Abstract: Using various embodiments, methods and systems for computing a self-assembling indirect control flow graph based on one or more function types and function pointer types are described. In one embodiment the indirect control flow graph is computed by finding one or more function types and function pointer types in source code and/or binary code, computing one or more identifier tags for each type, classifying functions and function pointers based on the computed tags. In one embodiment, the classification tags can be used in a tag check based Control Flow Integrity system. In another embodiment, the classification tags can be used to convert indirect function calls into direct function calls. Yet in another embodiment, tag checks can be eliminated in a Control Flow Integrity system.

Abstract: The concepts relate to radio channel utilization and more specifically to determining whether individual radio channels are available for use. One example can cause multiple sensing devices in a region to sense radio channels. The example can obtain signal information sensed by the multiple sensing devices in relation to an individual radio channel. The example can collectively analyze the signal information from the multiple sensing devices to determine whether the individual radio channel is being used for a licensed broadcast in the region.

Abstract: In general, techniques for implementing a flow distribution service using a plurality of traffic nodes that may operate as processing nodes of a distributed computing system are described. In some examples, the traffic nodes in the aggregate form a virtual appliance configured to apply a network service to packet flows.

Abstract: A device identification server identifies a “household” to which a particular device belongs by associating the device with a LAN MAC address of the router through which the device connects to a wide area network such as the Internet because the LAN MAC address (i) is unique to the router and (ii) is not readily discoverable by interaction with the router through the wide area network, impeding spoofing by malicious entities. The device queries and receives the LAN MAC address of the router through the local area network. The device passes the LAN MAC address of the router along with its digital fingerprint to the device identification server. Devices that report the same LAN MAC address of the router through which they connect to the wide area network are determined to be from the same “household”, i.e., to be managed by one and the same entity.

Abstract: A system, method, and computer program product are provided for testing at least a portion of a Network Function Virtualization based (NFV-based) communication network utilizing at least one virtual service testing element. In use, at least one virtual service testing element is instantiated, the at least one virtual service testing element being operable for testing at least a portion of a NFV-based communication network including a plurality of virtual services.

Abstract: Described herein are apparatuses and methods for providing communication in multiple frequencies in a multiband Ethernet over Coax (EoC) system. An exemplary apparatus comprises a transceiver for transmitting or receiving a first data packet on a first channel associated with a first frequency, and a transmitter for transmitting a second data packet on at least one second channel associated with at least one second frequency.

Abstract: Systems, apparatus and methods for estimating a location of a mobile device are presented. Before computing a location estimate, the mobile device groups a plurality of access points into two or more categories (for example, a first list of access points having a first characteristic and a second list of access points having a second characteristic). Round-trip time (RTT) measurements are computed for access points in the first list. A Short Interframe Space (SIFS) value may be determined for each access point in the first list or generally SIFT representing the first list as a whole. The RTT measurements are compensated with the appropriate SIFS value. The mobile device then computes its location or position fix estimate using the compensated RTT values while excluding less accurate RTT values from other access points. As a result, the location estimate eliminates adverse influent from some access points.

Abstract: Cable systems and assemblies integrate a reduced number of twin axial copper pairs to transmit and received in a full-duplex transmission signals at transmission speeds greater than or equal to one hundred Giga bytes per second. The reduced number of twin axial copper pairs comprise four or less twin axial copper pairs, in which each pair forms a single twin axial full-duplex cable for passive or active communication of the signals. A processor can be integrated with the twin axial copper pairs operate to encode the signals for fast transmission speeds.

Abstract: Systems and methods for locating network errors. The system includes a plurality of host nodes in a network of host nodes and intermediary nodes, and a database storing route data for each of a plurality of host node pairs. The system includes a controller configured to identify a subject intermediary node to investigate for network errors and select, using route data stored in the database, a set of target probe paths. Each target probe path includes a respective pair of host nodes separated by a network path including at least one target intermediary node, which is either the subject intermediary node or an intermediary node that is a next-hop neighbor of the subject intermediary node. The controller is configured to test each target probe path in the set of target probe paths and to determine, based on a result of the testing, an operational status of the subject intermediary node.

Abstract: Provided are a method, a base station and a computer storage medium for implementing inner loop and closed loop power control. The method includes that when User Equipment (UE) is in a soft handover status, a cell which belongs to a Radio Link Set (RLS) different from that of a serving cell of the UE sends a fixed power control instruction to instruct the UE to increase transmission power.

