Abstract: An immersive seat system may include audio outputs and/or haptic outputs configured to provide an occupant of an autonomous vehicle with an enhanced user experience. For example, the audio outputs and/or the haptic outputs may be controlled to provide a more enjoyable experience while riding to destination, and/or to provide information to the occupant about the vehicle in which the occupant is riding, objects in a proximity of the vehicle, actions to be taken by the vehicle, events involving the vehicle, environmental conditions, and/or other information.

Abstract: A method and system of using excess computational resources on autonomous vehicles. Such excess computational resources may be available during periods of low demand, or other periods of idleness (e.g., parking). Where portions of computing resources are available amongst a fleet of vehicles, such excess computing resources may be pooled as a single resource. The excess computational resources may be used, for example, to train and/or test machine-learning models. Performance metrics of such models may be determined using hardware and software on the autonomous vehicle, for example sensors. Models having performance metrics outperforming current models may be considered as validated models. Validated models may be transmitted to a remote computing system for dissemination to a fleet of vehicles.

Abstract: Various embodiments relate generally to autonomous vehicles and associated mechanical, electrical and electronic hardware, computer software and systems, and wired and wireless network communications to provide an autonomous vehicle fleet as a service. In particular, a method may include receiving, from a user device, a ride request to transport a user to a destination from an origin location through an autonomous vehicle system service. Based on the origin location associated with the request, an autonomous vehicle system may be selected from a fleet of autonomous vehicles to execute the ride request. The fleet may be managed by the autonomous vehicle system service. The ride request may then be provided to the autonomous vehicle system, and information about the autonomous vehicle system may also be provided to the user device.

Abstract: Systems, methods, and apparatuses described herein are directed to automated vehicle diagnostics and maintenance. For example, vehicles can include sensors monitoring vehicle components, for perceiving objects and obstacles in an environment, and for navigating the vehicle to a destination. Data from these and other sensors can be leveraged to track a performance of the vehicle over time to determine a state of vehicle components, and/or changes to acceleration/deceleration and steering behavior of the vehicle over time. As issues for servicing are determined, the methods, apparatuses, and systems can include automated scheduling of vehicle maintenance. For example, based on a determination of the potential issues based on sensor data and/or user indications, vehicle maintenance can be scheduled to be performed in the field or at a service center. Technicians can be assigned to perform vehicle maintenance based on the servicing issue and/or on capabilities of the technician.

Abstract: Systems, apparatus and methods may be configured to implement actively-controlled light emission from a robotic vehicle. A light emitter(s) of the robotic vehicle may be configurable to indicate a direction of travel of the robotic vehicle and/or display information (e.g., a greeting, a notice, a message, a graphic, passenger/customer/client content, vehicle livery, customized livery) using one or more colors of emitted light (e.g., orange for a first direction and purple for a second direction), one or more sequences of emitted light (e.g., a moving image/graphic), or positions of light emitter(s) on the robotic vehicle (e.g., symmetrically positioned light emitters). The robotic vehicle may not have a front or a back (e.g., a trunk/a hood) and may be configured to travel bi-directionally, in a first direction or a second direction (e.g., opposite the first direction), with the direction of travel being indicated by one or more of the light emitters.

Abstract: Various embodiments relate generally to autonomous vehicles and associated mechanical, electrical and electronic hardware, computer software and systems, and wired and wireless network communications to provide an autonomous vehicle fleet as a service. More specifically, systems, devices, and methods are configured to initiate modification of trajectories to influence navigation of autonomous vehicles. In particular, a method may include receiving a teleoperation message via a communication link from an autonomous vehicle, detecting data from the teleoperation message specifying an event associated with the autonomous vehicle, identifying one or more courses of action to perform responsive to detecting the data specifying the event, and generating visualization data to present information associated with the event to a display of a teleoperator computing device.

Abstract: Vehicle parking assist is described. In an example, computing system(s) associated with a first vehicle can receive, from sensor(s) associated with the first vehicle, sensor data associated with a second vehicle. Additionally, the computing system(s) can receive an indication that a second vehicle is proximate the first vehicle and can determine, based at least partly on the sensor data, that the second vehicle is moving toward a location proximate the first vehicle (e.g., to park). Based at least partly on the sensor data, the computing system(s) associated with the first vehicle can determine a position, an orientation, and/or a velocity of the second vehicle and based at least partly on determining the position, the orientation, and/or the velocity, can determine instruction(s) for guiding the second vehicle, for example to park. The instruction(s) can be output via light emitter(s), sound emitter(s), and/or a remote user interface associated with the second vehicle.

