Abstract: A communication optimization system/method for mobile networks uses a server that generates waypoints based on a first communication network within a route to be travelled by an aerial vehicle, the aerial vehicle comprising a communication hub configured to communicate with at least one communication node, a communication hub controller configured control movement of a steerable antenna, and an aerial vehicle controller configured control movement of the aerial vehicle. The server then transmits the waypoints to the aerial vehicle controller; periodically monitors networks not connected to the communication hub; when a second communication network not connected to the communication hub satisfies a threshold, transmits causes the communication controller to steer the steerable antenna in a direction of the second communication network, further causing the communication hub to communicate and connect with the second communication network.

Abstract: Described herein are methods and systems to send/receive medical data from one or more electronic devices to a secondary medical unit in delayed, intermittently-connected, low-bandwidth (DIL) environments. An application executing on the electronic devices may, in response to detecting a disruption within a communication network, execute an offline communication protocol to transmit medical data among a predetermined number of other electronic devices, wherein the offline communication protocol does not use the communication network. The application may then receive a request from a server of the secondary medical unit to transmit at least a part of the medical data. In response to authenticating the request, the application then transmits the medical data using an online communication protocol that uses the communication network or using an offline communication protocol.

Abstract: A communication optimization system/method for mobile networks uses a server that generates waypoints based on a first communication network within a route to be travelled by an aerial vehicle, the aerial vehicle comprising a communication hub configured to communicate with at least one communication node, a communication hub controller configured control movement of a steerable antenna, and an aerial vehicle controller configured control movement of the aerial vehicle. The server then transmits the waypoints to the aerial vehicle controller; periodically monitors networks not connected to the communication hub; when a second communication network not connected to the communication hub satisfies a threshold, transmits causes the communication controller to steer the steerable antenna in a direction of the second communication network, further causing the communication hub to communicate and connect with the second communication network.

Abstract: The present application relates to an implementation of a reliable transport protocol that provides receiver-based congestion control within a computing system. An exemplary system includes a first network device and a second network device within a network. During a handshake procedure, a transmission rate at which data can be sent as well as an acceptable corruptive loss rate for a data path between the first network device and the second network device in the network is determined. The second network device then receives data sent from the first network device at the transmission rate. When the acceptable corruptive loss rate for received data has been exceeded, the second network device determines an amount by which to reduce the transmission rate, and then sends a notification to the first network device indicating the amount by which to reduce the transmission rate for subsequently transmitted data.

Abstract: The present application relates to an implementation of a reliable transport protocol that provides receiver-based congestion control within a computing system. An exemplary system includes a first network device and a second network device within a network. During a handshake procedure, a transmission rate at which data can be sent as well as an acceptable corruptive loss rate for a data path between the first network device and the second network device in the network is determined. The second network device then receives data sent from the first network device at the transmission rate. When the acceptable corruptive loss rate for received data has been exceeded, the second network device determines an amount by which to reduce the transmission rate, and then sends a notification to the first network device indicating the amount by which to reduce the transmission rate for subsequently transmitted data.