Patent Publication Number: US-2022227590-A1

Title: Pallet System for Cargo Transport

Description:
PRIORITY CLAIM 
     The present application claims the benefit of priority of U.S. Provisional Patent Application 62/712,281 filed Jul. 31, 2018, entitled “Palette System for Cargo Transport.” The above-referenced patent application is hereby incorporated by reference herein in its entirety for all purposes. 
    
    
     FIELD 
     The present disclosure relates generally to a smart palette system for transporting cargo, and more particularly to systems and methods for transporting cargo using smart palettes. 
     BACKGROUND 
     A palette is a flat transport structure which can support cargo in a stable fashion while moved from one location to another (e.g., with a forklift, pallet jack, came, or other vehicle). The palette is a dumb structure that must be manually positioned or repositioned (e.g., inside a distribution warehouse, transport vehicle, etc.). It would be advantageous for a palette to be able to move itself rather than rely on external means. It would be further advantageous for a palette to immediately respond to events in a dynamic environment. For example, if a palette is in the way of a person or object, then it would be advantageous for the palette to automatically move out of the way. 
     SUMMARY 
     Aspects and advantages of the present disclosure will be set forth in part in the following description, or may be learned from the description, or may be learned through practice of the embodiments. 
     One example aspect of the present disclosure is directed to a computer-implemented method for transporting cargo using smart palettes. The method includes determining receipt of a first cargo onto a platform of a first smart palette at a first distribution hub. The method includes generating one or more signals that control a loading of the first smart palette and the first cargo onto a trailer located at the first distribution hub. The method includes determining a coordination with one or more second smart palettes associated with the trailer to determine a first position inside the trailer for the first smart palette and the first cargo. The method includes generating one or more signals that position the first smart palette and the first cargo at the first position inside the trailer. 
     Another example aspect of the present disclosure is directed to a system for transporting cargo using smart palettes. The system includes a plurality of smart palettes, one or more processors, and one or more tangible, non-transitory, computer readable media that collectively store instructions that when executed by the one or more processors cause the system to perform operations. The operations include determining a first cargo at a first location within a first distribution hub to be transported to a second distribution hub. The operations include selecting a first smart palette associated with the first distribution hub from the plurality of smart palettes, to move the first cargo from the first location to a trailer at the first distribution hub. The operations include providing data indicative of the trailer at the first distribution hub, and data indicative of one or more second smart palettes associated with the trailer to the first smart palette, wherein in response to receiving the data the first smart palette coordinates with the one or more second smart palettes to position the first smart palette and the first cargo inside the trailer. 
     Yet another example aspect of the present disclosure is directed to a smart palette. The smart palette includes a support structure that receives cargo, a drive mechanism that rotationally drives one or more ground engaging components of the smart palette to move the smart palette from a first location to a second location, one or more processors, and one or more tangible, non-transitory, computer readable media that collectively store instructions that when executed by the one or more processors cause the smart palette to perform operations. The operations include determining receipt of a first cargo onto a platform of the support structure at a first distribution hub. The operations include obtaining data indicative of a trailer at the first distribution hub to transport the first cargo, and data indicative of one or more second smart palettes associated with the trailer. The operations include controlling the drive mechanism to load the first cargo onto the trailer at the first distribution hub. The operations include coordinating with the one or more second smart palettes associated with the trailer to determine a first position inside the trailer for the first cargo. The operations include controlling the drive mechanism to position the first cargo and the support structure at the first position inside the trailer. 
     Other example aspects of the present disclosure are directed to systems, methods, vehicles, smart palettes, apparatuses, tangible, non-transitory computer-readable media, and memory devices for controlling or managing operations of smart palettes when providing a vehicle-based service. 
     These and other features, aspects, and advantages of various embodiments will become better understood with reference to the following description and appended claims. The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the present disclosure and, together with the description, serve to explain the related principles. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       Detailed discussion of embodiments directed to one of ordinary skill in the art are set forth below, which make reference to the appended figures, in which: 
         FIG. 1  depicts an example computing environment  100  according to example embodiments of the present disclosure; 
         FIG. 2A  depicts an example smart palette according to example embodiments of the present disclosure; 
         FIG. 2B  depicts an example of adjusting a platform size of a smart palette according to example embodiments of the present disclosure; 
         FIG. 3A  depicts an example of loading a smart palette onto a trailer according to example embodiments of the present disclosure; 
         FIG. 3B  depicts an example of unloading a smart palette from a trailer according to example embodiments of the present disclosure; 
         FIG. 3C-E  depict examples of smart palettes positioned inside a trailer according to example embodiments of the present disclosure; 
         FIGS. 4A-4I  depict an example of repositioning a smart palette inside a trailer according to example embodiments of the present disclosure; 
         FIG. 5  depicts a flow diagram of an example method  500  for providing a vehicle-based service according to example embodiments of the present disclosure; and 
         FIG. 6  depicts example system components according to example embodiments of the present disclosure. 
     
    
    
     Reference numerals that are repeated across plural figures are intended to identify the same components or features in various implementations. 
     DETAILED DESCRIPTION 
     Example aspects of the present disclosure are directed to smart palettes for transporting cargo. In particular, the smart palettes can be used to transport cargo from a first location to a second location as part of a vehicle-based service (e.g., transportation service, courier service, delivery service, freight service, etc.). For instance, an entity (e.g., service provider) can coordinate, direct, or operate a fleet of vehicles to provide a freight transport service. The fleet can include, for example, autonomous vehicles that can drive, navigate, operate, etc. with minimal and/or no interaction from a human driver. The service provider can operate a vehicle in the fleet (e.g., an autonomous vehicle or a non-autonomous vehicle) to transport cargo from the first location (e.g., first distribution hub) to the second location (e.g., second distribution hub). For example, the vehicle can include a cargo enclosure, container, bed, or other structure that can hold cargo (e.g., straight truck), or the vehicle can be attached (e.g., hitched) to a cargo enclosure, container, bed, trailer, or other structure that can hold cargo. Hereinafter the term “trailer” is used to refer to any of the aforementioned structures. The vehicle can transport the trailer that contains cargo from the first distribution hub to the second distribution hub. When the trailer is at the first distribution hub, the service provider can operate one or more smart palettes to autonomously load cargo located at the first distribution hub onto the trailer. The service provider can operate the vehicle to transport the trailer from the first distribution hub to the second distribution hub where one or more smart palettes can unload cargo from the trailer. In this way, the smart palette(s) can be used to transport the cargo from the first distribution hub to the second distribution hub. 
     More particularly, a service provider network can operate a fleet of one or more vehicles (e.g., ground-based vehicles) to provide a vehicle-based service, such as a transportation service, courier service, delivery service, or freight service. The vehicles can be autonomous vehicles that include various systems and devices configured to control the operation of the vehicle. For example, an autonomous vehicle can include an onboard vehicle computing system for operating the vehicle (e.g., located on or within the autonomous vehicle). In some implementations, the autonomous vehicles can operate in an autonomous mode. For example, the vehicle computing system can receive sensor data from sensors onboard the vehicle (e.g., cameras, LIDAR, RADAR), attempt to comprehend the environment proximate to the vehicle by performing various processing techniques on the sensor data, and generate an appropriate motion plan through the environment. In some implementations, the autonomous vehicles can operate in a manual mode. For example, a human operator (e.g., a driver) can manually control the autonomous vehicle. Moreover, the autonomous vehicle can be configured to communicate with one or more computing device(s) that are remote from the vehicle. As an example, the autonomous vehicle can communicate with an operations computing system that can be associated with the service provider network. The operations computing system can help the service provider network monitor, communicate with, manage, etc. the fleet of vehicles. As another example, the autonomous vehicle can communicate with one or more other vehicles (e.g., a vehicle computing system onboard each of the one or more other vehicles in the fleet), one or more smart palettes (e.g., a palette computing system onboard each of the one or more smart palettes), one or more other computing systems associated with the service provider network, and/or any other suitable remote computing system(s). In some implementations, the operations computing system can mediate communication between the autonomous vehicle and the computing device(s) that are remote from the vehicle. 
