Abstract: Logic blocks for IC designs (including gate-array, standard cell, or logic array designs) provide Design-for-Test-enabled flip-flops (DFT-enabled FFs) that inherently insure compliance with DFT rules associated with scan shifting. Test scan-chains are configured by daisy-chaining instances of the logic block in a transparent (invisible) manner to user-designed application circuits, which can be designed without any user-inserted test structures or other regard for DFT considerations. User asynchronous set and reset inputs and all Stuck-At faults on all user pins on these DFT-enabled FFs are observable via capture and scan-out. A first type of these DFT-enabled FFs features addressable control to partition test the application circuit. A second type of these DFT-enabled FFs features integral capture buffering that eliminates the need for partition test, simplifying control logic and reducing the number of test vectors needed.

Abstract: Logic blocks for IC designs (including gate-array, standard cell, or logic array designs) provide Design-for-Test-enabled flip-flops (DFT-enabled FFs) that inherently insure compliance with DFT rules associated with scan shifting. Test scan-chains are configured by daisy-chaining instances of the logic block in a transparent (invisible) manner to user-designed application circuits, which can be designed without any user-inserted test structures or other regard for DFT considerations. User asynchronous set and reset inputs and all Stuck-At faults on all user pins on these DFT-enabled FFs are observable via capture and scan-out. A first type of these DFT-enabled FFs features addressable control to partition test the application circuit. A second type of these DFT-enabled FFs features integral capture buffering that eliminates the need for partition test, simplifying control logic and reducing the number of test vectors needed.

Abstract: An embodiment of the invention includes a routing architecture with a plurality of predesigned layers and a custom layer. The structure includes a plurality of parallel vertical tracks. In one layer, the tracks include a pin coupled to an input/output of an underlying function block and the track also includes a first portion of an unbroken conductive path. A second portion of the unbroken conductive path is formed under the pin in at least a second predesigned layer. In some embodiments, the second portion of the unbroken conductive path is formed in the second predesigned layer for some tracks and a third predesigned layer for other tracks. Hence, pins and unbroken conductive paths are multiplexed in a single track. In addition, the second predesigned layer further includes long horizontal conductors.

Abstract: A system for remotely/automatedly testing an ASIC and particularly to testing a user-designed circuit is disclosed. In general, a system in accordance with the invention includes a plurality of cells, where the cells are couplable to form a user-designed circuit, e.g., by customizing routing. Within the ASIC and prior to any knowledge of the user-designed circuit, the ASIC includes circuitry to enable internal remote/automated testing of the user-designed circuit to be later formed. The circuitry controls the input and mode of operation of the cells and the sequencing of multiple synchronous or asynchronous clock domain inputs thereby providing testing of the user-designed circuit at speed for stuck-at-faults and delay faults.

Abstract: Described herein is an ASIC having an array of predesigned function blocks. The function blocks can be used to implement combinational logic, sequential logic, or a combination of both. The function blocks also have a selectable output drive strength. The output drive strength can be selected, in some embodiments, using mask programming.

Abstract: A differential receiver having a pair of cross-coupled signal conditioning devices improves transition time and data signal integrity. In an embodiment, the differential receiver includes two signal input nodes and a plurality of transistors, and two signal output nodes. The pair of cross-coupled signal conditioning devices are coupled to the transistors and function to reduce voltage swing between the two output nodes, thereby keeping the transistors in a saturation region.

Abstract: A differential receiver having a pair of cross-coupled signal conditioning devices improves transition time and data signal integrity. In an embodiment, the differential receiver includes two signal input nodes and a plurality of transistors, and two signal output nodes. The pair of cross-coupled signal conditioning devices are coupled to the transistors and function to reduce voltage swing between the two output nodes, thereby keeping the transistors in a saturation region.

Abstract: A system for remotely/automatedly testing an ASIC and particularly to testing a user-designed circuit is disclosed. In general, a system in accordance with the invention includes a plurality of cells, where the cells are couplable to form a user-designed circuit, e.g., by customizing routing. Within the ASIC and prior to any knowledge of the user-designed circuit, the ASIC includes circuitry to enable internal remote/automated testing of the user-designed circuit to be later formed. The circuitry controls the input and mode of operation of the cells and the sequencing of multiple synchronous or asynchronous clock domain inputs thereby providing testing of the user-designed circuit at speed for stuck-at-faults and delay faults.

Abstract: An embodiment of the invention includes a routing architecture with a plurality of predesigned layers and a custom layer. The structure includes a plurality of parallel vertical tracks. In one layer, the tracks include a pin coupled to an input/output of an underlying function block and the track also includes a first portion of an unbroken conductive path. A second portion of the unbroken conductive path is formed under the pin in at least a second predesigned layer. In some embodiments, the second portion of the unbroken conductive path is formed in the second predesigned layer for some tracks and a third predesigned layer for other tracks. Hence, pins and unbroken conductive paths are multiplexed in a single track. In addition, the second predesigned layer further includes long horizontal conductors.