A method for vehicle selection performed by a user equipment (UE) associated with a customer includes transmitting, from the UE to a vehicle control system, customer location information identifying a location of the customer. The method also includes receiving, from the vehicle control system based on transmitting the customer location information, vehicle location information and a set of compartment climate values associated with each vehicle of a set of vehicles within a range of the location of the customer. The method further includes outputting the current compartment climate value and a location associated with the vehicle location information of each vehicle of the set of vehicles for display at the UE. The method still further includes transmitting, to the vehicle control system, a message indicating a selection of one vehicle of the set of vehicles based on receiving a customer input at the UE, the one vehicle being selected based on one or both of the current compartment climate value of the one vehicle and the location associated with the vehicle location information of the one vehicle.

A control stand is disclosed for controlling a crane, an excavator, a crawler, or a similar construction machine having a seat, control elements actuable from the seat for inputting control commands, a display apparatus for displaying information, and a control unit for generating adjustment signals in dependence on input control commands and/or for providing information to the display apparatus. A crane is disclosed having such a control stand that can be configured in the form of a crane operator's cabin. The control elements and/or the display apparatus of the control stand and various further auxiliary units can be individually configurable. Personal pre-settings can be saved and can be reinvoked when the control stand or the crane is to be controlled by a certain machine operator.

An apparatus, a system, and a method for controlling an in-car temperature of an autonomous vehicle are provided. The control server determines an expected in-car temperature according to a re-riding time of each of one or more parking positions corresponding to a destination or a re-riding position of an autonomous vehicle, selects an optimal parking position or a temporary parking position based on the expected in-car temperature and an outdoor air temperature according to the re-riding time, transmits information about the optimal parking position or the temporary parking position to the autonomous vehicle. The controller of the autonomous vehicle is configured to perform autonomous driving and autonomous parking depending on the information about the optimal parking position or the temporary parking position, recognizes a voice of a user, determines autonomous driving related control corresponding to the voice of the user, and performs the autonomous driving related control corresponding to the voice of the user.

A control stand is disclosed for controlling a crane, an excavator, a crawler, or a similar construction machine having a seat, control elements actuable from the seat for inputting control commands, a display apparatus for displaying information, and a control unit for generating adjustment signals in dependence on input control commands and/or for providing information to the display apparatus. A crane is disclosed having such a control stand that can be configured in the form of a crane operator's cabin. The control elements and/or the display apparatus of the control stand and various further auxiliary units can be individually configurable. Personal pre-settings can be saved and can be reinvoked when the control stand or the crane is to be controlled by a certain machine operator.

A transport refrigeration system comprising: a refrigerated compartment, a refrigeration unit operably coupled to the refrigerated compartment, and a controller for controlling the environment within the refrigerated compartment by controlling the refrigeration unit; a container for storing perishable goods; and a wireless module secured to the container and configured to store a target container temperature; wherein the controller is configured to: receive the target container temperature from the wireless module responsive to the container being placed in the refrigerated compartment; and control the environment within the refrigerated compartment by controlling the operation of the refrigeration unit in accordance with the target container temperature.

A parking air conditioning device and a mounting bracket thereof are provided. The mounting bracket includes a loading frame. The loading frame includes a bottom bracket and a first connecting member fixedly connected to the bottom bracket to form a mounting position. The mounting frame includes a second connecting member and a plurality of first bolts. The second connecting member is located at a side of the first connecting member away from the mounting position and is spaced apart from the first connecting member. The first bolts are connected to the first connecting member and the second connecting member. When the mounting bracket is connected to a vehicle body crossbeam, the first bolts are respectively located at the upper and lower sides of the vehicle body crossbeam, and the first connecting member and the second connecting member clamp the vehicle body crossbeam.

There is provided a method comprising: determining an occupancy status of a first region of a vehicle; determining, based at least in part on the occupancy status, a first climate control setting for the first region; controlling a climate control system of the vehicle to adjust a climate of the first region according to the first climate control setting; determining that a second region of the vehicle is unoccupied, wherein the second region is fluidly connected to the first region; determining a second climate control setting, wherein the second climate control setting is based at least in part on the occupancy status of the first region and characteristic data associated with a predicted potential change in occupancy status for the second region; and controlling the climate control system to adjust a climate of the second region according to the second climate control setting.

A method for vehicle management performed by a vehicle control system includes monitoring a respective location associated with each vehicle of a plurality of vehicles based on location information transmitted from each of the plurality of vehicles. The method also includes receiving, from a user equipment (UE) associated with a customer, customer location information identifying a location of the customer. The method further includes receiving, from each vehicle of the plurality of vehicles, a set of current compartment climate values based on a triggering event at the vehicle. The method still further includes selecting one vehicle of the plurality of vehicles as a preferred vehicle based on a set of climate preferences associated with the customer. The method also includes transmitting, to the preferred vehicle, a message dispatching the preferred vehicle to the location of the customer, such that the preferred vehicle navigates to the location of the customer.

An air flow control system includes a plenum having an air inlet, a first air outlet, a second air outlet and a third air outlet, a vent door, an air guide, carried on the vent door, and an actuator. The actuator displaces the vent door between a first position closing the first air outlet and a second position opening the first air outlet. A climate control method for an autonomous vehicle is also provided.

An autonomous robot is provided. In one example embodiment, an autonomous robot can include a main body including one or more compartments. The one or more compartments can be configured to provide support for transporting an item. The autonomous robot can include a mobility assembly affixed to the main body and a sensor configured to obtain sensor data associated with a surrounding environment of the autonomous robot. The autonomous robot can include a computing system configured to plan a motion of the autonomous robot based at least in part on the sensor data. The computing system can be operably connected to the mobility assembly for controlling a motion of the autonomous robot. The autonomous robot can include a coupling assembly configured to temporarily secure the autonomous robot to an autonomous vehicle. The autonomous robot can include a power system and a ventilation system that can interface with the autonomous vehicle.