The invention relates to the technical field of domestic networks. A domestic network based on the present UPnp-Standard allows AV connections to be set up between two network subscriber stations—Network connections such as these are set up and managed under the control of a network station which is in the form of a control point. In this case, the UPnP-Standard allows the network station which is the form of a control point to log off the network after setting up an AV connection, and thus to be inactive while the AV connection that has been set up is in existence. This results in the problem that an AV connection which has been set up unnecessarily remains in existence even after the desired AV data stream has been transmitted, so that further connection requests for such stations must be answered with a rejection. The invention solves this problem in that it provides additional monitoring means in the network subscriber stations which determine whether the connection has remained unused for a specific time. If yes, a signaling request is sent to all the network subscriber stations. If the connection partner station does not then respond, the connection which has been set up can likewise be added autonomously by the requesting station.

A system including a drone or unmanned vehicle configured to perform surveillance of a premises. The drone surveillance includes autonomous navigation and/or remote or optional piloting around the premises. The drone includes a controller coupled to a plurality of sensors configured to collect drone data and security data at the premises, wherein the controller is configured to generate control data for the drone and the premises using the drone data and the security data. A remote device coupled to the drone includes a user interface configured to present the drone data, the security data, and/or the control data.

Methods and systems for reconfiguring an interface device are described. The interface device may comprise a housing, one or more processors disposed in the housing, a display, a network interface that enables communication with a security system, and a module connector. One or more of a plurality of modules may be removably coupled, via the module connector, with the interface device. The plurality of modules may enable the interface device to perform different functions. An example module, when coupled to the module connector, may enable communication between multiple networks.

A method for providing bidirectional communication between segments of a home network includes receiving a first communication signal at a first interface of an inter-domain bridge during a first time interval; receiving a second communication signal at a second interface of the inter-domain bridge during the first time interval; generating a superimposed signal of the first communication signal and the second communication signal; and transmitting the superimposed signal through the first interface and the second interface during a second time interval. The second time interval occurs after the first time interval.

Systems and methods for a security network integrating security system and network devices are disclosed. A system may comprise a gateway and first and second security panels, each located at a premises. The first and second security panels may be connected, via respective first and second wireless communication protocols, to respective first and second security system components. The first and second security panels may receive respective first and second security data from the respective first and second security system components. The gateway may be configured to receive, via the first and second wireless communication protocols, the respective first and second security data. The gateway may be configured to transmit at least one of the first security data and the second security data to a security server located external to the premises.

An integrated system includes a system user interface (SUI) that provides an iconic, at-a-glance representation of integrated security system status. The SUI is for use across all client devices including mobile or cellular telephones, a mobile portal, a web portal, and a touchscreen device. The SUI includes a number of display elements presented across all types of client devices for monitoring status of the integrated security system. The display elements of the SUI include an orb icon, text summary, security button, device warnings, system warnings, interesting sensors, and quiet sensors. The SUI thus provides system status summary information agnostically across all clients. Additionally, the SUI provides consistent iconography, terminology, and display rules across all clients as well as consistent sensor and system detail across clients.

A system including a drone or unmanned vehicle configured to perform surveillance of a premises. The drone surveillance includes autonomous navigation and/or remote or optional piloting around the premises. The drone includes a controller coupled to a plurality of sensors configured to collect drone data and security data at the premises, wherein the controller is configured to generate control data for the drone and the premises using the drone data and the security data. A remote device coupled to the drone includes a user interface configured to present the drone data, the security data, and/or the control data.

In a first aspect the invention provides a system that comprising a plurality of electronic modules, each one of the electronic modules configured for enabling automation of an electrical appliance to be connected to the electronic module. Each electronic module comprises at least a communication sub-part configured to enable communication over a power-line network with other modules, at least an acting means configured to act on an electrical voltage to be applied to the electrical appliance, at least a measurement means configured to measure a power consumption to be consumed by the electrical appliance, and an embedded intelligence means configured to process signals providing from or going to the at least one communication sub-part, the at least one acting means and the at least one measurement means. Each one of the plurality of electronic modules is enabled for communication with the others of the plurality of electronic modules over the power-line network by means of its at least one communication sub-part. In each one of the plurality of electronic modules the embedded intelligence means further comprises outgoing message sending means configured to send an outgoing message over the power-line network to at least one of the others of the plurality of electronic modules, ingoing message receiving means configured to receive an ingoing message over the power-line network from at least one of the others of the plurality of electronic modules, identifying means configured to identify an ingoing message relevant to the electronic module, presentation means configured to prepare a presentation message to be sent as outgoing message, the presentation message containing presentation information related to an identity of the electronic module, hierarchical ordering means configured to generate an ordered list of the plurality of modules that comprises the electronic module and the others of the plurality of electronic modules, depending on presentation information from the electronic module and presentation information received from the others of the plurality of electronic modules, and electing means for electing from the ordered list a president electronic module. The presentation means, the hierarchical ordering means and the electing means are configured such that the electing means in each of the plurality of electronic modules find the same president electronic module. The embedded intelligence means are further configured to handle information included an ingoing message sent from the president electronic module according to a determined priority protocol.

A method for optimizing a home automation system is provided having a plurality of communicating devices capable of exchanging information therebetween via a local low bandwidth PLC (Power Line Communication) network. The method includes a phase in which the PLC transmission power is adjusted for each new device added to the network. The phase includes the following successive steps: installing (10) the new device configured to transmit at a predefined maximum power on said PLC network; cutting off (20) all ongoing communications on the PLC network except for the new device; testing communication for each pre-existing device on the PLC network with which the new device is to be paired and, if communication fails, ensuring an automatic incremental increase (30) of the PLC transmission power of the pre-existing device until a first PLC transmission power value is reached at which PLC communication can be initialized between the pre-existing device and the new device; and ensuring an automatic reduction (40) of the PLC transmission power of the new device while communication between each pre-existing device and the new device is active.

A slotted message access protocol can be implemented for transmitting short packets. Each beacon period may be divided into multiple time slots. At least one time slot may be assigned to a network device per beacon period based, at least in part, on latency specifications of packets that the network device is configured to transmit. In one example, some of the unassigned time slots may be designated as contention-based time slots. Network devices may contend with each other to gain control of and transmit packets during a contention-based time slot based on the priority level of the packets to be transmitted. Network devices may also use an encryption key and an initialization vector for securely exchanging short packets. Furthermore, a repeater network device may be designated to retransmit a packet, received from an original transmitting network device, during a communication time slot assigned to the original transmitting network device.