Abstract: Apparatus and methods for providing information via an open-access network such as a wireless local area network (WLAN). In one embodiment, the information provided is contextually relevant to one or locations, more users or devices receiving the information. In one implementation, the information is provisioned by a network entity (for example, from a service provider network operator) and provided to one or more access points (APs) of the service provider network. The information is bit-stuffed into Wi-Fi beacon frames or other data structures that are broadcast by the APs to nearby client devices. A receiving client device extracts the information using a protocol embodied in application software on the client, and may also initiate a dedicated wireless connection with the AP for e.g., transmission of content related to the context and/or the bit-stuffed information, access of related Internet addresses, etc.

Abstract: The disclosed is a tracking system comprises RF tags/beacons and a Hub (Parent Node) (100) for centralized control, with Bi-directional serial communication (101) linking the Parent Node to Wireless Nodes (Child Nodes) (102). Data transfer occurs via a Cellular Network (106) to a cloud-based system featuring a user interface (108) for user instructions and result display, a Database (111) for storing asset data, and an Analytics Engine (110) for organizing data based on received asset-related information. The system ensures precise monitoring and scanning of RF tags/beacons for enhanced tracking accuracy. The present disclosure also relates to a method for asset tracking by way of the tracking system (10).

Abstract: Apparatus and methods for providing information via an open-access network such as a wireless local area network (WLAN). In one embodiment, the information provided is contextually relevant to one or locations, more users or devices receiving the information. In one implementation, the information is provisioned by a network entity (for example, from a service provider network operator) and provided to one or more access points (APs) of the service provider network. The information is bit-stuffed into Wi-Fi beacon frames or other data structures that are broadcast by the APs to nearby client devices. A receiving client device extracts the information using a protocol embodied in application software on the client, and may also initiate a dedicated wireless connection with the AP for e.g., transmission of content related to the context and/or the bit-stuffed information, access of related Internet addresses, etc.

Abstract: The invention relates cloud based IoT network monitoring and validation to enable optimal network selection and connectivity for IoT sensors. The present invention relates to a system to measure the signal quality directly from the network module of IoT sensors. It comprises of an application programming interface (API) 105, a Network detection dongle 103, communication network 110, server 115, network modules of network operators and IoT sensors 120, to be deployed or installed. The invention also relates to a method for determination of signal strength from network module of IoT sensors, wherein the API 105 is configured to run network detection software to determine and validate an optimal location for IoT sensor/device installation or deployment based on the highest signal strength.

Abstract: Apparatus and methods for extending and enhancing wireless networks. An exemplary wireless network configured according to the disclosure uses in-service Wireless Network Clients (WNCs), such as mobile phones, laptops, etc., to extend and enhance the wireless network coverage via peer-to-peer sub-networks. In one implementation, each WNC is configured to operate as a Service Access Node (SAN) to other wireless client devices in the same network. The SAN provides peer-to-peer communications capabilities (to communicate with wireless clients) and gateway functionality (to aggregate data traffic over its own uplink communications), thereby enabling wireless clients to “piggyback” their data link onto the WNC. Peer Control Manager (PCM) software on each WNC enables, disables, and controls the service functions for that WNC in accordance with an overarching Peer Controller (PC) entity operated by an Access Point Controller/Core Network.

Abstract: Apparatus and methods for providing information via an open-access network such as a wireless local area network (WLAN). In one embodiment, the information provided is contextually relevant to one or locations, more users or devices receiving the information. In one implementation, the information is provisioned by a network entity (for example, from a service provider network operator) and provided to one or more access points (APs) of the service provider network. The information is bit-stuffed into Wi-Fi beacon frames or other data structures that are broadcast by the APs to nearby client devices. A receiving client device extracts the information using a protocol embodied in application software on the client, and may also initiate a dedicated wireless connection with the AP for e.g., transmission of content related to the context and/or the bit-stuffed information, access of related Internet addresses, etc.

Abstract: The invention relates cloud based IoT network monitoring and validation to enable optimal network selection and connectivity for IoT sensors. The present invention relates to a system to measure the signal quality directly from the network module of IoT sensors. It comprises of an application programming interface (API) 105, a Network detection dongle 103, communication network 110, server 115, network modules of network operators and IoT sensors 120, to be deployed or installed. The invention also relates to a method for determination of signal strength from network module of IoT sensors, wherein the API 105 is configured to run network detection software to determine and validate an optimal location for IoT sensor/device installation or deployment based on the highest signal strength.

Abstract: Apparatus and methods for extending and enhancing wireless networks. An exemplary wireless network configured according to the disclosure uses in-service Wireless Network Clients (WNCs), such as mobile phones, laptops, etc., to extend and enhance the wireless network coverage via peer-to-peer sub-networks. In one implementation, each WNC is configured to operate as a Service Access Node (SAN) to other wireless client devices in the same network. The SAN provides peer-to-peer communications capabilities (to communicate with wireless clients) and gateway functionality (to aggregate data traffic over its own uplink communications), thereby enabling wireless clients to “piggyback” their data link onto the WNC. Peer Control Manager (PCM) software on each WNC enables, disables, and controls the service functions for that WNC in accordance with an overarching Peer Controller (PC) entity operated by an Access Point Controller/Core Network.

