Abstract: Systems and methods are provided for arbitrating sensor and actuator signals in various devices. One system includes input/output (I/O) circuitry, redundant computation circuits coupled to the I/O circuitry, and an arbitration circuit coupled between the I/O circuitry and the redundant computation circuits. The I/O circuitry is configured to be coupled to multiple non-redundant systems, and the redundant computation circuits are configured to be coupled to one of multiple system buses. One such device is an aircraft including multiple non-redundant systems and a plurality of system buses that are configured to transmit redundant messages to the non-redundant systems.

Abstract: A modular rack-level server and storage framework is disclosed. The modular rack system includes a plurality of chassis placed in one or more racks and a plurality of sleds placed in each chassis. Each sled includes an information handling system, a shared fan module, a shared power module, and a shared management module. The shared fan module cools the plurality of sleds in each chassis and the shared power module supplies power to one or more sleds in one or more chassis. The shared management module manages the operation of the plurality of chassis.

Abstract: A remote data access device and a remote data access method are provided. The remote data access device comprises: a storing module, a first controller and a second controller. The first controller comprises a first odd and a first even access queue. The second controller comprises a second odd and a second even access queue. The first and the second controller have the same MAC and IP addresses. The first and the second odd access queues receive the same odd remote access requests and the first and the second even access queues receive the same even remote access requests, the first controller performs a data access operation on the storing module according to the odd remote access requests in the first odd access queue and the second controller perform a data access operation on the storing module according to the even remote access requests in the second even access queue.

Abstract: The invention relates to a method and a device for exchanging data on the basis of the OPC communications protocol, wherein at least one OPC-ready server is connected parallel to a master OPC server. an OPC client is connected to the master OPC server over a first communications link and to at least one OPC-ready server via at least one second communications link. The OPC client exchanges data over the first communications link and the master OPC server, and over at least the second communications link and at least one OPC-ready server with automatic devices, and evaluates the data transmitted by the master OPC server and at least one OCT-ready server. In the event of failure, the master OPC server is at least partially switched over from the OPC client to at least one OPC-ready server such that the program continues to run smoothly in the same place.

Abstract: An equipment controlling system and a controlling method thereof are disclosed. The system includes a first controller connected to equipments of a first group to monitor and control operations of the equipments; and a second controller connected to equipments of a second group to monitor and control operations of the equipments; the first controller emergently controlling the equipments of the second group when the second controller malfunctions, and the second controller emergently controlling the equipments of the second group when the first controller malfunctions. When control problem of equipments such as indoor and outdoor unit due to malfunction of a controller is solved, a systemic and consistent control are enabled by consistently controlling the equipments so that control efficiency is enhanced and the equipments are kept in operating to provide a comfortable condition and an improved convenience to a user.

Abstract: A system and method is disclosed for system fault recovery by an implantable medical device which employs a global fault response. The system enables the device to consistently recover from transient faults while maintaining a history of the reason for the device fault. Upon detection of a fault, the primary controller of the device signals a reset controller which then issues a reset command. All sub-systems of the primary device controller are then reset together rather than resetting individual sub-systems independently to ensure deterministic behavior.