Abstract: A system and a method of using a centralized hub that controls and authenticates which aerial and/or terrestrial vehicles are on a local vehicle operations travelway. Communications networks are established that can handle one-off decisions for local networks, regarding the vehicles. This centralized hub may be implemented for each location, and federated with other centralized hubs.

Abstract: A system and a method of using a centralized hub that controls and authenticates which aerial and/or terrestrial vehicles are on a local vehicle operations travelway. Communications networks are established that can handle one-off decisions for local networks, regarding the vehicles. This centralized hub may be implemented for each location, and federated with other centralized hubs.

Abstract: A method of configuring a network within a vehicle, wherein the network includes a plurality of network elements and a plurality of communication links communicatively coupling the plurality of network elements for point-to-point communication, includes storing a last known configuration state of the network. Then, the network is monitored to determine a change in the configuration state of the network to establish a current configuration state. The current configuration state is then point-to-point propagated through the network via the communication links, and is stored at each of the plurality of network elements.

Abstract: Disclosed herein are embodiments of a flexible, extensible, modular approach to electrical and communication system architecture in a vehicle. In accordance with certain embodiments of the present invention, standardized, high-volume housings and components referred to as Plug-In Modules (PIMs) are used in vehicle electrical centers. By carefully designing standardized PIMs, the same PIMs can be used (in differing quantities) on any vehicle in the range of vehicles manufactured. Furthermore, the same PIMs can even be used across different vehicle manufacturers. The use of standard modules and standard housings allows for very high-volume production, thereby dramatically reducing the cost of the electrical centers. At the same time, there can be virtually zero giveaway in vehicles with lower option content. Methods of power and signal distribution using the disclosed electrical and communication system are provided. Methods of manufacturing the electrical and communication system are further provided.

Abstract: System and method for determining a workload level for a driver of a vehicle. The system includes a transceiver, a positioning unit, and a controller. The transceiver is capable of receiving data from a remote location. The data includes a remote workload level and a remote geographic position associated with the remote workload level. The positioning unit is capable of determining a current position of the vehicle. The controller is configured to compare the current position of the vehicle with the remote geographic location. If the current position of the vehicle is within a predetermined range of the remote geographic position, then a workload level for the vehicle will include at least in part the remote workload level.

Abstract: A vehicle communication network (200) includes a plurality of network elements (202–212) and a plurality of communication links (214–230) communicatively coupling the network elements in a point-to-point configuration. At least a portion of the plurality of communication links are specified in accordance with a shared-access bus protocol. The plurality of communication links are arranged to communicate data packets between the network elements, and data packets are modified for transport via the plurality of communication links.

Abstract: System and method for guiding a driver of a vehicle (20) from a starting point to a destination point using an assignment of levels of urgency of navigation cues. The system comprises a navigation unit (38), a controller (22) and a user interface (42). The navigation unit (38) is capable of selecting a route between the starting point and the destination point. The navigation unit (38) is further capable of generating a plurality of navigation cues to guide the driver along the selected route. The controller (22) is connected to the navigation unit (38) and receives navigation cues. The controller (22) has an urgency calculator (40) that is capable of assigning a level of urgency to the navigation cues. The controller (22) may also have a workload manager (60) that is capable of classifying an activity state of the driver as well as updating the level of urgency of the navigation cue. The user interface (42) presents the navigation cues based on the level of urgency of the navigation cues.

Abstract: Nodes which include additional sensing and communication capability as compared to prior nodes. The sensing capability allows determination of actual current flows through the particular nodes, including each port of the node, to allow a determination of power flow to better control operations. Because of this understanding of power flow, smaller modules or nodes can be utilized if desired. For protection of a lower power node, an upstream node can open the link to the node should it go overcurrent or otherwise fault. Further, with the additional sensing capability, actual load balancing and multiple controllable flows, such as for standby, can be developed. The additional communication in combination with the sensing also allows better fault isolation. By being able to determine the actual location of the fault, other operations in the vehicle can continue with just the faulty area being disconnected.

Abstract: A power management device (200) and a method for use in a power distribution network (100) receives electrical energy and first determines if the power is a primary or secondary power source. When a secondary power source, the power management device (200) waits in standby mode, but when the power is primary power source the power management device (200) configures itself to route power to another node in the power distribution network (100). Power levels and faults within the network can be monitored and controlled by a central controller. Likewise loads (218, 220) may then be powered on as determined by a central controller to reduce LdI/dt voltage spikes and other undesirable side effects.

