System and method for capacitance-based real-time micro-object position control with the aid of a digital computer

What is claimed is: 1. A system for capacitance-based real-time micro-object position control with an aid of a digital computer, comprising: at last one processor configured to execute computer-executable code and further configured to: obtain one or more parameters of a system for positioning one or more micro-objects, the system comprising a plurality of electrodes, the electrodes configured to induce movements of the one or more micro-objects when the one or more micro-objects are suspended in a fluid proximate to the electrodes upon a generation of one or more forces by one or more of the electrodes; model a capacitance of an interaction between each of the electrodes and at least one of the micro-objects as a function of a distance between that electrode and the at least one micro-object using dielectrophoretic forces acting upon that at least one micro-object, electrophoretic forces acting upon that at least one micro-object, and the system parameters comprising a viscous drag experienced by that at least one micro-object during the movements; obtain a position of one or more of the micro-objects within the fluid; and generate a control signal for each of the electrodes, the control signal comprising a command which generates one or more of the forces for a predefined period of time by that electrode, using the obtained position, the model, and a desired location of one or more of the micro-objects. 2. A system according to claim 1 , wherein that at least one micro-object remains at a constant height during the modeled interaction. 3. A system according to claim 1 , wherein acceleration of that at least one micro-object is not used during the modeling. 4. A system according to claim 1 , wherein the modeling further uses a stiction force acting upon that at least one micro-object. 5. A system according to claim 1 , wherein the electrodes and that at least one micro-object are represented as forming a capacitance electrical circuit in the model. 6. A system according to claim 1 , wherein the fluid is bounded by an enclosure and is on top of a layer of film. 7. A system according to claim 6 , wherein the layer of film is on top of the electrodes. 8. A system according to claim 6 , wherein the layer of film is laminated on top of the electrodes and that at least one micro-object touches a surface of the layer of film during the movements. 9. A system for capacitance-based real-time micro-object horizontal position control with an aid of a digital computer, comprising: at least one processor configured to execute computer-executable code and further configured to: obtain one or more parameters of a system for positioning one or more micro-objects, the system comprising a plurality of electrodes, the electrodes configured to induce movements of the one or more micro-objects along a film layer on top of the electrodes when the one or more micro-objects are suspended in a fluid on top of the film layer on top of the electrodes upon a generation of one or more forces by one or more of the electrodes; model a capacitance of an interaction between each of the electrodes and at least one of the micro-objects as a function of a distance between that electrode and the at least one micro-object using dielectrophoretic forces acting upon that at least one micro-object, electrophoretic forces acting upon that at least one micro-object, and the system parameters comprising a drag against the film layer experienced by that at least one micro-object during the movements; obtain a position of one or more of the micro-objects within the fluid; and generate a control signal for each of the electrodes, the control signal comprising a command which generates one or re of the forces for a predefined period of time by that electrode, using the obtained position, the model, and a desired location of one or more of the micro-objects. 10. A system according to claim 9 , wherein that at least one micro-object remains at a constant height during the modeled interaction. 11. A system according to claim 9 , wherein the modeling further uses a stiction force acting upon that at least one micro-object. 12. A system according to claim 9 , wherein the electrodes and that at least one micro-object are represented as forming a capacitance electrical circuit in the model. 13. A method for capacitance-based real-time micro-object position control with an aid of a digital computer, comprising the steps of: obtaining one or more parameters of a system for positioning one or more micro-objects, the system comprising a plurality of electrodes, the electrodes configured to induce movements of the one or more micro-objects when the one or more micro-objects are suspended in a fluid proximate to the electrodes upon a generation of one or more forces by the electrodes; modeling a capacitance of an interaction between each of the electrodes and at least one of the micro-objects as a function of a distance between that electrode and the at least one micro-object using dielectrophoretic forces acting upon that at Last one micro-object, electrophoretic forces acting upon that at least one micro-object, and the system parameters comprising a viscous drag experienced by that at least one micro-object during the movements; obtaining a position of one or more of the micro-objects within the fluid; and generating a control signal for each of the electrodes, the control signal comprising a command which generates one or more of the forces for, a predefined period of time by that electrode, using the obtained position, the model, and a desired location of one or more of the micro-objects, wherein the steps are performed by a computer. 14. A method according to claim 13 , wherein that at least one micro-object remains at a constant height during the modeled interaction. 15. A method according to claim 13 , wherein acceleration of that at least one micro-object is not used during the modeling. 16. A method according to claim 13 , wherein the modeling further uses a stiction force acting upon that at least one micro-object. 17. A method according to claim 13 , wherein the electrodes and that at least one micro-object are represented as forming a capacitance electrical circuit in the model. 18. A method according to claim 13 , wherein the fluid is bounded by an enclosure and is on top of a layer of film. 19. A method according to claim 18 , wherein the layer of film is on top of the electrodes. 20. A method according to claim 18 , wherein the layer of film is laminated on top of the electrodes and that at least one micro-object touches a surface of the layer of film during the movements.