Signaling indicative of a command to initialize a plurality of memory dies of a memory device can be received by the memory device. Initialization of a memory die of the memory device can be delayed, at the memory die and based at least in part on fuse states of an array of fuses of the memory die, by an amount of time relative to receipt of the signaling by the memory device. Delaying initialization of memory dies of the memory device in a staggered or asynchronous manner can evenly distribute power consumption of the memory dies so that the likelihood of an associated power spike is reduced or eliminated.

Systems and methods are disclosed, including selectively providing one of a first reset or a second reset to transition to a storage system from a low power mode to an operational power mode in response to a hardware reset signal and a value of a control bit on the storage system.

An Internet of Things (IoT) system is illustrated, which has a power supply device and an IoT device. The power supply device electrically connected to the IoT device provides power to the IoT device. The IoT device has a memory unit, a control unit and a networking unit. When the power device generates a surge configuration, the control unit executes a surge control command stored in the control unit after receiving the surge configuration. The surge control command drives the control unit selectively executes one of modes according to the surge configuration. The modes comprise a user mode and a reset mode. The present disclosure utilizes the surge configuration to restart and/or reset the IoT device, and thus the IoT device can be reset without installing a reset button.

Embodiments support secure booting of an IHS (Information Handling System) based on validation of the secure assembly and delivery of the IHS. A validation process of the IHS is initialized that delays further booting of the IHS until detected hardware components of the IHS are validated. An inventory certificate is retrieved that was uploaded to the IHS during factory provisioning of the IHS. The inventory certificate includes an inventory that identifies hardware components installed during factory assembly of the IHS. A collected inventory of detected hardware components of the IHS is compared against the inventory from the inventory certificate in order to validate the detected hardware components of the IHS as the same hardware components installed during factory assembly of the IHS. When the comparison validates the detected hardware components of the IHS as only including factory assembled hardware, further booting of the IHS is allowed.

A method for controlling a technical system, in particular of a motor vehicle.

To enhance the scaling of data processing systems in a computing environment, a number of data objects indicated in an allocation queue and a first attribute of the allocation queue are determined, where the allocation queue is accessible to a plurality of data processing systems. A number of data objects indicated in the allocation queue at a subsequent time is predicted based on the determined number of data objects and the first attribute. It is determined whether the active subset of the plurality of data processing systems satisfies a criterion for quantity adjustment based, at least in part, on the predicted number of data objects indicated in the allocation queue and a processing time goal. Based on determining that the active subset of data processing systems satisfies the criterion for quantity adjustment, a quantity of the active subset of data processing systems is adjusted.

The invention is part of the field of computer technology. It describes the architecture of a secure automation system and a method for safe autonomous operation of a technical apparatus, in particular a motor vehicle. The architecture disclosed herein solves the problem that any Byzantine error in one of the complex subsystems of a distributed real-time computer system, regardless of whether the error was triggered by a random hardware failure, a design error in the software or an intrusion, must be recognized and controlled in such a way that no security-relevant incident occurs. The architecture includes four largely independent subsystems which are arranged hierarchically and each form an isolated Fault-Containment Unit (FCU). At the top of the hierarchy is a secure subsystem, which executes simple software on fault-tolerant hardware. The other three subsystems are insecure because they contain complex software executed on non-fault-tolerant hardware.

The invention is part of the field of computer technology. It describes the architecture of a secure automation system and a method for safe autonomous operation of a technical apparatus, in particular a motor vehicle. The architecture disclosed herein solves the problem that any Byzantine error in one of the complex subsystems of a distributed real-time computer system, regardless of whether the error was triggered by a random hardware failure, a design error in the software or an intrusion, must be recognized and controlled in such a way that no security-relevant incident occurs. The architecture includes four largely independent subsystems which are arranged hierarchically and each form an isolated Fault-Containment Unit (FCU). At the top of the hierarchy is a secure subsystem, which executes simple software on fault-tolerant hardware. The other three subsystems are insecure because they contain complex software executed on non-fault-tolerant hardware.

Various embodiments relate to power reset. A system may include a first power source, a second power source, and a load coupled to the first power source and the second power source. The system may also include a modem configured to generate a signal responsive to receipt of a control signal. Further, the system may include circuitry coupled to the modem and configured to, responsive to receipt of the signal, open a first switch to disconnect the load from the first power source and open a second switch to disconnect the load from the second power source. Associated methods and mobile units are also disclosed.

Various embodiments relate to power reset. A system may include a first power source, a second power source, and a load coupled to the first power source and the second power source. The system may also include a modem configured to generate a signal responsive to receipt of a control signal. Further, the system may include circuitry coupled to the modem and configured to, responsive to receipt of the signal, open a first switch to disconnect the load from the first power source and open a second switch to disconnect the load from the second power source. Associated methods and mobile units are also disclosed.