Abstract: Systems, methods, and other embodiments described herein relate to using vehicles as mobile observation platforms. In one embodiment, a method includes, in response to receiving, in a selected vehicle that is equipped with at least one camera, a request for locating a target, identifying search parameters from the request that specify the target that is to be identified and a time window for analyzing visual data from the camera. The method includes analyzing the visual data according to the search parameters to identify the target by using at least a machine vision model executing on a processor within the selected vehicle. The visual data includes at least camera data that is currently being acquired. The method includes communicating detection results about whether the visual data includes the target to a remote device from which the request originated.

Abstract: An example operation includes one or more of: determining a first subgroup of a group of vehicles and a second subgroup of the group of vehicles, wherein the second subgroup has a higher carbon footprint than the first subgroup; and determining a driving behavior modification of a vehicle in the second subgroup based on a driving behavior of one or more vehicles in the first subgroup.

Abstract: An example operation includes one or more of determining a first carbon footprint of a first mode of transportation and a second carbon footprint of a second mode of transportation, where the first mode of transportation is a primary mode of transportation and the second carbon footprint is less than the first carbon footprint, responsive to the first carbon footprint being above a threshold, calculating a period of time the second mode of transportation is utilized to negate an amount above the threshold, and sending a notification to use the second mode of transportation for the period of time.

Abstract: An example operation includes one or more of receiving, by a server, characteristics related to a transport within a time period, wherein the characteristics are related to a condition of the transport, an operation behavior of the transport and an upkeep of the transport, providing, by the server, one or more actions to perform by the transport to increase a level of the characteristics, and responsive to the level of the characteristics being increased, determining, by the server, a next use of the transport after the time period.

Abstract: Systems, methods, and other embodiments described herein relate to using vehicles as mobile observation platforms. In one embodiment, a method includes, in response to receiving, in a selected vehicle that is equipped with at least one camera, a request for locating a target, identifying search parameters from the request that specify the target that is to be identified and a time window for analyzing visual data from the camera. The method includes analyzing the visual data according to the search parameters to identify the target by using at least a machine vision model executing on a processor within the selected vehicle. The visual data includes at least camera data that is currently being acquired. The method includes communicating detection results about whether the visual data includes the target to a remote device from which the request originated.

Abstract: An example operation includes one or more of obtaining, by a transport, data related to a performance of the transport, determining, by the transport, a performance level of the transport based on the obtained data, dynamically revising, by the transport, the performance level based on a current use of the transport, and determining, by the transport, a next use of the transport, based on the dynamically revised performance level.

Abstract: An example operation includes one or more of receiving, by a server, characteristics related to a transport within a time period, wherein the characteristics are related to a condition of the transport, an operation behavior of the transport and an upkeep of the transport, providing, by the server, one or more actions to perform by the transport to increase a level of the characteristics, and responsive to the level of the characteristics being increased, determining, by the server, a next use of the transport after the time period.

Abstract: System, methods, and other embodiments described herein relate to using vehicles as mobile observation platforms and improving the querying of visual data within the vehicles by leveraging edge computing resources of the vehicles in a distributed network. In one embodiment, a method includes, in response to receiving, in a selected vehicle that is equipped with at least one camera, a visual query from a remote device, identifying search parameters from the query that specify at least visual content that is to be identified. The method includes analyzing a subset of a visual inventory to identify whether the subset includes the visual content by using at least a machine vision model executing on a processor within the selected vehicle. The visual inventory includes camera data that is acquired by the selected vehicle. The method includes communicating detection results about whether the subset includes the visual content to the remote device.

Abstract: A virtual assistance system for a vehicle is provided. The virtual assistance system includes one or more processors, one or more memory modules communicatively coupled to the one or more processors, an input device communicatively coupled to the one or more processors, an output device communicatively coupled to the one or more processors, and machine readable instructions stored in the one or more memory modules. The virtual assistance system receives, through the input device, a request for an item from a user, retrieves a location of an entity associated the item, calculates an estimated arrival time when the vehicle will arrive at the location, compares the estimated arrival time with a predetermined time associated with the entity, and instructs the output device to generate a delivery prompt related to the item in response to comparing the estimated arrival time with the predetermined time.

Abstract: Embodiments described herein relate to a storage system for implementing crowdsourced delivery of a parcel. In one embodiment, the storage system includes a communication system configured to communicate wirelessly with an external server to receive an access setting, a storage locker, secured by a primary electronic locking mechanism, including a plurality of inner compartments each secured by respective secondary electronic locking mechanisms, one or more processors, and a memory communicably coupled to the one or more processors and storing: a locking module including instructions that when executed by the one or more processors cause the one or more processors to set the primary electronic locking mechanism and at least one secondary electronic locking mechanism to open in response to, respectively, a primary code and a secondary code based at least in part on information received in the access setting.

