Described herein is a visual indication system implemented on a mobile machine. The visual indication system at least partially surrounds the mobile machine and includes a plurality of displayable regions. Objects surrounding the mobile machine are detected using an object detection sensor. A direction with respect to the mobile machine is detected for each of the objects. A current state of the mobile machine is determined. An object-directed indicator for each of the objects is generated based on the current state of the mobile machine. The object-directed indicator for each of the objects is displayed on the visual indication system at a particular displayable region based on the direction of the particular object.

Techniques pertaining to vehicle occupancy indication and utilization thereof are described. A method may involve determining occupancy information regarding a number of occupants in a vehicle. The method may also involve indicating the occupancy information in either or both of a human-perceivable way and a machine-perceivable way.

By way of example, various methods for reproducing advertisements using a plurality of advertisement vehicles as well as controlling the plurality of advertisement vehicles are provided. In one example, a method for controlling a plurality of advertisement vehicles is provided as follows. Initially, information on the plurality of advertisement vehicles that are going to carry out a specific event is verified. Information on the specific event is sent to the plurality of advertisement vehicles and real-time traffic and/or people density information in an area in which the specific event is to be carried out is collected. A starting location of the specific event may also be determined based on at least one of: the real-time traffic density information or real-time location information of the plurality of advertisement vehicles. Then, driving route guidance with an initial destination set to the starting location of the specific event is sent to the plurality of advertisement vehicles such that the plurality of advertisement vehicles convenes at the starting location of the specific event.

There are provided an apparatus, a method, and an autonomous moving body which allow a recognition target to be notified with certainty that the recognition target is recognized by an autonomous moving body. A recognition result presenting apparatus according to an embodiment of the present disclosure detects a recognition target (person) present within a predetermined range from an automatic driving vehicle and presents, to the detected recognition target (person), the result of recognition indicating that the automatic driving vehicle recognizes the recognition target (person).

According to an embodiment, an information processing apparatus includes a hardware processor. The hardware processor is configured to acquire a previous output message from a moving object; acquire surrounding information of the moving object; detect motion information indicating a motion of an object as a destination of the message based on the surrounding information; determine whether the motion of the object indicated by the motion information corresponds to a motion indicated by the message; and update the message based on the motion information when the motion of the object indicated by the motion information is determined not to correspond to the motion indicated by the message.

A method, system and non-transitory computer readable medium which monitor a road user in order to move the external position of the vehicle intent notification (eHMI) to another external position that can be seen by the road user based on the gaze direction of the road user. In some aspects, the eHMI notification displays the vehicle intent for a single autonomous vehicle. In another aspect, a group eHMI notification displays the trajectories for a plurality of autonomous and non-autonomous vehicles. Based on the gaze direction of the road user, the eHMI notification can be displayed on a single external position or on multiple external positions. Different eHMI notifications can be displayed at different external positions on the autonomous vehicle to provide information to more than one road user.

A vehicle mounted pedestrian communication lamp including a housing defining an inner package space for receiving a main illuminating component and at least one secondary component for providing variable depictions based upon a processor input to the secondary element. The secondary element further includes at least one individual matrix display containing a plurality of illuminating elements. The illuminating elements each further include any of LED, TFFL, transparent LCD or OLED displays. The individual matrix display further includes either of a rigid or flexible display. The flexible display may also include a thin film transistor (TFT) display. Other features includes a pair of secondary illuminating components provided on either side of the main illuminating component. The main illuminating component can also be provided as a fog lamp. The processor communicates with an external input via any of Bluetooth or Near Field Communication protocols.

A display device provided in a vehicle that travels autonomously includes: a display unit configured to display information to an outside of the vehicle; a determination unit configured to determine whether a travel state of the vehicle is any one of a deceleration state, a stop state, and a start state, based on a detection result of an internal sensor of the vehicle; and a display control unit configured to display on the display unit the information corresponding to each of the deceleration state, the stop state, and the start state, based on a determination result of the determination unit. In response to the determination unit having determined that the vehicle is in the deceleration state, the display control unit is configured to display on the display unit the information including a display moving from an upper side to a lower side along a vertical direction of the vehicle.

Techniques are disclosed to realize a self-adaptive multiresolution digital plate (SAMDP) system that facilitates sharing of vehicle state information via a dynamically generated binary two-dimensional multispectral pattern. The binary 2D multispectral pattern adjusts its resolution to adapt to the visual perception process while communicating vehicle state information without relying on wireless communications (i.e. V2V, V2X, etc.). The techniques as described herein leverage the use of a multichannel spectral means that helps lower the error present in sensing and representation models used by automated driving systems.

Disclosed is a warning system to be provided on a first vehicle, which includes a radar for measuring the distance D with a second vehicle that is following same, a display visible from the following vehicle, a unit for calculating the safety distance DS and a camera for reading the registration number of the second vehicle.