Title :
Modeling and Control of a Nonlinear Mechanism for High Performance Microfluidic Systems
Author :
Kim, YongTae ; LeDuc, Philip ; Messner, Willam
Author_Institution :
Dept. of Mech. Eng., Carnegie Mellon Univ., Pittsburgh, PA, USA
Abstract :
This brief presents modeling and control of a nonlinear mechanism for long-term and high-speed flow regulation in a three-lane microfluidic system. The principle of this mechanism is to modulate a mechanically coupled variable resistance and variable volume reservoir for pressure control at the inlets of microfluidic systems. We developed a dual-loop control system that consists of an inner-loop position controller and an outer-loop pressure controller. We show excellent agreements between analyses, simulations, and experimental results, and demonstrate bandwidth of 10 Hz and duration of 15 hours. We envision that this system will be useful to researchers in areas such as flow cytometry, chemical synthesis, drug delivery, and investigation of spatiotemporally integrated biological responses at molecular, cellular, and tissue levels.
Keywords :
discrete time systems; flow control; linear systems; linearisation techniques; microfluidics; nonlinear control systems; position control; pressure control; three-term control; PID gains; bandwidth 10 Hz; cellular level; chemical synthesis; discrete-time model; drug delivery; dual-loop control system; flow cytometry; high performance microfluidic system; high-speed flow regulation; inner-loop position controller; linear controller; linearized model; long-term flow regulation; mechanically coupled variable resistance; molecular level; nonlinear mechanism control; nonlinear mechanism modeling; outer-loop pressure controller; proportional-integral-derivative gains; spatiotemporally integrated biological response; three-lane microfluidic system; time 15 hr; tissue level; variable volume reservoir; DC motors; Electron tubes; Mathematical model; Nonlinear dynamical systems; Reservoirs; Resistance; Transfer functions; Feedback control; laminar flow interface; linearization; microfluidics; pressure control; pump; resistance;
Journal_Title :
Control Systems Technology, IEEE Transactions on
DOI :
10.1109/TCST.2011.2172445
