A digital data communications network that supports efficient, scalable routing of data and use of network resources by combining a recursive division of the network into hierarchical sub-networks with repeating parameterized general purpose link communication protocols and an addressing methodology that reflects the physical structure of the underlying network hardware. The sub-division of the network enhances security by reducing the amount of the network visible to an attack and by insulating the network hardware itself from attack. The fixed bandwidth range at each sub-network level allows quality of service to be assured and controlled. The routing of data is aided by a topological addressing scheme that allows data packets to be forwarded towards their destination based on only local knowledge of the network structure, with automatic support for mobility and multicasting. The repeating structures in the network greatly simplify network management and reduce the effort to engineer new network capabilities.

Provided is a remote controller for controlling an object placed in a remote location. The remote controller may include: a communication interface configured to form a communication channel with the object; an operator including an input interface configured to receive a user input, and at least one first magnet; a movement sensor configured to detect a movement of the operator generated by the user input, and measure characteristics of the movement of the operator; at least one second magnet disposed around the first magnet; a controller configured to, in response to the detection of the movement, apply a current to at least one of the first magnet and the second magnet to generate a magnetic force applied to the operator, wherein the controller is further configured to adjust the current to change the magnetic force according to the measured characteristics of the movement of the operator.

A sensor management unit receives, from at least one sensor device installed external to the sensor management unit, sensing data generated by the sensor device monitoring a target. The sensing data includes background noise data representing noise from a cause other than the target. The sensor management unit includes a background noise data obtaining unit that obtains the background noise data, a reliability determination unit that determines a reliability of the sensing data based on the background noise data, and a determination result output unit that outputs a result of the determination by the reliability determination unit.

A distributed radio frequency communication system facilitates communication between a wireless terminal and a core network. The system includes a remote radio unit (RRU) coupled to at least one antenna to communicate with the wireless terminal. The RRU includes electronic circuitry to perform at least a first portion of a first-level protocol of a radio access network (RAN) for communicating between the wireless terminal and the core network. The system also includes a baseband unit (BBU) coupled to the core network, and configured to perform at least a second-level protocol of the RAN. A fronthaul link is coupled to the BBU and the RRU. The fronthaul link utilizes an adaptive fronthaul protocol for communication between the BBU and the RRU. The adaptive fronthaul protocol has provisions for adapting to conditions of the fronthaul link and radio network by changing the way data is communicated over the fronthaul link.

An information handling system for managing a network includes a first stackable network switch, a second stackable network switch, and a hardware switching management controller. The first stackable network switch includes a first configuration setting to enable the first stackable network switch to operate in a switch stack. The first configuration setting is accessible via an OpenFlow protocol. The second stackable network switch includes a second configuration setting to enable the second stackable network switch to operate in the switch stack. The second configuration setting is accessible via the OpenFlow protocol. The hardware switching management controller includes an OpenFlow stacking manager configured to set the first configuration setting and the second configuration setting such that the switch stack includes the first and second stackable network switches.

A first fabric abstraction layer couples to a data link layer and a physical layer of a network fabric device. The network fabric device is connected to other network elements within a network via at least one network connection, such as a fiber optic connection. A second fabric abstraction layer couples to the data link layer and an application of the network device. The second fabric abstraction layer provides an application programming interface (API) to the application. The API allows the application to generate configuration instructions for configuring the at least one network connection. Upon receiving the configuration instructions generated by the application, the second abstraction layer sends the configuration instructions to the first abstraction layer via the data link layer. The first abstraction layer then configures the at least one network connection to transmit data according to the configuration instructions.

The present invention relates to a Digital Addressable Lighting Interface (DALI) interface and a power device comprising the same. The present invention can provide a DALI interface comprising: a first limiting circuit unit for outputting a limited current based on a DALI transmission signal and a DALI reception signal; and a gate drive circuit unit for generating, based on the limited current, a drain-source voltage that is used for generating a DALI signal in accordance with the DALI standard. As a result, the present invention can generate a signal complying with the DALI standard even under various voltage and current conditions of a DALI master.

Methods, systems and devices for network congestion control exploit the inherent burstiness of network traffic, using a wave-based characterization of network traffic and corresponding multiplexing methods and approaches.

A method of providing network communications includes spawning a virtual machine that virtualizes network capabilities of the device such that a virtual network connection is provided; using the virtual network connection, transmitting a packet to a first node using a first routing protocol for communication to a destination device; setting a timer, the timer having a value corresponding to an amount of time greater than an average response time of the destination device; and, upon expiration of the timer, transmitting the packet to a second node using a second routing protocol for communication to the destination device.

Embodiments are direct to monitoring communication between computers may be using network monitoring computers (NMCs). Network packets that are communicated between the computers may be captured and stored in a data store. If the NMCs identify a secure communication session established between two computers, the NMCs may obtain key information that corresponds to the secure communication session that includes a session key that may be provided by a key provider. Correlation information associated with the secure communication session may be captured by the NMCs. The correlation information may include tuple information associated with the secure communication session. And, the key information and the correlation information may be stored in a key escrow. The key information may be indexed in the key escrow using the correlation information.