A device architecture includes a spatially reconfigurable array of processors, such as configurable units of a CGRA, having spare homogenous subarrays, and a parameter store on the device which stores parameters that tag one or more elements as unusable. Configuration data is distributed using a statically reconfigurable bus system, to implement the pattern of placement of configuration data, in dependence on the tagged elements. As a result, a spatially reconfigurable array having unusable elements can be repaired.

A control system is provides that includes a logic gate generating an output state signal, and first and second redundant controllers, wherein the first controller is configured to output a first state signal to a first input of the logic gate, and the second controller is configured to output a second state signal to a second input of the logic gate, and wherein the first controller is configured to receive an impedance isolated feedback signal corresponding to the second state signal from the second controller, and the second controller is configured to receive an impedance isolated feedback signal corresponding to the first state signal from the first controller, so that each controller can determine whether both inputs to the logic gate match one another.

An overvoltage protection device including an output stage, a first switch and a first load providing circuit is provided. The output stage has a first input terminal to receive a first signal, and generates an output signal at an output terminal of the output stage according to the first signal. A first terminal of the first switch is coupled to the first input terminal of the output stage, and a control terminal of the first switch receives a second signal. The first signal is the delayed second signal. The first load providing circuit is coupled to a second terminal of the first switch. The first load providing circuit provides an impedance to the first input terminal when the first switch is turned on.

Integrated circuits such as application specific integrated circuits or programmable logic devices may include multiple copies of a same circuit together with a majority vote circuit in a configuration that is sometimes also referred to as multi-mode redundancy. An adder circuit may be coupled to these multiple copies and produce a carry-out signal and a sum signal based on signals received from the multiple copies. The carry-out signal of the adder circuit may provide the result of the majority vote operation. A logic exclusive OR gate may perform a logic exclusive OR operation between the sum signal and the carry-out signal, thereby generating an error signal. The error signal may indicate that one of the multiple copies produces an output that is different than the outputs produced by the other copies.

A semiconductor device includes: first to N.sup.th input terminals (where N is an integer equal to or greater than 2); and a redundant input terminal. When a K.sup.th input terminal (where K is an integer ranging from 1 to N−1) is defective among the first to N.sup.th input terminals, (K+1).sup.th to N.sup.th input terminals receive signals of K.sup.th to (N−1).sup.th input terminals, respectively, and the redundant input terminal receives a signal of the N.sup.th input terminal.

The disclosure relates to an integrated circuit comprising: a first voltage terminal; a second voltage terminal; and a plurality of logic cells, comprising one or more field effect transistors having a p-type channel and one or more field effect transistors having an n-type channel. The plurality of logic cells comprises a regular subset of cells and a spare subset of cells. Electrical connectors are arranged to: connect the gates of the regular subset of cells in order to provide a functional logic arrangement; connect the gates of the one or more field effect transistors having a p-type channel of the spare subset of cells to the first voltage terminal; and connect the gates of the one or more field effect transistors having an n-type channel of the spare subset of cells to the second voltage terminal.

In a switching device and a system for converting a differential input signal into a ground-referenced output signal using a control signal, error states are detected, and detected error states lead to the deactivation of the ground-referenced output signal and are indicated on the control signal in addition.

A control system is provides that includes a logic gate generating an output state signal, and first and second redundant controllers, wherein the first controller is configured to output a first state signal to a first input of the logic gate, and the second controller is configured to output a second state signal to a second input of the logic gate, and wherein the first controller is configured to receive an impedance isolated feedback signal corresponding to the second state signal from the second controller, and the second controller is configured to receive an impedance isolated feedback signal corresponding to the first state signal from the first controller, so that each controller can determine whether both inputs to the logic gate match one another.

Disclosed herein is a method for making embryonic bio-inspired hardware efficient against faults through self-healing, fault prediction, and fault-prediction assisted self-healing. The disclosed self-healing recovers a faulty embryonic cell through innovative usage of healthy cells. Through experimentations, it is observed that self-healing is effective, but it takes a considerable amount of time for the hardware to recover from a fault that occurs suddenly without forewarning. To get over this problem of delay, novel deep learning-based formulations are utilized for fault predictions. The self-healing technique is then deployed along with the disclosed fault prediction methods to gauge the accuracy and delay of embryonic hardware.

Systems or methods of the present disclosure may provide a programmable logic device including multiple logic array blocks each having multiple programmable elements. The multiple logic array blocks are arranged in multiple rows that are segmented into multiple segments. The programmable logic device also includes repair circuitry disposed between the multiple segments. The repair circuitry remaps logic within a first segment of the multiple segments when a first logic array block of the multiple logic array blocks has failed. Moreover, the first segment includes the first logic array block.