Abstract: A computer program, an information processing system, and an information processing method are capable of properly managing the connection state of communication connection with an external device. When an operating system shifts an application to a background state, the operating system provides the application with a background shift notification. In the case where communication connection, targeted for management, between the application and an external accessory system is in an active state, the application having received the background shift notification cuts off, via the operating system, the communication connection established between the application and the accessory system, and switches the state of the communication connection, targeted for management, to an inactive state.

Abstract: A node for connecting to an interconnection network may include a network interface. The node may also include a processor coupled with the network interface. The node may further include a memory coupled with the processor. The processor may be configured for periodically analyzing the connectedness of the node to the interconnection network to determine a metric for the node in relation to other nodes within the interconnection network. The node may be designated as a member of a core set of nodes within the interconnection network based upon the metric. The node may detect at least one of a derived update or an update indicating another node connects to or disconnects from the interconnection network. The node may transmit a routing update to another member of the core set of nodes only when the node is designated as part of the core set of nodes.

Abstract: A device may receive an indication to generate a probe packet associated with a tunnel included in a first network. The tunnel may include a first tunnel endpoint and a second tunnel endpoint and may correspond to a path, associated with a second network, between the first tunnel endpoint and the second tunnel endpoint. The device may generate the probe packet including information associated with the tunnel. The device may provide the probe packet, via the first tunnel endpoint, such that the probe packet is received by a network device that lies on the path. The device may receive a response packet, associated with the probe packet and provided by the network device, that includes path information. The path information may include information associated with the network device. The device may store the path information to allow the network device to be identified as lying on the path.

Abstract: Provided are a method and an apparatus for transmitting a reception confirmation in a wireless system. A terminal determines at least one downlink sub-frame for ACK/NACK feedback from each of a plurality of serving cells and determines the number of ACK/NACK bits for the plurality of serving cells. The terminal generates bundled ACK/NACK bits by arraying the ACK/NACK bits in the ascending order of the cell index of the plurality of serving cells, and transmits the bundled ACK/NACK bits.

Abstract: A method that includes: (1) transmitting, at a first transmit time point, a first probe packet over a network connection to a conferencing server immediately before transmitting a data packet, the first probe packet arriving at the conferencing server at a first receive time point; (2) transmitting, at a second transmit time point, a second probe packet over the network connection to the conferencing server immediately after transmitting the data packet, the second probe packet arriving at the conferencing server at a second receive time point, the first and second probe packets being smaller than the data packet; (3) receiving information encoding a first difference between the first and second transmit time points and a second difference between the first and second receive time points; and (4) based on the first and second differences, modifying a transmission parameter associated with data packets to be transmitted thereafter to the conferencing server.

Abstract: A test and measurement system for synchronizing multiple oscilloscopes including a host oscilloscope and at least one client oscilloscope. The host oscilloscope includes a host timebase clock configured to output a clock signal, a host digitizer including a digitizer synchronization clock based on the clock signal, and a host acquisition controller includes a trigger synchronization clock based the clock signal and outputs a run signal to begin an acquisition of an input signal. Each client oscilloscope includes a client timebase clock configured to receive the clock signal from the host timebase clock and output the clock signal, a client digitizer including a digitizer synchronization clock based on the clock signal, and a client acquisition controller includes a trigger synchronization clock based on the clock signal and receives the run signal from the host acquisition controller and begins an acquisition of another input signal based on the run signal.

Abstract: The present invention addresses challenges associated with making timing measurements involving multifarious radio links. Such measurements are referred to herein as “enhanced” to connote that such timing determinations are being made across multifarious radio links. A radio link will be understood as connecting two radio nodes, and two radio links are considered to be multifarious with respect to each other if they are opposite in terms of uplink and downlink transmit directions, and further if they are associated with different cell identifiers and/or if the two links are between different pairs of radio nodes. The sharing of “enhanced timing measurement” capability information, e.g., between radio nodes and positioning nodes is disclosed. Such information indicates the enhanced timing measurement capability of a radio node. Sharing such information enables another node to determine an enhanced timing measurement configuration to be used by a radio node.

