Context-aware vehicle communications system and control logic with adaptive crowd-sensing capabilities

What is claimed: 1. A method for controlling operation of a motor vehicle, the motor vehicle including a prime mover, a sensor, an electronic user interface (EUI), a vehicle controller governing operation of the EUI, and a vehicle communications system wirelessly connecting the vehicle controller and EUI to a distributed computer network, the method comprising: determining, via the vehicle controller based on a signal received from the sensor, if the prime mover of the motor vehicle is in an on state; determining, via the vehicle controller responsive to the prime mover being in the on state, current trip characteristics, including start and destination locations, real-time vehicle data specific to the motor vehicle, and driver data specific to a driver of the motor vehicle, for a current trip of the motor vehicle; determining, via the vehicle controller, previous trip characteristics including respective duration data and routing data for each of one or more previous trips of the motor vehicle corresponding to the current trip; receiving, via the vehicle communications system over the distributed computer network from a vehicle participatory sensing system aggregating data from multiple participative vehicles, operational data, including road surface conditions, traffic conditions, and unexpected driving scenarios, for the current trip as sensed by the participative vehicles; analyzing the received operational data with the current trip characteristics and the previous trip characteristics to determine a predicted trip duration and/or a predicted trip route; and directing, via the vehicle controller, a safety system of the motor vehicle to change safety settings and/or the EUI to output to the driver of the motor vehicle the predicted trip duration and/or trip route determined from the analyzed operational data. 2. The method of claim 1 , further comprising adapting a data fidelity and/or a data sampling frequency of the received operational data based on a determined user expectation of the driver of the motor vehicle and/or a determined aggregate expectation of a group of the participative vehicles. 3. The method of claim 1 , further comprising adapting a presentation of the predicted trip duration and/or trip route based on a time context data and/or a location context data, the time context data including a designation of the current trip as either rush hour or midday and either nighttime or daytime, and the location context data including a designation of the current trip as either on commute or off commute and either familiar or unfamiliar. 4. The method of claim 1 , wherein the operational data further includes ambient lighting conditions data, weather conditions data, and/or driving intersection data collected by the participative vehicles. 5. The method of claim 1 , wherein the vehicle data includes respective operating states for one or more vehicle systems of the motor vehicle during the current trip. 6. The method of claim 1 , wherein the driver data includes respective operating characteristics for one or more driving variables of the driver during the current trip. 7. The method of claim 1 , wherein the driver data includes an indication that the driver is either a defensive or aggressive driver, either tends to speed or not speed, and/or a number of driving violations for the driver. 8. The method of claim 1 , wherein the current trip characteristics for the current trip of the motor vehicle further include a start time, an intended route to reach the destination location from the start location, and/or a current location of the motor vehicle. 9. The method of claim 1 , wherein the previous trip characteristics include a respective start time, a respective start location, a respective trip duration and/or a respective destination location for each of a plurality of the previous trips taken by the driver with the motor vehicle. 10. The method of claim 1 , further comprising: receiving, via the vehicle communications system from the vehicle participatory sensing system, historical trip duration data corresponding to the current trip as sensed by the participative vehicles; and directing the EUI to output to the driver of the motor vehicle an indication of whether the current trip of the motor vehicle is predicted to be early, on time, or late based on a comparison of the historical trip duration data and the predicted trip duration. 11. The method of claim 10 , further comprising: responsive to the current trip of the motor vehicle being predicted to be early, directing the EUI to output to the driver of the motor vehicle an opportunistic route diversion; and responsive to the current trip of the motor vehicle being predicted to be late, directing the EUI to output to the driver of the motor vehicle a calming measure, modifying operation a vehicle system to implement increased protection measures, and/or delaying presentation of non-critical information to the driver by the EUI. 12. The method of claim 1 , wherein the analyzing includes aggregating the received operational data, current trip characteristics, and previous trip characteristics, filtering the aggregated data, and purging select portions of the aggregated data. 13. The method of claim 1 , wherein the EUI is an audiovisual (AV) telematics unit mounted inside a passenger compartment of the motor vehicle, and wherein outputting the predicted trip duration and/or trip route is via the AV telematics unit. 14. A motor vehicle comprising: a vehicle body with a passenger compartment; a prime mover including an engine and/or a motor; an audiovisual (AV) telematics unit mounted within the passenger compartment and operable to transmit audio and/or video information to a driver of the motor vehicle; a vehicle communications system mounted to the vehicle body and operable to wirelessly connect the AV telematics unit to a distributed computer network; and an AV electronic control unit (ECU) communicatively connected to the AV telematics unit and the vehicle communications system, the AV ECU being programmed to: determine, via a signal received from a sensor, if the prime mover is in an on state; responsive to the prime mover being in the on state, determine current trip characteristics, including start and destination locations, real-time vehicle data specific to the motor vehicle, and driver data specific to the driver of the motor vehicle, for a current trip of the motor vehicle; determine previous trip characteristics including respective duration data and routing data for each of multiple previous trips of the motor vehicle corresponding to the current trip; receive, via the vehicle communications system from a vehicle participatory sensing system aggregating data from multiple participative vehicles, operational data, including road surface conditions, traffic conditions, and unexpected driving scenarios, for the current trip as sensed by the participative vehicles; analyze the received operational data with the current trip characteristics and the previous trip characteristics to determine a predicted trip duration and/or a predicted trip route; and direct a safety system of the motor vehicle to change safety settings and/or the AV telematics unit to output to the driver of the motor vehicle the predicted trip duration and/or trip route determined from the analyzed operational data. 15. The motor vehicle of claim 14 , wherein the AV ECU is further programmed to adapt a data fidelity and/or a data sampling frequency of the received operational data based on a determined user expectation of the driver of the motor vehicle and/or a de