Abstract: A vehicle network and method for communicating information within a vehicle. The network includes a plurality of network elements joined by communication links. A data frame is provided for communicating information between a first device and a second device attached to the network. A network element in the network is capable of mapping a first resource on an incoming communication link of the network element to a second link resource of an outgoing communication link of the network element. The network element further has ports for receiving the data frame from the first link resource of the incoming communication link and for communicating the data frame to the second link resource of the outgoing communication link. The mapping may be done statically or dynamically such as based on information stored in the network element or based on information stored in the data frame.

Abstract: A system and method for coordinating parameters in a switch fabric network (22) of a vehicle (20). The network (22) has a plurality of nodes (24) that are interconnected by communication links for the transmission of data packets there between. Events in the vehicle (20) may be handled in connection with a vehicle parameter. One example of a vehicle parameter that may be used in the vehicle is the rotation of a crank shaft in the vehicle. An application uses that information to make a determination whether change a setting of a device in the vehicle (20). If so, the application generates a command data packet and transmits the command data packet over the switch fabric network (22). The command data packet transmitted by the application includes the new setting for the device along with a value of the vehicle parameter when the new setting should occur in the device.

Abstract: A system and method for tunneling standard bus protocol messages through an automotive switch fabric network. When a bus protocol message arrives on a connecting node in the network, a bus driver in the node will capture the message and store it into a message buffer where the message can be further processed by a tunneling application. Each received bus protocol message will be broken, or combined, to suit the available packet size of the underlying transmit layer of the switch fabric network. Data portions such as message identification, sequence number, port number, bus data type, and data length are reserved in each data packet. If the message is being broken down, the sequence number is used to differentiate the broken segments of the bus protocol message. The bus data type is used to indicate the type of protocol data being transmitted over the switch fabric. The same tunneling application may be used to reassemble the bus protocol message at a receiving node.

Abstract: System and method for guiding a driver of a vehicle (20) from a starting point to a destination point using an assignment of levels of urgency of navigation cues. The system comprises a navigation unit (38), a controller (22) and a user interface (42). The navigation unit (38) is capable of selecting a route between the starting point and the destination point. The navigation unit (38) is further capable of generating a plurality of navigation cues to guide the driver along the selected route. The controller (22) is connected to the navigation unit (38) and receives navigation cues. The controller (22) has an urgency calculator (40) that is capable of assigning a level of urgency to the navigation cues. The controller (22) may also have a workload manager (60) that is capable of classifying an activity state of the driver as well as updating the level of urgency of the navigation cue. The user interface (42) presents the navigation cues based on the level of urgency of the navigation cues.

Abstract: A vehicle network architecture includes an interrupted shared-access bus and a switch fabric incorporated therein at the point of interruption. The switch fabric permits incorporation of a feature or device into the shared access bus architecture without modification or revisions of the shared access bus protocol or legacy devices.

Abstract: A vehicle communication network (200) includes a plurality of network elements (208-212) and a plurality of communication links (214-230) communicatively coupling the network elements in a point-to-point configuration. At least a portion of the plurality of communication links may be specified in accordance with a shared-access bus protocol. The plurality of communication links are arranged to communicate data packets between the network elements.

Abstract: A power management device (200) and a method for use in a power distribution network (100) receives electrical energy and first determines if the power is a primary or secondary power source. When a secondary power source, the power management device (200) waits in standby mode, but when the power is primary power source the power management device (200) configures itself to route power to another node in the power distribution network (100). Power levels and faults within the network can be monitored and controlled by a central controller. Likewise loads (218, 220) may then be powered on as determined by a central controller to reduce LdI/dt voltage spikes and other undesirable side effects.

Abstract: An interface includes a base with locking flanges for securing the base to a second structure within a vehicle. A plurality of switch caps are pivotably supported on the base and extend through apertures formed in the base. Each switch cap has a first surface and a second surface such that pressure applied to one of the first surface and the second surface causes limited rocking motion of the switch cap and actuation of a corresponding momentary contact switch.

Abstract: A vehicle communication network (200) includes a plurality of network elements (208-212) and a plurality of communication links (214-230) communicatively coupling the network elements in a point-to-point configuration. A portion of the communication capability is reserved according to a class of message traffic.

Abstract: A vehicle communication network (200) includes a plurality of network elements (208-212) and a plurality of communication links (214-230) communicatively coupling the network elements in a point-to-point configuration. At least a portion of the plurality of communication links may be specified in accordance with a shared-access bus protocol. The plurality of communication links are arranged to communicate data packets between the network elements.

Abstract: A vehicle communication network (200) includes a plurality of network elements (202-212) and a plurality of communication links (214-230) communicatively coupling the network elements in a point-to-point configuration. At least a portion of the plurality of communication links are specified in accordance with a shared-access bus protocol. The plurality of communication links are arranged to communicate data packets between the network elements, and data packets are modified for transport via the plurality of communication links.