Abstract: A system and method for processing data for use with a microcontroller having a processing unit provides for sending an input data address to a memory as part of a read request for input data stored in the memory, receiving the input data from the memory, generating a plurality of trace signals, generating a first plurality of signatures based upon the plurality of trace signals, receiving a second plurality of corresponding signatures from a second microcontroller, comparing each signature of the first plurality of signatures to each corresponding signature of the second plurality of corresponding signatures, generating a first error signal if the comparison produces at least one mismatch, and utilizing the first error signal to generate one or more disable signals for disabling operation of one or more devices under control of the microcontroller.

Abstract: A system and method for increasing lockstep core availability provides for writing a state of a main CPU core to a state buffer, executing one or more instructions of a task by the main CPU core to generate a first output for each executed instruction, and executing the one or more instructions of the task by a checker CPU core to generate a second output for each executed instruction. The method further includes comparing the first output with the second output, and if the first output does not match the second output, generating one or more control signals, and based upon the generation of the one or more control signals, loading the state of the main CPU core from the state buffer to the main CPU core and the checker CPU core.

Abstract: A system and method for determining operational robustness of a system on a chip (SoC) includes modifying one or more internal states of the SoC, during operation of the SoC, to mimic an effect which one or more disturbances have on the SoC, generating one or more signal traces that correspond to at least one internal state of the SoC after modifying the one or more internal states of the SoC, and determining if the operation of the SoC is stable based on the one or more generated signal traces.

Abstract: Some embodiments of the invention relate to an embedded processing system. The system includes a memory unit to store a plurality of operating instructions and a processing unit coupled to the memory unit. The processing unit can execute logical operations corresponding to respective operating instructions. An input/output (I/O) interface receives a first time-varying waveform and provides an I/O signal that is based on the first time-varying waveform. A comparison unit coupled to the processing unit and adapted to selectively assert an error signal based on whether the I/O signal has a predetermined relationship with a reference signal, wherein the predetermined relationship holds true during normal operation but fails to hold true when an unexpected event occurs and causes an unexpected change at least one of the I/O signal and reference signal.

Abstract: Some embodiments relate to a Direct Memory Access (DMA) controller. The DMA controller includes a set of transaction control registers to receive a sequence of transaction control sets that collectively describe a data transfer to be processed by the DMA controller. A bus controller reads and writes to memory while the DMA controller executes a first transaction control set to accomplish part of the data transfer described in the sequence of transaction control sets. An integrity checker determines an actual error detection code based on data or an address actually processed by the DMA controller during execution of the first transaction control set. The integrity checker also selectively flags an error based on whether the actual error detection code is the same as an expected error detection code contained in a second transaction control set of the sequence of transaction control sets.

Abstract: Some embodiments of the present disclosure relate to a watchdog timer having an enhanced functionality that enables the watchdog timer to monitor a process flow of the microprocessor on a task-by-task basis that enables a simple output signal to be used to determine if the watchdog timer is malfunctioning. The watchdog timer has a state machine that increments a state variable from an initial value over a watchdog period. A deterministic service request, received from a microprocessor, controls operation of the watchdog timer. The deterministic service request has an indicator of a monitoring operation to be performed, a password, and an estimated state variable. A comparison element determines if the microprocessor is operating properly based upon a comparison of the received password to an expected password and the received estimated state variable to an actual state variable.

Abstract: Some embodiments of the invention relate to an embedded processing system. The system includes a memory unit to store a plurality of operating instructions and a processing unit coupled to the memory unit. The processing unit can execute logical operations corresponding to respective operating instructions. An input/output (I/O) interface receives a first time-varying waveform and provides an I/O signal that is based on the first time-varying waveform. A comparison unit coupled to the processing unit and adapted to selectively assert an error signal based on whether the I/O signal has a predetermined relationship with a reference signal, wherein the predetermined relationship holds true during normal operation but fails to hold true when an unexpected event occurs and causes an unexpected change at least one of the I/O signal and reference signal.

Abstract: A method can be used for monitoring a processing circuit. The processing circuit generates a response to a request and the response is compared with an expected response. A pass pulse is generated when the response matches the expected response. The causing, comparing and generating steps are repeated a number of times A frequency at which pass pulses occur is evaluated.

Abstract: Embodiments relate to systems and methods for detecting register corruption within CPUs operating on the same input data enabling non-invasive read access to and comparison of contents of at least one set of according ones of registers of different CPUs to detect corrupted registers in form of according registers with inconsistent contents.

Abstract: The disclosed invention provides a structure and method for detecting address line (e.g., wordline, bitline) memory failures. In one embodiment, the method and structure comprise generating an address signature, by re-encoding an internally generated address signal from activated elements (e.g., wordlines) inside a memory array. The regenerated address signature may be compared with a requested memory address location. If the regenerated address signature and memory location are equal than there is no error in the memory array, but if the regenerated address signature and memory location are equal than an error is present in the memory array. Accordingly, re-encoding an address signature provides a closed loop check that a wordline and/or bitline, that was actually activated in a memory array, was the correct requested wordline and/or bitline, that no other wordlines or bitlines were also triggered, and that the wordline and/or bitline is continuous.

