Abstract: Monitoring of a vehicle is provided. A plurality of video feeds captured from cameras of the vehicle are received, over a network from a vehicle, each of the plurality of video feeds including a plurality frames, each of the frames of each of the video feeds being assigned a sequence number that increases for each successive frame. The sequence numbers are analyzed to identify missing frames, delayed frames, or stale frames. The plurality of video feeds is displayed, to one or more monitors, the sequence numbers corresponding to the displayed frames, and for each of the plurality of video feeds, indications of whether any missed frames, delayed frames, or stale frames were identified.

Abstract: A system includes a multi-access edge computing camera that can determine characteristics of a group of waiting vehicle passengers based on machine-classification and count of individual elements of the group derived from imaging the group with the camera and supplement at least the count based on short-range wireless broadcast received from mobile devices possessed by members of the group. The camera conveys the characteristics to a dispatch process, and the dispatch process determines that a non-dispatched fleet vehicle has present capacity to accommodate the determined characteristics. The dispatch process determine that the characteristics meet a defined predicate for dispatch of the non-dispatched fleet vehicle and responsive to determining that the characteristics meet a defined predicate for dispatch of the non-dispatched fleet vehicle, dispatches the fleet vehicle.

Abstract: The disclosure generally pertains to systems and methods for providing off-road track drivability guidance. In an example scenario, a processor receives a sensor signal that is generated when a vehicle is driven on an off-road track. The processor evaluates the sensor signal to obtain information about a driving surface of the off-road track such as, a material composition, a gradient, and/or an amount of provided traction. The processor conveys the information to another processor (which may be a part of a server computer) that determines a drivability status of the off-road track based on the information about the driving surface and additional parameters, such as present and/or future weather conditions. The server computer may provide the drivability status in response to a query from a processor that is located in another vehicle (or in a personal communication device carried by a driver of the vehicle).

Abstract: An autonomous vehicle may determine that it has an amount of power remaining projected to be needed to reach a recharging point by autonomously traveling with predefined systems disabled. The vehicle may disable the predefined systems and travel towards the recharging point. Subsequent to the disabling, the autonomous vehicle may determine that it no longer has the amount of power remaining projected to be needed to reach the recharging point. The vehicle may then communicate with a server and request assistance. The vehicle may then travel to an instructed rendezvous point with a second autonomous vehicle, the rendezvous received from the server. The two vehicles may then communicate to allow the first vehicle to leverage a capability of the second autonomous vehicle, responsive to the first and second autonomous vehicles being within communication range, allowing the first vehicle to reach the recharging point via the leveraging.

Abstract: A method is disclosed for vehicular operation on a road comprising a road network configured to communicate with one or more vehicles on the road, the method comprising sending a signal from a first vehicle to the road network, the signal comprising an intended path of the first vehicle on the road; receiving the signal at the road network; and adjusting at least one of a speed and a path of a second vehicle with respect to the road in response to the signal.

Abstract: A vehicle computer can be programmed to detect, in a vehicle, one of a plurality of variations, based on data received from one or more vehicle sensors or a vehicle interface, to transmit, to a remote computer, variation data including the detected variation and a version of software in the vehicle computer, wherein the variation data identifies the detected variation and the version of the software, to receive, from the remote computer, a response including that a software update is identified based on the detected variation, and upon identifying the software update, to download and install the software update in the vehicle computer.

Abstract: Synchronized work zone traffic management systems and methods are disclosed herein. An example method includes synchronizing, by a first vehicle, communication with a second vehicle over a wireless link, and displaying alternatingly, by the first vehicle, one of two messages on a first external display according to an alternating schema. A first message indicates to drivers to drive slowly and a second message indicates to the drivers to stop. The first message being displayed on the first external display when the second vehicle is displaying the second message on a second external display. The first vehicle displaying the second message on the first external display when the second vehicle is displaying the first message on the second external display. The alternating displaying of the first and second messages being used to control flow of traffic on a one-way street.

Abstract: A system includes a stationary infrastructure element including a camera mounted to the infrastructure element and an infrastructure server. The infrastructure server includes a processor and a memory, the memory storing instructions executable by the processor to receive a request from a movable vehicle, the request identifying a data anomaly including at least one of (1) a sensor of the vehicle collecting data below a confidence threshold or (2) a geographic location outside a geographic database of the vehicle, to actuate the camera to collect image data of one of the vehicle or the geographic location, to identify geo-coordinates of the vehicle or the geographic location based on identified pixels in the image data including the vehicle or the geographic location, and to provide the geo-coordinates to the vehicle to address the data anomaly.

Abstract: A system includes a processor configured to detect the presence of a wireless network access point usable for vehicular communication. The processor is also configured to connect to the wireless access point and report connection information relating to the connected wireless access point to an entity capable of establishing direct cellular connection with a vehicle, identifying the connected wireless access point as an alternative communication method if cellular communication is unavailable.

Abstract: Using key performance indicator (KPI) data sensed by vehicles is provided. A data server is programmed to receive, over a wide-area network from a plurality of vehicles, connectivity data of modems of the plurality of vehicles to the wide-area network, the connectivity data indicating KPI data, which road segment was being traversed when the KPI data was captured, and a time period during which the KPI data was captured. The data server is further programmed to identify outlier data elements in the KPI data using outlier detection criteria; and compile the KPI data per road segment and time period excluding the outlier data elements.

