This invention relates to a method of building a hybrid quantum-classical computing network, comprising: a first step of transformation of an application composed of services into a Petri net including both Petri places (8, 9) and Petri transitions (81, 82, 91-94) between said Petri places (8, 9), any said Petri place (8, 9) corresponding to: either a first type building block corresponding to any quantum processing unit (8) which processes a job into a result, or a second type building block corresponding to any plugin unit (9), which converts a job into another job and/or a result into another result, any Petri transition (81, 82, 91-94) corresponding to any link between two building blocks (8, 9), all said links (81, 82, 91-94) being formatted so as to make any building block (8, 9) interchangeable, a second step of transformation of said Petri net into a hybrid quantum-classical computing network, replacing any building block by its corresponding unit (8, 9), interconnecting all said corresponding units (8, 9) together by replacing any Petri transition (81, 82, 91-94) by a connection simply transmitting without processing nor converting.

Implementations generally relate methods, systems, and computer readable media for providing automatic access point registration. In some implementations, a method includes receiving an indication of automatic device onboarding activation. The method further includes receiving a selection of one or more reference devices. The method further includes determining one or more detectable devices of the one or more candidate devices to be onboarded that are detectable by at least one of the one or more reference devices. The method further includes obtaining one or more automatic configuration parameters from one or more of the reference devices. The method further includes configuring one or more of the detectable devices to be onboarded with the one or more automatic configuration parameters.

A remote user can specify data collection and processing characteristics of a wireless sensor network. In one example, a configuration station enables a user to activate/deactivate different sensor channels of data to support a delivery of data streams to customers. In another example, a configuration station enables a user to specify reporting intervals for different sensor channels of data. In yet another example, a configuration station enables a user to specify transformation functions for different sensor channels of data. The remote configuration process can be applied to every sensor in every sensor module unit attached to every wireless node at a monitored location.

A system, method, and computer program product are provided for accessing a device connected to a network. In operation, a device connected to a network is accessed by multiplexing and demultiplexing multiple connections.

Techniques for automatically configuring necessary parameters of a device to be coupled to a network with minimum human intervention are disclosed. In one embodiment, a wired and/or wireless Ad-hoc network is established to facilitate communications among a group of devices. When a new device is added to the network, a rudimentary communication path is initially established between one of the devices in the network and the new device such that necessary parameters (e.g., SSID, WEP security, channel frequency) can be exchanged for the new device to function properly in the network. To ensure the parameters are exchanged in a secure fashion, an additional public security procedure can be used between the two devices.

A variety of kits are provided that are configured with components, systems and methods for monitoring various industrial settings, including kits with self-configuring sensor networks, communication gateways, and automatically configured back end systems.

Systems herein allow an administrator to efficiently enroll computing devices into a mobile device management system, even when those computing devices are offline and not connected to the system. A management server can include a console that allows the administrator to enroll an offline computing device by selecting an offline enrollment option on a registration record. This option can cause the management server to create a device record, indicating the computing device is enrolled. The management server can also create and save a provisioning file onto a storage device, such as a USB drive. Assets, such as graphics and applications, specified by the device record are also saved onto the storage device. The storage device can be physically connected to the computing device, at which point the provisioning file guides automatic installation of the assets and implementation of device settings and compliance rules specified by the device record.

The presentation of sensor network information can be provided to a user via a customized dashboard web interface. The dashboard web interface can be based on customized transformation and alert functions that can be applied to one or more sensor channels of data produced from sensors at a monitored location. The customized alerts can provide real-time monitoring of targeted conditions at the monitored location.

A method includes deploying a network device within a fabric having a management network by attaching the network device through the management network to a port of a role allocator, wherein the role allocator includes one or more ports designated as first level port connections and one or more other ports designated as second level port connections. If the deployed network device is attached to one of the ports designated as first level port connections, the deployed network device is configured as a first level device. If the deployed network device is attached to one of the ports designated as second level port connections, the deployed network device is configured as a second level device.

A method and system for architecture analysis on IT assets of an enterprise is provided. An asset information of an enterprise is received. The asset information is associated with information of a plurality of Information Technology (IT) assets utilized in the enterprise. Interdependency of IT assets among the plurality of IT assets is determined. The interdependency is determined based at least in part, on similarity of one or more lines of codes of plurality of IT assets. A dependency map of the plurality of IT assets is determined based on the interdependency of IT assets among the plurality of IT assets.