The disclosure generally pertains to systems and methods for providing a vehicle-based security system. In an example method, at least a first image and a second image may be received from an infrared camera associated with a vehicle. A thermal 3-dimensional map may then be constructed from the first image and the second image. An area of interest may be identified in the thermal 3-dimensional map. A visual camera associated with the vehicle may then be instructed to obtain a third image including the area of interest. The third image including the area of interest may then be received, and a living object in the third image may be determined. A notification associated with the living object may then be transmitted.

Approaches to utilizing contextual right-of-way decision making for autonomous vehicles are disclosed. An autonomous vehicle is operated in a road setting within an operating environment having other road users. The operation of the autonomous vehicle is based on safety constraints providing limits on operation of the autonomous vehicle. The presence of a selected other road user within the operating environment is detected. Potential trajectories for the autonomous vehicle within the operating environment are evaluated with respect to the other road user. The autonomous vehicle interacts with the other road user by generating vehicle control signals based on a machine learned model and within the one or more safety constraints. The machine learned model is based on a hierarchy of costs corresponding to characteristics of maneuvers by the autonomous vehicle.

A driving assistance apparatus includes a controller programmed to perform a deceleration assistance process of assisting in decelerating a vehicle before the vehicle arrives at a deceleration object, and to control a display apparatus to display, in a first display area, first notification information for notifying an occupant of the vehicle of the deceleration object that is a target for the deceleration assistance process. When a first object and a second object that is different from the first object are both detected as the deceleration object and the second object is the target for the deceleration assistance process but the first object is not the target for the deceleration assistance process, the controller is programmed to control the display apparatus to display, in a second display area, second notification information for notifying the occupant of the first object, the second display area is different from the first display area.

Described herein are various systems and processes for predictive operating assistance of vehicles. The systems and techniques described herein may be applicable to vehicles such as vehicles operated by a driver, semi-autonomous vehicles, and/or autonomous vehicles. The assistance techniques described herein may be predictive. That is, the techniques allow for the prediction of non-optimal or dangerous operating conditions before the vehicle control is compromised. Accordingly, a warning may be provided and/or operation of the vehicle may be changed based on the predictive assistance determinations. In certain embodiments, the techniques described herein may provide warnings to a driver, may detect faults within the vehicle, may aid in route planning, may detect obstacles proximate to the vehicle, and/or may aid in the operation of the vehicle.

An information processing device includes a control unit. The control unit is configured to execute acquiring information about temperature inside or outside a vehicle, and generating a command to open or close a window included in the vehicle based on the information about the temperature inside or outside the vehicle.

A method for driving-related object detection, the method may include receiving an input image by an input of an object detector; and detecting, by an object detector, objects that appear in the input image. The detecting includes searching for (i) a first object having a first size that is within a first size range and belongs to a four wheel vehicle class, (ii) a second object having a second size that is within a second size range and belongs to a subclass out of multiple four wheel vehicle subclasses, (iii) a pedestrian, and (iv) a two wheel vehicle; wherein a maximum of the first size range does not substantially exceed a minimum of the second size range.

Methods and systems for autonomous vehicle recharging or refueling are disclosed. Autonomous electric vehicles may be automatically recharged by routing the vehicles to available charging stations when not in operation, according to methods described herein. A charge level of the battery of an autonomous electric vehicle may be monitored until it reaches a recharging threshold, at which point an on-board computer may generate a predicted use profile for the vehicle. Based upon the predicted use profile, a time and location for the vehicle to recharge may be determined. In some embodiments, the vehicle may be controlled to automatically travel to a charging station, recharge the battery, and return to its starting location in order to recharge when not in use.

Methods and systems autonomously parking and retrieving vehicles are disclosed. Available parking spaces or parking facilities may be identified, and the vehicle may be navigated to an available space from a drop-off location without passengers. Special-purpose sensors, GPS data, or wireless signal triangulation may be used to identify vehicles and available parking spots. Upon a user request or a prediction of upcoming user demand, the vehicle may be retrieved autonomously from a parking space. Other vehicles may be autonomously moved to facilitate parking or retrieval.

A method and apparatus for operating an automated vehicle. The method includes: acquiring environmental data values which represent objects in an environment of the automated vehicle; determining a position of the automated vehicle; comparing the environmental data values with a digital map, depending on the position of the automated vehicle, the digital map including environmental features, a first subset of the objects being determined as static objects when these objects are comprised as environmental features in the digital map, and a second subset of the objects are determined as non-static objects, when these objects are not comprised as an environmental feature in the digital map; determining a motion behavior of the non-static objects relative to the automated vehicle; determining a travel strategy for the automated vehicle, depending on the motion behavior of the non-static objects; and operating the automated vehicle, depending on the travel strategy.

A monitoring system for an environment of a vehicle. The vehicle includes a group of sensors adapted to cover various regions of the environment. The monitoring system includes a receiving module, a classification module, and a processing module. The receiving module is adapted to obtain information about a driving task of the vehicle. The classification module is adapted to classify, based on the obtained information, the group of sensors in at least a first subset and a second subset. The processing module is adapted to process sensor data of the first subset with higher priority than sensor data from sensors from the second subset.