Suppression of flow oscillations in a vertical Bridgman crystal growth system

We consider the feedback control of flows in a vertical Bridgman crystal growth system. The vertical Bridgman process is used to grow single crystals for a wide array of applications, ranging from lasers to highspeed microelectronics to infrared sensors. We model the Bridgman system using conservati...

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Bibliographic Details
Main Authors: Sonda, P., Yeckel, A., Derby, J.J., Daoutidis, P.
Format: Conference Proceeding
Language:English
Subjects:
Applied sciences
Computer science
control theory
systems
Control system synthesis
Control systems
Control theory. Systems
Crystals
Exact sciences and technology
Feedback control
Laser applications
Laser feedback
Laser modes
Nonlinear equations
Optical arrays
Pi control
Sensor arrays
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Summary:We consider the feedback control of flows in a vertical Bridgman crystal growth system. The vertical Bridgman process is used to grow single crystals for a wide array of applications, ranging from lasers to highspeed microelectronics to infrared sensors. We model the Bridgman system using conservation equations for energy and momentum and physically reasonable boundary and initial conditions. The Galerkin finite element method is used to spatially discretize this nonlinear, differential-algebraic equation set. We consider a prototypical Bridgman system experiencing a time-varying disturbance to its furnace temperature profile. A single-input single-output control system is considered for controller design. Proportional, proportional-integral, and input-output linearizing controllers are applied to the vertical Bridgman model to attenuate the flow oscillations. The volume-averaged flow kinetic energy is chosen as the single controlled output. The flows are controlled via rotation of the crucible containing the molten material. Simulation results show that nonlinear control is superior to P and PI control in the suppression of the flow oscillations.
ISSN:0743-1619
2378-5861
DOI:10.23919/ACC.2004.1383617