Abstract: An apparatus includes an image recorder configured to record video images. The apparatus also includes a display screen configured to present the video images to a user and to create notations overlying one or more of the video images based on user input. The apparatus further includes a transceiver configured to stream the video images over a wireless mesh network and to transmit data associated with the notations over the wireless mesh network. The apparatus could also include components for providing cryptographic keys to wireless nodes joining the wireless mesh network, a sensor for detecting or measuring one or more characteristics, and/or an asset tracker for transmitting or receive signals for identifying a location of the apparatus. The apparatus could further include at least one voice unit supporting bidirectional voice communications and/or a site survey unit for identifying signal strengths associated with detected wireless nodes.

Abstract: Redundant, non-overlapping paths or routes for a sensor signal in a mesh network are selected based on predetermined metrics. In one embodiment, a wireless sensor transmits a signal that is received by two separate infrastructure nodes. The signal is retransmitted by the two intermediate nodes via the selected non-overlapping routes to a controller node. Routes are identified for at least two infrastructure nodes that receive signals from an added sensor. Performance metrics are calculated for each route. The two routes with the best performance metrics are selected in one embodiment.

Abstract: A system includes a wireless leaf node configured to modify operation of an industrial process. The system also includes a plurality of wireless access points configured to transmit data to the wireless leaf node in specified time slots and to receive an acknowledgement from the wireless leaf node in response to successful receipt of the data by the wireless leaf node. Various communication schemes are disclosed for supporting communications between the wireless leaf node and the access points. Each access point could also include a local slot manager configured to assign the specified time slots for that access point to communicate with the wireless leaf node. The wireless leaf node could represent a wireless actuator.

Abstract: Wireless communication systems using transmitter initiated communications methods. Several devices in the system listen by following a common frequency hopping sequence. When communication is desired, a transmitting device sends a request to send signal to an addressee; if available, the addressee sends a clear to send signal, and the transmitting device and the addressee then perform communications using a separate frequency hopping sequence. Methods for adding new devices are also included. In an example, a new device uses a discovery frequency hopping sequence to ping a number of frequencies until the common frequency hopping sequence is discovered. In another example, a new device listens on a single frequency forming part of the common frequency hopping sequence until the common frequency hopping sequence overlaps the single frequency.

Abstract: A system, apparatuses, and methods support simultaneous connectivity between devices in an industrial control and automation or other system. For example, a data publisher can publish or provide data to multiple data subscribers. This can be done using a multicast group associated with the multiple data subscribers. The data publisher transmits a data message using a network address associated with the multicast group. Each data subscriber associated with the multicast group receives a copy of the data message. As a particular example, the data publisher could represent a wireless sensor or wireless actuator in the industrial control and automation or other system. Also, the data subscribers could represent multiple controllers or actuators in the industrial control and automation or other system. In this way, the multicasting functionality allows for simpler connectivity or interaction between devices in the industrial control and automation or other system.

Abstract: Wireless communication systems using transmitter initiated communications methods. Several devices in the system listen by following a common frequency hopping sequence. When communication is desired, a transmitting device sends a request to send signal to an addressee; if available, the addressee sends a clear to send signal, and the transmitting device and the addressee then perform communications using a separate frequency hopping sequence. Methods for adding new devices are also included. In an example, a new device uses a discovery frequency hopping sequence to ping a number of frequencies until the common frequency hopping sequence is discovered. In another example, a new device listens on a single frequency forming part of the common frequency hopping sequence until the common frequency hopping sequence overlaps the single frequency.

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 method includes wirelessly receiving first data at a first backbone router and routing the first data from the first backbone router to a backbone network using a backbone connection of the first backbone router when the backbone connection is operational. The method also includes detecting a failure of the backbone connection after routing of the first data and automatically reconfiguring the first backbone router to function as a field router that does not route data using the backbone connection. The method further includes wirelessly receiving second data at the first backbone router and wirelessly routing the second data along an alternate path from the first backbone router to a second backbone router without using the backbone connection. The method could also include establishing the alternate path between the first backbone router and the second backbone router based on whether the first and second backbone routers are within wireless range.

