A first protocol stack for communication on a first physical line is implemented. At least parts of a second protocol stack for communication on a second physical line are implemented. The first protocol stack and the second protocol stack are bonded at the Physical Medium Dependent layer of the first protocol stack and the Physical Medium Dependent layer of the second protocol stack (172). In some scenarios, the bonding may be at an upper edge of the Physical Medium Dependent layer, i.e., at the δ interface.

A computer implemented method and system for maximizing a number of connections that can be executed from a mobile application is disclosed. The method comprises determining whether a connection slot is available for a received call request; executing the call when a connection slot is available; processing the call request when a connection slot is not available, where processing comprises: determining a priority level for the request; when the determined priority level is a low priority, putting the request in a queue for later processing; and when the determined priority level is a high priority, when a low priority call is in progress, performing the steps of: canceling the in-progress low priority call; placing the cancelled low priority call in a queue for later processing; and executing the high priority call; and when no low priority call is in progress, placing the high priority call request in the queue.

A system for automatic authentication of service requests includes authentication of a remote access device. This authentication may be accomplished automatically prior to text or audio communication between a customer and a service agent. In some embodiments, authentication is accomplished automatically by authentication of the remote access device or accomplished by asking the customer questions. A single authentication of the remote access device may be used to authenticate a service request transferred between service agents. The authentication of the remote device may include, for example, use of a personal identification number, a fingerprint, a photograph, and/or a hardware identifier. Some embodiments include an intelligent pipeline configured for managing queues of customer service requests and/or customer service agent control over a customer's access device. Some embodiments include logic configured to manage and enhance communication channels between devices.

A content processing method is provided, including: obtaining first content blocks, the first content block including structured data; transmitting, through a single bidirectional communication link established based on an application layer protocol, the first content blocks in a streaming manner according to a first sequence for obtaining the first content blocks; receiving, through the single bidirectional communication link, second content blocks returned in a streaming manner, the second content blocks being obtained by performing content type conversion on the first content blocks, transmission of the first content blocks and reception of the second content blocks being asynchronously performed via the single bidirectional communication link; and outputting the second content blocks sequentially according to a second sequence for receiving the second content blocks.

The present disclosure relates to a communication apparatus and a communication method, and a program which make it possible to achieve higher reliability.

When a packet is distributed to a plurality of lanes and transmitted, at least one of a packet header or a packet footer of the packet is transmitted independently in each of the lanes. The packet footer transmitted in each of the lanes is CRC calculated from a payload of the packet distributed to each of the lanes corresponding thereto, and the packet header transmitted in each of the lanes includes word count indicating the number of bytes of a payload of the packet distributed to each of the lanes corresponding thereto. The present technology can be applied to, for example, a communication system used for connecting an on-board camera.

Connection with an apparatus with a lower standard is easily performed. A digital signal to which coding has been performed is transmitted to an external device by a differential signal through a plurality of channels via a transmission path. In this case, a digital signal to which first coding has been performed and from which clock extraction is not available is transmitted through a part of the plurality of channels, and a digital signal to which second coding has been performed and from which clock extraction is available is transmitted through the other channels of the plurality of channels. A reception side processes the digital signal received through the plurality of channels on the basis of the clock extracted from the digital signal received through any one of other channels.

A method is provided in one example embodiment and includes receiving at a first network node a request to obtain data from a second network node, wherein the first and second network nodes are connected via n access networks; partitioning the request into n subrequests proportionally based on relative throughputs of the n access networks; and transmitting each of the n subrequests to the second network node via a respective one of the n access networks.

An unmanned aerial vehicle manages storage of data and transfer between other connected devices. The unmanned aerial vehicle captures sensor data from sensors on the unmanned aerial vehicle. The unmanned aerial vehicle transfers the captured sensor data from the unmanned aerial vehicle to a remote controller via a wireless interface. The captured data may be transferred via a TCP link, a UDP link, or a combination thereof If a loss of link is detected, the captured sensor data is stored to a buffer and a battery level of the unmanned aerial vehicle and a flight status of the unmanned aerial vehicle is monitored. The stored sensor data is transferred from the buffer to a non-volatile storage responsive to the battery level dropping below a predefined threshold or detecting that the unmanned aerial vehicle is stationary and a shutdown may be imminent.

This disclosure is directed to an intelligent transducer for transforming a first event signal received from an input signal system into a second event signal transmitted to an output signal system by using a first event signal-specific transformation signal received from one or more disparate application signal systems and sensing an attribute of the first event signal-specific transformation signal.

Methods, systems, and apparatuses for discovering dynamic path maximum transmission unit (PMTU) between a sending computing device and a receiving computing device (e.g., a client device and a host device) are described herein. A sending computing device may iteratively transmit bursts of probe packets, each burst being defined by a search range between a maximum packet size and a minimum packet size. The sending computing device may iteratively update the search range based on the previous iteration until the search converges on the PMTU. When the PMTU is discovered, each of the computing devices may update their transport and presentation layer buffers based on the discovered PMTU without any other protocol level disruption. In a multi-path scenario, the computing device may discover PMTU for each of the paths and select a performance optimal path based on the individual PMTUs and other network characteristics such as loss, latency, and throughput.