Abstract: Systems and methods for incorporating a new channel-type value in the header of a Generic Associated Channel (G-ACh) for Connectivity Fault Management (CFM) Layer-2 packets over Multi-Protocol Label Switching (MPLS) networks are provided. The channel-type value of the G-ACh header may be used for identification of the network-generated CFM Layer-2 packets. In one implementation, a system may include a processing device and a memory device, where the memory device may be configured to store instructions that, when executed, cause the processing device to obtain a Connectivity Fault Management (CFM) packet, encapsulate the CFM packet with Pseudo-Wire (PW) and Label-Switched Path (LSP) labels to create an expanded packet, and incorporate a specific channel-type value in a G-ACh header of the expanded packet to uniquely identify the CFM packet.

Abstract: Systems and methods for incorporating a new channel-type value in the header of a Generic Associated Channel (G-ACh) for Connectivity Fault Management (CFM) Layer-2 packets over Multi-Protocol Label Switching (MPLS) networks are provided. The channel-type value of the G-ACh header may be used for identification of the network-generated CFM Layer-2 packets. In one implementation, a system may include a processing device and a memory device, where the memory device may be configured to store instructions that, when executed, cause the processing device to obtain a Connectivity Fault Management (CFM) packet, encapsulate the CFM packet with Pseudo-Wire (PW) and Label-Switched Path (LSP) labels to create an expanded packet, and incorporate a specific channel-type value in a G-ACh header of the expanded packet to uniquely identify the CFM packet.

Abstract: Example systems, methods, computer-readable media, and apparatuses for dynamic provisioning of wireless devices with health gateways are disclosed. One example method includes detecting, by a wireless device, a signal from a health gateway, the signal including connection information and service information; determining whether the health gateway is a suitable based on the connection information and the service information; and in response to determining that the health gateway is suitable, establishing a communications connection with the health gateway.

Abstract: Service availability determination systems and methods include determining availability of a packet service in a Maintenance Interval (MI) based on frame loss measurements in short intervals ?t and marking each ?t as available or unavailable based on the frame loss measurements and an associated Frame Loss Ratio (FLR) threshold, wherein each ?t is a High Loss interval (HLI) when exceeding the FLR threshold; utilizing a sliding window of size n, n being an integer, to determine whether the packet service is available or unavailable; and utilizing an extension period after an end of the MI with the sliding window to ensure all ?t's in the MI are marked as available or unavailable.

Abstract: Service availability determination systems and methods include determining availability of a packet service in a Maintenance Interval (MI) based on frame loss measurements in short intervals ?t and marking each ?t as available or unavailable based on the frame loss measurements and an associated Frame Loss Ratio (FLR) threshold, wherein each ?t is a High Loss interval (HLI) when exceeding the FLR threshold; utilizing a sliding window of size n, n being an integer, to determine whether the packet service is available or unavailable; and utilizing an extension period after an end of the MI with the sliding window to ensure all ?t' s in the MI are marked as available or unavailable.

Abstract: Methods and apparatuses for optimizing performance using data from an Internet of Things (IoT) device with analytics engines. The method receives, from a requesting Internet of Things (IoT) device, a request for trend data of physical resource consumption based at least in part on a portion of received data from at least one of a plurality of IoT devices. The method retrieves, from memory of an analytics engine, at least the portion of the received data. The method calculates, in a calculator of the analytics engine, the trend data based on at least the portion of the received data. The method transmits, to the requesting IoT device, the calculated trend data, wherein the requesting IoT device adjusts parameters in an IoT device using the calculated trend data.

Abstract: Disclosed is a method and apparatus for enhanced availability of network-assisted services. The method may include receiving, from at least one peripheral device, one or more provisioning requests to provide service to the at least one peripheral device. The method may also include determining whether to handle one or more provisioning requests based on capabilities of the mobile gateway. Furthermore, the method may include, in response to the determination to handle the one or more provisioning requests, requesting, from a server, at least one application based on the one or more provisioning requests, wherein the at least one application enables the mobile gateway to service the at least one peripheral device.

Abstract: Methods, systems, computer-readable media, and apparatuses for remote patient monitoring and event detection are presented. For example, one method includes receiving, by a computing device via wireless communication, one or more sensor signals from a sensor associated with a patient; obtaining a patient condition based on the one or more sensor signals using a trained machine-learning (“ML”) model; and responsive to detecting an emergency condition based on the patient condition, providing an indication of the emergency condition.

Abstract: Systems, methods, apparatuses, and non-transitory computer-readable media for micro and macro activity detection and monitoring are disclosed.

Abstract: Techniques described herein enable store-and-forward systems to hold data at source node (e.g., service platform) until they can be provided to the destination node e.g., user device). In other words, data can be buffered at the source node until the destination node is “online,” and the establishment of a connection between the destination node and the intermediate node can trigger the retrieval of this data from the source node by the intermediate node. Additional techniques may be implemented to ensure the data connection between the intermediate node in the destination node does not expire while data is being communicated from the source node to the intermediate node.

