Abstract: The present invention generally relates to microfluidics and more particularly to the design of customized microfluidic systems using a microfluidic computer aided design system. In one embodiment of the present invention a microfluidic circuit design method is provided. The method includes developing synthesizable computer code for a design. Next, a microfluidic circuit schematic, including a plurality of symbols for microfluidic components, is generated either interactively or using the synthesizable computer code. The microfluidic circuit schematic is then functionally simulated. The microfluidic components are placed and routed on a template to form a physical layout. Then the physical layout is physically simulated using dynamic simulation models of the microfluidic components; and the physical layout is written to a layout file.

Abstract: The present invention generally relates to design automation techniques and more particularly to the design of customized microfluidic systems using a microfluidic computer aided design system. In one embodiment of the present invention the system includes a synthesis module for synthesizing software of a design into a component level description of the design. The design has a plurality of microfluidic components, and the component level description has symbols associated with the plurality of microfluidic components. The system further includes a design capture module, including a schematic entry tool, for placing and connecting the symbols on a schematic according to the design; and a functional analysis module for functionally simulating selected symbols of the schematic.

Abstract: The present invention generally relates to design automation techniques and more particularly to the design of customized microfluidic systems using a microfluidic computer aided design system. In one embodiment of the present invention the system includes a synthesis module for synthesizing software of a design into a component level description of the design. The design has a plurality of microfluidic components, and the component level description has symbols associated with the plurality of microfluidic components. The system further includes a design capture module, including a schematic entry tool, for placing and connecting the symbols on a schematic according to the design; and a functional analysis module for functionally simulating selected symbols of the schematic.

Abstract: The present invention provides for the design of a microfluidic system, including a microfluidic chip or circuit, using an object oriented microfluidic computer aided design system. In an embodiment of the present invention, in a computer system having a computer memory and an object-oriented environment, a method for physically laying out a microfluidic circuit, having a plurality of microfluidic components is provided. First, a first symbol object representing a microfluidic component is placed, where the first symbol object includes a fluid channel object which represents a first fluid channel of the microfluidic component. Next, a connecting fluid channel object on a channel layer is placed, where the connecting fluid channel object represents a second fluid channel used to connect two microfluidic components of the plurality of microfluidic components.

Abstract: The present invention provides for the design of a microfluidic system, including a microfluidic chip or circuit, using an object oriented microfluidic computer aided design system. In an embodiment of the present invention, in a computer system having a computer memory and an object-oriented environment, a method for physically laying out a microfluidic circuit, having a plurality of microfluidic components is provided. First, a first symbol object representing a microfluidic component is placed, where the first symbol object includes a fluid channel object which represents a first fluid channel of the microfluidic component. Next, a connecting fluid channel object on a channel layer is placed, where the connecting fluid channel object represents a second fluid channel used to connect two microfluidic components of the plurality of microfluidic components.

Abstract: The present invention generally relates to microfluidics and more particularly to the design of customized microfluidic systems using a microfluidic computer aided design system. In one embodiment of the present invention a microfluidic circuit design method is provided. The method includes developing synthesizable computer code for a design. Next, a microfluidic circuit schematic, including a plurality of symbols for microfluidic components, is generated either interactively or using the synthesizable computer code. The microfluidic circuit schematic is then functionally simulated. The microfluidic components are placed and routed on a template to form a physical layout. Then the physical layout is physically simulated using dynamic simulation models of the microfluidic components; and the physical layout is written to a layout file.

Abstract: The present invention generally relates to microfluidics and more particularly to the design of customized microfluidic systems using a microfluidic computer aided design system. In one embodiment of the present invention a microfluidic circuit design method is provided. The method includes developing synthesizable computer code for a design. Next, a microfluidic circuit schematic, including a plurality of symbols for microfluidic components, is generated either interactively or using the synthesizable computer code. The microfluidic circuit schematic is then functionally simulated. The microfluidic components are placed and routed on a template to form a physical layout. Then the physical layout is physically simulated using dynamic simulation models of the microfluidic components; and the physical layout is written to a layout file.

Abstract: The present invention generally relates to design automation techniques and more particularly to the design of customized microfluidic systems using a microfluidic computer aided design system. In one embodiment of the present invention the system includes a synthesis module for synthesizing software of a design into a component level description of the design. The design has a plurality of microfluidic components, and the component level description has symbols associated with the plurality of microfluidic components. The system further includes a design capture module, including a schematic entry tool, for placing and connecting the symbols on a schematic according to the design; and a functional analysis module for functionally simulating selected symbols of the schematic.

Abstract: The present invention provides for the design of a microfluidic system, including a microfluidic chip or circuit, using an object oriented microfluidic computer aided design system. In an embodiment of the present invention, in a computer system having a computer memory and an object-oriented environment, a method for physically laying out a microfluidic circuit, having a plurality of microfluidic components is provided. First, a first symbol object representing a microfluidic component is placed, where the first symbol object includes a fluid channel object which represents a first fluid channel of the microfluidic component. Next, a connecting fluid channel object on a channel layer is placed, where the connecting fluid channel object represents a second fluid channel used to connect two microfluidic components of the plurality of microfluidic components.

Abstract: The present invention generally relates to microfluidics and more particularly to the design of customized microfluidic systems using a microfluidic computer aided design system. In one embodiment of the present invention a microfluidic circuit design method is provided. The method includes developing synthesizable computer code for a design. Next, a microfluidic circuit schematic, including a plurality of symbols for microfluidic components, is generated either interactively or using the synthesizable computer code. The microfluidic circuit schematic is then functionally simulated. The microfluidic components are placed and routed on a template to form a physical layout. Then the physical layout is physically simulated using dynamic simulation models of the microfluidic components; and the physical layout is written to a layout file.