Abstract: A system for detecting a classifying objects in a vehicle can comprise one or more sensors for detecting the presence of an object, other than a passenger, on the vehicle. The system can classify the object as, for example, a personal object or trash. The system can provide a series of escalating reminders for the passenger to take the object with them when they exit the vehicle. When a personal object is left in the vehicle after the passenger has exited the vehicle, the system can communicate with a computing device of a central control or the passenger using additional communication channels such as, for example, e-mail, text, or the Internet. When trash is left in the vehicle, the vehicle can automatically contact, or return to, a maintenance facility for servicing. This can prevent the use of unclean vehicles for new passengers, among other things.

Abstract: Systems, apparatus and methods implemented in algorithms, hardware, software, firmware, logic, or circuitry may be configured to process data and sensory input to determine whether an object external to an autonomous vehicle (e.g., another vehicle, a pedestrian, road debris, a bicyclist, etc.) may be a potential collision threat to the autonomous vehicle. The autonomous vehicle may be configured to implement interior active safety systems to protect passengers of the autonomous vehicle during a collision with an object or during evasive maneuvers by the autonomous vehicle, for example. The interior active safety systems may be configured to provide passengers with notice of an impending collision and/or emergency maneuvers by the vehicle by tensioning seat belts prior to executing an evasive maneuver and/or prior to a predicted point of collision.

Abstract: Various embodiments relate generally to autonomous vehicles and associated mechanical, electrical and electronic hardware, computer software and systems, and wired and wireless network communications to provide an autonomous vehicle fleet as a service. In particular, a method may include receiving, at an autonomous vehicle system, a command to control an ambient feature associated with the autonomous vehicle system. One or more courses of action may be determined based on the command. In addition, one or more probabilistic models associated with the one or more courses of action may also be determined. Based on the one or more probabilistic models, confidence levels may also be determined to form a subset of the one or more courses of action. A course of action from the subset of the one or more courses of action may then be executed at the autonomous vehicle system responsive to the command.

Abstract: Systems, apparatus and methods to implement sectional design (e.g., in quadrants) of an autonomous vehicle may include modular construction techniques to assemble an autonomous vehicle from multiple structural sections. The multiple structural sections may be configured to implement radial and bilateral symmetry. A structural section based configuration may include a power supply configuration (e.g., using rechargeable batteries) including a double-backed power supply system. The power supply system may include a kill switch disposed on a power supply (e.g., at an end of a rechargeable battery). The kill switch may be configured to disable the power supply system in the event of an emergency or after a collision, for example. The radial and bilateral symmetry may provide for bi-directional driving operations of the autonomous vehicle as the vehicle may not have a designated front end or a back end.

Abstract: An occupant protection system for a vehicle may include an expandable curtain and/or an expandable bladder configured to be expanded from a stowed state to a deployed state. In the deployed state, the expandable curtain may include first and second sides configured to extend along respective portions of first and second interior sides of the vehicle. The expandable curtain may also include a transverse portion extending between the first and second sides, and the first and second sides, and the transverse portion of the expandable curtain may form a contiguous barrier. The expandable bladder when deployed may be supported by the expandable curtain during contact by an occupant. The occupant protection system may also include a deployment control system configured to cause the expandable curtain and/or the expandable bladder to expand to the deployed state. The occupant protection system may be used in vehicles having a carriage-style seating arrangement.

Abstract: An occupant protection system for a vehicle may include an expandable curtain and/or an expandable bladder configured to be expanded from a stowed state to a deployed state. In the deployed state, the expandable curtain may include first and second sides configured to extend along respective portions of first and second interior sides of the vehicle. The expandable curtain may also include a transverse portion extending between the first and second sides, and the first and second sides, and the transverse portion of the expandable curtain may form a contiguous barrier. The expandable bladder when deployed may be supported by the expandable curtain during contact by an occupant. The occupant protection system may also include a deployment control system configured to cause the expandable curtain and/or the expandable bladder to expand to the deployed state. The occupant protection system may be used in vehicles having a carriage-style seating arrangement.