Abstract: Apparatus and methods for extending and enhancing wireless networks. An exemplary wireless network configured according to the disclosure uses in-service Wireless Network Clients (WNCs), such as mobile phones, laptops, etc., to extend and enhance the wireless network coverage via peer-to-peer sub-networks. In one implementation, each WNC is configured to operate as a Service Access Node (SAN) to other wireless client devices in the same network. The SAN provides peer-to-peer communications capabilities (to communicate with wireless clients) and gateway functionality (to aggregate data traffic over its own uplink communications), thereby enabling wireless clients to “piggyback” their data link onto the WNC. Peer Control Manager (PCM) software on each WNC enables, disables, and controls the service functions for that WNC in accordance with an overarching Peer Controller (PC) entity operated by an Access Point Controller/Core Network.

Abstract: Apparatus and methods for providing information via an open-access network such as a wireless local area network (WLAN). In one embodiment, the information provided is contextually relevant to one or locations, more users or devices receiving the information. In one implementation, the information is provisioned by a network entity (for example, from a service provider network operator) and provided to one or more access points (APs) of the service provider network. The information is bit-stuffed into Wi-Fi beacon frames or other data structures that are broadcast by the APs to nearby client devices. A receiving client device extracts the information using a protocol embodied in application software on the client, and may also initiate a dedicated wireless connection with the AP for e.g., transmission of content related to the context and/or the bit-stuffed information, access of related Internet addresses, etc.

Abstract: Apparatus and methods for providing information via an open-access network such as a wireless local area network (WLAN). In one embodiment, the information provided is contextually relevant to one or locations, more users or devices receiving the information. In one implementation, the information is provisioned by a network entity (for example, from a service provider network operator) and provided to one or more access points (APs) of the service provider network. The information is bit-stuffed into Wi-Fi beacon frames or other data structures that are broadcast by the APs to nearby client devices. A receiving client device extracts the information using a protocol embodied in application software on the client, and may also initiate a dedicated wireless connection with the AP for e.g., transmission of content related to the context and/or the bit-stuffed information, access of related Internet addresses, etc.

Abstract: Apparatus and methods for extending and enhancing wireless networks. An exemplary wireless network configured according to the disclosure uses in-service Wireless Network Clients (WNCs), such as mobile phones, laptops, etc., to extend and enhance the wireless network coverage via peer-to-peer sub-networks. In one implementation, each WNC is configured to operate as a Service Access Node (SAN) to other wireless client devices in the same network. The SAN provides peer-to-peer communications capabilities (to communicate with wireless clients) and gateway functionality (to aggregate data traffic over its own uplink communications), thereby enabling wireless clients to “piggyback” their data link onto the WNC. Peer Control Manager (PCM) software on each WNC enables, disables, and controls the service functions for that WNC in accordance with an overarching Peer Controller (PC) entity operated by an Access Point Controller/Core Network.

Abstract: Apparatus and methods for extending and enhancing wireless networks. An exemplary wireless network configured according to the disclosure uses in-service Wireless Network Clients (WNCs), such as mobile phones, laptops, etc., to extend and enhance the wireless network coverage via peer-to-peer sub-networks. In one implementation, each WNC is configured to operate as a Service Access Node (SAN) to other wireless client devices in the same network. The SAN provides peer-to-peer communications capabilities (to communicate with wireless clients) and gateway functionality (to aggregate data traffic over its own uplink communications), thereby enabling wireless clients to “piggyback” their data link onto the WNC. Peer Control Manager (PCM) software on each WNC enables, disables, and controls the service functions for that WNC in accordance with an overarching Peer Controller (PC) entity operated by an Access Point Controller/Core Network.

Abstract: Apparatus and methods for providing information via an open-access network such as a wireless local area network (WLAN). In one embodiment, the information provided is contextually relevant to one or locations, more users or devices receiving the information. In one implementation, the information is provisioned by a network entity (for example, from a service provider network operator) and provided to one or more access points (APs) of the service provider network. The information is bit-stuffed into Wi-Fi beacon frames or other data structures that are broadcast by the APs to nearby client devices. A receiving client device extracts the information using a protocol embodied in application software on the client, and may also initiate a dedicated wireless connection with the AP for e.g., transmission of content related to the context and/or the bit-stuffed information, access of related Internet addresses, etc.

Abstract: Apparatus and methods for extending and enhancing wireless networks. An exemplary wireless network configured according to the disclosure uses in-service Wireless Network Clients (WNCs), such as mobile phones, laptops, etc., to extend and enhance the wireless network coverage via peer-to-peer sub-networks. In one implementation, each WNC is configured to operate as a Service Access Node (SAN) to other wireless client devices in the same network. The SAN provides peer-to-peer communications capabilities (to communicate with wireless clients) and gateway functionality (to aggregate data traffic over its own uplink communications), thereby enabling wireless clients to “piggyback” their data link onto the WNC. Peer Control Manager (PCM) software on each WNC enables, disables, and controls the service functions for that WNC in accordance with an overarching Peer Controller (PC) entity operated by an Access Point Controller/Core Network.