Abstract: A launch vehicle can include a mobility system, a launch system, and a computing system. The mobility system can be configured to travel to a general target location. The launch system can be configured to house a plurality of autonomous delivery vehicles assigned for transporting one or more deliverable items from the general target location to respective specific target delivery locations. The computing system can be configured to control launch of the plurality of autonomous delivery vehicles from the launch vehicle at a respective plurality of predetermined launch positions, each predetermined launch position associated with a corresponding launch time, and each autonomous delivery vehicle configured to travel from a launch position of the respective plurality of predetermined launch positions to a specific target delivery location of the respective specific target delivery locations and from the specific target delivery location to one or more predetermined landing positions.

Abstract: The present disclosure provides a sensor cleaning system that cleans one or more sensors of an autonomous vehicle. Each sensor can have one or more corresponding sensor cleaning units that are configured to clean such sensor using a fluid (e.g., a gas or a liquid). Thus, the sensor cleaning system can include both a gas cleaning system and a liquid cleaning system. According to one aspect, the sensor cleaning system can provide individualized cleaning of the autonomous vehicle sensors. According to another aspect, a liquid cleaning system can be pressurized or otherwise powered by the gas cleaning system or other gas system.

Abstract: Aspects of the disclosure relate to enhanced telematics processing systems with improved third party source data integration features and enhanced customized driving output determinations. A computing platform may receive telematics data and third party source data. The computing platform may enrich the telematics data using the third party source data. After generating the enriched telematics data, the computing platform may use machine learning algorithms and datasets to validate the enriched telematics data. The computing platform may ingest, via a batch ingestion process, the enriched telematics data. For example, the computing platform may store the enriched telematics data and generate additional enriched telematics data until expiration of a predetermined period of time. The computing platform may ingest the enriched telematics data associated with each trip. Once the enriched telematics data has been ingested, the computing platform may generate a standardized common trip format output for each trip.

Abstract: Embodiments of the disclosure concern systems, methods and compositions for generating Rev-dependent lentiviral vectors. In specific embodiments, the vectors are generated in a system that comprises Phosphofurin Acid Cluster Sorting protein 1 (PACS1) and/or Phosphofurin Acid Cluster Sorting protein 2 (PACS2). In embodiments, the vectors are utilized for therapeutic or research applications.

Abstract: The present disclosure provides a sensor cleaning system that cleans one or more sensors of an autonomous vehicle. Each sensor can have one or more corresponding sensor cleaning units that are configured to clean such sensor using a fluid (e.g., a gas or a liquid). Thus, the sensor cleaning system can include both a gas cleaning system and a liquid cleaning system. According to one aspect, the sensor cleaning system can provide individualized cleaning of the autonomous vehicle sensors. According to another aspect, a liquid cleaning system can be pressurized or otherwise powered by the gas cleaning system or other gas system.

Abstract: Devices, systems, and methods for cooling an autonomous vehicle computing system are provided. A modular cooling device can include a cooling baseplate and one or more modular heat frames. The cooling baseplate can include at least one planar cooling surface, an inlet configured to receive a cooling fluid, an outlet, and at least one cooling channel coupled between the inlet and the outlet. The at least one cooling channel can be configured to allow the cooling fluid to flow between the inlet and the outlet and provide cooling to the at least one planar cooling surface. Each modular heat frame can be configured to house at least one autonomous vehicle computing system component, be coupled parallel to the at least one planar cooling surface, and transfer heat from the at least one autonomous vehicle computing system component housed by the modular heat frame to the cooling baseplate.

Abstract: Aspects of the disclosure relate to enhanced telematics processing systems with improved third party source data integration features and enhanced customized driving output determinations. A computing platform may receive telematics data and third party source data. The computing platform may enrich the telematics data using the third party source data. After generating the enriched telematics data, the computing platform may use machine learning algorithms and datasets to validate the enriched telematics data. The computing platform may ingest, via a batch ingestion process, the enriched telematics data. For example, the computing platform may store the enriched telematics data and generate additional enriched telematics data until expiration of a predetermined period of time. The computing platform may ingest the enriched telematics data associated with each trip. Once the enriched telematics data has been ingested, the computing platform may generate a standardized common trip format output for each trip.

Abstract: Aspects of the disclosure relate to enhanced telematics processing systems with improved third party source data integration features and enhanced customized driving output determinations. A computing platform may receive telematics data and third party source data. The computing platform may enrich the telematics data using the third party source data. After generating the enriched telematics data, the computing platform may use machine learning algorithms and datasets to validate the enriched telematics data. The computing platform may ingest, via a batch ingestion process, the enriched telematics data. For example, the computing platform may store the enriched telematics data and generate additional enriched telematics data until expiration of a predetermined period of time. The computing platform may ingest the enriched telematics data associated with each trip. Once the enriched telematics data has been ingested, the computing platform may generate a standardized common trip format output for each trip.

Abstract: Systems and methods for displaying imagery on a Light Detection and Ranging (LIDAR) system are provided. In one example embodiment, a method includes determining, by the one or more computing devices, a rotational frequency of a LIDAR device located on a vehicle. The method includes illuminating, by the one or more computing devices, one or more of a plurality of light emitting elements coupled to the LIDAR device based at least in part on the rotational frequency of the LIDAR device and the one or more images for display.

Abstract: The present disclosure is directed to communicating autonomous-vehicle status. In particular, the methods, devices, and systems of the present disclosure can: determine one or more maintenance statuses of one or more of multiple different systems of an autonomous vehicle; and depict at least one of the status(es) via a display device affixed to an exterior of the autonomous vehicle and configured to display information associated with the multiple different systems such that the information is visible to an observer located outside the autonomous vehicle.