     According to aspects of the present disclosure, the service provider network can operate a plurality of smart palettes to transport cargo, as part of a vehicle-based service. The smart palette(s) can include various systems and devices configured to control the operation of the smart palette. For example, a smart palette can include an onboard palette computing system for operating the smart palette (e.g., located on or within the smart palette). The palette computing system can operate the smart palette to autonomously load or unload cargo onto a trailer, and to position or reposition the smart palette inside the trailer. The palette computing system can coordinate with one or more other smart palettes (e.g., a palette computing system onboard each of the one or more other smart palettes) associated with the trailer to determine the smart palette&#39;s position inside the trailer. The one or more other smart palettes associated with the trailer can include one or more smart palettes that have been previously positioned (e.g., pre-positioned) inside the trailer when the palette computing system operates the smart palette to autonomously load cargo and/or position the smart palette. In addition, or as an alternative thereto, the one or more other smart palettes associated with the trailer can include one or more smart palettes that will be positioned (e.g., post-positioned) inside the trailer after the palette computing system operates the smart palette to autonomously load cargo and/or position the smart palette. 
     In some implementations, the smart palette can include a motor or other drive means configured to rotationally drive one or more ground engaging components, such as wheels or tracks. The palette computing system can control the motor to move the smart palette from a first location to a second location. For example, the palette computing system can control the motor to move the smart palette to a cargo pick-up location (e.g., a location of cargo at a distribution hub) to pick-up cargo, move the smart palette from a cargo pick-up location to a trailer location (e.g., a location of a trailer at a distribution hub), move the smart palette onto a trailer, move the smart palette off a trailer, and move the smart palette from a trailer location to a cargo drop-off location (e.g., a location at a distribution hub) to drop-off cargo. 
     In some implementations, the smart palette can include a platform that can receive and hold cargo. For example, the operations computing system can determine that a first cargo located at a first distribution hub is to be transported to a second distribution hub. The operations computing system can instruct the smart palette to move to a cargo pick-up location of the first cargo at the first distribution hub and cause the first cargo to be placed on the platform of the smart palette. The palette computing system can control the motor of the smart palette to move the smart palette to the cargo pick-up location where the smart palette can receive and hold the first cargo on the platform. The palette computing system can determine receipt of the first cargo onto the platform and control the motor of the smart palette to move the smart palette with the first cargo from the cargo pick-up location to a trailer location of a trailer at the first distribution hub. 
     In some implementations, the smart palette can include one or more sensors (e.g., cameras, LIDAR, RADAR, compass, accelerometer, gyroscope etc.). The palette computing system can obtain sensor data from the sensor(s), attempt to comprehend the environment proximate to the smart palette by performing various processing techniques on the sensor data, and generate an appropriate action based on the sensor data. 
     As an example, the palette computing system can obtain sensor data indicative of an environment within a distribution hub and generate a motion plan from a first location to a second location at the distribution hub (e.g., from a cargo pick-up location to a trailer location, or from a trailer location to a cargo drop-off location). 
     As another example, the palette computing system can obtain sensor data indicative of an environment inside a trailer to determine a position for positioning the smart palette inside the trailer. 
     As another example, the palette computing system can obtain sensor data indicative of a weight distribution of cargo on the platform of the smart palette. The palette computing system can use the weight distribution data to determine whether the cargo&#39;s weight is within acceptable limits of the smart palette (e.g., below a maximum weight that the smart palette is capable of moving). 
     As another example, the palette computing system can obtain sensor data indicative of a weight distribution of cargo on the platform of the smart palette at two or more times. The palette computing system can also compare the weight distribution data at a first and second time to determine a change in weight distribution. The palette computing system can determine, based on the change in weight distribution, if the cargo is shifting or sliding on the platform when the smart palette is in motion (e.g., when the smart palette is moving from a first location to a second location, when the smart palette is inside a moving trailer that is being transported from a first distribution hub to a second distribution hub, etc.). The palette computing system can control the smart palette to adjust for the change in weight distribution in order to keep the cargo&#39;s center of mass within the boundaries of the platform. 
     As another example, the palette computing system can obtain sensor data indicative of an orientation of the smart palette. The palette computing system can use the orientation data to determine if the smart palette is not level (e.g., when the smart palette is on an inclined surface, when the smart palette is inside a trailer on an inclined surface, etc.). If the palette computing system determines that the smart palette is holding cargo when the smart palette is not level, then the palette computing system can control the smart palette to adjust the orientation of the platform in order to prevent the cargo from shifting, sliding, or falling off the platform. 
     In some implementations, the smart palette can include a communications interface to communicate with one or more other computing systems. The palette computing system can use the communications interface to communicate with the operations computing system, one or more other smart palette computing systems, or a vehicle computing system, in order to transport cargo (e.g., from a first distribution hub to a second distribution hub). 
     As an example, the palette computing system can communicate with the operations computing system to obtain data indicative of a first cargo to be transported. The cargo data can include a cargo pick-up location at a first distribution hub, a destination distribution hub for the first cargo, a cargo drop-off location at the destination distribution hub, a trailer location of a trailer at the first distribution hub, and a vehicle (e.g., autonomous vehicle) assigned to transport the trailer (e.g., from the first distribution hub to the destination distribution hub). The palette computing system can control the smart palette to move to the cargo pick-up location at the first distribution hub to receive the first cargo, and control the smart palette to move to the trailer location and load the first cargo (e.g., load the smart palette with the first cargo) onto the trailer. The palette computing system can communicate with a vehicle computing system of the vehicle assigned to transport the trailer to obtain data indicative of the trailer location after departing the first distribution hub (e.g., a location of the trailer during transit). The palette computing system can use the trailer location data to determine if the trailer has arrived at the destination distribution hub (or the second distribution hub). If the palette computing system determines that the trailer has arrived at the destination distribution hub, then the palette computing system can control the smart palette to unload the first cargo from the trailer (e.g., unload the smart palette with the first cargo), and control the smart palette to move to the cargo drop-off location at the destination distribution hub. 
     As another example, the palette computing system can communicate with the operations computing system to obtain data indicative of a first cargo to be transported and a cargo route for the first cargo. The cargo route can include a first distribution hub associated with a cargo pick-up location, a destination distribution hub associated with a cargo drop-off location, and one or more transfer distribution hubs. Each distribution hub in the cargo route can be associated with a trailer location of a trailer, and a vehicle assigned to transport the trailer. The palette computing system can control the smart palette to receive and load the first cargo onto a first trailer that is located at the first distribution hub. If the palette computing system determines that the trailer has arrived at a transfer distribution hub from the one or more transfer distribution hubs, then the palette computing system can control the smart palette to unload the first cargo from the first trailer, and load the first cargo onto a second trailer that is located at the transfer distribution hub. 
