Abstract: A wireless network includes leaf nodes (such as wireless sensors or other wireless devices) and infrastructure nodes (such as access points). The leaf nodes communicate data messages to the infrastructure nodes. The infrastructure nodes communicate the data messages to gateway infrastructure nodes, which transmit the data messages over a wired network. The leaf nodes may communicate data messages to multiple infrastructure nodes in various ways. For example, the leaf nodes may transmit multiple messages, one at a time, to multiple infrastructure nodes. The leaf nodes may also broadcast a single message to multiple infrastructure nodes. In addition, the leaf nodes may communicate a single message containing a group identifier (such as a multi-cast group address) associated with multiple infrastructure nodes. In this way, communications from the leaf nodes may be more reliable. This may be particularly useful, for example, in networks such as 802.11-based networks.

Abstract: A wireless network includes leaf nodes (such as wireless sensors or other wireless devices) and infrastructure nodes (such as access points). The leaf nodes communicate data messages to the infrastructure nodes. The infrastructure nodes communicate the data messages to gateway infrastructure nodes, which transmit the data messages over a wired network. The leaf nodes may communicate data messages to multiple infrastructure nodes in various ways. For example, the leaf nodes may transmit multiple messages, one at a time, to multiple infrastructure nodes. The leaf nodes may also broadcast a single message to multiple infrastructure nodes. In addition, the leaf nodes may communicate a single message containing a group identifier (such as a multi-cast group address) associated with multiple infrastructure nodes. In this way, communications from the leaf nodes may be more reliable. This may be particularly useful, for example, in networks such as 802.11-based networks.

Abstract: A network includes a plurality of logical access entities. Each access entity includes one or more communication interfaces. The network further includes a plurality of logical node entities. Each logical node entity includes one or more communication interfaces that are configured to wirelessly communicate in a redundant manner with any of the logical access entities. In an embodiment, a communication degradation in the network is assessed, and the network is configured as a function of that assessment to provide fault tolerance within the network.

Abstract: A network includes a plurality of logical access entities. Each access entity includes two or more communication interfaces. The network further includes a plurality of logical node entities. Each logical node entity includes two or more communication interfaces that are configured to wirelessly communicate in a redundant manner with any of the logical access entities. In an embodiment, a communication degradation in the network is assessed, and the network is configured as a function of that assessment to provide fault tolerance within the network.

Abstract: An apparatus includes a plurality of antennas, where each antenna is configured to receive wireless signals transmitted using adaptive beam forming. The apparatus also includes a plurality of wireless radios, where each wireless radio is configured to output signals representing the wireless signals received by one of the antennas. The apparatus further includes a plurality of first diversity combiner units, where each first diversity combiner unit is configured to perform spread spectrum diversity combining using the signals output by one of the wireless radios. In addition, the apparatus includes a second diversity combiner unit configured to perform antenna diversity combining using signals output by the first diversity combiner units, where the second diversity combiner unit is configured to output recovered wireless signals.

Abstract: Various techniques are disclosed for improved reliability of wireless communications using packet combination-based error correction. For example, a method includes receiving a first message transmitted wirelessly, where the first message contains a first copy of a data packet and has at least one error. The method also includes receiving a second message transmitted wirelessly, where the second message contains a second copy of the data packet and has at least one error. The method further includes identifying a set of bit positions based on where the first and second copies of the data packet differ and modifying the set of bit positions to produce a modified set of bit positions. In addition, the method includes modifying one or more bit values in the modified set of bit positions to produce at least one modified copy of the data packet and determining if the at least one modified copy of the data packet is error-free.