Abstract: Various embodiments relate generally to autonomous vehicles and associated mechanical, electrical and electronic hardware, computer software and systems, and wired and wireless network communications to provide an autonomous vehicle fleet as a service. In particular, a method may include identifying a location of a user device associated with a user, transmitting a command to an autonomous vehicle system associated with an autonomous vehicle service to transit to the location, and providing information associated with the user device to the autonomous vehicle system, where the information includes configuration data to adapt one or more sub-systems of the autonomous vehicle. Sub-systems of the autonomous vehicle may include interior lighting, ambient sound, road handling, seating configuration, communication synchronization, and temperature control systems.

Abstract: A system for charging one or more batteries of a vehicle may include a charging box mounted to a vehicle to facilitate connection to a charge coupler from under the vehicle. The charge coupler may be configured to provide an electrical connection between an electrical power source and the charging box. A vehicle including the charging box may maneuver to a position above the charge coupler, after which electrical contacts of the charging box and the charge coupler may be brought into contact with one another. The charge coupler and/or the charging box may be configured to provide electrical communication between the electrical power source and the one or more batteries, so that the electrical power source may charge one or more of the batteries. Thereafter, the electrical contacts may be separated from one another, and the vehicle may maneuver away from the charge coupler.

Abstract: A system for charging one or more batteries of a vehicle may include a charging box mounted to a vehicle to facilitate connection to a charge coupler from under the vehicle. The charge coupler may be configured to provide an electrical connection between an electrical power source and the charging box. A vehicle including the charging box may maneuver to a position above the charge coupler, after which electrical contacts of the charging box and the charge coupler may be brought into contact with one another. The charge coupler and/or the charging box may be configured to provide electrical communication between the electrical power source and the one or more batteries, so that the electrical power source may charge one or more of the batteries. Thereafter, the electrical contacts may be separated from one another, and the vehicle may maneuver away from the charge coupler.

Abstract: An aesthetically pleasing discreet wearable system for interacting with a vehicle, or fleet of vehicles. The wearable system may be worn as a necklace, bracelet, anklet, or the like and allows for communication between a passenger and a vehicle, or fleet of vehicles. A passenger may summon or cancel a ride, alter interior lighting and music levels, or otherwise control a vehicle by interacting with the wearable system. Such interaction includes signals generated by a microphone, by a touch sensor, or by gesture recognition. The wearable system communicates to the passenger a successful summoning of a ride, successfully canceling a ride, and a time to arrival by combinations of vibrations, light emissions, and audio alerts.

Abstract: Remote controlling of a vehicle, such as an autonomous vehicle, may sometimes be more efficient and/or reliable. Such control, however, may require processes for ensuring safety of surrounding persons and objects. Aspects of this disclosure include using onboard sensors to detect objects in an environment and alter remote commands according to such objects, e.g. by reducing a maximum permitted velocity of the vehicle as a function of distance to detected objects. In some examples described herein, such remote controlling may be performed by using objects in the environment as control objects, with movements of the control objects resulting in movement of the vehicle.

Abstract: Systems, apparatus and methods implemented in algorithms, hardware, software, firmware, logic, or circuitry may be configured to process data and sensory input to determine whether an object external to an autonomous vehicle (e.g., another vehicle, a pedestrian, road debris, a bicyclist, etc.) may be a potential collision threat to the autonomous vehicle. The autonomous vehicle may be configured to implement interior active safety systems to protect passengers of the autonomous vehicle during a collision with an object or during evasive maneuvers by the autonomous vehicle, for example. The interior active safety systems may be configured to provide passengers with notice of an impending collision and/or emergency maneuvers by the vehicle by tensioning seat belts prior to executing an evasive maneuver and/or prior to a predicted point of collision.

Abstract: A system for detecting a classifying objects in a vehicle can comprise one or more sensors for detecting the presence of an object, other than a passenger, on the vehicle. The system can classify the object as, for example, a personal object or trash. The system can provide a series of escalating reminders for the passenger to take the object with them when they exit the vehicle. When a personal object is left in the vehicle after the passenger has exited the vehicle, the system can communicate with a computing device of a central control or the passenger using additional communication channels such as, for example, e-mail, text, or the Internet. When trash is left in the vehicle, the vehicle can automatically contact, or return to, a maintenance facility for servicing. This can prevent the use of unclean vehicles for new passengers, among other things.