | Test Set | |
---|---|---|
MRE | 0.0193 | 0.0322 |
RMSE | 0.0239 | 0.0271 |
R2 | 0.8535 | 0.7981 |
General Design Features | Value | UAV Performance Features | Value |
---|---|---|---|
Maximum take-off weight (g) | 1000 | Maximum ascent speed (m/s) | 9 |
Number of arms | 4 | Maximum descent speed (m/s) | 7 |
Length of fuselage unfolding (mm) | 380 | Maximum horizontal flight speed (m/s) | 25 |
Width of fuselage unfolding (mm) | 300 | Maximum tilt angle (°) | 40 |
Height of fuselage unfolding (mm) | 120 | Maximum flight time (min) | 40 |
Wheelbase (mm) | 400 | Maximum take-off altitude (km) | 6 |
Wind resistance class | 6 | ||
Battery capacity (Ah) | 4.5 | ||
Maximum transmission distance (km) | 7 | ||
Camera Pixels (millions) | 4.8 |
Target Model | Benchmark Models | Commonality (%) | Target Model | Benchmark Models | Commonality (%) |
---|---|---|---|---|---|
Novel model | DJI Mini SE | 77.7 | Novel model | DJI Inspire 1 | 75.9 |
DJI Mavic air | 76.9 | DJI M30 | 80.2 | ||
DJI Mavic 2 | 87.0 | DJI M300 | 75.7 | ||
DJI Mini 3 Pro | 79.8 | DJI M200 | 76.0 | ||
DJI Mavic 3 | 89.9 | Autel EVO ll Pro | 82.4 | ||
DJI Air 2S | 84.5 | Autel EVO ll Lite+ | 87.7 | ||
DJI Mavic Air 2 | 84.9 | Autel EVO NANO | 79.4 | ||
DJI Mini 2 | 79.4 | Habsen ACE pro | 80.9 | ||
DJI Avata | 71.1 | Habsen zinomini SE | 78.5 | ||
DJI FPV | 79.0 | Habsen zinomini pro | 78.0 | ||
DJI Phantom 4 Pro | 83.2 | parrot ANAFI Ai | 80.1 | ||
DJI Inspire 2 | 76.9 | parrot ANAFI-USA | 78.0 |
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Zhang, Y.; Zeng, Y.; Cao, K. Commonality Evaluation and Prediction Study of Light and Small Multi-Rotor UAVs. Drones 2023, 7, 698. https://doi.org/10.3390/drones7120698
Zhang Y, Zeng Y, Cao K. Commonality Evaluation and Prediction Study of Light and Small Multi-Rotor UAVs. Drones. 2023; 7(12):698. https://doi.org/10.3390/drones7120698
Chicago/Turabian StyleZhang, Yongjie, Yongqi Zeng, and Kang Cao. 2023. "Commonality Evaluation and Prediction Study of Light and Small Multi-Rotor UAVs" Drones 7, no. 12: 698. https://doi.org/10.3390/drones7120698
APA StyleZhang, Y., Zeng, Y., & Cao, K. (2023). Commonality Evaluation and Prediction Study of Light and Small Multi-Rotor UAVs. Drones, 7(12), 698. https://doi.org/10.3390/drones7120698