An allocation apparatus configured to allocate a plurality of information processing devices to two or more management apparatuses that perform distributed management of the plurality of information processing devices, the allocation apparatus includes: an allocation unit configured to allocate an address range on a network, allocatable to a plurality of information processing devices, to the two or more management apparatuses; and an acquisition unit configured to obtain, from each of the two or more management apparatuses, management information indicating a state of the information processing device whose address belongs to a range allocated to the management apparatus, wherein the allocation unit dynamically performs allocation of the address range on the network based on the management information that has been obtained by the acquisition unit.

A display device configured to communicate with at least one other display device connected to a network is disclosed. The display device includes communication circuitry configured to receive unique information and a service set identifier (SSID) from each of the at least one other display device, the unique information for use in identification of each of the at least one other display device, and a controller configured to change an SSID based on a comparison between unique information of the display device and at least one piece of the received unique information.

Exemplary methods at a content centric networking (CCN) gateway located at an autonomous system (AS), wherein the CCN gateway is communicatively coupled to a CCN domain name system (DNS) server, include receiving, on a first face, a first interest message comprising of a first content name identifying a first content being requested by the first interest message. The methods include in response to determining the first content is not located at the AS, determining a first remote AS name that identifies a first remote AS where the first content is located, generating a first 2-level (2L) content name comprising of the first remote AS name and the first content name, forwarding the first interest message comprising of the first 2L content name, and in response to receiving a first content object (CO) message comprising of the first 2L content name and the first content, forwarding the first content.

In general, techniques are described for steering data traffic for a subscriber session from a network interface of a wireless access gateway to an anchoring one of a plurality of forwarding units of the wireless access gateway using a layer 2 (L2) address of the data traffic. For example, a wireless access gateway for a wireless local area network (WLAN) access network is described as having a decentralized data plane that includes multiple forwarding units for implementing subscriber sessions. Each forwarding unit may present a network interface for sending and receiving network packets and includes packet processing capabilities to enable subscriber data packet processing to perform the functionality of the wireless access gateway. The techniques enable steering data traffic for a given subscriber session to a particular one of the forwarding units of the wireless access gateway using an L2 address of the data traffic.

A computer system including a storage device and a controller is provided. The storage device is configured to store Service Set Identifiers (SSIDs), location information, and Media Access Control (MAC) addresses of a plurality of Access Points (APs). The controller is configured to determine a group of APs among the APs, whose MAC addresses are within a MAC address block, determine a first number of the group of APs whose SSIDs match one or more of a plurality of predetermined naming patterns or whose location information indicates a location change across a predetermined distance, determine whether a ratio of the first number to a total number of the group of APs exceeds a predetermined threshold, and classify the APs in the group as mobile APs when the ratio exceeds the predetermined threshold.

A method for configuring a transfer of signals associated with an iterative and synchronized, time-based data acquisition (DAQ) operation between at least one input device and at least one output device is disclosed herein. The method includes requesting and receiving signal data samples (SDSs) from the at least one input device. A series of the SDSs are mapped to a buffer. The time indicators of SDSs are compared to confirm that SDSs are incrementally-next in time relative one another. A missing signal data sample is retransmitted if necessary. The series of SDSs is remapped in the buffer as necessary to arrange the series in time sequence. The method also includes transmitting in real time at least a portion of the present signal data sample to an output device prior to receiving the missing signal data sample.

Generally, this disclosure provides devices, systems and methods for subframe restricted Channel State Information (CSI) reporting with Rank Indicator (RI) inheritance. A User Equipment (UE) device may include an RI generation module to generate RIs based on a received CSI configuration from an evolved Node B (eNB) of a serving cell of the UE. The UE may also include an RI Reference Process CSI generation module to generate a first Reference CSI including a first selected RI of the generated RIs, the first selection based on a first subframe set of the received CSI configuration, and to generate a second Reference CSI including a second selected RI of the generated RIs, the second selection based on a second subframe set of the received CSI configuration. The UE may further include a Linked Process CSI generation module to generate a linked CSI including an inherited RI from the first Reference CSI.

A method includes, prior to authenticating a mobile device, receiving by an access point a first message from the mobile device, determining that the mobile device is to be authenticated prior to responding to the first message, and sending to an authentication server a second message that includes an authentication request and the first message. The method also includes receiving from the authentication server a third message that includes a response to the authentication request and that further includes the first message.

Embodiments provide a method, an apparatus, and a system for joining a node to a network. The method includes: receiving an access indication that is sent by a joined node and that carries information about at least one joining node; broadcasting, according to the access indication, a MAP frame carrying the information about the at least one joining node, so that a joining node corresponding to the joining node information directly completes registration after receiving the MAP frame; and sending, by a DM, an authentication password to the joining node, so that the joining node completes authentication according to the authentication password and joins the network.

Various embodiments provide methods, devices, and non-transitory processor-readable storage media enabling network path probing with a communications device by sending probes via a network connection to a STUN server and receiving probe replies. The communications device may increment a counter and transmit a test probe configured to be dropped at the first access point (NAT) causing all subsequent NATs to release their IP/port mappings. The communications device may send another probe to the STUN server and receive a probe reply. The communications device may compare the first and second probe replies to determine whether the final IP addresses within the network path match. By continuously incrementing the counter and querying access points, the communications device may determine the number of access points lay along any given network path. The presence of addition or unexpected numbers of NAT Servers may indicate the presence of a rogue access point.