Examples may include techniques to allocate physical accelerator resources from pools of accelerator resources. In particular, virtual computing devices can be composed from physical resources and physical accelerator resources dynamically allocated to the virtual computing devices. The present disclosure provides that physical accelerator resources can be dynamically allocated, or composed, to a virtual computing device despite not being physically coupled to other components in the virtual device.

A grounding clip for a plug-in universal (PIU) module enclosure in an optical network element includes a first wing portion shaped to be positioned between and in contact with a first side of a faceplate of the network element and the chassis, a second wing portion shaped to be positioned between and in contact with a second side of the faceplate and the chassis, and a center portion shaped to extend over and to be in contact with the PIU module enclosure when the grounding assembly is installed in the network element. The grounding clip includes an opening through which a fastener electrically and mechanically couples the grounding clip to a printed circuit board (PCB) and to the chassis when installed, the PCB being installed within the chassis and configured to be communicably coupled to a PIU module when the PIU module is installed in the PIU module enclosure.

A grounding clip for a plug-in universal (PIU) module enclosure in an optical network element includes a first wing portion shaped to be positioned between and in contact with a first side of a faceplate of the network element and the chassis, a second wing portion shaped to be positioned between and in contact with a second side of the faceplate and the chassis, and a center portion shaped to extend over and to be in contact with the PIU module enclosure when the grounding assembly is installed in the network element. The grounding clip includes an opening through which a fastener electrically and mechanically couples the grounding clip to a printed circuit board (PCB) and to the chassis when installed, the PCB being installed within the chassis and configured to be communicably coupled to a PIU module when the PIU module is installed in the PIU module enclosure.

An information handling system for managing equipment in a datacenter captures image data when a field of view of an imaging system includes a server rack, establishes a wireless communication link with a first element of the datacenter equipment via the wireless communication interface, receives information defining a first network connection between the first element and a second element of the datacenter equipment based upon the establishing of the wireless communication link, and displays an augmented reality overlay on the display over the image data. The augmented reality overlay identifies a first network connector of the first element. The first network connector is first connector of the first network connection.

Disclosed is a line card chassis which includes line card units, optical electrical conversion units and optical fiber interface units. The optical-electrical conversion unit has an onboard optical assembly module used for mutual conversion between an optical signal and an electrical signal; an electrical signal interface of the onboard optical assembly module is connected to the line card unit through an electrical connector, and an optical signal interface of the onboard optical assembly module is connected to the optical fiber interface unit through an optical connector; and the optical fiber interface unit couples the optical signal to a cluster interface of a panel on a router through an optical fiber, and the cluster interface is to concatenate different chassis in the router. Also disclosed is a multi-chassis cluster router and a packet processing method.

Disclosed is a line card chassis which includes line card units, optical electrical conversion units and optical fiber interface units. The optical-electrical conversion unit has an onboard optical assembly module used for mutual conversion between an optical signal and an electrical signal; an electrical signal interface of the onboard optical assembly module is connected to the line card unit through an electrical connector, and an optical signal interface of the onboard optical assembly module is connected to the optical fiber interface unit through an optical connector; and the optical fiber interface unit couples the optical signal to a cluster interface of a panel on a router through an optical fiber, and the cluster interface is to concatenate different chassis in the router. Also disclosed is a multi-chassis cluster router and a packet processing method.

Technologies for allocating resources of a set of managed nodes to workloads to manage heat generation include an orchestrator server to receive resource allocation objective data including a target temperature for one or more of the managed nodes. The orchestrator server is also to determine an initial assignment of a set of workloads among the managed nodes, receive telemetry data from the managed nodes indicative of resource utilization by each of the managed nodes and one or more temperatures and fan speeds of the managed nodes as the workloads are performed, predict future heat generation of the workloads as a function of the telemetry data, determine, as a function of the predicted future heat generation, an adjustment to the assignment of the workloads to achieve the target temperature, and apply the adjustments to the assignments of the workloads among the managed nodes as the workloads are performed.

Technologies for allocating resources of a set of managed nodes to workloads to manage heat generation include an orchestrator server to receive resource allocation objective data including a target temperature for one or more of the managed nodes. The orchestrator server is also to determine an initial assignment of a set of workloads among the managed nodes, receive telemetry data from the managed nodes indicative of resource utilization by each of the managed nodes and one or more temperatures and fan speeds of the managed nodes as the workloads are performed, predict future heat generation of the workloads as a function of the telemetry data, determine, as a function of the predicted future heat generation, an adjustment to the assignment of the workloads to achieve the target temperature, and apply the adjustments to the assignments of the workloads among the managed nodes as the workloads are performed.

Technologies for managing the efficiency of workload execution in a managed node include a managed node that includes one or more processors that each include multiple cores. The managed nodes is to execute threads of workloads assigned to the managed node, generate telemetry data indicative of an efficiency of execution of the threads, determine, as a function of the telemetry data, an adjustment to a configuration of the threads among the cores to increase the efficiency of the execution of the threads, and apply the determined adjustment. Other embodiments are also described and claimed.

Technologies for managing the efficiency of workload execution in a managed node include a managed node that includes one or more processors that each include multiple cores. The managed nodes is to execute threads of workloads assigned to the managed node, generate telemetry data indicative of an efficiency of execution of the threads, determine, as a function of the telemetry data, an adjustment to a configuration of the threads among the cores to increase the efficiency of the execution of the threads, and apply the determined adjustment. Other embodiments are also described and claimed.