     As another example, the palette computing system can communicate with one or more other palette computing systems to position the smart palette inside a trailer. The palette computing system can determine a trailer to load a first cargo (e.g., based on cargo data obtained from the operations computing system) and determine one or more other smart palettes that are associated with the trailer. The one or more other smart palettes can each be associated with respective cargo to be transported inside the trailer, or that will be transported inside the trailer. The palette computing system can coordinate with the one or more other palette computing systems to position the smart palette with the first cargo inside the trailer, for example, based on a transportation route of an autonomous vehicle assigned to transport the trailer (e.g., so that smart palettes with cargo that will unload sooner are positioned nearer to an exit of the trailer), a load distribution of the smart palette and the one or more other smart palettes inside the trailer (e.g., to distribute the load evenly inside the trailer), and/or one or more dimensions associated with the first cargo (e.g., to minimize unused space inside the trailer). In some implementations, the palette computing system can identify one or more pre-positioned smart palettes from the one or more other smart palettes, and the palette computing system can coordinate with the pre-positioned smart palette(s) to determine a position for the smart palette with the first cargo. In some implementations, after the palette computing system positions the smart palette with the first cargo inside the trailer, the palette computing system can identify one or more post-positioned smart palettes from the one or more other smart palette(s), and the palette computing system can coordinate with the post-positioned smart palette(s) to reposition the smart palette with the first cargo inside the trailer (e.g., based on a position of the post-positioned smart palette(s) inside the trailer). 
     In some implementations, the palette computing system can communicate with a vehicle computing system of an autonomous vehicle assigned to transport a trailer including the smart palette with the first cargo to obtain data indicative of a change in a transportation route of the autonomous vehicle. The palette computing system can use the transportation route change data to reposition the smart palette inside the trailer (e.g., by coordinating with one or more other smart palettes inside the trailer). 
     As an example, the autonomous vehicle can be associated with a transportation route indicating that the autonomous vehicle will transport the trailer from a first distribution hub to a second distribution hub, and the palette computing system can load the smart palette onto the trailer at the first distribution hub based on this transportation route. If the transportation route is changed while the autonomous vehicle is in transit to the second distribution hub such that the autonomous vehicle will instead transport the trailer to a third distribution hub (e.g., the autonomous vehicle is rerouted due to traffic conditions, maintenance issues, or logistics), then the palette computing system can communicate with a vehicle computing system of the autonomous vehicle to obtain data indicative of the change in the transportation route. The palette computing system can coordinate with one or more other smart palette(s) inside the trailer to determine a new position for the smart palette based on the transportation route change data. The palette computing system can control the smart palette to reposition the smart palette at the new position while the autonomous vehicle is transporting the trailer. Likewise, a palette computing system associated with each of the one or more other smart palette(s) inside the trailer can determine a new position for a corresponding smart palette, based on the transportation route change data, and reposition the corresponding smart palette. In this way, when the trailer arrives at the third distribution hub, cargo to be unloaded at the third distribution hub is positioned nearer to an exit of the trailer and the cargo can be unloaded quickly and efficiently. 
     As another example, the palette computing system can communicate with a vehicle computing system of an autonomous vehicle that is transporting the smart palette and a first cargo on a platform of the smart palette (e.g., inside a trailer hitched to the autonomous vehicle), to obtain data indicative of a change in load distribution. The palette computing system or the vehicle computing system can obtain the data indicative of the change in load distribution from one or more sensors associated with the smart palette and/or the trailer. The palette computing system can use the data to reposition the smart palette inside the trailer. If the autonomous vehicle experiences a tire blowout of a tire near the front of the trailer, then the vehicle computing system onboard the autonomous vehicle can determine to shift the load distribution inside the trailer towards the rear of the trailer. The palette computing system can obtain data indicative of the change in load distribution and coordinate with one or more other smart palettes inside the trailer to determine a new position for the smart palette based on the change in the load distribution. The palette computing system can control the smart palette to position the smart palette at the new position. Likewise, each of the one or more other palette computing systems can determine a respective new position for a corresponding smart palette based on the change in the load distribution, and position the corresponding smart palette at the new position. 
     The systems and methods described herein may provide a number of technical effects and benefits. For instance, by enabling a smart palette that can communicate with a vehicle computing system of an autonomous vehicle, and loading the smart palette onto a trailer of the autonomous vehicle together with cargo, the smart palette can autonomously determine when the cargo has arrived at a destination and autonomously unload the cargo at the destination. Additionally, by enabling a palette computing system onboard the smart palette to communicate with one or more other palette computing systems associated with the trailer, the palette computing system can autonomously position the smart palette inside the trailer to optimize loading and unloading cargo, load distribution inside the trailer, and utilization of available space inside the trailer. Furthermore, the present disclosure enables the palette computing system to reposition the smart palette inside the trailer while the trailer is in transit based on a change in destination of the autonomous vehicle and/or a change in load distribution associated with the trailer. In this way, the present disclosure enables the transportation of cargo from one location to another with improved speed and efficiency. 
     The systems and methods described herein may also provide resulting improvements to computing technology tasked with transporting cargo. For example, the systems and methods described herein may provide improvements in a utilization of the fleet of vehicles for providing a vehicle-based service by reducing a time spent at one or more distribution hubs for loading and unloading cargo, resulting in increased throughput and improved efficiency. 
     With reference now to the FIGS., example embodiments of the present disclosure will be discussed in further detail. 
       FIG. 1  depicts an example computing environment  100  according to example embodiments of the present disclosure. The example environment  100  illustrated in  FIG. 1  is provided as an example only. The components, systems, connections, and/or other aspects illustrated in  FIG. 1  are optional and are provided as examples of what is possible, but not required, to implement the present disclosure. The example environment  100  can include one or more autonomous vehicles  10 , one or more trailers  20 , one or more smart palettes  30 , and an operations computing system  108 . Vehicle(s)  10  can each be associated with a vehicle computing system  102 . Smart palette(s)  30  can each be associated with a palette computing system  103 . Vehicle computing system  102 , palette computing system  103 , and operations computing system  108  can be remote from each other and communicatively coupled to one another over one or more networks  40 . 
     In some implementations, vehicle(s)  10  incorporating the vehicle computing system  102  can be part of a fleet of vehicles managed by the operations computing system  108 . The operations computing system  108  can manage vehicle(s)  10  via the vehicle computing system  102 . Vehicle(s)  10  can be a ground-based autonomous vehicle (e.g., car, truck, bus), an air-based autonomous vehicle (e.g., airplane, drone, helicopter, or other aircraft), or other types of vehicles (e.g., boat, ship, or other watercraft). Vehicle(s)  10  can be an autonomous vehicle that can drive, navigate, operate, etc. with minimal and/or no interaction from a human driver, or vehicle(s)  10  can be manually controlled by a human operator. 
     In some implementations, the operations computing system  108  can assign vehicle(s)  10  to transport the trailer(s)  20 . Trailer(s)  20  can include one or more sensors  125  that can acquire sensor data indicative of cargo that is loaded onto trailer(s)  20 . For example, the sensor data can include data indicative of a total weight of the cargo inside trailer(s)  20 , and a distribution of the weight (e.g., load distribution) inside trailer(s)  20 . When operations computing system  108  assigns vehicle(s)  10  to transport the trailer(s)  20 , vehicle computing system  102 can control the vehicle(s)  10  to hitch trailer(s)  20  and communicate with the sensor(s)  125  to obtain the sensor data. Alternatively, in some implementations, trailer(s)  20  can each be associated with a trailer computing system that is communicatively coupled to one or more remote computing systems (e.g., vehicle computing system  102 , palette computing system  103 , operations computing system  108 , etc.) over network(s)  40 . The trailer computing system can obtain sensor data that is acquired by the sensor(s)  125  and provide the sensor data to the one or more remote computing systems. 