Abstract: An example method for segment routing based wide area network (WAN) orchestration in a network environment is provided and includes monitoring a segment routing (SR) enabled WAN environment in at least near real-time by a path computation element (PCE) located outside the WAN, receiving an event notification at the PCE, and performing traffic engineering using SR to reroute traffic off shortest paths. In one embodiment, where a current state of the WAN is not pre-computed, performing traffic engineering comprises optimizing routes to remove violation of any utilization policies, deploying the optimized routes in the WAN, re-optimizing routes for other parameters, and further deploying the re-optimized routes in the WAN. In another embodiment, performing traffic engineering comprises optimizing routes to remove violation of any utilization policies and for other parameters, and deploying the optimized routes in the WAN.

Abstract: A method performed by a network device may include assembling a multiprotocol label switching (MPLS) echo request, the echo request including an instruction for a transit node to forward the echo request via a bypass path associated with the transit node, and an instruction for an egress node to send an echo reply indicating that the echo request was received on the bypass path. The method may also include sending the MPLS echo request over a functioning label switched path (LSP).

Abstract: A method and apparatus are disclosed to establish and verify a Tunneled Direct Link Setup (TDLS) link between a first wireless device and a second wireless device. In some embodiments, the first wireless device may receive a TDLS setup confirmation message from the second wireless device. Based on the TDLS setup confirmation message, the first wireless device may transmit a TDLS verification message to the second wireless. The TDLS link may be verified when the second wireless device receives the TDLS verification message. In some embodiments, when the TDLS verification message is not received by the second wireless device, a TDLS check message may be sent by the second wireless device to the first wireless device. The first wireless device may transmit a TDLS check complete message based on the TDLS check message. The TDLS link may be verified when the second device receives the TDLS check complete message.

Abstract: A transmitting apparatus includes a first communicator, a designator, and a second communicator. The first communicator sends out a message by wireless broadcast communication to plural first communication apparatus, being located within a wireless communication range of the first communicator, of plural communication apparatus that have a wireless broadcast communication function and that constitute a wireless multi-hop network. The designator designates a second communication apparatus that is located outside the wireless communication range of the first communicator and that can establish a first communication channel, from among the plural communication apparatus having a the wireless broadcast communication function. The second communicator is wider in a communication range than the first communicator. The second communicator establishes the first communication channel with the second communication apparatus designated by the designator.

Abstract: A transmitting wireless device provides channel access information to a receiving wireless device for the receiving wireless device to make a determination of when to transmit and what transmissions parameters to use for the transmission. The channel access information may be used differently by wireless devices operating in a basic service set and an overlapping basic service set. Channel access information may include fields indicative of transmission power used, signal to noise ratio headroom available, and so on. Channel access information may be generated and transmitted at the PHY layer of an implementation, thus providing a fast delivery to the receiving wireless device.

Abstract: Classification techniques are employed in computer networks. For example, network activity is monitored in a computer network and the monitored network activity is used to discover an endpoint of unknown type. A first set of classification models is utilized to identify an endpoint type of the discovered endpoint based on the monitored network activity. In addition, communication patterns between different endpoints of known types are monitored in the computer network, and a second set of classification models is utilized to determine a logical topology of the computer network based on the monitored communication patterns.

Abstract: When a first throughput between the wireless device and a first access node meets a threshold, an application requirement of an application running on the wireless device is determined. Measurements are received of a first signal level of the communication link between the wireless device and the first access node and a second signal level of a signal from a second access node received at the wireless device. A first data rate is estimated using a first communication scheme between the wireless device and the first and second access nodes, and a second data rate is estimated using a second communication scheme between the wireless device and the first and second access nodes. One of the communication schemes is selected for use by the wireless device and the first and second access nodes based on the estimated first data rate and the estimated second data rate and the application requirement.

Abstract: Technology is discussed to allow transmission points within a Wireless Wide Area Network (WWAN) to adapt to Up Link (UL) and Down Link (DL) traffic demands independently. To mitigate potential interference arising from transmission points scheduled for conflicting UL and DL transmissions, measurements between transmission points can be made to indicate a level of coupling. Based on the various levels of coupling between transmission points, clusters can be formed. Where a high level of coupling is present, transmission points can be included in a common cluster. Where a low level of coupling is present, they can be isolated. Transmission points within the same cluster are scheduled with a common pattern of UL and DL transmissions to avoid interference. Transmission points in different clusters can have different patterns of UL and DL transmission to independently adapt to the relative demands for UL and DL transmissions experienced within these different clusters.