Abstract: Drone-based vehicle connectivity systems and methods are disclosed herein. A method can include determining a loss of network connectivity by any of a vehicle and/or a drone associated with the vehicle, receiving an emergency message from the vehicle, launching the drone to navigate to a location where network connectivity exists, and transmitting the emergency message to a service provider when a connection to a network is established.

Abstract: A server may determine that two-way communication to a plurality of autonomous vehicles has been lost, during conditions suitable for using the autonomous vehicles for evacuation. The server may also determine evacuation points and determine a geographic perimeter around each evacuation point, the perimeter projected to encompass sufficient vehicles to service the evacuation point based on determined evacuation needs of a given evacuation point. Further, the server may formulate an evacuation instruction for each evacuation point, each instruction having one or more parameters, including at least the geographic perimeter corresponding to a given evacuation point, wherein a given evacuation instruction instructs vehicles executing the instruction to travel to the corresponding evacuation point.

Abstract: A vehicle receives a first portion of content via ATSC broadcast, generates a random nonce, responsive to receiving the content, and sends the nonce and a request for content verification to a remote server. The vehicle receives a message from the remote server indicating whether the first portion of content is likely valid, the message including a second portion of content and a hash value when the content is likely valid. The vehicle then calculates a second hash value, using the random nonce and the first portion of content. The vehicle compares the second hash value to the first hash value, and responsive to the second hash value matching the first hash value, combines the second portion of content and the first portion of content to create combined content. The vehicle then uses a security strategy to convert the combined content into utilizable content, and utilizes the content.

Abstract: This disclosure is generally directed to harvesting electrical energy from RF signals that may be present in a vehicle. The RF signals may include cellular signals and Wi-Fi signals, for example. In an example system, an RF signal strength evaluator may be used to evaluate the RF signals in order to identify a strongest RF signal or a strongest band of RF signals that can be harvested to obtain electrical energy. An RF-to-electrical energy converter converts the RF signals(s) to electrical energy, which can be stored in an energy storage element. The energy storage element can be coupled to a device charger for charging various types of devices in the vehicle. In some instances, the system can be used to generate an ambient RF energy map that may be used by one or more vehicles to identify an optimal spot to park for harvesting RF signals.

Abstract: A system includes a processor configured to determine a navigation instruction execution location within a predefined distance from a vehicle location. The processor is also configured to communicate with a wireless transceiver to receive information identifying an intervening turn-option location, between the execution location and vehicle location. The processor is further configured to determine a distance between the vehicle location and turn-option location and display the determined distance on a navigation display, until the vehicle passes the turn-option location.

Abstract: A server may determine that two-way communication to a plurality of autonomous vehicles has been lost, during conditions suitable for using the autonomous vehicles for evacuation. The server may also determine evacuation points and determine a geographic perimeter around each evacuation point, the perimeter projected to encompass sufficient vehicles to service the evacuation point based on determined evacuation needs of a given evacuation point. Further, the server may formulate an evacuation instruction for each evacuation point, each instruction having one or more parameters, including at least the geographic perimeter corresponding to a given evacuation point, wherein a given evacuation instruction instructs vehicles executing the instruction to travel to the corresponding evacuation point.

Abstract: A server may determine a plurality of recommended exit paths for vehicles departing a locality. The server may also correlate a plurality of present geofenced locations within the locality to exit paths, so that each location has one or more exit paths correlated thereto, informing vehicles within a given locality about the one or more exit paths recommended for that locality. Further, the server may instruct an ATSC transmitter to broadcast map data for the locality, the map data including designations of geofences around the locations and the correlations between the geofenced locations and the exit paths.

Abstract: A point-to-multipoint retransmit of the parking availability data is performed with a predefined update period. A quantity of unicast requests for parking availability is received via one or more cellular towers. If the quantity of unicast requests received within the predefined update period exceeds a ratio of point-to-multipoint bandwidth to unicast messaging bandwidth of the one or more cellular towers, a transition is made to use of the point-to-multipoint messaging for sending the parking availability data via the one or more cellular towers; and otherwise, a transition is made to use of the unicast messaging for sending the parking availability data via the one or more cellular towers.

Abstract: A system includes a processor configured to determine that a vehicle is in a predefined power-preservation state. The processor is also configured to determine a lowest transmit-power available cellular band for vehicle telematics services, responsive to the power-preservation state. The processor is further configured to disable all bands other than the lowest-power available band and use the lowest-power available band for vehicle communication as long as the power-preservation state persists.

Abstract: A system determines at least one driving style, reflecting driving behavior for a driver of a vehicle and based on inputs from a plurality of vehicle systems. The system receives a plurality of wireless signals from elements within a wireless communication range, each signal indicating the behavior of one or more drivers of other vehicles within a predefined distance of the vehicle. Further, the system determines, based on the wireless signals, whether one or more drivers are exhibiting behavior comparable to the driver of the vehicle based on predefined comparison thresholds and, responsive to determining that one or more drivers are exhibiting comparable behavior, provides guidance as to how to maneuver the vehicle to reach the vehicles driven by the one or more drivers exhibiting comparable behavior.