     In some implementations, smart palette(s)  30  incorporating the palette computing system  103  can be operated by operations computing system  108 . Operations computing system  108  can operate smart palette(s)  30  via palette computing system  103 . Operations computing system  108  can assign smart palette(s)  30  to transport cargo from a first distribution hub to a second distribution hub. Smart palette(s)  30  can include a platform for receiving cargo, and palette control(s)  126  (e.g., a motor or other drive means configured to rotationally drive one or more ground engaging components, such as wheels or tracks). 
     Smart palette(s)  30  can be capable of sensing its environment, navigating its environment with minimal or no human input, and/or the like. Smart palette(s)  30  can include one or more sensors  124 , palette computing system  103 , and one or more palette controls  126 . Computing system  103  can assist in controlling smart palette(s)  30 . For example, computing system  103  can receive data generated by sensor(s)  124 , attempt to comprehend an environment surrounding smart palette(s)  30  by performing various processing techniques on the data generated by sensor(s)  124 , generate, determine, select, and/or the like a motion plan for navigating smart palette(s)  30  through, within, and/or the like such surrounding environment, and/or the like. Computing system  103  can interface with palette control(s)  126  to operate smart palette(s)  30  (e.g., in accordance with the motion plan, and/or the like). 
     Computing system  103  can include one or more computing devices  104 . Computing device(s)  104  can include circuitry configured to perform one or more operations, functions, and/or the like described herein. For example, computing device(s)  104  can include one or more processor(s)  112 , one or more communication interfaces  114 , and memory  116  (e.g., one or more hardware components for storing executable instructions, data, and/or the like). Communication interface(s)  114  can enable computing device(s)  104  to communicate with one another, and/or can enable smart palette(s)  30  (e.g., computing system  103 , computing device(s)  104 , and/or the like) to communicate with one or more computing systems, computing devices, and/or the like distinct from smart palette(s)  30  (e.g., vehicle computing system  102 , operations computing system  108 , and/or the like). Memory  116  can include (e.g., store, and/or the like) instructions  118  and data  120 . When executed by processor(s)  112 , instructions  118  can cause smart palette(s)  30  (e.g., computing system  103 , computing device(s)  104 , and/or the like) to perform one or more operations, functions, and/or the like described herein. Data  120  can include, represent, and/or the like information associated with such operations, functions, and/or the like, data generated by sensor(s)  124 , cargo data  124 , palette data  137 , transportation route data  140 , load distribution data  142 , trailer location data  144 , and/or the like. 
     Cargo data  124  can include a first distribution hub corresponding to cargo associated with smart palette(s)  30 , a cargo pick-up location at the first distribution hub associated with the cargo, a destination distribution hub corresponding to cargo associated with smart palette(s)  30 , and a cargo drop-off location at the destination distribution hub associated with the cargo. In some implementations, cargo data  124  can include a cargo route for the cargo. The cargo route can include the first distribution hub, the destination distribution hub, and one or more transfer distribution hubs corresponding to cargo associated with smart palette(s)  30 . Each distribution hub in the cargo route can be associated with a trailer location of a trailer that is associated with smart palette(s)  30  at the distribution hub, and a vehicle  10  assigned to transport the trailer from the distribution hub to another location. 
     Palette data  137  can include data indicative of one or more palette computing systems  103  onboard one or more smart palettes  30  that are associated with the same trailer (e.g., that are transported in the same trailer), a destination distribution hub corresponding to cargo associated with the one or more smart palettes  30 , one or more cargo dimensions corresponding to cargo associated with the one or more smart palettes  30 , and a palette size associated with the one or more smart palettes  30 . 
     Transportation route data  140  can include a transportation route associated with vehicle(s)  10  that is transporting smart palette(s)  30  (e.g., that is transporting smart palette(s) inside trailer  20  that is hitched to vehicle(s)  10 ). 
     Load distribution data  142  can include a distribution of weight associated with smart palette(s)  30  inside the same trailer. In some implementations, load distribution data  142  can include an optimal distribution of weight inside the trailer. 
     Trailer location data  144  can include a location of a trailer associated with smart palette(s)  30  at a distribution hub where smart palette(s)  30  is currently located, and/or a location of a trailer associated with smart palette(s)  30  during transit from a first location (e.g., first distribution hub) to a second location (e.g., second distribution hub). 
     Computing system  103  can be physically located onboard smart palette(s)  30 , and computing systems  102 ,  108  can be distinct and/or remotely located from smart palette(s)  30 . Network(s)  40  (e.g., wired networks, wireless networks, and/or the like) can interface smart palette(s)  30  (e.g., computing system  103 , computing device(s)  104 , and/or the like) with computing systems  102 ,  108 , which can include one or more computing devices analogous to computing device(s)  104 , one or more components (e.g., memory, processors, communication interfaces, and/or the like) analogous to those of computing device(s)  104 , and/or the like. Irrespective of attribution described or implied herein, unless explicitly indicated otherwise, the operations, functions, and/or the like described herein can be performed by computing system(s)  103  and/or  108  (e.g., by computing system  103 , by computing system  108 , by a combination of computing systems  103  and  108 , and/or the like). 
     Computing system  103  can include positioning system  110 , which can include one or more devices, circuitry, and/or the like for analyzing, approximating, determining, and/or the like one or more geographic positions of smart palette(s)  30 . For example, positioning system  110  can analyze, approximate, determine, and/or the like such position(s) using one or more inertial sensors, triangulations and/or proximities to network components (e.g., cellular towers, WiFi access points, and/or the like), satellite positioning systems, network addresses, and/or the like. Computing system  103  can include perception system  128 , prediction system  130 , and motion-planning system  132 , which can cooperate to perceive a dynamic environment surrounding smart palette(s)  30 , generate, determine, select, and/or the like a motion plan for smart palette(s)  30 , and/or the like. 
     Perception system  128  can receive data from sensor(s)  124 , which can be coupled to or otherwise included within smart palette(s)  30 . Sensor(s)  124  can include, for example, one or more cameras (e.g., visible spectrum cameras, infrared cameras, and/or the like), light detection and ranging (LIDAR) systems, radio detection and ranging (RADAR) systems, and/or the like. Sensor(s)  124  can generate data including information that describes one or more locations, velocities, vectors, and/or the like of objects in the environment surrounding smart palette(s)  30 . For example, a LIDAR system can generate data indicating the relative location (e.g., in three-dimensional space relative to the LIDAR system, and/or the like) of a number of points corresponding to objects that have reflected a ranging laser of the LIDAR system. Such a LIDAR system can, for example, measure distances by measuring the interference between outgoing and incoming light waves, measuring the time of flight (TOF) it takes a short laser pulse to travel from a sensor to an object and back, calculating the distance based at least in part on the TOF with respect to the known speed of light, based at least in part on a phase-shift with known wavelength, and/or the like. As another example, a RADAR system can generate data indicating one or more relative locations (e.g., in three-dimensional space relative to the RADAR system, and/or the like) of a number of points corresponding to objects that have reflected a ranging radio wave of the RADAR system. For example, radio waves (e.g., pulsed, continuous, and/or the like) transmitted by such a RADAR system can reflect off an object and return to a receiver of the RADAR system, generating data from which information about the object&#39;s location, speed, and/or the like can be determined. As another example, for one or more cameras, various processing techniques, for example, range-imaging techniques (e.g., structure from motion, structured light, stereo triangulation, and/or the like) can be performed to identify one or more locations (e.g., in three-dimensional space relative to the camera(s), and/or the like) of a number of points corresponding to objects depicted in imagery captured by the camera(s). 