Abstract: A backnet can be created within a dedicated private network of a customer that enables a distinct party to access and/or control a portion of the resources within the private network. In one example, a backnet includes a separate virtual interface for an appliance or other such resource that is not visible or accessible to the customer owning the customer cloud, but can be accessed by another appliance or component in the customer cloud, or an appliance vendor external to the customer cloud. While the customer can control the permission for the backnet, the vendor can control or implement the resources within the backnet in a way that is isolated from the customer. Usage of the backnet can be separately monitored and billed to the vendor, even though the resources are part of the dedicated customer cloud.

Abstract: Push to talk (PTT) devices that communicate packet-based voice communications are disclosed. An example PTT device receives voice packets via a packet-based communication network from another PTT device. Voice information in the received voice packets are used to reconstruct the voice communication. The receiving PTT device is able to identify an occurrence of at least one delayed, corrupted or lost voice packet, and then communicate a packet re-transmit request to the other PTT device requesting a replacement voice packet that has a portion of the voice communication that is identical to the voice communication portion of the delayed, corrupted or lost voice packet. The voice communication may then be repaired based on the received replacement voice packet. While the voice communication is being repaired, a comfort tone may be generated so that the listener of the PTT device understands that the voice communication is being repaired.

Abstract: For bit rate adjustment based on ambient interference levels, an apparatus determines an ambient interference level of ambient interference. In addition, the apparatus modifies a bit rate of a lossy compressed data stream in response to the ambient interference level.

Abstract: Examples relate to determining access point power output. In one example, a computing device may: identify, for a particular access point, a plurality of neighboring access points; identify, for each neighboring access point, a pathloss value that indicates a difference in a transmit power of the neighboring access point and a received signal strength observed by the particular access point; identify, from the neighboring access points, at least one adjacent access point, each adjacent access point having a pathloss value that is less than a pathloss threshold; generate a representative pathloss using the pathloss values of each adjacent access point; determine a target power level for the representative pathloss; and provide at least one of the neighboring access points with instructions that cause the at least one neighboring access point to adjust a power output level of the at least one neighboring access point.

Abstract: A network component comprising at least one processor configured to implement a method comprising collecting wavelength availability information associated with a wavelength switched optical network (WSON), receiving a path computation request to transport a signal through the WSON, calculating at least one route through the WSON for the signal, and assigning at least one wavelength for the signal to use along the route. Also disclosed is a network comprising a first path computation element (PCE) configured to compute at least one route for a signal between a source and a destination, and a second PCE in communication with the first PCE, wherein the second PCE is configured to receive the route from the first PCE and assign at least one wavelength to the route.

Abstract: One or more management systems coordinate wavelength configuration patterns of a plurality of multi-wavelength optical transport nodes in an optical network for a first transport period. The one or more management systems determine data traffic demand changes in the optical network; and coordinate wavelength configuration patterns of the plurality of multi-wavelength optical transport nodes in the optical network for a second transport period, that is subsequent to the first transport period, based on the determined data traffic demand changes.

Abstract: A Wireless battery area network permits the wirelessly monitoring and controlling of individual batteries within large-scale battery applications. The system automatically configures its wireless nodes in the network and provides for the linking of a plurality of batteries (10) to a master battery management unit (M-BMU) (100) by establishing a wireless battery area network within a battery pack that include slave units (S-BMU) (210). The entire system may also be controlled by a top level battery management unit (T-BMU) (510). The system and method allows for the monitoring of voltage, current, temperature, or impedance of individual batteries and for the balancing or bypassing of a battery. A communications controller allows for optimization of wireless communications parameters and beamforming.

Abstract: In some embodiments, an apparatus includes a first network control entity within a control plane of a switch fabric system. The first network control entity is configured to receive a first test signal including a test instruction to be implemented within the switch fabric system. The first network control entity is configured to send a second test signal including the test instruction to a second network control entity such that the second network control entity implements the test instruction for a predetermined amount of time.

