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An Interactive Modeling, Simulation, Animation, and Real-Time Control (MoSART) Twin-Lift Helicopter System Environment. Chen-I Lim Richard P. Metzger,Jr. Armando A. Rodriguez. American Control Conference June 3 rd 1999 Hyatt Regency, San Diego, CA.
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An Interactive Modeling, Simulation, Animation, and Real-Time Control (MoSART) Twin-Lift Helicopter System Environment Chen-I Lim Richard P. Metzger,Jr. Armando A. Rodriguez American Control Conference June 3rd 1999 Hyatt Regency, San Diego, CA Ack : White House , NSF, WAESO/CIMD, Boeing, Intel, Microsoft, CADSI, Knowledge Revolution, MathWorks, Lego, Xilinx, Honeywell, National Instruments, Integrated Systems, ASU CIEE. http://www.eas.asu.edu/~aar/research/mosart/Presentations
New Technologies • Affordable High Performance Computing • Hi-fidelity Simulation Capability • Simulink / MATLAB, etc… • Visual C++ • PC Animation Creation / Manipulation Technologies • 3D Modeling Software (e.g. 3D Studio, RPM D3D toolbox, etc.) • Microsoft DirectX (provides: 3D-animation, sound, video, user-input, etc.) • Object Oriented Programming (OOP) Framework • ActiveX / OLE
Key Environment Features • Accelerated-time simulation • Alter model/controller: • structure • parameters (on-the-fly) • Advanced visualization: • real-time graphics • visual indicators/aids • 3D animation models • Direct user input via joystick, mouse, etc. • Integration with MATLAB and Simulink
Contributions of Work System-specific interactive MoSART environments High performance: Windows/ C++ Advanced visualization tools: Direct-3D Extensible: integration with MATLAB User friendly
Sikorsky UH-60 Blackhawk Aerodynamic Derivatives Near Hover
Longitudinal Dynamics Near Hover . X/ Blc State Space Representation: . 0 1 0 0 = 0 MqMu + MBlc Blc x -g 0 Xu x xBlc .. . .. . Blc - Cyclic control Open loop poles: / Blc Unstable: backflapping mode Horizontal damping mode …need AFCS to minimize pilot workload
Horizontal Speed Controller Cyclic control, Blc . Desired speed Speed, x Horizontal Speed Dynamics k (s+a) s + - (s+b)2 (2500) ( s + 50 )2 b2 a = 2.5 b = 0.6 k = 0.5e-3
About the Program MATLAB Engine v5.0 Direct-3D v3.0 Visual C++/ MFC Windows ’95/’98/NT Pentium PC System Requirements: Pentium PC running Windows 95/NT. 32 MB RAM. Direct-3D 3.0. Recommended: Pentium II 266 w/ MMX running Windows NT 4.0. 64 MB RAM. Direct-3D 3.0.
Interactive MoSART Environment Modules Interactive Environment Application Program User Interface (PUI) Simulation Module (SIM) Graphical Animation Module (GAM) Help/Instruct Module (HIM) Communication Module (COM) Physical System Simulink MATLAB Other Applications Internet ActiveX
Program User Interface (PUI) User Friendly Windows ’95/NT Interface • Menus • Multiple windows • Program control toolbars Interactive System Diagram • Block diagram representation of system • Point-and-click access
Simulation Module (SIM) Numerical Simulation • Fast compiled C++: >3000 Hz / 266MHz PII • Better than real-time simulation On-the-Fly Parameter Editing • Plant models • Controller parameters • Reference Commands, Disturbances, Noise, etc. • Integration methods: Euler, Runge-Kutta 4, etc. Extensibility
Simulation Module: Extensibility Changing plant parameters on-the-fly Playback of externally generated simulation: e.g. MATLAB/SIMULINK Dynamic linking: MATLAB Engine ... (Edit Mode) (Playback Mode) (External-Link Mode)
Graphical Animation Module (GAM) 3D Animation • Direct-3D • Texture-mapped, light-shaded polygons • Wireframe copters from previous simulations (SMAC) Visualization Tools & Indicators • Real-Time Variable Display Window • 2D Animation Window: pitch indicator • Real-time multiple-graph plotting Extensibility
Animation Module: Extensibility Direct-3D standard file format 3D modeling packages: e.g. 3D Studio Libraries of 3D objects widely available: Internet & commercial vendors.
Help-Instruct Module (HIM) On-line Help • Instructions on using the environment • Program reference HTML / PDF Documents • Model documentation/ references • Interactive tutorials
Utility of Environment Open-loop joystick control Closed-loop user joystick control TLHS: Modal Analysis TLHS: Command Following
Open-Loop Joystick Control Very oscillatory cyclic control Undesirable level of pitching. Difficult to maintain a desired speed Very difficult to maintain a desired pitch attitude
Closed-Loop Command Following Acceptable levels of pitching Smooth cyclic control response Good acceleration and smooth speed transient
TLHS System Configuration Master Slave Spreader Bar Payload
TLHS System Poles TLHS open-loop poles 3 AVM Vertical Spring SM ASM 2 Horizontal Spring Backflapping 1 Symmetric Damping Imaginary Axis 0 Average Vertical Damping -1 Tethered Helicopter Anti-Symmetric Damping -2 Pendular -3 -2.5 -2 -1.5 -1 -0.5 0 0.5 1 Real Axis
TLHS: Command Following Command: 5 ft/sec forward speed 5 ft/sec climb
Future Directions • More visual indicators • Advanced SIM and GAM (e.g. TLHS) • Expanded HIM: web support, multimedia • Develop Model Documentation Feature • Enhanced integration with MATLAB / SIMULINK / LABVIEW / Excel….all are ActiveX Compatible • Integrated design & analysis environment • Develop Additional Environments MoSART-FAME … development of Facility VISIT: http://www.eas.asu.edu/~aar/research/mosart/Presentations/
END OF PRESENTATION Some auxilary slides follow
Horizontal Speed Controller Controller #1 (proportional only) Controller #2 (Dynamical Feedback)