Abstract: A first copy of an intrinsic ID of a first node may be stored on a second node. The first node may receive a challenge that causes it to generate a second copy of its intrinsic ID. The second copy and a random value may be used as inputs of a function to generate a first code. The first code is transmitted to the second node. The second node decodes the first code using its local copies of the random value and/or the intrinsic ID. The second node checks the decoded information against its local information and authenticates the first node if there is a match.

Abstract: This disclosure relates generally to computerized systems and methods of producing a physical representation of an in silico Integrated Circuit (IC) having an in silico Multi-Mode Redundant (MMR) pipeline circuit. An IC layout of the in silico IC is initially generated with the electronic design automation (EDA) program. Multi-Mode Redundant Self-Correcting Sequential State Element (MMRSCSSE) layouts are then rendered immotile while initial redundant Combinational Logic Circuit (CLC) layouts are removed from the IC layout after the MMRSCSSE layouts have been rendered immotile. By first placing the MMRSCSSE layouts and then rendering them immotile, the remaining logic can be placed again and optimized without compromising critical node spacing. As such, the described method provides for a more efficient way to create the IC layout of the in silico IC while maintaining critical node spacing.

Abstract: A local sorting module includes a set of storage elements storing binary vectors configured in a one-dimensional (1D) or two-dimensional (2D) array structure and separated by respective comparators configured to conditionally compare and sort the binary vectors. The comparators may perform a sort using a compare-and-flip or a compare-and-swap operation. Local sorting modules may be coupled with a global sorting module for enabling a tournament sort algorithm to output values stored in storage elements one at a time until all data is outputted in a predetermined sorting order.

Abstract: Embodiments of the present invention provide an authenticating service of a chip having an intrinsic identifier (ID). In a typical embodiment, an authenticating device is provided that includes an identification (ID) engine, a self-test engine, and an intrinsic component. The intrinsic component is associated with a chip and includes an intrinsic feature. The self-test engine retrieves the intrinsic feature and communicates it to the identification engine. The identification engine receives the intrinsic feature, generates a first authentication value using the intrinsic feature, and stores the authentication value in memory. The self-test engine generates a second authentication value using an authentication challenge. The identification engine includes a compare circuitry that compares the first authentication value and the second authentication value and generates an authentication output value based on the results of the compare of the two values.

Abstract: A first copy of an intrinsic ID of a first node may be stored on a second node. The first node may receive a challenge that causes it to generate a second copy of its intrinsic ID. The second copy and a random value may be used as inputs of a function to generate a first code. The first code is transmitted to the second node. The second node decodes the first code using its local copies of the random value and/or the intrinsic ID. The second node checks the decoded information against its local information and authenticates the first node if there is a match.

Abstract: Embodiments of the present invention provide an authenticating service of a chip having an intrinsic identifier (ID). In a typical embodiment, an authenticating device is provided that includes an identification (ID) engine, a self-test engine, and an intrinsic component. The intrinsic component is associated with a chip and includes an intrinsic feature. The self-test engine retrieves the intrinsic feature and communicates it to the identification engine. The identification engine receives the intrinsic feature, generates a first authentication value using the intrinsic feature, and stores the authentication value in memory. The self-test engine generates a second authentication value using an authentication challenge. The identification engine includes a compare circuitry that compares the first authentication value and the second authentication value and generates an authentication output value based on the results of the compare of the two values.

Abstract: A memory having variable size blocks of failed memory addresses is connected to a TCAM storing data values of ranges of addresses in the memory. The ranges of addresses correspond to virtual addresses that, in combination with an offset, point away from failed memory addresses. A reduction circuit connected to the TCAM produces an output for each programmed range of addresses based on a virtual address. A priority encoder, connected to the reduction circuit, selects a first range from the reduction circuit and passes the first range to a random-access memory (RAM). Responsive to the virtual address bring an address in one of the ranges of addresses, the priority encoder passes the first range containing the virtual address to the RAM, which passes a corresponding offset value to the Adder based on the first range. The Adder calculates a physical memory address directing the virtual address to a functional memory location.

Abstract: Circuitry that includes static random access memory (SRAM) access circuitry and a group of SRAM memory cells is disclosed. A digital fingerprint of the group of SRAM memory cells is determined by using the SRAM access circuitry to force at least a portion of the group of SRAM memory cells into a metastable state and then releasing the portion of the SRAM memory cells. Each SRAM memory cell that was released then selects one of two stable states and the SRAM access circuitry provides a selection profile based on the selections. The digital fingerprint is based on the selection profile.

Abstract: Embodiments of the present invention provide an authenticating service of a chip having an intrinsic identifier (ID). In a typical embodiment, an authenticating device is provided that includes an identification (ID) engine, a self-test engine, and an intrinsic component. The intrinsic component is associated with a chip and includes an intrinsic feature. The self-test engine retrieves the intrinsic feature and communicates it to the identification engine. The identification engine receives the intrinsic feature, generates a first authentication value using the intrinsic feature, and stores the authentication value in memory. The self-test engine generates a second authentication value using an authentication challenge. The identification engine includes a compare circuitry that compares the first authentication value and the second authentication value and generates an authentication output value based on the results of the compare of the two values.

Abstract: Circuitry that includes static random access memory (SRAM) access circuitry and a group of SRAM memory cells is disclosed. A digital fingerprint of the group of SRAM memory cells is determined by using the SRAM access circuitry to force at least a portion of the group of SRAM memory cells into a metastable state and then releasing the portion of the SRAM memory cells. Each SRAM memory cell that was released then selects one of two stable states and the SRAM access circuitry provides a selection profile based on the selections. The digital fingerprint is based on the selection profile.