Embodiments disclosed herein generally relate to line-powered wireless communications systems, and more specifically to methods and apparatus for providing persistent and ubiquitous wireless communications and sensor networks in physical premises to enable a wide variety of different applications and use cases.

Embodiments disclosed herein generally relate to line-powered wireless communications systems, and more specifically to methods and apparatus for providing persistent and ubiquitous wireless communications and sensor networks in physical premises to enable a wide variety of different applications and use cases.

Embodiments disclosed herein generally relate to line-powered wireless communications systems, and more specifically to methods and apparatus for providing persistent and ubiquitous wireless communications and sensor networks in physical premises to enable a wide variety of different applications and use cases.

A method and an apparatus for enhancing user experience while performing an event using a plurality of devices connected to each other is provided. The method includes analyzing an event extracted from an input received by the device, identifying the at least one task to be performed based on the analyzing of the event, generating a workflow corresponding to the identified at least one task, selecting at least one node of the workflow corresponding to the generated workflow, and performing an action, by an application installed in or connected to the device, in response to a the selection of at least one node of the workflow.

Various embodiments comprise systems, methods, architectures, mechanisms and apparatus for enabling dynamic configuration of CBSD devices with CBRS spectrum grants defined/sized using enhanced SAS channel assignment capabilities supporting low bandwidth channels/applications (e.g., IoT services) in the shared spectrum while minimizing spectrum wastage. Existing CBSD-SAS call flow message exchange and registration data specifications are modified in accordance with various embodiments to provide support for radio types having spectrum requirements less than the nominal minimum channel size.

The invention provides AI/Machine Learning frameworks i.e., a Workbench, (FIG. 2 (213)) with intelligences and modelling methods to address What-If scenarios(FIG. 2 (220)), users can devise specific studies (FIG. 3 (313)) with workbench to build and train models, ML workbench (FIG. 2 (213)) thus provides both domain-specific standard analytics as well as user-defined scenarios, while assisting the user to optimize their model performance, the seamless user Interface provides best-in-class visualization (FIG. 2 (226)) and dashboards (FIG. 2 (225)), while also enabling collaborative information specifics exchange (FIG. 9) and workflows across disciplines.

The invention discloses a SMART, portable internet of thing (IoT) based device and/or system to monitor various key parameters automatically, in a given operating area or operating system in various application fields, which automatically performs multiple monitoring functions such as sampling, measuring, analyzing, reporting and stabilizing key controllable parameters and there auto-maintain these parameters as per desired level. The SMART, portable device and system of the invention can be used in many applications in various fields such as Bio-Medical, Agriculture, Waste Treatment, Distilleries, RO Plants, etc, to name a few, where maintaining the key parameters like, pH, EC, Temperature, etc, are key for higher yields and/or efficient/smooth functioning and there these key parameters are required to be controlled.

An electronic device may include: a communication module; a processor operatively connected to the communication module; and a memory operatively connected to the processor and configured to store computer program code. The computer program code, when executed, enables the processor to: upon detection of execution of a first operation of a first Internet of Things (IoT) device, obtain, from the memory, a first instruction to operate the first IoT device in a second operation; transmit the first instruction to the first IoT device to operate the first IoT device in the second operation; and monitor execution of the second operation by the first IoT device.

Various embodiments comprise systems, methods, architectures, mechanisms and apparatus for enabling dynamic configuration of CBSD devices with CBRS spectrum grants defined/sized using enhanced SAS channel assignment capabilities supporting low bandwidth channels/applications (e.g., IoT services) in the shared spectrum while minimizing spectrum wastage. Existing CBSD-SAS call flow message exchange and registration data specifications are modified in accordance with various embodiments to provide support for radio types having spectrum requirements less than the nominal minimum channel size.

A method and a system for providing one or more services to one or more user devices [202] in an IoT network in a scalable M2M (Machine to Machine) framework. The method comprises receiving a connection request from the one or more user devices [202] at a load balance of the IoT network, the connection request comprises at least a username comprising a cluster identifier. The load balancer [204] determines a cluster identifier based on the connection request and identifies at least one target cluster from the one or more clusters [206], said target cluster being associated with the identifier cluster identifier. The load balancer [204] routes the connection request to the at least one target cluster to provide the one or more services to the one or more user devices [202].