     Perception system  128  can retrieve, obtain, and/or the like map data  122 , which can provide information about an environment surrounding smart palette(s)  30 . For example, map data  122  can provide information regarding: the identity and location of different travel ways (e.g., to travel within a distribution hub, and/or the like), buildings, other static items or objects (e.g., cargo, and/or the like); the location and directions of travel lanes (e.g., for a plurality of smart palettes within a distribution hub , and/or the like); traffic-control data (e.g., the location and/or instructions of signage, traffic lights, other traffic-control devices, and/or the like); other map data providing information that can assist computing system  103  in comprehending, perceiving, and/or the like an environment surrounding smart palette(s)  30 , its relationship thereto, and/or the like. 
     Perception system  128  can (e.g., based at least in part on data received from sensor(s)  124 , map data  122 , and/or the like) identify one or more objects proximate to smart palette(s)  30  and determine, for each of such object(s), state data describing a current state of the object, for example, an estimate of the object&#39;s: size/footprint (e.g., as represented by a bounding shape such as a polygon, polyhedron, and/or the like); class (e.g., vehicle, smart palette, pedestrian, and/or the like); current location (also referred to as position), speed (also referred to as velocity), acceleration, heading, orientation, yaw rate; and/or the like. In some embodiments, perception system  128  can determine such state data for each object over a number of iterations, for example, updating, as part of each iteration, the state data for each object. Accordingly, perception system  128  can detect, track, and/or the like such object(s) over time. 
     Prediction system  130  can receive state data from perception system  128  and can predict (e.g., based at least in part on such state data, and/or the like) one or more future locations for each object. For example, prediction system  130  can predict where each object will be located within the next five seconds, ten seconds, twenty seconds, and/or the like. As one example, an object can be predicted to adhere to its current trajectory according to its current speed. Additionally or alternatively, other prediction techniques, modeling, and/or the like can be used. 
     Motion-planning system  132  can generate, determine, select, and/or the like a motion plan for smart palette(s)  30 , for example, based at least in part on state data of object(s) provided by perception system  128 , predicted future location(s) of object(s) provided by prediction system  130 , and/or the like. For example, utilizing information about current location(s) of object(s), predicted future location(s) of object(s), and/or the like, motion-planning system  132  can generate, determine, select, and/or the like a motion plan for smart palette(s)  30  that it determines (e.g., based at least in part on one or more operation parameters, and/or the like) best navigates smart palette(s)  30  relative to the object(s). Motion-planning system  132  can provide the motion plan to palette control system  134 , which can directly and/or indirectly control smart palette(s)  30  via palette control(s)  126  (e.g., one or more actuators, devices, and/or the like that control gas, power flow, steering, braking, and/or the like) in accordance with the motion plan. 
     Perception system  128 , prediction system  130 , motion-planning system  132 , and/or palette control system  134  can include logic utilized to provide functionality described herein. Perception system  128 , prediction system  130 , motion-planning system  132 , and/or palette control system  134  can be implemented in hardware (e.g., circuitry, and/or the like), firmware, software configured to control one or more processors, one or more combinations thereof, and/or the like. For example, instructions  118 , when executed by processor(s)  112 , can cause smart palette(s)  30  (e.g., computing system  103 , computing device(s)  104 , and/or the like) to implement functionality of perception system  128 , prediction system  130 , motion-planning system  132 , and/or vehicle-control system  134  described herein. 
       FIG. 2A  depicts an example smart palette according to example embodiments of the present disclosure. As shown in  FIG. 2A , smart palette  231  can include platform  232  and one or more ground engaging components  233  (e.g., wheels, tracks, etc.). Smart palette  231  can include an onboard palette computing system  103  and sensor(s)  124  (not shown). Smart palette  231  can receive cargo  250  on platform  232 , and can move from one location to another location using the ground engaging component(s)  233 . For example, operations computing system  108  can instruct computing system  103  of smart palette  231  to pick-up cargo  250 . Operations computing system  108  can provide cargo data  136  indicative of a cargo pick-up location of cargo  250  at a distribution hub, and trailer location data  144  indicative of a location of a trailer at the distribution hub, to computing system  103 . In response, computing system  103  can control ground engaging component(s)  233  to move smart palette  231  to the cargo pick-up location, where smart palette  231  can receive and hold cargo  250  on platform  232 , and to move smart palette  231  from the cargo pick-up location to the trailer location. In some implementations, cargo data  132  can include a destination distribution hub and a cargo drop-off location at the destination distribution hub for cargo  250 , and when computing system  103  determines that the trailer is at the destination distribution hub, computing system  103  can control ground engaging component(s)  233  to move smart palette  231  from a location of the trailer at the destination distribution hub to the cargo drop-off location. 
     In some implementations, sensor(s)  124  ( FIG. 1 ) can acquire sensor data indicative of smart palette  231  receiving cargo  250 , and computing system  103  can determine receipt of cargo  250  based on the sensor data. In some implementations, sensor(s)  124  can acquire sensor data indicative of an environment within a distribution hub and computing system  103  generate a motion plan from a first location to a second location at the distribution hub based on the sensor data (e.g., from a current location of smart palette  231  to a cargo pick-up location, from a cargo pick-up location to a trailer location, or from a trailer location to a cargo drop-off location). In some implementations, sensor(s)  124  can acquire sensor data indicative of an environment inside a trailer, and computing system  103  generate a motion plan from a first position to a second position inside the trailer based on the sensor data. 
       FIG. 2B  depicts an example of adjusting a platform size of a smart palette according to example embodiments of the present disclosure. As shown in  FIG. 2B , computing system  103  can adjust a platform size of smart palette  231 . For example, operations computing system  108  can provide data indicative of a cargo pick-up location and cargo dimensions of cargo  260  to computing system  103 . Operations computing system  108  can instruct smart palette  231  to pick-up cargo  260 , and in response computing system  103  can control smart palette  231  to move to the cargo pick-up location, where smart palette  231  can receive and hold cargo  260  on platform  232 . Additionally, if the cargo dimensions of cargo  260  indicate that cargo  260  is larger than a current platform size of platform  232 , then computing system  103  can adjust the platform size of platform  232  to accommodate the cargo dimensions by expanding platform  232 . For example, computing system  103  can adjust the platform width of platform  232  from a first width w 1  to a second width w 2 . 
