Smart sensors, platforms for smart sensors, and associated systems and methods, are disclosed herein. In some implementations, the platform includes hardware interfaces that are abstracted and/or standardized as defined by various common group types. The abstracted interfaces allow numerous different sensors to be connected and integrated into the smart sensor as desired for a specific application. Further, the platform can reuse a standardized software backbone as a sensor platform as sensors are varied, as well as across multiple smart sensors. In some implementations, the standardized sensor platform can include an on-board resident user interface (RUI) with an internet-accessible portal, allowing users to connect to the RUI on the sensor platform through any network accessible device. The platform can also include an artificial intelligence and/or machine learning engine to turn raw sensor data into real-time automation and inspection information within the sensor within the local environment.

Examples described herein relate to a network interface device that includes circuitry and a memory. In some examples, the circuitry is to perform image construction operations, wherein the image construction operations comprise access to a base image of an application from the memory in the network interface device. In some examples, the circuitry is to provide a host server access to a constructed image bundle of the application.

A method is provided for determining an installation location. The method includes: providing a machine-readable description of the application to be installed; enhancing the machine-readable description with further requirements and/or properties; linking the application to be installed with an object identifier which includes the enhanced description and the requirements and/or properties of the application to be installed; linking objects existing in the distributed network environment with, in each case, at least one further object identifier which describes at least one property of an object; storing the object identifiers of the application to be installed and of the objects in the distributed network environment in a database; receiving a query regarding the application to be installed; providing the stored object identifiers of the application to be installed and of the objects for an evaluation unit; and receiving a determined appropriate installation location from the evaluation unit.

A method is provided for determining an installation location. The method includes: providing a machine-readable description of the application to be installed; enhancing the machine-readable description with further requirements and/or properties; linking the application to be installed with an object identifier which includes the enhanced description and the requirements and/or properties of the application to be installed; linking objects existing in the distributed network environment with, in each case, at least one further object identifier which describes at least one property of an object; storing the object identifiers of the application to be installed and of the objects in the distributed network environment in a database; receiving a query regarding the application to be installed; providing the stored object identifiers of the application to be installed and of the objects for an evaluation unit; and receiving a determined appropriate installation location from the evaluation unit.

Implementations of the present disclosure are generally directed to activating features in power machines. More particularly, implementations of the present disclosure are directed to remote activation of features in power machines. Implementations include, methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for transmitting a request for an initialization indicator for a software package from an initialization system of a power machine comprising hardware physically capable of executing at least one function, the request being transmitted, by a communication link of the initialization system, from a machine controller of the initialization system to a remote system, communicating, by the communication link, the initialization indicator from the remote system to the machine controller, and in response to receiving the initialization indicator: storing, by the machine controller, the initialization indicator, and executing, by the machine controller, the software package to control the at least one function.

Disclosed are various examples of provisioning a data processing unit (DPU) management operating system (OS). A management hypervisor installer executed on a host device launches or causes a server component to provide a management operating system (OS)installer image at a particular URI accessible over a network internal to the host device. A baseboard management controller (BMC) transfers the DPU management OS installer image to the DPU device. A volatile memory based virtual disk is created using the DPU management OS installer image. The DPU device is booted to a DPU management OS installer on the volatile memory based virtual disk. The DPU management OS installer installs a DPU management operating system to a nonvolatile memory of the DPU device on reboot of the DPU device.

Disclosed are various examples of provisioning a data processing unit (DPU) management operating system (OS). A management hypervisor installer executed on a host device launches or causes a server component to provide a management operating system (OS)installer image at a particular URI accessible over a network internal to the host device. A baseboard management controller (BMC) transfers the DPU management OS installer image to the DPU device. A volatile memory based virtual disk is created using the DPU management OS installer image. The DPU device is booted to a DPU management OS installer on the volatile memory based virtual disk. The DPU management OS installer installs a DPU management operating system to a nonvolatile memory of the DPU device on reboot of the DPU device.

Embodiments of the present disclosure relate to systems and methods for creating logical groups of packages by tagging individual packages with a tag associated with metadata corresponding to packages that are part of the group. A group of packages may be defined from a plurality of packages that make up an application ecosystem using the tag. A command to perform a first operation of a set of operations performed by the package manager on the group of packages may be provided to a package manager, wherein the command may reference the tag and wherein the package manager is modified to perform each of the set of operations on one or more of the plurality of packages simultaneously. The first operation may be performed by the package manager on the group of packages simultaneously using the metadata to identify each package that is part of the group.

Embodiments of the present disclosure relate to systems and methods for creating logical groups of packages by tagging individual packages with a tag associated with metadata corresponding to packages that are part of the group. A group of packages may be defined from a plurality of packages that make up an application ecosystem using the tag. A command to perform a first operation of a set of operations performed by the package manager on the group of packages may be provided to a package manager, wherein the command may reference the tag and wherein the package manager is modified to perform each of the set of operations on one or more of the plurality of packages simultaneously. The first operation may be performed by the package manager on the group of packages simultaneously using the metadata to identify each package that is part of the group.

Techniques are described for performing browser-driven application capture of application installations. When the browser on the client machine detects a request to begin an application capture session, it downloads an orchestrator binary from an origin server. The orchestrator is a self-extracting executable that decompresses components responsible for preparing the client machine for the application capture session. Preparing the client machine includes starting a local web server, executing a registry script to create the necessary registry state, mounting a virtual disk, and deploying an agent that will record state changes on the client machine. Once the client machine has been prepared, the application installation can begin. During the installation process, the agent intercepts state changes occurring on the client machine and redirects them to the virtual disk. Once finished, the application capture session is completed by adding identity and metadata information to the virtual disk to generate the application package.