Abstract: Some embodiments of the invention relate to an embedded processing system. The system includes a memory unit to store a plurality of operating instructions and a processing unit coupled to the memory unit. The processing unit can execute logical operations corresponding to respective operating instructions. An input/output (I/O) interface receives a first time-varying waveform and provides an I/O signal that is based on the first time-varying waveform. A comparison unit coupled to the processing unit and adapted to selectively assert an error signal based on whether the I/O signal has a predetermined relationship with a reference signal, wherein the predetermined relationship holds true during normal operation but fails to hold true when an unexpected event occurs and causes an unexpected change at least one of the I/O signal and reference signal.

Abstract: Processors, microprocessors and logical block systems and methods, error detection systems and methods, and integrated circuits are disclosed. In an embodiment, a logic-based computing system includes a first processing core; a second processing core generated from the first processing core and including an inverted logical equivalent of the first processing core such that an output of the second processing core is a complement of an output of the first processing core; and comparator logic coupled to receive the outputs of the first and second processing cores as inputs and provide an error output if the output of the second processing core is not the complement of the output of the first processing core.

Abstract: A system and method for signature-based redundancy comparison provides for receiving, by a master part, an input signal and generating, by the master part, a binary output signal, generating a delayed input signal based on the input signal, generating a first output signature based on the binary output signal, and generating a delayed first output signature based on the first output signature. The system and method further comprise generating a delayed binary output signal based on the delayed input signal, generating, by a checker part, a delayed second output signature based on the delayed binary output signal, comparing the delayed first output signature with the delayed second output signature, and generating an error signal, where the state of the error signal is based upon the comparison.

Abstract: A system and method for processing data for use with a microcontroller having a processing unit provides for sending an input data address to a memory as part of a read request for input data stored in the memory, receiving the input data from the memory, generating a plurality of trace signals, generating a first plurality of signatures based upon the plurality of trace signals, receiving a second plurality of corresponding signatures from a second microcontroller, comparing each signature of the first plurality of signatures to each corresponding signature of the second plurality of corresponding signatures, generating a first error signal if the comparison produces at least one mismatch, and utilizing the first error signal to generate one or more disable signals for disabling operation of one or more devices under control of the microcontroller.

Abstract: A data transmission system includes at least one transmission line. A sender is configured to send data frames to the at least one transmission line and a recipient is configured to receive the data frames from the at least one transmission line. The sender and the recipient are both configured to determine a check sum based on a plurality of corresponding data frames that are sent to and, respectively, received from the at least one transmission line. A check sum comparing unit is configured to receive and to compare the check sum determined by the sender and the corresponding check sum determined by the recipient. The check sum comparing unit is also configured to signal a transmission error or initiate a safety function when the check sums compared are not equal.

Abstract: Some embodiments of the invention relate to an embedded processing system. The system includes a memory unit to store a plurality of operating instructions and a processing unit coupled to the memory unit. The processing unit can execute logical operations corresponding to respective operating instructions. An input/output (I/O) interface receives a first time-varying waveform and provides an I/O signal that is based on the first time-varying waveform. A comparison unit coupled to the processing unit and adapted to selectively assert an error signal based on whether the I/O signal has a predetermined relationship with a reference signal, wherein the predetermined relationship holds true during normal operation but fails to hold true when an unexpected event occurs and causes an unexpected change at least one of the I/O signal and reference signal.

Abstract: The disclosed invention provides a structure and method for detecting address line (e.g., wordline, bitline) memory failures. In one embodiment, the method and structure comprise generating an address signature, by re-encoding an internally generated address signal from activated elements (e.g., wordlines) inside a memory array. The regenerated address signature may be compared with a requested memory address location. If the regenerated address signature and memory location are equal than there is no error in the memory array, but if the regenerated address signature and memory location are equal than an error is present in the memory array. Accordingly, re-encoding an address signature provides a closed loop check that a wordline and/or bitline, that was actually activated in a memory array, was the correct requested wordline and/or bitline, that no other wordlines or bitlines were also triggered, and that the wordline and/or bitline is continuous.

Abstract: Processors, microprocessors and logical block systems and methods, error detection systems and methods, and integrated circuits are disclosed. In an embodiment, a logic-based computing system includes a first processing core; a second processing core generated from the first processing core and including an inverted logical equivalent of the first processing core such that an output of the second processing core is a complement of an output of the first processing core; and comparator logic coupled to receive the outputs of the first and second processing cores as inputs and provide an error output if the output of the second processing core is not the complement of the output of the first processing core.

Abstract: Embodiments relate to systems and methods for reading from and writing to interface peripherals or other shared resources during robust computation utilizing temporally separated redundant execution. Embodiments can be utilized in safety-relevant applications related to automotive, banking and finance, aerospace, defense, Internet payment, and others.

Abstract: Systems, devices and methods of automatic diverse software generation are disclosed. In an embodiment, a method includes providing a base algorithm implementation related to a first hardware profile of a hardware resource, automatically generating a diverse algorithm implementation related to a second hardware profile different from the first hardware profile using the base algorithm implementation and information about the hardware resource, and executing the base algorithm implementation and the diverse algorithm implementation. Embodiments of systems and devices, including microprocessors and compilers, are also disclosed.