       FIG. 3A  depicts an example of loading a smart palette onto a trailer according to example embodiments of the present disclosure. As shown in  FIG. 3A , a computing system  103  associated with smart palette  331  can control smart palette  331  to load cargo  350  onto trailer  320 . For example, trailer  320  and smart palette  331  can be located at a first distribution hub. Operations computing system  108  can assign smart palette to transport cargo  350  from the first distribution hub to a second distribution hub, and can provide cargo data  136  and trailer location data  144  to computing system  103 . In response, computing system  103  can control smart palette  331  to move to a pick-up location of cargo  350  to pick-up cargo  350  (e.g., based on cargo data  136 ), control smart palette  331  to move to the location of trailer  320  (e.g., based on trailer location data  144 ), and control smart palette  331  to load cargo  350  onto trailer  320  (e.g., by moving smart palette  331  with cargo  350  inside trailer  320 ). Vehicle  310  can be assigned by operations computing system  108  to transport trailer  320  from the first distribution hub to the second distribution hub. In some implementations, a vehicle computing system  102  associated with vehicle  310  can control vehicle  310  to hitch trailer  320  before smart palette  331  is loaded onto trailer  320 . Alternatively, in some implementations, palette computing system  103  can control vehicle  310  to hitch trailer  320  after smart palette  331  is loaded onto trailer  320 . 
       FIG. 3B  depicts an example of unloading a smart palette from a trailer according to example embodiments of the present disclosure. As shown in  FIG. 3B , computing system  103  can control smart palette  331  to unload cargo  350  from trailer  320 . For example, cargo data  136  can include a destination distribution hub of cargo  350 , and palette computing system  103  can provide trailer location data  144  to computing system  103  when trailer  320  is in transit. If computing system  103  determines that trailer  320  has arrived at the destination distribution hub of cargo  350  (e.g., based on trailer location data  144 ), then computing system  103  can control smart palette  331  to unload cargo  350  from trailer  320  (e.g., by moving smart palette  331  with cargo  350  off trailer  320 ). In some implementations, vehicle computing system  102  can control vehicle  310  to unhitch trailer  320  before smart palette  331  is unloaded from trailer  320 . Alternatively, in some implementations, palette computing system  103  can control vehicle  310  to unhitch trailer  320  after smart palette  331  is unloaded from trailer  320 . Alternatively, in some implementations, palette computing system  103  can control vehicle  310  to remain hitched trailer  320  before and after smart palette  331  is unloaded from trailer  320  (e.g., to transport trailer  320  to another location). 
       FIG. 3C  depicts an example of smart palettes positioned inside a trailer according to example embodiments of the present disclosure. As shown in  FIG. 3C , smart palettes  331 ,  332 ,  333 ,  334 ,  335 , and  336  can be positioned inside trailer  320 . Operations computing system  108  can provide palette data  137  to computing system  103  indicative of a palette computing system associated with each smart palette  332 - 336 , and computing system  103  can communicate with the palette computing system associated with each smart palette  332 - 336  (e.g., based on palette data  137 ) to position smart palette  331  inside trailer  320 . Computing system  103  can obtain data indicative of a position of each smart palette  332 - 336  from the palette computing system associated with each smart palette  332 - 336 , to determine unused space inside trailer  320 . Computing system  103  can position smart palette  331  at the unused space (or a portion thereof) inside trailer  320 . 
     In some implementations, palette computing system  103  can provide transportation route data  140  to computing system  103  indicative of a transportation route of vehicle  310 , and computing system  103  can communicate with the palette computing system associated with each smart palette  332 - 336  to position smart palette  331  inside trailer  320  based on the transportation route data  140 . Computing system  103  can obtain palette data  137  indicative of a destination distribution hub corresponding to cargo associated with each smart palette  332 - 336  (e.g., from operations computing system  108  and/or palette computing systems associated with each smart palette  332 - 336 ) so that palettes with cargo that will unload sooner are positioned nearer to an exit of the trailer  320 . For example, if a destination distribution hub associated with smart palette  331  is distribution hub “A” (e.g., hub A), a destination distribution hub associated with smart palette  332  is distribution hub “B” (e.g., hub B), and the transportation route of vehicle  310  indicates that trailer  320  will arrive at hub A before hub B, then computing system  103  can position smart palette  331  nearer to an exit of trailer  320 . Alternatively, if the transportation route of vehicle  310  indicates that trailer  320  will arrive at hub B before hub A, then computing system  103  can position smart palette  331  farther from an exit of trailer  320  so that the palette computing system associated with smart palette  332  can position smart palette  332  nearer to the exit. 
     In some implementations, palette computing system  103  can provide load distribution data  142  to computing system  103  indicative of a load distribution of smart palettes  331 - 336  inside trailer  320 , and computing system  103  can communicate with the palette computing system associated with each smart palette  332 - 336  to position smart palette  331  inside trailer  320  based on the load distribution data  142 . Palette computing system  103  can obtain data indicative of the load distribution from sensor(s)  125  associated with trailer  320  to provide the data to computing system  103 . Computing system  103  can communicate with the palette computing system associated with each smart palette  332 - 336  to determine an optimal position for smart palette  331  inside trailer  320 . For example, computing system  103  can determine a position for smart palette  331  such that the weight associated with each smart palette  331 - 336  is distributed evenly inside trailer  320 . In some implementations, load distribution data  142  can include an optimal load distribution. For example, if a tire of vehicle  310  associated with a front end of trailer  320  is damaged or deflated, then palette computing system  103  can provide load distribution data  142  that includes an optimal load distribution toward a rear end of trailer  320 . In response to receiving data indicative of the optimal load distribution, computing system  103  can communicate with the palette computing system associated with each smart palette  332 - 336  to determine a position for smart palette  331  such that weight associated with each smart palette  331 -  336  is distributed toward the rear end of trailer  320 . 
     In some implementations, palette data  137  can include data indicative of a palette size associated with each smart palette  331 - 336  and/or one or more dimensions corresponding to cargo associated with each smart palette  331 - 336 . Alternatively, computing system  103  can obtain palette data  137  from the palette computing system associated with each smart palette  332 - 336  indicative of the palette size associated with each smart palette  331 - 336  and/or the one or more dimensions corresponding to cargo associated with each smart palette  332 - 336 . Computing system  103  can use the palette data  137  to more accurately determine an unused space inside trailer  320 , and communicate with the palette computing system associated with each smart palette  332 - 336  to position smart palette  331  inside trailer  320  to minimize the unused space inside the trailer. For example, as shown in  FIG. 3D , a portion of cargo associated with smart palette  332  extends beyond the palette size of smart palette  332 . Computing system  103  can determine that unused space inside trailer  320  does not include the region occupied by the extended portion, and can position smart palette  331  based on the determined unused space such that palette  331  does not occupy the region associated with the extended portion. In particular, as shown in  FIG. 3E , if computing system  103  determines that a portion of cargo associated with smart palette  331  extends beyond the palette size of smart palette  331 , then computing system  103  can position smart palette  331  to minimize the unused space inside the trailer. 
       FIGS. 4A-4I  depict an example of repositioning a smart palette inside a trailer according to example embodiments of the present disclosure. As shown in  FIG. 4A , vehicle  410  can be assigned to transport a trailer that includes smart palettes  431 ,  432 ,  433 ,  434 , and  435 . Smart palette  431  can be positioned inside the trailer at position A, smart palette  432  at position B, smart palette  433  at position C, smart palette  434  at position D, smart palette  435  at position F, such that position E inside the trailer is unused space. 
