Patent application number | Description | Published |
20090077515 | Method of Constrained Aggressor Set Selection for Crosstalk Induced Noise - A preliminary static timing analysis run is performed to calculate the delay and slew as well as timing windows for each net in the design, followed by coupling analysis for each given aggressor-victim combination, and to calculate the noise effect on the timing of victim net. Given a set of functional groups that relate the coupled aggressors to each other, the worst set of aggressors are calculated that satisfy the constraints from the functional groups, based on the calculated impact of each aggressor on the victim. Similarly the set of aggressors which contribute to the maximum amount of inductive coupling noise effect on timing are calculated. Furthermore, the coupling noise impact of the reduced set of aggressors on the given victim line and adjust the delay value calculated in the preliminary static timing analysis run. | 03-19-2009 |
20100251198 | METHOD FOR EXTRACTING INFORMATION FOR A CIRCUIT DESIGN - The present disclosure is directed to a method for extracting information for a circuit design. The method may utilize an incremental extraction process for extracting information for a portion of the circuit design. Extracted results of this portion may be merged with a previously extracted result to obtain an integrated result that is equivalent to that of extracting the entire circuit design. The incremental extraction process may identify a set of changed shapes, a set of affected shapes, and a set of involved shapes for extraction. The method may also divide the circuit design into a plurality of regions, wherein two or more regions may be processed in parallel. | 09-30-2010 |
20100262940 | Accurate Approximation of Resistance in a Wire with Irregular Biasing and Determination of Interconnect Capacitances in VLSI Layouts in the Presence of Catastrophic Optical Proximity Correction - The Width Bias Calculator (WBC) calculates electrical values by effectively averaging the electrical values to either side of a target wire shape whereby values are approximated for design validation without a significant impact on performance or memory consumption. | 10-14-2010 |
20110078642 | Method for Calculating Capacitance Gradients in VLSI Layouts Using A Shape Processing Engine - Computing the gradients of capacitances in an integrated circuit chip layout with respect to design and process parameters is described. Included is a shape processing engine in the form of a variational mapping engine and a capacitance calculation engine that includes a gradient calculation engine. The variational mapping engine translates physical parameter variations into variations on the edges of the elementary patterns to which the layout of the integrated circuit is decomposed. The gradient calculation engine computes capacitance gradients by combining information from two sources. The first source consists of pre-existing gradients in a capacitance lookup table. The second source consists of analytical expressions of capacitance correction factors. | 03-31-2011 |
20120180013 | METHOD FOR EXTRACTING INFORMATION FOR A CIRCUIT DESIGN - The present disclosure is directed to a method for extracting information for a circuit design. The method includes establishing a reflexive relationship between a plurality of design shapes corresponding to a plurality of circuit components in the circuit design. The method includes receiving a design change for at least one design shape of the plurality of design shapes. The method includes identifying a set of changed shapes, a set of affected shapes, and a set of involved shapes. The method includes extracting at least one of a capacitance, an inductance or a resistance for the updated circuit design based on at least one of the set of changed shapes, the set of affected shapes and the set of involved shapes. The method includes updating the plurality of circuit components in the circuit design based on at least one of the set of changed shapes and the set of affected shapes. | 07-12-2012 |
20120185815 | METHOD FOR EXTRACTING INFORMATION FOR A CIRCUIT DESIGN - The present disclosure is directed to a method for extracting information for a circuit design. The method may utilize an incremental extraction process for extracting information for a portion of the circuit design. Extracted results of this portion may be merged with a previously extracted result to obtain an integrated result that is equivalent to that of extracting the entire circuit design. The incremental extraction process may identify a set of changed shapes, a set of affected shapes, and a set of involved shapes for extraction. The method may also divide the circuit design into a plurality of regions, wherein two or more regions may be processed in parallel. | 07-19-2012 |
Patent application number | Description | Published |
20110161908 | GENERATING CAPACITANCE LOOK-UP TABLES FOR WIRING PATTERNS IN THE PRESENCE OF METAL FILLS - A computer system selects a signal conductor from an electronic circuit design layout and assigns a first potential to the selected signal conductor. Next, the computer system assigns a second potential to other signal conductors included in the electronic circuit design layout. The computer system then selects a metal fill from the electronic circuit design layout, which is void from carrying an electrical signal, and generates a zero charge equation for the selected metal fill. The zero charge equation establishes that a total charge residing on the selected metal fill is equal to zero. The computer system includes the zero charge equation in a system of equations, which includes grid point potential equations, and solves the system of equations. In turn, the computer system computes capacitance values for the signal conductors based upon the system of equation solutions, and simulates the electronic circuit design layout using the computed capacitance values. | 06-30-2011 |
20120204140 | Generating Capacitance Look-up Tables for Wiring Patterns in the Presence of Metal Fills - A computer system selects a signal conductor from an electronic circuit design layout and assigns a first potential to the selected signal conductor. Next, the computer system assigns a second potential to other signal conductors included in the electronic circuit design layout. The computer system then selects a metal fill from the electronic circuit design layout, which is void from carrying an electrical signal, and generates a zero charge equation for the selected metal fill. The zero charge equation establishes that a total charge residing on the selected metal fill is equal to zero. The computer system includes the zero charge equation in a system of equations, which includes grid point potential equations, and solves the system of equations. In turn, the computer system computes capacitance values for the signal conductors based upon the system of equation solutions, and simulates the electronic circuit design layout using the computed capacitance values. | 08-09-2012 |
20130246992 | Generating Capacitance Look-up Tables for Wiring Patterns in the Presence of Metal Fills - A computer system selects a signal conductor from an electronic circuit design layout and assigns a first potential to the selected signal conductor. Next, the computer system assigns a second potential to other signal conductors included in the electronic circuit design layout. The computer system then selects a metal fill from the electronic circuit design layout, which is void from carrying an electrical signal, and generates a zero charge equation for the selected metal fill. The zero charge equation establishes that a total charge residing on the selected metal fill is equal to zero. The computer system includes the zero charge equation in a system of equations, which includes grid point potential equations, and solves the system of equations. In turn, the computer system computes capacitance values for the signal conductors based upon the system of equation solutions, and simulates the electronic circuit design layout using the computed capacitance values. | 09-19-2013 |