Abstract: Devices, systems, and methods for cooling an autonomous vehicle computing system are provided. A modular cooling device can include a cooling baseplate and one or more modular heat frames. The cooling baseplate can include at least one planar cooling surface, an inlet configured to receive a cooling fluid, an outlet, and at least one cooling channel coupled between the inlet and the outlet. The at least one cooling channel can be configured to allow the cooling fluid to flow between the inlet and the outlet and provide cooling to the at least one planar cooling surface. Each modular heat frame can be configured to house at least one autonomous vehicle computing system component, be coupled parallel to the at least one planar cooling surface, and transfer heat from the at least one autonomous vehicle computing system component housed by the modular heat frame to the cooling baseplate.

Abstract: Systems and methods for providing cooling to vehicle systems on an autonomous vehicle from a plurality of cooling sources are provided. A cooling system can include a thermal interface configured to provide cooling to one or more vehicle systems of the autonomous vehicle, a plurality of cooling sources coupled to the thermal interface, and a controller configured to control each cooling source to provide a respective cooling to the thermal interface to meet a total cooling parameter for the one or more vehicle systems. Each cooling source can be configured to provide a respective cooling capacity to the thermal interface. The thermal interface can be configured to receive the respective cooling provided by each of the cooling sources. The thermal interface can be further configured to provide the respective cooling received by each of the cooling sources to the one or more vehicle systems to meet the total cooling parameter.

Abstract: Systems and methods for power and thermal management of autonomous vehicles are provided. In one example embodiment, a computing system includes processor(s) and one or more tangible, non-transitory, computer readable media that collectively store instructions that when executed by the processor(s) cause the computing system to perform operations. The operations include obtaining data associated with an autonomous vehicle. The operations include identifying one or more vehicle parameters associated with the autonomous vehicle based at least in part on the data associated with the autonomous vehicle. The operations include determining a modification to one or more operating characteristics of one or more systems onboard the autonomous vehicle based at least in part on the one or more vehicle parameters.

Abstract: Systems and methods for displaying imagery on a Light Detection and Ranging (LIDAR) system are provided. In one example embodiment, a method includes determining, by the one or more computing devices, a rotational frequency of a LIDAR device located on a vehicle. The method includes illuminating, by the one or more computing devices, one or more of a plurality of light emitting elements coupled to the LIDAR device based at least in part on the rotational frequency of the LIDAR device and the one or more images for display.

Abstract: The present disclosure provides a sensor cleaning system that cleans one or more sensors of an autonomous vehicle. Each sensor can have one or more corresponding sensor cleaning units that are configured to clean such sensor using a fluid (e.g., a gas or a liquid). Thus, the sensor cleaning system can include both a gas cleaning system and a liquid cleaning system. According to one aspect, the sensor cleaning system can provide individualized cleaning of the autonomous vehicle sensors. According to another aspect, a liquid cleaning system can be pressurized or otherwise powered by the gas cleaning system or other gas system.

Abstract: Systems and methods for displaying imagery on a Light Detection and Ranging (LIDAR) system are provided. In one example embodiment, a method includes determining, by the one or more computing devices, a rotational frequency of a LIDAR device located on a vehicle. The method includes illuminating, by the one or more computing devices, one or more of a plurality of light emitting elements coupled to the LIDAR device based at least in part on the rotational frequency of the LIDAR device and the one or more images for display.

Abstract: A sensing apparatus for use in combination with a stationary bicycle comprises a housing that supports a source of emitted radiation and a detector of radiation of the same wavelength as that emitted by the source, fixing means for fixing the housing to an exercise device such that radiation is emitted towards a region of space that can be occupied by a part of a body of a user of the exercise device and selectively transmitted on to the detector depending on whether a part of a user's body is located within the space, a processor which measures at least one property of the radiation from the source that is passed to the detector and from the measured property produces an output signal indicative of the proximity of the user relative to the device within that space.

Abstract: A handlebar assembly (100) is disclosed comprising a lower base portion (101) which is adapted to support a handlebar (202) through a guide means which is so constructed and arranged to permit the handlebar (202) to move along a path relative to the base portion (101) whereby upon movement of the handlebar (202) along the path to the left or the right relative to a central position the handlebar (202) tilts and the center of the handlebar (202) moves downwards relative to the base portion (101) as well as horizontally from the central position. The assembly allows the handlebars to move in a way which mimics the movement of the handlebars of a bicycle. In a modification, the guide means may restrain the handlebar for movement up/down or forwards/backwards or side to side, again to provide a more realistic range of movement.

Abstract: A controller is disclosed, especially but not exclusively, for use in combination with an exercise apparatus. The controller comprises in one arrangement a handlebar assembly and one or more input devices, of at least one of the input device being responsive to movement of the handlebars. The controller may include a support such as a handlebar stem, and may provide output signals to a microprocessor in turn to control operation of a programme running on the microprocessor.

Abstract: A sensing apparatus for use in combination with a stationary bicycle comprises a housing that supports a source of emitted radiation and a detector of radiation of the same wavelength as that emitted by the source, fixing means for fixing the housing to an exercise device such that radiation is emitted towards a region of space that can be occupied by a part of a body of a user of the exercise device and selectively transmitted on to the detector depending on whether a part of a user's body is located within the space, a processor which measures at least one property of the radiation from the source that is passed to the detector and from the measured property produces an output signal indicative of the proximity of the user relative to the device within that space