Abstract: A system includes a memory that stores instructions and receives a circuit netlist, and includes a processing unit that accesses the memory and executes the instructions. The instructions include an EDA application that includes a test-point flop allocation module that is configured to evaluate the circuit netlist to determine compatibility of the test-point nodes in the circuit netlist. The test-point flop allocation module can further allocate each of the test-point flops to a test-point sharing group comprising a plurality of compatible test-point nodes. The EDA application also includes a circuit layout module configured to generate a circuit layout associated with the circuit design, the circuit layout comprising the functional logic and scan-chains comprising the test-point flops allocated to the test-point sharing groups in response to the circuit netlist. The circuit layout is employable to fabricate an integrated circuit (IC) chip.

Abstract: Methods and design system for generating 2-dimensional distribution architecture for testing integrated circuit design that utilizes double grid to minimize interdependencies between grid cells and the associated functional logic to facilitate the a physically efficient scan of integrated circuit designs, that simultaneously minimizes required test application time (“TAT”), test data volume, tester memory and cost associated with design for test (“DFT”), while also retaining test coverage. An additional grid parallel to a 2-dimensional XOR grid may be implemented that improves the quality of test coverage by optimally adding additional data inputs which decreases correlations between grid cells. A column spreader may feed data into column wires and row spreader may feed data into column wires. The double grid allows data to be fed into two wires, row and column, respectively, which provides twice as much stimulus data in each direction, without significantly increasing the wiring used to build the grid.

Abstract: Exemplary embodiments of the present disclosure relate to a clock distribution network for a scan design, which may include, for example, a clock signal network(s), and a plurality of partitioned clock signal networks coupled to the clock signal network(s) through a controlling logic(s); where the controlling logic(s) may be configured to stagger a clock signal from the clock signal network(s), and where each of the partitioned clock signal networks may be connected to a group of flip-flops. A first partitioned clock signal network of the partitioned clock signal networks may be connected to a first group of flip-flops and a second partitioned clock signal network of the partitioned clock signal networks may be connected to a second group of flip-flops, and where the first group of flip-flops may be different than the second group of flip-flops. The controlling logic(s) may include a shift register(s).

Abstract: Methods and computer-readable media for testing integrated circuit designs implement a physically efficient scan by optimally balancing and connecting scan segments in a 2-dimensional compression chain architecture. A compression architecture that provides an optimal and balanced configuration of scan segments in 2D compression grids to not only decrease test time, but also to maximize compression efficiency and limit wiring congestion for IC designs that contain complex scan segments facilitates efficient scanning of data by bisecting the elements into balanced partitions of the same target scan length. A segment padding algorithm, followed by a bisecting algorithm and ultimately an element swapping algorithm may be applied to optimally balance and connect scan segments in 2-D compression chains, optimizing an efficient compression architecture which minimizes scan testing resources and time.

Abstract: Systems disclosed herein provide for efficient top-level compactors for systems on a chip (SoCs) with multiple identical cores. Embodiments of the systems provide for compactors with a time-skewed assignment configuration, compactors with a space-skewed assignment configuration, compactors with time/space-skewed assignment configuration, and compactors that can selectively switch between the time/space-skewed assignment configuration and a symmetric assignment configuration.