A remote control an automotive vehicle, the remote control including a 3-D shaped object, stretch sensors connecting the 3-D shaped object to a structure of the vehicle and a control unit configured to collect information from the stretch sensors, the remote control being configured to control a display of the automotive vehicle, the remote control being configured to be integrated in a stretchable fabric part of an interior of the vehicle.

A computer-implemented remote starting method includes instructing the remote start of a vehicle using a wireless device. The method also includes inputting, to the wireless device, a desired vehicle interior temperature. The method further includes sending a remote start instruction to a vehicle from the wireless device, including at least the desired temperature and monitoring a current temperature of the vehicle. The method additionally includes outputting, on the wireless device, the current vehicle temperature.

The techniques of this disclosure relate to a vehicle occupancy-monitoring system. The system includes a controller circuit that receives occupant data from an occupancy-monitoring sensor of a vehicle. The controller circuit determines an occupancy status of respective seats in a cabin of the vehicle based on the occupancy-monitoring sensor. The controller circuit indicates the occupancy status of the respective seats on a display located in a field of view of occupants of the vehicle. The display is integral to one of a roof light module, a door panel, or a headliner of the cabin. The system can improve passenger safety by alerting the operator and other occupants about the occupancy status of the passengers.

The disclosure is generally directed to remotely-controlled automated vehicle parking operations. A driver of a vehicle stands on a curb and launches a software application on a handheld device. The software application uses a camera of the handheld device to capture images of the vehicle that can be observed by the driver. The software application then attempts to obtain a visual lock between the camera and the vehicle. In some cases, obtaining the visual lock may be hampered due to adverse lighting conditions. Light may be transmitted from the handheld device to illuminate the vehicle for better image capture. Alternatively, a command can be transmitted from the handheld device to a controller in the vehicle for turning on a light in the vehicle. After obtaining visual lock, various techniques such as vehicle path prediction and interpolation, can be used for effectively tracking the vehicle.

A vehicular display control device including: a memory; and a processor coupled to the memory, the processor being configured to: detect when an operation region including plural switches provided to a steering wheel has been operated; and in a case in which operation of the operation region has been detected, display, at a display region set in front of a driving seat, an operation region image corresponding to the operation region and a status image indicating a current status of a function allocated to the switch that is being operated among the plural switches.

A brake control system includes a display, a processor, and a light sensor. The processor controls brakes of a towed vehicle. The processor also controls a brightness of the display based on information received from the light sensor. The light sensor may include a light dependent resistor or a photoresistor. The processor selectively sets or adjusts the brightness of the display based on sensed ambient light.

A head mounted system can include a video camera that is configured to provide image data. A wireless interface circuit can be configured to receive augmentation data from a remote server. A processor circuit can be coupled to the video camera, where the processor circuit can be configured to register the image data with the augmentation data and combine the image data with the augmentation data to provide augmented image data. A projector circuit, coupled to the processor circuit, the projector circuit can be configured to project the augmented image data from the head mounted system onto a surface.

A vehicle is provided to analyze a signal received by a communicator and identify a first electronic device that transmits the received signal and a second electronic device that will transmit the received signal. The vehicle identifies a lighting algorithm that corresponds to an analysis result of the received signal and sequentially turns on a plurality of lighting devices based on the identified lighting algorithm.

The present disclosure relates to a portable, hand held and/or mountable control device for remote controlling at least one device provided by a vehicle. The control device comprises one or more control applications and indicator icons on a touch sensitive display and one or more motion and orientation detection sensors. The control application provided as keys on the display is selected based on user input and based on the user selected control application the device to be controlled can be controlled wirelessly by voice, steering tilt or motion based operation of the control device. Additionally, the control device can determine a fault or a correct completion of controlling by monitoring the devices. The present disclosure also provides a method for remote controlling the at least one device provided by the vehicle.

The systems and methods disclosed herein are configured to provide a mobile device for remotely controlling the movement of a vehicle and trailer. The mobile device provides an intuitive user interface and control input mechanism for controlling the movement of the vehicle and trailer with one hand. In particular, the control input mechanism performs a method to determine an arrangement of controls for use with one hand.