     As a first example based on the palette positions shown in  FIG. 4A , if a palette computing system  103  associated with vehicle  410  determines a tire failure of a tire associated with a rear end of the trailer (e.g., during transit), then palette computing system  103  can provide load distribution data  142  to palette computing systems  103  associated with smart palettes  431 - 435  (e.g., to a palette computing system  103  associated with each of smart palettes  431 - 435 ) indicative of an optimal load distribution toward a front end of the trailer. As shown in  FIG. 4B  at time t 1 , in response to receiving the data indicative of the optimal load distribution, computing system  103  associated with smart palette  435  can reposition smart palette  435  from position F to position E inside the trailer to shift the load distribution toward the front end of the trailer. Alternatively, if palette data  137  includes data indicative of a cargo weight and computing systems  103  determine that a cargo weight associated with smart palette  433  is more than a cargo weight associated with smart palette  435 , then as shown in  FIG. 4C  at time t 1 , computing system  103  associated with smart palette  432  can reposition smart palette  432  from position B to position E, and computing system  103  associated with smart palette  433  can reposition smart palette  433  from position C to position B, to shift the load distribution toward the front end of the trailer. Alternatively, as shown in  FIG. 4D  at time t 1 , if computing systems  103  determine that a cargo weight associated with smart palette  432  is less than a cargo weight associated with smart palette  433  and  435 , then computing system  103  associated with smart palette  435  can reposition smart palette  435  from position F to position E, computing system  103  associated with smart palette  433  can reposition smart palette  433  from position C to position F, and computing system  103  associated with smart palette  432  can reposition smart palette  432  from position B to position C, to shift the load distribution toward the front end of the trailer. Alternatively, as shown in  FIG. 4E , if computing systems  103  determine that a cargo weight associated with smart palette  431  is less than a cargo weight associated with smart palettes  432 - 435 , then: at time t 1  smart palette  435  can be repositioned from position F to E, smart palette  433  can be repositioned from position C to F, smart palette  432  can be repositioned from position B to C, and smart palette  431  can be repositioned from position A to B; at time t 2  smart palette  435  can be repositioned from position E to D, smart palette  433  can be repositioned from position F to E, smart palette  432  can be repositioned from position C to F, and smart palette  431  can be repositioned from position B to C; and at time t 3  smart palette  433  can be repositioned from position E to B, and smart palette  432  can be repositioned from position F to E. In this way, computing systems  103  associated with smart palettes  431 - 435  can reposition smart palettes  431 - 435  based on a cargo weight associated with each of smart palettes  431 - 435  such that more weight is distributed toward a front end of trailer  320 . 
     As a second example based on the palette positions shown in  FIG. 4A , if a palette computing system  103  associated with vehicle  410  determines a tire failure (e.g., during transit) of a tire associated with a right side of the trailer, then palette computing system  103  can provide load distribution data  142  to palette computing systems  103  associated with smart palettes  431 - 435  (e.g., to a palette computing system  103  associated with each of smart palettes  431 - 435 ) indicative of an optimal load distribution toward a left side of the trailer. As shown in  FIG. 4F  at time t 1 , computing system  103  associated with smart palette  432  can reposition smart palette  432  from position B to position D inside the trailer to shift the load distribution toward the left side of the trailer. 
     As a third example based on the palette positions shown in  FIG. 4A , a destination distribution hub associated with cargo corresponding to smart palettes  433  and  435  can be distribution hub “X” (e.g., hub X), a destination distribution hub associated with cargo corresponding to smart palette  432  can be distribution hub “Y” (e.g., hub Y), and a transportation route associated with vehicle  410  can indicate that the trailer will arrive at hub X before hub Y. Accordingly, as shown in  FIG. 4A , smart palettes  433  and  435  can be positioned nearer to an exit of the trailer (e.g., towards a rear end of the trailer) so that smart palettes  433  and  435  can be immediately unload from the trailer when the trailer arrives at hub X. If a palette computing system  103  associated with vehicle  410  adjusts the transportation route (e.g., during transit) such that the trailer will arrive at hub Y before hub X, then the palette computing system  103  can provide transportation route data  142  to palette computing systems  103  associated with smart palettes  431 - 435  (e.g., to a palette computing system  103  associated with each of smart palettes  431 - 435 ) indicative of the change in the transportation route (e.g., the adjusted transportation route). As shown in  FIG. 4G  at time t 1 , in response to receiving the data indicative of the change in the transportation route, computing system  103  associated with smart palette  435  can reposition smart palette  435  from position F to position E, computing system  103  associated with smart palette  433  can reposition smart palette  433  from position C to position F, and computing system  103  associated with smart palette  432  can reposition smart palette  432  from position B to position C, such that smart palette  432  is nearer to the exit of the trailer so that smart palette  432  can be immediately unloaded from the trailer when the trailer arrives at hub Y. As shown in  FIG. 4H , if transportation route data  140  indicates that the trailer is being transported to hub X when the trailer departs hub Y, then at time t 2  (after computing system  103  associated with smart palette  432  unloads smart palette  432  at hub Y) computing system  103  associated with smart palette  433  can reposition smart palette  433  from position F to position C, and computing system  103  associated with smart palette  435  can reposition smart palette  435  from position E to position F, such that smart palettes  433  and  435  are nearer to the exit of the trailer so that smart palettes  433  and  435  can be immediately unloaded from the trailer when the trailer arrives at hub X. Alternatively, as shown in  FIG. 41 , if the transportation route data  140  indicates that the trailer is being transported to distribution hub “Z” (e.g., hub Z) when the trailer departs hub Y, and palette data  137  indicates that a destination distribution hub associated with cargo corresponding to smart palette  431  is hub Z, then at t 2  (after computing system  103  associated with smart palette  432  unloads smart palette  432  at hub Y) computing system  103  associated with smart palette  431  can reposition smart palette  431  from position A to position C, such that smart palette  431  is nearer to the exit of the trailer so that smart palette  431  can be immediately unloaded from the trailer when the trailer arrives at hub Z. In this way, computing systems  103  associated with smart palettes  431 - 435  can reposition smart palettes  431 - 435  based on a change in the transportation route associated vehicle  410  so that smart palettes with cargo that will unload sooner are positioned nearer to the exit of the trailer. 
       FIG. 5  depicts a flow diagram of an example method  500  for providing a vehicle-based service according to example embodiments of the present disclosure. One or more portion(s) of the method  500  can be implemented as operations by one or more computing system(s) such as computing system(s)  102 ,  103 ,  108 , and  610  shown in  FIGS. 1 and 6 . For example,  FIG. 5  illustrates certain operations being performed by specific computing systems described herein. However, it should be appreciated that such operations may generally be performed by any suitable computing system or combination of computing systems consistent with the disclosure provided herein. Moreover, one or more portion(s) of the method  500  can be implemented as an algorithm on the hardware components of the system(s) described herein (e.g., as in  FIGS. 1 and 6 ), for example, transport cargo from one location to another location.  FIG. 5  depicts elements performed in a particular order for purposes of illustration and discussion. Those of ordinary skill in the art, using the disclosures provided herein, will understand that the elements of method  500  discussed herein can be adapted, rearranged, expanded, omitted, combined, and/or modified in various ways without deviating from the scope of the present disclosure. 
       FIG. 5  depicts a flow diagram of method  500  for transporting cargo using a smart palette according to example embodiments of the present disclosure. 
     At ( 501 ), the method  500  includes determining receipt of a first cargo by a first smart palette. For example, a palette computing system  103  associated with a smart palette  30  can determine receipt of a first cargo onto a platform of a first smart palette  30  at a first distribution hub. 
     At ( 502 ), the method  500  includes loading the first smart palette and first cargo onto a trailer. For example, computing system  103  can generate one or more signals that control a loading of the first smart palette  30  and the first cargo onto a trailer  20  located at the first distribution hub. 
