Systems and methods for controlling movement of an active payload support system. In one example, a seat system for a vehicle includes a seat, a support structure coupled to the seat and including an actuator configured to move the seat at a command angle relative to a floor of the vehicle responsive to movement of the vehicle, at least one sensor positioned to detect movement of the vehicle, and a controller configured to receive a signal from the at least one sensor, generate a command signal to instruct the actuator to move the seat relative to a floor of the vehicle, determine whether the command signal will cause the seat to exceed a limit, scale the command signal to conform to movement of the vehicle within the limit, and provide a force command to the actuator to move the seat based on the scaled command signal.

Methods and systems for a vehicle system that include determining whether a vehicle action is necessary and providing a notification to predetermined users. Sensors provide signals to a sensing control system to generate the notification.

Methods and systems for a traffic control system provide arrangements and processes for managing automated vehicles. The traffic control system can register vehicles and then control the operation of the vehicles through a section of roadway. The automated control includes the communication of directions and other messages that ensure the proper function of the vehicle while under the guidance of the traffic control system.

Methods and systems for a complete vehicle ecosystem are provided. Specifically, systems that when taken alone, or together, provide an individual or group of individuals with an intuitive and comfortable vehicular environment. The present disclosure includes a system to create, modify, and maintain profiles associated with users. The user profiles are generated based on selectively collecting data associated with the users. Although each user profile may include settings, preferences, habits, and content associated with an individual user and/or vehicle, some user profiles may represent multiple users. These user profiles can change a configuration of a vehicle to match settings for a user, such as a driver and/or passenger. The configurations may also include the recognition of a unique set of gestures for a user. Further, the user profiles can be transferred from vehicle-to-vehicle and/or user-to-user.

Methods and systems are presented for accepting inputs into a vehicle or other conveyance to control functions of the conveyance. A vehicle control system can receive gestures and other inputs. The vehicle control system can also obtain information about the user of the vehicle control system and information about the environment in which the conveyance is operating. Based on the input and the other information, the vehicle control system can modify or improve the performance or execution of user interface and functions of the conveyance. The changes make the user interfaces and/or functions user-friendly and intuitive.

Various systems, mediums, and methods may be implemented to retrieve data from a user's mobile device. In one example, a system may determine a number of reviews received by the user's mobile device. Some of the reviews may include poor reviews, such as low ratings (e.g., one or two star ratings), negative written reviews, and/or other forms of data indicative of various establishments and/or services. In such instances, the system may generate notifications and transmit the notifications to merchant devices, such that the merchants may be alerted of the user having a history of providing poor reviews. As such, the system and/or the merchants may be notified accordingly to ensure the user will be satisfied with the services provided and to avoid a negative review from the user.

An occupant customized seat control apparatus and method are provided. The method includes recognizing, by a camera, an occupant that approaches a vehicle, controlling a display to move based on a height of the recognized occupant, determining whether the recognized occupant is an infant, and when the recognized occupant is determined to be an infant, determining whether a booster seat needs to be controlled based on the height of the recognized occupant, and when at least one of the booster seat, a footrest, or the combination thereof needs to be controlled, converting a value of the recognized height into a booster seat actuator movement amount value, and controlling the booster seat to move based on the converted actuator movement amount value.

Vehicle systems configured to interact with remotely located smart systems are disclosed. An example vehicle includes memory, machine-readable instructions, and one or more processors. The one or more processors are configured to execute the machine-readable instructions to send, from the vehicle to a smart system located remotely relative to the vehicle, a first message configured to cause the smart system to adjust one or more functions of a device controllable via the smart system. The one or more processors are further configured to execute the machine-readable instructions to receive, at the vehicle from the smart system, a second message including information associated with the smart system or the device.

Guided driver positioning system and methods are disclosed herein. An example method can include determining gait for a user of a vehicle from images obtained from a camera, the gait being indicative of a posture of the user, determining a distance between the user and a display of the vehicle, and automatically adjusting a vehicle component in response to the gait and the distance to change a user position relative to the display.

Methods, systems, and a computer readable medium are provided for a vehicle containing multiple blade processors for performing vehicle and/or infotainment tasks, functions, and operations. The blade processors can be included in a crate having a first communication zone defining a trusted network within the vehicle to connect with trusted computational devices and/or modules provided or certified by the vehicle manufacturer but not untrusted computational devices and/or modules provided by vehicle occupants, a second communication zone defining an untrusted network to connect with the untrusted computational devices and/or modules, and a third communication zone providing power and data transmission to the blade processors. A master blade processor can assign a component and/or module requiring a blade processor for execution to a selected blade processor.