Managing vehicle operations according to driver behavior by: defining a multi-dimensional preemptive driver daily behavior (PDDB) data structure; defining a PDDB abnormal behavior criteria; and defining a PDDB abnormal behavior algorithm. Further, by: collecting PDDB data; acquiring a PDDB assessment according to the PDDB analysis; and preemptively communicating driver vehicle-access instructions according to the PDDB assessment.

A system for analyzing the environment of a vehicle i) receives a plurality of data from at least one sensor associated with a vehicle, such that the plurality of data includes at least one environmental condition at a location; (ii) analyzes the plurality of data to determine the at least one environmental condition at the location; (iii) determines a condition of a building at the location based upon the at least one environmental condition; (iv) determines an insurance product for the building based upon the determined condition associated with the building; and (v) generates an insurance quote for the insurance product. As a result, the speed and accuracy of insurance providers learning about potential clients and the conditions of the potential client's property and needs is increased.

A system and method of controlling network traffic for a network in a device that has a plurality of units, including one or more provider and recipient units. The recipient units are configured to send respective subscription requests for data originating from the provider units. A controller is programmed to enter an initial phase when at least one initial condition is met. A repeat phase is entered when a list of currently active subscription is received. In the repeat phase, the controller is configured to monitor the network for a respective timing checking request sent by the provider units. When the controller receives a timing checking request, the controller stores the request in the queue module as respective queue member. The controller is configured to perform a timing analysis test on a selected member of the queue module and control the device based partly on the timing analysis test.

A driving system for a first vehicle comprises a first and second sensor configured to obtain proximity data for one or more vehicles proximate the first vehicle, and a processor in communication with the first and second sensors and programmed to perform the functions of identifying a plurality of vehicles in a first field-of-view instance based on the proximity data, wherein the plurality of vehicles in the first field-of-view has a trajectory to approach a second field-of-view instance based on the proximity data, and adjusting a vehicle maneuver in response to one of the plurality of vehicles being absent from the second field-of-view instance.

Driver assistance is provided. An issue corresponding to a driver of a vehicle is automatically identified based on analysis of collected data. A set of actions is selected to address the identified issue corresponding to the driver based on the analysis of the collected data and preference data of the driver. The driver is notified of the selected set of actions to address the identified issue corresponding to the driver.

A method for enabling driver operation of a motor vehicle includes receiving an electrical signal representing a property sensed by touching a region of skin of an occupant in the motor vehicle, and determining whether the occupant's ability to drive the motor vehicle is impaired based on the electrical signal. The method further includes performing an image based verification to determine whether the occupant from whom the property was sensed is in a driving position of the motor vehicle, and providing a control signal to enable operation of the motor vehicle based on a result of the determining and a result of the image based verification.

An automatic driving system for an automatically driven vehicle. In the system, a travel direction acquirer is configured to acquire travel direction information that is information indicative of whether or not each of lanes in a parking lot is unidirectional. In addition, in the system, an allowance determination unit is configured to, if determining, based on the travel direction information acquired by the travel direction acquirer, that each of the lanes in the parking lot is unidirectional, allow automatic driving of the automatically driven vehicle.

A system and method of controlling network traffic for a network in a device that has a plurality of units, including one or more provider and recipient units. The recipient units are configured to send respective subscription requests for data originating from the provider units. A controller is programmed to enter an initial phase when at least one initial condition is met. A repeat phase is entered when a list of currently active subscription is received. In the repeat phase, the controller is configured to monitor the network for a respective timing checking request sent by the provider units. When the controller receives a timing checking request, the controller stores the request in the queue module as respective queue member. The controller is configured to perform a timing analysis test on a selected member of the queue module and control the device based partly on the timing analysis test.

A platoon control system includes a platoon control in communication with a plurality of individual platoon vehicle controls associated with respective platoon vehicles of a platoon of vehicles traveling along an initial traffic lane. The platoon control determines if there is sufficient clearance in another lane for the platoon of vehicles. Responsive to the platoon control, the individual platoon vehicle controls control the respective platoon vehicles to maneuver the platoon vehicles from the initial traffic lane to the other lane in a manner that limits or substantially precludes other vehicles from interrupting the platoon of vehicles. Responsive to the platoon control, the individual platoon vehicle controls control the respective platoon vehicles to allow a new platoon vehicle to enter the platoon of vehicles and/or to regroup following departure of a platoon vehicle from the platoon of vehicles.

Various technologies described herein pertain to causing presentation on a user interface of an immediate portion of a navigation route of an autonomous vehicle. A computing system of the autonomous vehicle determines whether an object detected by sensor(s) of the autonomous vehicle proximate to the immediate portion of the navigation route are of a type and relative position defined as one of consequential and inconsequential for a human passenger. In response to determining that an object has both a type and relative position defined as consequential, the computing system causes presentation on the user interface a representation of the object relative to the immediate portion of the navigation route to provide a confidence engendering indication that the autonomous vehicle has detected the object. Otherwise if inconsequential, presentation on the user interface of any representation of the object is not caused by the computing system to avoid creating a confusing presentation.