An apparatus may be configured to be mounted on a rack. The apparatus may include a communication component. The communication component may be used for communicating with a network device when the network device is mounted on the rack. The apparatus may include a storage device. The storage device may be used for storing information to be provided to the network device, via the communication component, when the network device is mounted on the rack.

A disclosed example includes: a resource utilization analyzer to determine 1) first workloads of a first workload type deployed in a first server room in a data center, and 2) second workloads of a second workload type deployed in the first server room; a workload authorizer to determine that first virtual machines executing the first workloads and second virtual machines executing the second workloads cause a first server rack to generate an amount of heat; and a migrator to migrate the first virtual machines from the first server rack of the first server room to a second server rack of a second server room in the data center to reduce a temperature in the first server room based on the amount of heat, the migrator to migrate the first virtual machines to the second server rack without migrating the second virtual machines to the second server rack.

A server node connection system uses two or more proximity sensors per server node to determine progressive, real time changes in wipe length for each individual connector on the node that is connected to an opposing header connector on header connected to a midplane of the server assembly/rack. The system is capable of scanning, monitoring, trending, and alarming.

A dynamic information tag is disclosed for performing a dynamic information tag operation. The dynamic information tag includes a tag housing, the tag housing being sized to fit within a recess of an information handling system configured for receipt of a static information tag; a control and connection portion; and, a display coupled to the control and connection portion, the display being controlled via the control and connection portion to present information handling system information.

A storage system that supports independent scaling of compute resources and storage resources, the storage system including: one or more chassis, wherein each chassis includes a plurality of slots, each slot configured to receive a blade; a plurality of compute resources; a plurality of storage resources; a plurality of blades, where each blade includes at least one compute resource or at least one storage resource and each of the storage resources may be directly accessed by each of the compute resources without utilizing an intermediate compute resource; a first power domain configured to deliver power to one or more of the compute resources; and a second power domain configured to deliver power to the storage resources, wherein the first power domain and the second power domain can be independently operated.

A resource circuit board is configured for use by a physical migration system, the resource circuit board including at least one common interface shaped and configured to connect to an interconnect of a base circuit board; and at least one migration-support interface the at least one common interface being different from the at least one migration-support interface, the at least one migration-support interface: shaped to connect to at least one corresponding migration-support interface of the physical migration system; and configured to provide at least one of power and connectivity to the resource circuit board during a physical migration of the resource circuit board.

Provided is a rack, comprising: a plurality of rack units; and a plurality of lockers each housing a different respective subset of the rack units, wherein respective lockers among the plurality comprise: a first respective barrier disposed between a respective pair of the rack units; a second respective barrier disposed between another respective pair of the rack units; a third respective barrier that is orthogonal to the first barrier and the second barrier, the third respective barrier being moveably or removeably coupled to the rack; a respective volume configured to receive one or more computing devices; and a respective lock configured to secure the third respective barrier to the rack in the closed position when in a locked state.

Technologies for allocating resources of managed nodes to workloads to balance multiple resource allocation objectives include an orchestrator server to receive resource allocation objective data indicative of multiple resource allocation objectives to be satisfied. The orchestrator server is additionally to determine an initial assignment of a set of workloads among the managed nodes and receive telemetry data from the managed nodes. The orchestrator server is further to determine, as a function of the telemetry data and the resource allocation objective data, an adjustment to the assignment of the workloads to increase an achievement of at least one of the resource allocation objectives without decreasing an achievement of another of the resource allocation objectives, and apply the adjustments to the assignments of the workloads among the managed nodes as the workloads are performed. Other embodiments are also described and claimed.

In some examples, a method includes: determining workload constraints for placement of information technology (IT) equipment within a data center; determining physical constraints for placement of the IT equipment; inferring hardware placement capabilities of IT equipment racks within the data center; and generating a ranked list of locations for IT equipment placement within the data center based on the determined workload constraints, determined physical constraints, and inferred hardware placement capabilities.

Configurations for rack communication systems are disclosed. In at least one embodiment, a non-contact communication signal is formed between a rack and an installed component.