Abstract: Technologies for dynamically allocating resources among a set of managed nodes include an orchestrator server to receive telemetry data from the managed nodes indicative of resource utilization and workload performance by the managed nodes as the workloads are executed, generate a resource allocation map indicative of allocations of resources among the managed nodes, determine, as a function of the telemetry data and the resource allocation map, a dynamic adjustment to allocation of resources to at least one of the managed nodes to improve performance of at least one of the workloads executed on the at least one of the managed nodes, and apply the adjustment to the allocation of the resources among the managed nodes as the workloads are executed. Other embodiments are also described and claimed.

Abstract: Aspects of the present disclosure include methods, apparatus, and computer readable medium for storing encrypted data including receiving a radio frequency signal and data to be encrypted, identifying a radio frequency fingerprint of the signal, generating a numerical representation of the radio frequency fingerprint, generating an encryption key using at least a portion of the representation, encrypting the data using the encryption key, and storing the encrypted data.

Abstract: 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.

Abstract: Systems described herein operate to improve network performance in a multi-tenant cloud computing environment. Systems can include communication circuitry and processing circuitry to generate a phase sequence matrix that indicates the identity and number of phases of a workload by measuring resources of the compute node during execution of the workload throughout a lifetime of the workload. The processing circuitry can generate a workload fingerprint that includes the phase sequence matrix and a phrase residency matrix. The phase residency matrix can indicate the fraction of execution time of the workload spent in each phase identified in the phase sequence matrix. A cloud controller can access the workload fingerprint for multiple workloads operating on multiple compute nodes in the cloud cluster to adjust workload allocations based at least on these workload fingerprints and on whether service level objectives (SLOs) are being met.

Abstract: Technologies for encrypted data access by field-programmable gate array (FPGA) user kernels include a computing device having an FPGA and an external memory device accessible by the FPGA. The FPGA includes a secure key store, a micro-encryption engine, and multiple slots for user kernels that are each identifiable with an index. A user kernel is programmed at an index and a symmetric encryption key is provisioned to the secure key store at the index. The micro encryption engine may read encrypted data from the external memory device, decrypt the encrypted data with the key associated with the index of the user kernel, and forward plain text data to the user kernel. The micro encryption engine may also receive plain text data from the user kernel, encrypt the plain text data with the key, and write the encrypted data to the external memory device. Other embodiments are described and claimed.

Abstract: Apparatuses and methods for providing change of custody signaling in a wireless sensor network are disclosed herein. In embodiments, an apparatus for providing transfer of custody signaling in a wireless sensor network (WSN) may be provided. The apparatus may include communications circuitry to interact with a cloud server to receive an instruction regarding a change of custody for at least one sensor node within a WSN, the at least one sensor node assigned to the apparatus for tracking, and the instruction may identify a second apparatus within the WSN to assume custody of the at least one sensor. The apparatus may further include a control unit coupled to the communications circuitry to signal the second apparatus and the at least one sensor node regarding the transfer of custody, wherein the signaling is over a wireless protocol of the WSN.

Abstract: Lost, misplaced, incorrectly delivered, and damaged assets are a common occurrence in shipment or asset tracking. Disclosed are various embodiments concerning a battery-less or intermittent battery use environments in which a node uses internal logic (e.g., circuitry and/or software) that, based at least in part on sensor information and stored information regarding the history of the node, may track events that have occurred to the node. The node may be responsive to events and determine whether exceptions have occurred that require attention. For example, detecting damage might cause the node to update an output to indicate the node and associated material, if any, needs to be rerouted to address the exception.

Abstract: A control system for a vehicle and method for controlling a vehicle component. The control system includes a sensor and a controller. The sensor senses vibrations of the vehicle and senses alterations to the vibrations that result from user contact with a handle of the vehicle. The alterations are associated with a particular vehicle component and/or a particular predetermined function to be performed by the vehicle component. The controller receives an indication of the vibrations and the alterations from the sensor, and then causes the vehicle component to perform the predetermined function that is associated with the alterations.

Abstract: Technologies for allocating resources of a set of managed nodes to workloads based on resource utilization phase residencies include an orchestrator server to receive resource allocation objective data and determine an assignment of a set of workloads among the managed nodes. The orchestrator server is further to receive telemetry data from the managed nodes, determine, as a function of the telemetry data, phase residency data, determine, as a function of at least the phase residency 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 the achievement of any of the other resource allocation objectives, and apply the adjustment to the assignments of the workloads among the managed nodes as the workloads are performed.

Abstract: A blade computing system is described with a wireless communication between blades. In one embodiment, the system includes a first blade in the enclosure having a radio transceiver to communicate with a radio transceiver of a second blade in the enclosure. The second blade has a radio transceiver to communicate with the radio transceiver of the first blade. A switch in the enclosure communicates with the first blade and the second blade and establishes a connection through the respective radio transceivers between the first blade and the second blade.