Abstract: A method includes providing wireless service to a mobile leaf node using at least one first infrastructure node in an industrial control or monitoring system. The method also includes detecting movement of the mobile leaf node away from the at least one first infrastructure node. The method further includes handing off the mobile leaf node to at least one second infrastructure node in the industrial control or monitoring system so that the at least one second infrastructure node provides the wireless service to the mobile leaf node. The wireless service provided to the mobile leaf node remains deterministic. Various techniques can be used to detect the movement of the mobile leaf node. Also, the first and second infrastructure nodes could be in different clusters of nodes, and various techniques can be used to support handoffs between infrastructure nodes in different clusters.

Abstract: A method to dynamically reconfigure a network by receiving a data packet for transmission from a node in the network at a media access control layer of the node and determining a slot assignment for the data packet based on an application required quality of service. The application required quality of service is determined based on at least one of a number of slots required by the data packet, an application-specified data rate, an application-specified delay requirement and an application-specified number of reserved retries, and application-associated priority values for the data packet. The media access control layer is enabled for time division multiple access.

Abstract: A system includes multiple wireless nodes forming a cluster in a wireless network, where each wireless node is configured to communicate and exchange data wirelessly based on a clock. One of the wireless nodes is configured to operate as a cluster master. Each of the other wireless nodes is configured to (i) receive time synchronization information from a parent node, (ii) adjust its clock based on the received time synchronization information, and (iii) broadcast time synchronization information based on the time synchronization information received by that wireless node. The time synchronization information received by each of the other wireless nodes is based on time synchronization information provided by the cluster master so that the other wireless nodes substantially synchronize their clocks with the clock of the cluster master.

Abstract: An apparatus includes a transceiver configured to transmit wireless signals to and receive wireless signals from wireless nodes associated with an industrial process. The apparatus also includes a controller configured to initiate transmission of the wireless signals and to process data contained in the received wireless signals. The transceiver includes a diversity receiver configured to process the wireless signals from the wireless nodes. The transceiver may be further configured to perform beam-shaping in order to transmit a directional beam to at least one of the wireless nodes. Also, the controller may be configured to perform spatial routing by identifying a target of a wireless transmission and to initiate transmission of the directional beam towards a known or estimated location associated with the identified target.

Abstract: A method includes repeatedly transmitting messages from a first wireless node at a transmit power. The method also includes receiving feedback from a second wireless node, where the feedback is based on a quality of reception of at least some of the messages at the second wireless node. The method further includes adjusting the transmit power of the first wireless node based on the feedback to maintain the quality of reception proximate to a setpoint. The feedback could be received from multiple second wireless nodes. The feedback could include quantized values. The quality of reception could include a bit error rate, a packet error rate, and/or a receive signal strength. The quality of reception can be determined for a sliding window associated with a subset of the transmitted messages.

Abstract: A method includes obtaining a data message having data associated with a process system and mapping the data message to one of multiple classifications. The method also includes wirelessly transmitting the data message, where a Quality of Service (QoS) associated with the transmission is based on the mapping. Mapping the data message could include identifying a type associated with the data message and mapping the data message based on the identified type. The type may include a publish message type, an alert message type, or a management message type. The publish message type could be mapped to an Unsolicited Grant Service (UGS) class, the alert message type could be mapped to a real-time Polling Service (rtPS) class, and the management message type could be mapped to a Best Effort (BE) or non-real-time Polling Service (nrtPS) class. A WiMAX standard could be used to transmit the message, and a WiMAX or WiFi standard could be used to obtain the message.

Abstract: A system includes multiple wireless nodes forming a cluster in a wireless network, where each wireless node is configured to communicate and exchange data wirelessly based on a clock. One of the wireless nodes is configured to operate as a cluster master. Each of the other wireless nodes is configured to (i) receive time synchronization information from a parent node, (ii) adjust its clock based on the received time synchronization information, and (iii) broadcast time synchronization information based on the time synchronization information received by that wireless node. The time synchronization information received by each of the other wireless nodes is based on time synchronization information provided by the cluster master so that the other wireless nodes substantially synchronize their clocks with the clock of the cluster master.

