Presented are control systems for operating rechargeable electrochemical devices, methods for making/using such systems, and vehicles with intelligent battery charging and charging behavior feedback capabilities. A method of operating a rechargeable battery includes an electronic controller receiving battery data from a battery sensing device indicative of a battery state of charge (SOC). Using this battery data, the controller determines a number of low SOC excursions at which the battery SOC is below a predefined low SOC threshold and a number of high SOC excursions at which the battery SOC exceeds a predefined high SOC threshold. The controller then determines if the number of low SOC excursions exceeds a predefined maximum allowable low excursions and/or the number of high SOC excursions exceeds a predefined maximum allowable high excursions. If so, the controller responsively commands a resident subsystem to execute a control operation that mitigates degradation of the rechargeable battery.

A vehicle drive mode selection system selects a preset drive mode for a vehicle when sensors on the vehicle’s steering wheel are triggered. Upon triggering of the sensors on the steering wheel, a drive mode selector of the vehicle is configured to switch a current drive mode of the vehicle to the preset drive mode.

A method for assisting a vision of a driver includes: receiving a signal indicating that weather information is emergency weather information from a navigation device according to setting by a vehicle driver, and turning on a vision assisting device included in the vehicle in response to the signal; obtaining an image of an infrared thermal camera of the vision assisting device, which photographs a front of the vehicle when the vehicle travels, and obtaining an image of a camera of the vision assisting device, which photographs the front of the vehicle when the vehicle travels; controlling an image processor of the vision assisting device to determine whether a matching rate between image data of the infrared thermal camera and image data of the camera is equal to or less than a first threshold; and, when the matching rate is equal to or less than the first threshold, using distances between the vehicle and respective objects located at the front, a rear, and sides of the traveling vehicle, speeds of the respective objects, which are detected by a radar sensor of the vision assisting device, and the images of the infrared thermal camera photographing the front of the vehicle to generate a surrounding state image of the vehicle, which includes the distances and the speeds.

Arrangements described herein can display a set speed deviation for a vehicle using spatiotemporal patterns. A set speed and an actual speed for a vehicle can be acquired. A deviation between the set speed and the actual speed of the vehicle can be determined. Responsive to determining the deviation between the predetermined set speed and the actual speed, a spatiotemporal pattern can be displayed within the vehicle. The spatiotemporal pattern can indicate to a user the deviation between the set speed and the actual speed via the spatiotemporal pattern. In one or more arrangements, the spatiotemporal pattern can be a repeating wave pattern.

A driving control system of a vehicle sets a target speed as an automatic setting speed when the driving control system is an automatic speed setting mode, changes a speed setting mode to a manual speed setting mode when a speed change input is received in the automatic speed setting mode, sets the target speed as a manual setting speed when the driving control system is a manual speed setting mode, changes the manual setting speed depending on the speed change input when the speed change input is received in the manual speed setting mode, and changes the speed setting mode to the automatic speed setting mode when the manual setting speed coincides with the automatic setting speed in the manual speed setting mode.

A control system for a vehicle comprises a controller comprising a processor and a non-transitory computer-readable medium including instructions. The system comprises first, second, and third inputs configured to be manipulated by an operator. The system comprises first, second, and third displays adjacent the first, second, and third inputs, respectively. The first, second and third displays are configured to show first, second, and third indicia, respectively. Manipulation of the first input by the operator transmits a selection input signal to the controller. The controller receives the selection input signal. The processor compares the selection input signal to the instructions in the non-transitory computer-readable medium, transmits a selection output signal to the second and third displays, removes the second and third indicia from the second and third displays, and shows a first sub-selection indicium on the second display and a second sub-selection indicium on the third display.

A method for determining stability of a vehicle having a load suspended from the vehicle is provided. The method can include obtaining measurements from a plurality of sensors positioned on the vehicle, obtaining a measurement from a vehicle accelerometer operative to determine an inclination of the vehicle, determining a position of the load suspended from the vehicle, determining a slung load of the load suspended from the vehicle, using the determined slung load and the determined position of the load suspended from the vehicle, determining tipping moments acting on the vehicle, determining righting moments acting on the vehicle and determining a tipping stability based on the determined tipping moments and determined righting moments.

An apparatus for controlling a display of a cluster for a vehicle includes: a setting unit receiving settings indicating three-dimensional (3D) levels with respect to various information from an operator; a communication unit collecting information to be displayed on the cluster; a control unit controlling the cluster to apply 3D levels corresponding to the information collected by the communication unit and to display the collected information with the corresponding 3D levels applied thereto; and the cluster displaying the collected information with the corresponding 3D levels applied thereto.

Systems, methods, and other embodiments described herein relate to providing cooperative control according to system conditions of a vehicle. In one embodiment, a method includes determining a system condition associated with operation of functions associated with an assistance system within an ego vehicle. The system condition is based, at least in part, on environmental conditions around the ego vehicle. The method includes defining available modes according to which control modes of the ego vehicle can operate with the system condition. The method includes controlling the ego vehicle according to a selected mode of the available modes.

Systems and methods are provided for presenting in a hybrid electric vehicle display, proximate to or in some relation to each other, engine power usage, motor-generator power usage, and battery state of charge information. By combining the display of engine power usage, motor-generator power, and battery state of charge information, power distribution and related information may be presented to the operator of a vehicle to explain the vehicle's performance from a power split output and usage perspective. This can provide reassurance or confirmation that the vehicle is operating as it should, identify a problematic condition, etc.