Abstract: A method, system and controlling bridge (CB) for acquiring port extension (PE) topology information, and a method and system for processing an upstream port, wherein, the method for acquiring the port extension (PE) topology information includes: a CB receiving a link layer discovery protocol (LLDP) message sent by the PE, and perceiving an attachment of the PE; the CB receiving Extended Port Create message sent by the PE, and instantiating corresponding instantiated ports inside the CB. By adopting the above-mentioned technical scheme, the topology information of the PE connected to the CB can be obtained and a channel for forwarding data can be established, effectively.

Abstract: Systems and methods of limiting wireless discovery range. A transmitting device may limit wireless discovery range by adjusting one or more transmission attributes of a discovery message, measuring inter-device distance based on range determination messages, or any combination thereof. A receiving device may limit wireless discovery range based on one or more attributes of a received discovery message, measuring inter-device distance based on range determination messages, or any combination thereof. Discovery messages may include a range adaptation bit indicating whether range adaptation is to be performed.

Abstract: The present invention relates to a wireless communication system. In detail, the invention relates to a method for a terminal to transmit a UCI in a carrier aggregation-based wireless communication system, and to an apparatus therefor, wherein the method involves the steps of: forming a first cell group having a PCell; forming a second cell group having one or more SCells; receiving one or more data in the second cell group; and transmitting HARQ-ACK information on the one or more data through a PUCCH, wherein, when the first and second cell groups are managed by an identical base station, the HARQ-ACK information is transmitted in the PCell, and, when the first and second cell groups are managed by different base stations, the HARQ-ACK information is transmitted in the second cell group.

Abstract: A method is provided in one example embodiment and includes receiving a request to create a path through a network, wherein the path originates on a first network device and terminates on the second network device; identifying a first controller associated with the first network device, wherein the first controller proxies control plane functions for the first network device; identifying a second controller associated with the second network device, wherein the second controller proxies control plane functions for the second network device; and computing the path using the first controller as a source and the second controller as a destination. The first controller installs the computed path on the first network device and the second controller installs the computed path on the second network device.

Abstract: The present invention discloses a method, an apparatus, and a system for detecting connectivity. A node receives connectivity detection request information; determines, according to nicknames of target nodes, whether the is one of the target nodes; if the node is one of the target nodes, sends connectivity detection reply information to a source node; if the node is not one of the target nodes, performs corresponding processing according to a value of a hop count and whether the node is on a path that is in the multicast distribution tree and is from the source node to any one of the target nodes. With the present invention, a source node is capable of receiving only a feedback of a node on a true path, thereby making it easier to identify a path.

Abstract: A system and method for diagnosing a problem on a packet network. Network performance information associated with data packet communications over a packet network may be collected. A network performance information parameter may be monitored and a determination that the network performance information parameter crosses a threshold value may be made. In response to determining that the network performance information parameter crossed the threshold value, diagnostics may be initiated to determine a cause of the network performance information parameter crossing the threshold value.

Abstract: Systems and methods are provided to facilitate the performance of a Session Border Controller (SBC)-localized handoff. As part of the SBC-localized handoff, a communication device may transmit packets within a data call to an SBC via a first IP address. Subsequently, the communication device may be assigned a second IP address. The communication device may then transmit further packets to the SBC via the second IP address. In response, the SBC may route all traffic within the data call direct to the communication device via the second IP address, regardless of whether the traffic indicates that the traffic should be delivered to the first IP address.

Abstract: According to certain aspects, embodiments of the invention relate to methods and apparatuses for performing diagnostics on a loop in a communications system. According to certain aspects, embodiments of the invention include performing SELT from a customer premises side of the loop. According to certain other aspects, embodiments of the invention address the issue of initiating a CPE side SELT procedure and also collecting the diagnostics data while a CPE is offline.

Abstract: A sensor value is obtained by a sensor included in a terminal from among a plurality of terminals each of which includes the sensor, the acquired sensor value is stored along with an identifier used to identify a terminal with which the acquired sensor value was acquired, identifiers are extracted with which a difference of corresponding stored sensor values is equal to or smaller than a threshold value by comparing stored sensor values corresponding to different identifiers, an instruction for acquiring the sensor value is transmitted to at least one of the terminals corresponding to the extracted identifiers, and an instruction for extending an interval of acquiring the sensor value is transmitted to the terminals which are other than the at least one of the terminals corresponding to the extracted identifiers.