Abstract: Different components in a wireless transceiver are powered using different power supplies. For example, one or more first tasks in the wireless transceiver can be powered with a Galvanic cell, and one or more second tasks in the wireless transceiver can be powered with a fuel cell. The one or more first tasks could represent higher-current or intermittent tasks, and the one or more second tasks could represent lower-current or continuous tasks. The one or more first tasks could include transmission of a radio frequency (RF) signal, which may involve RF signal modulation or RF signal amplification. The one or more second tasks could include RF signal tuning, RF signal reception, RF signal demodulation, analog-to-digital conversion, digital-to-analog conversion, digital signal processing, operation of a controller, illumination of a display, operation of an audio speaker, operation of a microphone, or operation of a keypad.

Abstract: Wireless configuration tools for communicating with and configuring wireless device systems. An illustrative tool makes use of a software defined radio (SDR) to communicate in multiple formats, modes, or frequencies, with multiple wireless device systems that may otherwise be incompatible. In some embodiments, the tool determines what type and how many wireless systems are to be configured prior to configuration of any of the systems. The tool may then adjust how each system is configured to reduce intra-system as well as inter-system interference. Methods for performing such functions are also included.

Abstract: A method includes storing a security credential associated with a communication network on a portable storage device. The method also includes detecting removal of the portable storage device from a specified location. The method further includes allowing at least one communication device to communicate over the communication network using the security credential. In addition, the method includes revoking the security credential after a specified time period has elapsed. The portable storage device could represent a card, and the specified location could represent a card reader/writer. Also, the communication network could represent a wireless network, and the security credential could represent a cryptographic key.

Abstract: A method includes identifying a condition associated with a communication network and/or an industrial control and automation system. The method also includes selecting, based on the identified condition, one or more quality of service (QoS) parameters used to route data through the communication network. In addition, the method includes communicating information identifying the one or more QoS parameters to one or more components in the communication network. The one or more QoS parameters could be contained within one of multiple QoS policies, and the method could include selecting one of the QoS policies. The condition could represent an emergency condition, and the one or more QoS parameters could include a higher QoS priority for traffic (such as voice communications and sensor data) to and from specified personnel (such as first responders). The communication network could represent at least one wired network and/or at least one wireless network.

Abstract: A method includes obtaining data to be transmitted wirelessly and detecting if any transmitting devices having a higher priority are currently using at least one of multiple wireless channels. The method also includes transmitting the data wirelessly over the multiple wireless channels in a first specified manner when no transmitting devices having the higher priority are detected. The method further includes transmitting at least a portion of the data wirelessly over the multiple wireless channels in a second specified manner when at least one transmitting device having the higher priority is detected. The data could normally be transmitted using OFDM. When a higher-priority transmitting device is detected, at least a portion of the data could be transmitted using a reduced transmit power and a reduced constellation size and/or larger error correcting code. One or more wireless channels associated with one of two quadrature components could also be suppressed.

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 receiving data at a first wireless node in a wireless network, where the data is associated with an industrial control and automation system. The method also includes decrypting the received data using a first encryption key to produce decrypted data and encrypting the decrypted data using a second encryption key to produce encrypted data. The method further includes communicating the encrypted data to at least a second wireless node in the wireless network. Another method includes generating first data at a first wireless node in a wireless network, where the data is associated with an industrial control and automation system. The other method also includes encrypting the first data using an encryption key and transmitting the first data to multiple second wireless nodes in the wireless network, where the second wireless nodes are capable of using the same encryption key to decrypt the first data.

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 method includes wirelessly receiving first data at a first backbone router and routing the first data from the first backbone router to a backbone network using a backbone connection of the first backbone router when the backbone connection is operational. The method also includes detecting a failure of the backbone connection after routing of the first data and automatically reconfiguring the first backbone router to function as a field router that does not route data using the backbone connection. The method further includes wirelessly receiving second data at the first backbone router and wirelessly routing the second data along an alternate path from the first backbone router to a second backbone router without using the backbone connection. The method could also include establishing the alternate path between the first backbone router and the second backbone router based on whether the first and second backbone routers are within wireless range.

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.