Abstract: Disclosed is a system (102) for determining a location of an explosive device. The system (102) detects an explosive device using one or more devices (204) based on one or more nano-explosive detection sensors (206) associated with the one or more devices (204). The system (102) further identifies a type, a quantity and a signal strength associated with the explosive device. The system (102) computes a distance between the explosive device and the one or more devices (204). The system (102) determines explosive device co-ordinates based on the computed distance and device co-ordinates associated with each device (204). The system (102) receives a data packet comprising data associated with the explosive device from the one or more devices (204). The system (102) determines a location of the explosive device based on an analysis of the data packet received from the one or more devices (204).

Abstract: The present disclosure relates to a system (102) for assigning dynamic operation of devices in a communication network (106). The system (102) receives one or more behavioral attributes and one or more contextual attributes associated with one or more devices (232) in a communication network (106). The system (102) further determines one or more clusters (234) associated with each device from the one or more devices (232). The system (102) further determines, dynamically, one or more network slices, from a set of network slices associated with the one or more clusters (234). The system (102) further determines, dynamically, one or more analytics models associated with the one or more clusters (234). The system (102) further assigns dynamic operation of the one or more clusters (234) based on the one or more contextual attributes, the one or more network slices and the one or more analytics models.

Abstract: Disclosed is a system (102) for determining a location of an explosive device. The system (102) detects an explosive device using one or more devices (204) based on one or more nano-explosive detection sensors (206) associated with the one or more devices (204). The system (102) further identifies a type, a quantity and a signal strength associated with the explosive device. The system (102) computes a distance between the explosive device and the one or more devices (204). The system (102) determines explosive device co-ordinates based on the computed distance and device co-ordinates associated with each device (204). The system (102) receives a data packet comprising data associated with the explosive device from the one or more devices (204). The system (102) determines a location of the explosive device based on an analysis of the data packet received from the one or more devices (204).

Abstract: The present disclosure relates to a system (102) for assigning dynamic operation of devices in a communication network (106). The system (102) receives one or more behavioral attributes and one or more contextual attributes associated with one or more devices (232) in a communication network (106). The system (102) further determines one or more clusters (234) associated with each device from the one or more devices (232). The system (102) further determines, dynamically, one or more network slices, from a set of network slices associated with the one or more clusters (234). The system (102) further determines, dynamically, one or more analytics models associated with the one or more clusters (234). The system (102) further assigns dynamic operation of the one or more clusters (234) based on the one or more contextual attributes, the one or more network slices and the one or more analytics models.

Abstract: Disclosed is a Central Aircraft Network System (CANS) for transmitting data, associated with an aircraft, to a ground station via one or more communication channels. A data receiving module receives data from at least one data source. An AIDPS determines priority information pertaining to the data. In one aspect, the priority information may be determined by analyzing the data and a predefined data pattern model. An ICSMS determines one or more communication channels, of a plurality of communication channels, to be used for transmitting the data. The ICSMS further establishes the one or more communication channels between the aircraft and a ground station in order to transmit the data to the ground station via the one or more communication channels.

Abstract: The present disclosure relates to system(s) and method(s) for alerting one or more service providers based on analysis of real-time sensor data. The system is configured to receive real-time sensor data and historical sensor data captured by one or more agent devices. Further, the system is configured to determine an anomaly corresponding to a target agent device from the one or more agent devices, based on comparison of the real-time sensor data and one or more predefined threshold parameters. The system is further configured to generate an alert corresponding to the anomaly and identify one or more service providers, affected by the anomaly, based on analysis of the historical sensor data and the anomaly. Further, the system is configured to transmit the alert to the one or more service providers, thereby alerting the one or more service providers.

Abstract: An apparatus for improving data transfer speed by using Multipath Transport Control Protocol (MPTCP) and Multiple-Input Multiple-Output (MIMO) combination, wherein the apparatus comprises a user interface module called Application Management System (AMS) module (100) to receive user inputs for managing transport protocol (MPTCP or conventional TCP/UDP/SCTP) usage selection. The apparatus also includes a Selection, Inspection Control (SIC) middleware module (101) which STARTs and STOPs the corresponding MPTCP module or conventional TCP/UDP/SCTP module based on the user inputs received from AMS. The MPTCP module splits the data traffic into multiple TCP subflows and sends the subflows via wired network interface (104), wherein each network interface is connected to one MIMO systems (107) for achieving efficient data transfer.

Abstract: An apparatus for improving data transfer speed by using Multipath Transport Control Protocol (MPTCP) and Multiple-Input Multiple-Output (MIMO) combination, wherein the apparatus comprises a user interface module called Application Management System (AMS) module (100) to receive user inputs for managing transport protocol (MPTCP or conventional TCP/UDP/SCTP) usage selection. The apparatus also includes a Selection, Inspection Control (SIC) middleware module (101) which STARTs and STOPs the corresponding MPTCP module or conventional TCP/UDP/SCTP module based on the user inputs received from AMS. The MPTCP module splits the data traffic into multiple TCP subflows and sends the subflows via wired network interface (104), wherein each network interface is connected to one MIMO systems (107) for achieving efficient data transfer.