Abstract: A system includes a first cluster having multiple first wireless nodes. One first node is configured to act as a first cluster master, and other first nodes are configured to receive time synchronization information provided by the first cluster master. The system also includes a second cluster having one or more second wireless nodes. One second node is configured to act as a second cluster master, and any other second nodes configured to receive time synchronization information provided by the second cluster master. The system further includes a manager configured to merge the clusters into a combined cluster. One of the nodes is configured to act as a single cluster master for the combined cluster, and the other nodes are configured to receive time synchronization information provided by the single cluster master.

Abstract: A process control system having wireless nodes (field devices, routers, wireless gateways, etc.) communicating with enhanced throughput using frequency hopping. The frequency channel using which each node transmits is determined by frequency agility/frequency hopping technique. Multiple nodes then transmit the packets in their respective channels, but in overlapping duration. In one embodiment such a technique is employed in combination with TDMA, with the boundaries of time slots being ‘global’ (same for all the nodes in the network) and thus the overlapping duration equals the duration of the time slot. In an alternative embodiment employed in combination of SDMA, each node transmits in a (substantially) non-overlapping corresponding beam area, but without reference to global boundaries. In yet another alternative embodiment, a combination of SDMA, TDMA and overlapping duration is used.

Abstract: Wireless devices, systems and approaches or methods having the capability of determining the location of a given wireless device. An example system includes a wireless device that generates at least one pulse as a part of an output signal, and the at least one pulse is captured by anchor devices and used, in a time of arrival approach, to determine the location of the example device. The at least one pulse may be generated during a designated portion of an otherwise normally modulated message. Another example system includes an anchor node that generates a directional output signal, the direction output signal including data indicating its direction, and the directions of output signals from plural anchor nodes when pointed at a wireless device are used to determine the location of the wireless device. Combinations of the pulse and directional antenna systems, devices used within each of these systems, and approaches associated with these systems are also included.

Abstract: A wireless network includes leaf nodes (such as wireless sensors or other wireless devices) and infrastructure nodes (such as access points). The leaf nodes communicate data messages to the infrastructure nodes. The infrastructure nodes communicate the data messages to gateway infrastructure nodes, which transmit the data messages over a wired network. The leaf nodes may communicate data messages to multiple infrastructure nodes in various ways. For example, the leaf nodes may transmit multiple messages, one at a time, to multiple infrastructure nodes. The leaf nodes may also broadcast a single message to multiple infrastructure nodes. In addition, the leaf nodes may communicate a single message containing a group identifier (such as a multi-cast group address) associated with multiple infrastructure nodes. In this way, communications from the leaf nodes may be more reliable. This may be particularly useful, for example, in networks such as 802.11-based networks.

Abstract: A direction finding system used with an exit having a transmitter at that exit sending a location beam having a direction with respect to a compass direction. A receiver is carried by a person seeking directional guidance to the exit. The receiver receives the beam and determines the direction of the beam with respect to the compass direction. A display indicates the direction in which the person should move to reach the exit. Either the transmitter or the receiver or both may use an antenna array for sending and/or receiving a plurality of signals, each having a specific direction with respect to the compass direction. In a preferred embodiment, the receiver corrects for differences between the sent direction and the actual direction received.

Abstract: A wireless network system includes a plurality of nodes. Each node includes two or more redundant network interfaces, and each one of these network interfaces operates on a different channel. A plurality of links couple the nodes together. A layer residing on each of the nodes detects a link status associated with each interface, and switches to a redundant interface of a node when the link degrades beyond a tolerance. The routing and control layer provides redundant non-overlapping routes.

Abstract: A network includes a plurality of logical access entities. Each access entity includes one or more communication interfaces. The network further includes a plurality of logical node entities. Each logical node entity includes one or more communication interfaces that are configured to wirelessly communicate in a redundant manner with any of the logical access entities. In an embodiment, a communication degradation in the network is assessed, and the network is configured as a function of that assessment to provide fault tolerance within the network.