In some embodiments, a dynamic shading system of a vehicle includes one or more occupant sensors, a window configured for dynamic shading, and a control unit communicatively coupled to the one or more occupant sensors and the window. The one or more occupant sensors are configured to output a signal indicative of a position of each of one or more occupants within the vehicle. The control unit executes logic to shade areas of the window based on the position of each of the one or more occupants in order to shade each of the one or more occupants in accordance with a shade preference of each of the one or more occupants.

In some embodiments, a dynamic shading system of a vehicle includes one or more occupant sensors, a window configured for dynamic shading, and a control unit communicatively coupled to the one or more occupant sensors and the window. The one or more occupant sensors are configured to output a signal indicative of a position of each of one or more occupants within the vehicle. The control unit executes logic to shade areas of the window based on the position of each of the one or more occupants in order to shade each of the one or more occupants in accordance with a shade preference of each of the one or more occupants.

A road surface display device mounted to an own vehicle includes: a road surface image control portion generating a road surface image which is displayed on a road surface ahead of the own vehicle and includes images each indicating an expected arrival zone where the own vehicle is expected to arrive at an expected arrival time; a detection portion obtaining display states of a different vehicle image, which is a road surface image displayed by a different vehicle, and an own vehicle image, which is the road surface image displayed by the own vehicle, and detecting a presence of overlapping or proximity between the two images; and a display adjustment portion, when the presence of overlapping or proximity is detected, displaying an image indicating a shorter expected arrival time in a region where the presence of overlapping or proximity is detected on the road surface.

The present invention is a safety and alert system installed in a child seat of a vehicle. The system has at least one weight detector to detect the presence of a child on a child seat. Temperature sensors and a heart monitor will be activated when the presence of a child is detected. A processing unit processes signals received from one of the sensors or a GPS tracker unit, when the body temperature of a child and the inside temperature of a vehicle are not within a preset safe range and/or when the child is unattended for a period of time more than the preset time limit. These signals are then sent to the alerting unit to allow proper action to be taken. A GPS tracker unit tracks the current location of the vehicle and sends location information to the proper authorities. The alerting unit sends sound messages, text messages or electronic emails to a user. At least one tint sticker and LED light are installed on a vehicle window to indicate and alert people outside of the vehicle, by turning ON LED lights, that a child has been left unattended in a vehicle or that there is an emergency involving a child inside of a vehicle.

Technical solutions are described for vehicle collision prevention for a vehicle when the vehicle is in a parked condition. An example method includes performing a stationary safety monitoring when the vehicle is in parked condition. The stationary safety monitoring includes detecting presence of a moving object within a predetermined region from the vehicle. Further, the method includes, in response to detecting the moving object in the predetermined region initiating a notification for the moving object to prevent collision with the vehicle.

A lane change support apparatus includes an electronic control unit configured to, when it is recognized that there is an abnormality in a driver of a host vehicle, determine whether or not lane change is possible. The electronic control unit is configured to determine that the lane change is possible when a vehicle speed of the host vehicle is lower than a predetermined upper limit speed, a following vehicle present closest to the host vehicle has stayed in a rear guard vehicle approval range for a predetermined time or longer, and a vehicle is not present in a lane change allowance gap.

A system for monitoring vehicle dynamics and detecting adverse events during operation is presented. Position sensors attached to a vehicle are configured to identify a vehicle orientation (heading) as well as the vehicle's direction of travel (trajectory). A system controller connected to these position sensors can detect the difference between these two measurements. When the difference between these two measurements exceeds a safety threshold, it can be an indication of a slip event. A slip event can be caused by compromised traction or stability and may lead to a loss of vehicle control. The system controller can be configured to monitor various vehicle dynamics to detect these slip events. The system controller may be configured to track geolocations of slip events to create a database of historical slip events for determining location-based risk factors and prevention of future events.

The present disclosure relates generally to safety lighting devices for automotive vehicles. A safety lighting system coupled to an automotive vehicle includes a power source that is independent of an electrical system of the vehicle. The system also includes a lighting feature electrically coupled to the power source, wherein the lighting feature is configured to activate in response to an impact event.

A method for forming an emergency lane on a multi-lane road on which multiple transportation vehicles are located on at least two parallel driving lanes and on which at least one emergency vehicle is located, wherein the emergency vehicle is connected to more than one of the transportation vehicles via a wireless communications connection to exchange data and the transportation vehicles are prompted to form an emergency lane via the wireless communications connection. A transportation vehicle having an apparatus for implementing the method.

A method for forming an emergency lane on a multi-lane road on which multiple transportation vehicles are located on at least two parallel driving lanes and on which at least one emergency vehicle is located, wherein the emergency vehicle is connected to more than one of the transportation vehicles via a wireless communications connection to exchange data and the transportation vehicles are prompted to form an emergency lane via the wireless communications connection. A transportation vehicle having an apparatus for implementing the method.