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Getting Started
Overview
Architecture Overview
Installation
User Guide
User Guide
Tutorial - Modeling
Tutorial - Bearings in ROSS
Tutorial - Thermo-Hydro-Dynamic (THD) Bearings
Tutorial - Active Magnetic Bearings (AMB)
Tutorial about Seals: Labyrinth, Hole-pattern, and Hybrid
Tutorial - Faults
Tutorial - Static and Modal Analyses
Tutorial - Time and Frequency Analyzes
Tutorial - Stochastic ROSS
Tutorial - MultiRotor System
Example 1 - Number of DOF influence in Natural Frequency
Example 2 - Effect of varying slenderness ratio
Example 3 - Isotropic Bearings, asymmetrical rotor.
Example 4 - Anisotropic Bearings.
Example 5 - Cross-coupled bearings.
Example 6 - Isotropic bearings with damping.
Example 7 - Hydrodynamic Bearings
Example 8 - Overhung rotor.
Example 9 - Hydrodynamic Journal Bearings (using Fluid Flow methods)
Example 13 - Uncertainties on bearings coefficients
Example 14 - Uncertainties on material properties
Example 16 - Look at different models of the disk-shaft interface
Example 17 - Features of Eigenvalues and Eigenvectors - Isotropic Bearings
Example 18 - Features of Eigenvalues and Eigenvectors - Anisotropic Bearings
Example 19 - Features of Eigenvalues and Eigenvectors - System with Mixed Modes
Example 20 - Features of Eigenvalues and Eigenvectors - Cross-Coupling in the Bearings
Example 21 - Features of Eigenvalues and Eigenvectors - Hydrodynamic Bearings
Example 22 - Features of Eigenvalues and Eigenvectors - The Effect o f Axial Load and Follower Torque
Example 23 - An Overhung Rotor
Example 24 - A Tapared Shaft
Example 25 - Coaxial rotor
Example 26 - Isotropic System
Example 27 - Anisotropic System
Example 28 - Rigid rotor on isotropic bearings
Example 29 - Rigid rotor on anisotropic bearings
Example 30 - Natural frequencies, mode shapes and natural frenquency map of a rigid rotor
Example 31 - Isotropic Bearings with Damping
Example 32 - Response to Forces Applied through Auxiliary Bearings
Fluid-flow: Elliptical Bearing
Fluid-flow: Short Bearing
Fluid-flow theory
Fluid-flow: Wear Bearing
References
API Reference
ross.Material
ross.ShaftElement
ross.DiskElement
ross.BearingElement
ross.SealElement
ross.BallBearingElement
ross.RollerBearingElement
ross.CylindricalBearing
ross.PlainJournal
ross.TiltingPad
ross.ThrustPad
ross.LabyrinthSeal
ross.HolePatternSeal
ross.MagneticBearingElement
ross.GearElement
ross.CouplingElement
ross.Probe
ross.PointMass
ross.Rotor
ross.MultiRotor
ross.Rotor.run_modal
ross.Rotor.run_critical_speed
ross.Rotor.run_freq_response
ross.Rotor.run_forced_response
ross.Rotor.run_unbalance_response
ross.Rotor.run_campbell
ross.Rotor.run_time_response
ross.Rotor.run_level1
ross.Rotor.run_ucs
ross.Rotor.run_static
ross.Rotor.run_misalignment
ross.Rotor.run_rubbing
ross.Rotor.run_crack
ross.Orbit
ross.Shape
ross.CriticalSpeedResults
ross.ModalResults
ross.CampbellResults
ross.FrequencyResponseResults
ross.ForcedResponseResults
ross.StaticResults
ross.SummaryResults
ross.ConvergenceResults
ross.TimeResponseResults
ross.Level1Results
ross.UCSResults
ross.BearingFluidFlow
Additional Info
Release notes
Contributing
Citing
.rst
.pdf
ross.Rotor.run_modal
Contents
Rotor.run_modal
ross.Rotor.run_modal
#
Rotor.
run_modal
=
<methodtools._LruCacheWire
object>
#
Contents
Rotor.run_modal
