Systems and methods are provided for providing predictive energy consumption feedback for powering a transport climate control system. This can include determining whether an energy level of an energy storage source is greater than an expected energy consumption of a transport climate control system during a route, based on route parameters. The route parameters may be obtained via a human-machine interface. When the energy storage source is less than the expected energy consumption, a user is alerted. The systems and methods may further compare the energy level to an expected energy level during transit to determine if the energy level is greater or less than expected and alert the user when the energy level is less than expected.

A method for preconditioning vehicles of a vehicle fleet, wherein vehicles of the vehicle fleet are provided at a vehicle fleet parking area when not used. The method includes the step of preconditioning a number of the vehicles of the vehicle fleet parked at the vehicle fleet parking area before such a vehicle is to be used, and the step of selecting the number of vehicles to be preconditioned based on historical data with respect to demand for using vehicles of the vehicle fleet.

A method for autonomous climate control optimization of a transport vehicle having a climate control system is provided. The method includes a controller receiving geolocation specific data providing location information of the transport vehicle. The method also includes the controller receiving climate control data providing operational status information of the climate control system. The method also includes the controller receiving passenger/load data providing passenger/load information travelling in the transport vehicle. Also, the method includes the controller generating adjustment instructions of the climate control system based on the geolocation specific data, the climate control data, and the passenger/load data. Further, the method includes adjusting operation of the climate control system based on the adjustment instructions.

During pre-air conditioning in a vehicle cabin, when consumed electric power exceeds use permission electric power while an auxiliary heating device is operating, an operation of the auxiliary heating device is stopped. In contrast, when the consumed electric power exceeds the use permission electric power while the auxiliary heating device is not operating, a rotation speed of an electric compressor of an air conditioner is restricted. Therefore, the temperature environment in the vehicle cabin is improved by continuing the pre-air conditioning of the air conditioner while reducing the consumed electric power by stopping the operation of the auxiliary heating device.

This disclosure relates to a system and method for isolating an interior of a motor vehicle from poor outdoor air quality. More particularly, this disclosure relates to a system and method configured to identify conditions associated with poor outdoor air quality and to respond to those conditions by isolating the interior of the motor vehicle from the outdoor environment. An example system includes a selector configured to permit a user to select a drive mode of the motor vehicle, a location system configured to detect a location of the motor vehicle, and a controller configured to issue one or more commands to isolate an interior of the motor vehicle from an environment outside the motor vehicle based on either a selected drive mode or a detected location.

A method and system for utilizing environmental data are described. The method includes receiving external environmental data and receiving in-cabin environmental data. A mitigation action for an in-cabin environment of a vehicle is provided. The mitigation action is based on the external environmental data and the in-cabin environmental data.

A vehicular vision system includes a front camera configured to be disposed at an in-cabin side of a windshield of a vehicle. The camera, when disposed at the vehicle windshield, views through the windshield forward of the vehicle. Responsive at least in part to processing by an image processor of image data captured by the front camera when disposed at the vehicle windshield, and while the equipped vehicle is traveling along a road, another vehicle on the road ahead of the equipped vehicle is detected. Responsive at least in part to processing by the image processor of captured image data, the vehicular vision system determines erratic driving of the detected other vehicle on the road ahead of the equipped vehicle and generates an output responsive to the determination of the erratic driving of the detected other vehicle on the road ahead of the equipped vehicle.

An air conditioning control device acquires environmental measurement information, acquires an action schedule of a user of a host vehicle on the basis of past or future schedule table information of the user, and estimates a boarding time at which the user gets on the host vehicle, a destination, and a route based on the action schedule. The control device then derives an instruction value pattern that includes a first instruction value for the air conditioning device at the boarding time, a second instruction value for the air conditioning device in a travel route toward the destination, and a third instruction value for the air conditioning device in a case that the user gets on after getting off the vehicle, based on the environmental measurement information. An air conditioning controller controls an air conditioning device of the host vehicle based on the instruction value pattern.

A management controller manages an automated valet parking service in which a vehicle travels autonomously to enter or exit a designated parking position in a parking lot having a plurality of parking positions. The management controller acquires the designated parking position of a service utilizing vehicle parked by the automated valet parking service. The management controller acquires a scheduled exit time of the service utilizing vehicle. The management controller determines a start timing of an air conditioner of the service utilizing vehicle based on the designated parking position and the scheduled exit time, and The management controller instructs the service utilizing vehicle to start the air conditioner at the start timing.

Disclosed is a system for managing power in a transport refrigeration unit (TRU) installed on a trailer, having: a TRU controller configured to execute a range extender mode of operation to manage operations of the TRU and TRU components, wherein the TRU controller: selects a power management strategy from a plurality of demand-side power management strategies; determines, from the selected power management strategy, operational parameters for a TRU; and executes the generated operational parameters.