Abstract: System and methods described herein relate to crowdsourced delivery, including receiving a delivery request, selecting a plurality of participants, determining a delivery route including at least one transfer of the parcel between a first participant and a second participant of the plurality of participants, with at least the first participant operating a vehicle having a secure storage locker that includes at least one secure compartment to hold the parcel, generating access keys including at least a first access key that enables access to the secure storage locker and a second access key that enables access to a secure compartment in the storage locker, transmitting the access keys to the second participant, distributing delivery tasks, based on the delivery route, to the plurality of participants, wherein completion of the delivery tasks results in delivery of the parcel to the delivery destination, and monitoring completion of the delivery tasks by the plurality of participants.

Abstract: System, methods, and other embodiments described herein relate to determining a location of a vehicle within a structure. In one embodiment, a method includes collecting, from at least one sensor in the vehicle, sensor data that indicates information associated with control of the vehicle in the structure. The method includes classifying gradients along a path of the vehicle through the structure according to the sensor data. The method includes identifying traversed levels of the structure along the path according to the gradients. The method includes providing the location including at least an indicator of the traversed levels as an electronic output.

Abstract: A system for illuminating a path for an object by a vehicle includes one or more processors, a memory device, one or more lights, and one or more sensors. The memory device, one or more lights, and one or more sensors may be in communication with the one or more processors. The memory device may include an object detection module and an illumination module. The object detection module includes instructions that cause the one or more processors to identify a presence of the object based on the one or more signals generated by the one or more sensors and determine object movement information of the object based on the one or more signals generated by the one or more sensors. The illumination module includes instructions that cause the one or more processors to illuminate using the one or more lights an area for the object based on the object movement information.

Abstract: A system for optimizing rescue efforts includes one or more processors, a network access device and a memory device. The network access device and the memory device are in communication with the one or more processors. The memory device includes an event detection module, a transmission module, and a reception module. The event detection module has instructions that cause the one or more processor to determine a location of an emergency event. The transmission module causes the one or more processors to transmit the location via the network access device to one or more detection systems that are within a detection range of the emergency event, wherein the one or more detection systems are one or more vehicles. The reception module causes the one or more processor to obtaining information regarding the emergency event via the one or more sensors that are within the detection range of the emergency event.

Abstract: System, methods, and other embodiments described herein relate to determining a location of a vehicle within a structure. In one embodiment, a method includes collecting, from at least one sensor in the vehicle, sensor data that indicates information associated with control of the vehicle in the structure. The method includes classifying gradients along a path of the vehicle through the structure according to the sensor data. The method includes identifying traversed levels of the structure along the path according to the gradients. The method includes providing the location including at least an indicator of the traversed levels as an electronic output.

Abstract: System, methods, and other embodiments described herein relate to using vehicles as mobile observation platforms and improving the querying of visual data within the vehicles by leveraging edge computing resources of the vehicles in a distributed network. In one embodiment, a method includes, in response to receiving, in a selected vehicle that is equipped with at least one camera, a visual query from a remote device, identifying search parameters from the query that specify at least visual content that is to be identified. The method includes analyzing a subset of a visual inventory to identify whether the subset includes the visual content by using at least a machine vision model executing on a processor within the selected vehicle. The visual inventory includes camera data that is acquired by the selected vehicle. The method includes communicating detection results about whether the subset includes the visual content to the remote device.

Abstract: A virtual assistance system for a vehicle is provided. The virtual assistance system includes one or more processors, one or more memory modules communicatively coupled to the one or more processors, an input device communicatively coupled to the one or more processors, an output device communicatively coupled to the one or more processors, and machine readable instructions stored in the one or more memory modules. The virtual assistance system receives, through the input device, a request for an item from a user, retrieves a location of an entity associated the item, calculates an estimated arrival time when the vehicle will arrive at the location, compares the estimated arrival time with a predetermined time associated with the entity, and instructs the output device to generate a delivery prompt related to the item in response to comparing the estimated arrival time with the predetermined time.

Abstract: Systems and methods for customer relationship management are disclosed. In one example, a customer relationship management system can receive, from a customer device, a customer location and a request for a sales representative. In response, the customer relationship management system can send, for display to a sales representative device, the customer location and then receive, from the sales representative device, a request for customer profile information. In response to this request, the customer relationship management system can send, for display to the sales representative device, at least some of the customer profile information.

Abstract: Systems and methods for customer relationship management are disclosed. In one example, a customer relationship management system can receive, from a customer device, a customer location and a request for a sales representative. In response, the customer relationship management system can send, for display to a sales representative device, the customer location and then receive, from the sales representative device, a request for customer profile information. In response to this request, the customer relationship management system can send, for display to the sales representative device, at least some of the customer profile information.

Abstract: Systems and methods for customer relationship management are disclosed. In one example, a customer relationship management system can receive, from a customer device, a customer location and a request for a sales representative. In response, the customer relationship management system can send, for display to a sales representative device, the customer location and then receive, from the sales representative device, a request for customer profile information. In response to this request, the customer relationship management system can send, for display to the sales representative device, at least some of the customer profile information.