Abstract: A method and apparatus for testing network links bi-directionally and independently employ local test apparatus (1000) at one end of the link (1105, 1110, 1115) and remote test apparatus (1200) at the opposite end of the link. The local test apparatus transmits test traffic to the remote test apparatus which analyzes the test traffic to determine characteristics of the link in the local-to-remote direction. While the analysis is taking place, the remote test apparatus transmits interim test results to the local test apparatus, i.e., while the remote test apparatus is still running the test and without disrupting the test. Preferably, the remote test apparatus transmits test traffic to the local test apparatus which the latter analyzes to determine characteristics of the link in the remote-to-local direction. The local test apparatus may report the test results for both directions. The network may be a connected or connectionless network.

Abstract: Methods and systems for discovering a path of network traffic that travels from a source host to a destination host are disclosed. A method involves, at the source host, generating probe packets that have the same load balancing parameters as packets of an application that generates application packets for transmission from the source host to the destination host and a path discovery signature comprised of bits from at least one of the network layer header and the transport layer header. The method also involves transmitting the probe packets from the source host to the destination host. In some embodiments, the steps of the method are performed when program instructions contained in a computer-readable storage medium are executed by one or more processors.

Abstract: Latency on different devices (e.g., devices of differing brand, model, vintage, etc.) can vary significantly and tens of milliseconds can affect human perception of lagging and leading components of a performance. As a result, use of a uniform latency estimate across a wide variety of devices is unlikely to provide good results, and hand-estimating round-trip latency across a wide variety of devices is costly and would constantly need to be updated for new devices. Instead, a system has been developed for automatically estimating latency through audio subsystems using feedback recording and analysis of recorded audio.

Abstract: A method for detecting errors in a transfer of data from a transmitter to at least one receiver includes coding the data together with address information identifying the receiver in a series of data packets and transferring the data and the address information using the data packets. The method also includes generating, at the transmitter, a check value for each data packet and transferring the check value with/in the data packet to the receiver. The method further includes comparing, at the receiver, the check value with an expectation value, wherein an error is detected in the event of a deviation. For each data packet to be transmitted, the method includes calculating a number sequence value from the address information using a first calculation rule, generating the check value from the sequence value using a second calculation rule and transmitting the data packet with the check value to the receiver.

Abstract: Aspects dynamically set enterprise-level security rules by assessing risk factors associated with a user. Risk values representing likelihoods of loss of enterprise secure data are determined for different attributes of a user, and added together to generate a user risk factor. If the risk factor does not meet one or more off-site access threshold value(s), additional security enhancements applicable to the user and not enabled within currently applied security are iteratively selected and used to revise the security settings, and the risk factor is revised by a risk abrogation value of each of the selected security enhancements, until either the revised risk factor meets the off-site access threshold value(s) (wherein access is granted to the secure data from the off-site location pursuant to the revised security settings), or until no additional applicable security enhancements are available (wherein user access to the secure data from the off-site location is denied).

Abstract: The present invention provides a method for determining a neighboring base station, a base station, and a processing network element. The method for determining a neighboring base station includes: receiving, by a base station, a measurement report, sent by a terminal, of another base station adjacent to the base station; sending, by the base station, the measurement report to a processing network element; and determining, by the processing network element, a neighboring base station of the base station according to the measurement report. The technical solution provided in the present invention can be used to determine a neighboring base station of a base station, which avoids a problem in the prior art that an error is likely to occur in manually determining a neighboring base station of a base station, thereby improving accuracy of determining a neighbor relationship between base stations.

Abstract: An information processing device includes a first communication interface, a second communication interface, a detecting unit, and a controller. The detecting unit detects a notification received by the first communication interface. In a case where the detecting unit detects a notification transmitted from the second communication interface to a communication medium connected to the second communication interface and indicating that a device serving as a transmission source has been connected to the communication medium, the controller performs control so that communication is not performed by at least one of the first communication interface and the second communication interface.

Abstract: In one embodiment, a device in a computer network establishes a reliable map that defines a set of packet criteria for which reliability is desired over an unreliable link to a peer device. In response to receiving a first packet from the peer device over the unreliable link, the device acknowledges the first packet to the peer device when the first packet matches the packet criteria of the reliable map. Also, in response to receiving a second packet destined via the peer device over the unreliable link, the device buffers the second packet when the second packet matches the packet criteria of the reliable map and retransmits the buffered second packet over the unreliable link to the peer device until acknowledged by the peer device.