Abstract: In accordance with some embodiments, a cloud service provider may operate a data center in a way that dynamically reallocates resources across nodes within the data center based on both utilization and service level agreements. In other words, the allocation of resources may be adjusted dynamically based on current conditions. The current conditions in the data center may be a function of the nature of all the current workloads. Instead of simply managing the workloads in a way to increase overall execution efficiency, the data center instead may manage the workload to achieve quality of service requirements for particular workloads according to service level agreements.

Abstract: Aspects of the present disclosure include methods, apparatus, and computer readable medium for storing encrypted data including receiving a radio frequency signal and data to be encrypted, identifying a radio frequency fingerprint of the signal, generating a numerical representation of the radio frequency fingerprint, generating an encryption key using at least a portion of the representation, encrypting the data using the encryption key, and storing the encrypted data.

Abstract: This disclosure describes a vehicle system for identifying environmental objects within an operator's surroundings in a first window and removing object obstructions through a neural network in a second window to generate a rendered window, or scene, for display. As more windows are processed, the neural network may increase its understanding of the surroundings. The neural network may be a generative adversarial network (GAN) that may be trained to identify environmental objects by introducing noise data into those environmental objects. After receiving a first window from at least one camera on the vehicle, a rendered window may be created from a second window received from the at least one camera based on environmental objects identified within the first window through the GAN and removing object obstructions. The rendered window, without the object obstructions, and having superimposed environmental objects based on the GAN, may be displayed on an output device.

Abstract: A blade computing system is described with a wireless communication between blades. In one embodiment, the system includes a first blade in the enclosure having a radio transceiver to communicate with a radio transceiver of a second blade in the enclosure. The second blade has a radio transceiver to communicate with the radio transceiver of the first blade. A switch in the enclosure communicates with the first blade and the second blade and establishes a connection through the respective radio transceivers between the first blade and the second blade.

Abstract: A haptic feedback system for a vehicle having a first handlebar and a second handlebar that provides data from the vehicle to an operator of the vehicle includes a data module for collecting data to be communicated to the operator of the vehicle, a wireless communication module for transmitting the data to be communicated to the operator of the vehicle, and at least one glove worn by the operator. The glove includes a wireless communication receiver for receiving the data transmitted by the wireless communication module, and a haptic communication apparatus in a wrist portion of the glove. The haptic communication apparatus conveys the data received by the wireless communication receiver to the operator, and a battery in the glove provides power to the wireless communication receiver and the haptic communication apparatus.

Abstract: Technologies for assigning workloads based on resource utilization phases include an orchestrator server to assign a set of workloads to the managed nodes. The orchestrator server is also to receive telemetry data from the managed nodes and identify, as a function of the telemetry data, historical resource utilization phases of the workloads. Further, the orchestrator server is to determine, as a function of the historical resource utilization phases and as the workloads are performed, predicted resource utilization phases for the workloads, and apply, as a function of the predicted resources utilization phases, adjustments to the assignments of the workloads among the managed nodes as the workloads are performed.

Abstract: An embodiment of network coordinator apparatus may include a node provisioner to provision each of a plurality of low power nodes, a node associater to create a first association for each of the plurality of lower power nodes, and a node coordinator communicatively coupled to the node provisioner and the node associater to coordinate the plurality of lower power nodes.

Abstract: A method for distributing at least one computational process amongst shared resources is proposed. At least two shared resources capable of performing the computational process are determined. According to the method, a workload characteristic for each of the shared resources is predicted. The workload characteristic accounts for at least two subsystems of each shared resource. One of the at least two shared resources is selected based on the predicted workload characteristics.

Abstract: Lost, misplaced, incorrectly delivered, and damaged assets are a common occurrence in shipment or asset tracking. Disclosed are various embodiments concerning a battery-less or intermittent battery use environments in which a node uses internal logic (e.g., circuitry and/or software) that, based at least in part on sensor information and stored information regarding the history of the node, may track events that have occurred to the node. The node may be responsive to events and determine whether exceptions have occurred that require attention. For example, detecting damage might cause the node to update an output to indicate the node and associated material, if any, needs to be rerouted to address the exception.

Abstract: Apparatuses and methods for providing change of custody signaling in a wireless sensor network are disclosed herein. In embodiments, an apparatus for providing transfer of custody signaling in a wireless sensor network (WSN) may be provided. The apparatus may include communications circuitry to interact with a cloud server to receive an instruction regarding a change of custody for at least one sensor node within a WSN, the at least one sensor node assigned to the apparatus for tracking, and the instruction may identify a second apparatus within the WSN to assume custody of the at least one sensor. The apparatus may further include a control unit coupled to the communications circuitry to signal the second apparatus and the at least one sensor node regarding the transfer of custody, wherein the signaling is over a wireless protocol of the WSN.