Abstract: Example systems, methods, computer-readable media, and apparatuses for dynamic provisioning of wireless devices with health gateways are disclosed. One example method includes detecting, by a wireless device, a signal from a health gateway, the signal including connection information and service information; determining whether the health gateway is a suitable based on the connection information and the service information; and in response to determining that the health gateway is suitable, establishing a communications connection with the health gateway.

Abstract: The disclosure relates to mechanisms that may be used to route notifications in an Internet of Things (IoT) environment according to user activity and/or proximity detection. More particularly, in various embodiments, an entity that manages the IoT environment may receive one or more messages, actions, or responses that indicate detected activity or detected proximity associated with one or more users from one or more IoT devices in the IoT environment. The management entity may then establish an activity and proximity trail from the one or more messages, actions, or responses that indicate the detected activity or the detected proximity, whereby in response to an IoT device reporting one or more notifications, an IoT device in proximity to at least one of the one or more users may be identified and the one or more notifications may be routed to the identified IoT device.

Abstract: A system and method for discovering services in an Internet of Things (IoT) environment are disclosed. The method may include providing service-feature information from a consumer app to a query service that is indicative of a service provided by a remotely located provider app and incorporating the service-feature information into resource records of an additional information section of a multicast domain name service (mDNS) message. The message is multicasted to other IoT devices, and a response message is received from at least one provider device. The additional information section of the response message is then analyzed to determine whether a service provided by the at least one provider device meets criteria defined by the service-feature information.

Abstract: Techniques described herein enable store-and-forward systems to hold data at source node (e.g., service platform) until they can be provided to the destination node e.g., user device). In other words, data can be buffered at the source node until the destination node is “online,” and the establishment of a connection between the destination node and the intermediate node can trigger the retrieval of this data from the source node by the intermediate node. Additional techniques may be implemented to ensure the data connection between the intermediate node in the destination node does not expire while data is being communicated from the source node to the intermediate node.

Abstract: The disclosure generally relates to enabling communication among one or more Internet of Things (IoT) device groups. In particular, various heterogeneous IoT devices that may need to interact with one another in different ways may be organized into IoT device groups to support efficient interaction among the IoT devices. For example, pre-defined IoT device groups may be formed organize certain IoT devices that perform similar activities and certain IoT devices may be dynamically allocated to ad-hoc IoT device groups for certain contexts (e.g., the ad-hoc IoT device groups may include IoT devices that can implement a desired function and therefore be dynamically formed to implement the desired function). Furthermore, the IoT groups may communicate hierarchically, wherein messages may be exchanged among IoT group owners or ranking members to support efficient communication between different IoT groups.

Abstract: The disclosure generally relates to Internet of Things (IoT) device social networking, and in particular to an IoT device publish-subscribe messaging model and automatic IoT device social network expansion. For example, IoT devices from different networks may publish status data that relates to certain topics, wherein the published status updates may be managed in a distributed manner at each IoT network. Furthermore, IoT devices interested in published data can subscribe to data relating to certain topics, which may be used to dynamically adjust actions that the subscribing IoT devices may take. Furthermore, IoT devices can employ common social networking capabilities (e.g., refer, follow, like, publish, subscribe, etc.) to interact with other IoT devices and find relevant information from other IoT devices that can be used to improve performance and effectiveness.

Abstract: A call request message is sent from an access terminal to an application server in order to request initiation of a group communication session to a communication group and to request that an allocation of the floor to the given access terminal for the duration of the given group communication session remain uninterrupted by call targets of the session. The application server announces the session, and sends a floor-grant to the access terminal after the session is accepted by at least one target. The access terminal forwards media to the application server which is then forwarded to the at least one target. The floor is not transferred away from the access terminal during the session. For example, floor requests are suppressed at the at least one target, or floor requests are sent by the at least one target but are then ignored or denied by the application server.

Abstract: The disclosure is related to determining an association among Internet of Things (IoT) devices. A first IoT device receives an identifier of a second IoT device, obtains a schema of the second IoT device based on the identifier of the second IoT device, and determines whether or not there is an association between the first IoT device and the second IoT device based on a schema of the first IoT device and the schema of the second IoT device, where the schema of the first IoT device comprises schema elements and corresponding values of the first IoT device and the schema of the second IoT device comprises schema elements and corresponding values of the second IoT device.

Abstract: To ensure that multicasts from access points sent in response to periodic beacons reach a variety of listening clients that may have longer sleep intervals than an interval between beacons, this disclosure describes systems, methods, and apparatus for multicasting bursts of frames where a burst number is selected so as to be equal to or greater than a range of common sleep intervals. Further, where multicast frames are re-multicast according to known protocols, the repeated bursts can be offset from the re-multicast start time suggested by the protocol, in order to increase a likelihood that clients with especially long sleep intervals receive the multicast frame.

Abstract: Methods and apparatuses for indicating a bearer status with a device are provided. A call setup message can be received from an application server indicating a request to initiate a call with a target device. A dedicated bearer status of a dedicated bearer with the target device can be verified, and a message can be sent to the application server indicating the dedicated bearer status with the target device.