     At ( 503 ), the method  500  includes coordinating with one or more second smart palettes associated with the trailer to position the first smart palette inside the trailer. For example, computing system  103  can determine a coordination with one or more second smart palettes  30  associated with the trailer  20  to determine a first position inside the trailer  20  for the first smart palette  30  and the first cargo. Computing system  103  can generate one or more signals that position the first smart palette  30  and the first cargo at the first position inside the trailer  20 . Computing system  103  can obtain palette data  137  indicative of the one or more second smart palettes  30  that are associated with the trailer  20 , and communicate with the one or more second smart palettes  30  that are associated with the trailer  20  to determine the first position for the first smart palette  30 . 
     In some implementations, computing system  103  can determine the first position based at least in part on at least one of transportation route data  140  including a transportation route of autonomous vehicle  10  that is transporting the trailer  20 , load distribution data  142  including a load distribution of the first smart palette  30  and the one or more second smart palettes  30  inside the trailer  20 , or palette data  127  including one or more dimensions associated with the first cargo. 
     In some implementations, computing system  103  can obtain transportation route data  140  indicative of a transportation route associated with the trailer  20  (e.g., transportation route associated with the autonomous vehicle  10  transporting the trailer  20 ), palette data  137  indicative of one or more destination distribution hubs associated with the first smart palette  30  and the one or more second smart palettes  30 , load distribution data  142  indicative of a load distribution of the first smart palette  30  and the one or more second smart palettes  30  inside the trailer  20 , and palette data  137  indicative of one or more dimensions of cargo associated with the first smart palette  30  and the one or more second smart palettes  30 . Computing system  103  can determine the first position for the first smart palette based at least in part on the transportation route, the one or more destination distribution hubs, the load distribution, and the one or more dimensions of cargo. Computing system  103  can provide data indicative of the first position to at least one of the one or more second smart palettes  30  or a computing system associated with the trailer  20  (e.g., palette computing system  103  of the autonomous vehicle  10  hitched to the trailer  20 ). 
     In some implementations, computing system  103  can provide at least one of data indicative of one or more destination distribution hubs associated with the first cargo, or one or more dimensions of the first cargo, to a remote computing system associated with the one or more second smart palettes  30  (e.g., to a palette computing system  103  onboard the one or more second smart palettes  30  or an operations computing system  108  that is remote from the first smart palette  30  and the one or more second smart palettes  30 ). Computing system  103  can receive data indicative of the first position for the first smart palette from the remote computing system associated with the one or more second smart palettes  30  in response to providing at least one of the data indicative of the one or more destination distribution hubs associated with the first cargo or the one or more dimensions of the first cargo. 
     In some implementations, computing system  103  can generate one or more signals that move the first smart palette  30  and the first cargo to the first position inside the trailer  20 , and determine a coordination with at least one of the one or more second smart palettes  30  to move the at least one second smart palette  30  from an initial position associated with the second smart palette  30  inside the trailer  20  to a different position inside the trailer  20 . 
     In some implementations, the one or more second smart palettes  30  can include at least one second smart palette  30  that is previously positioned inside the trailer  20  when loading the first smart palette  30  onto the trailer  20 . 
     In some implementations, the one or more second smart palettes  30  can include at least one second smart palette  30  associated with the first distribution hub and loaded onto the trailer  20  at the first distribution hub after the first smart palette  30  is positioned inside the trailer  20 . 
     At ( 504 ), the method  500  includes repositioning the first smart palette inside the trailer during transit. For example, computing system  103  can obtain data indicative of at least one second smart palette  30  from the one or more second smart palettes  30  being onto the trailer  20 , being positioned inside the trailer  20 , or being repositioned inside the trailer  20 . Computing system  103  can determine a coordination with the at least one second smart palette  30  to determine a second position inside the trailer  20  for the first smart palette  30  and first cargo. Computing system  103  can generate one or more signals that move the first smart palette  30  and the first cargo from the first position to the second position. 
     In some implementations, computing system  103  can generate one or more signals that move the first smart palette  30  from the first position inside the trailer  20  to a second position inside the trailer  20  while the trailer  20  is in transit from a location at the first distribution hub to another location. 
     In some implementations, computing system  103  can obtain load distribution data  142  indicative of a change in load distribution of the first smart palette  30  and the one or more second smart palettes  30  inside the trailer  20 , and determine a coordination with the one or more second smart palettes  30  to determine the second position based at least in part on the change in the load distribution. The load distribution data  142  can be based at least in part on sensor data from one or more sensors  124  associated with at least one of the first smart palette  30 , the one or more second smart palettes  30 , or the trailer  20 . 
     In some implementations, computing system  103  can obtain transportation route data  140  indicative of a change in destination associated with the trailer  20  from an autonomous vehicle  10  that is transporting the trailer  20  from the location at the first distribution hub to the other location, and determine a coordination with the one or more second smart palettes  30  to determine the second position based at least in part on the change in destination. 
     At ( 505 ), the method  500  includes unloading the first smart palette and first cargo from the trailer. For example, computing system  103  can determine that the trailer  20  is at a second distribution hub that is a destination distribution hub of the first cargo, and generate one or more signals that move the first smart palette  30  and the first cargo from the trailer  20  to a second location within the second distribution hub when the second distribution hub is the destination distribution hub. 
       FIG. 6  depicts an example computing system  600  according to example embodiments of the present disclosure. The example system  600  illustrated in  FIG. 6  is provided as an example only. The components, systems, connections, and/or other aspects illustrated in  FIG. 6  are optional and are provided as examples of what is possible, but not required, to implement the present disclosure. The example system  600  can include palette computing system  103  of smart palette(s)  30  and, in some implementations, remote computing system(s)  610  including one or more remote computing system(s) that are remote from smart palette(s)  30  (e.g., palette computing system  103 , operations computing system  108 ) that can be communicatively coupled to one another over one or more networks  620 . The remote computing system  610  can be associated with a central operations system and/or an entity associated with the smart palette(s)  30  such as, for example, a fleet operator, service provider, etc. 
     The computing device(s)  601  of the palette computing system  103  can include processor(s)  602  and a memory  604 . The one or more processors  602  can be any suitable processing device (e.g., a processor core, a microprocessor, an ASIC, a FPGA, a controller, a microcontroller, etc.) and can be one processor or a plurality of processors that are operatively connected. The memory  604  can include one or more non-transitory computer-readable storage media, such as RAM, ROM, EEPROM, EPROM, one or more memory devices, flash memory devices, etc., and combinations thereof. 
     The memory  604  can store information that can be accessed by the one or more processors  602 . For instance, the memory  604  (e.g., one or more non-transitory computer-readable storage mediums, memory devices) on-board the smart palette(s)  30  can include computer-readable instructions  606  that can be executed by the one or more processors  602 . The instructions  606  can be software written in any suitable programming language or can be implemented in hardware. Additionally, or alternatively, the instructions  606  can be executed in logically and/or virtually separate threads on processor(s)  602 . 
     For example, the memory  604  on-board the smart palette(s)  30  can store instructions  606  that when executed by the one or more processors  602  on-board the smart palette(s)  30  cause the one or more processors  602  (the palette computing system  103 ) to perform operations such as any of the operations and functions of the palette computing system  103 , as described herein, one or more operations of method  500 , and/or any other operations and functions of the palette computing system  103 , as described herein. 
     The memory  604  can store data  608  that can be obtained, received, accessed, written, manipulated, created, and/or stored. The data  608  can include, for instance, data associated with perception, prediction, motion plan, maps, cargo, palettes, transportation route, load distribution, trailer location, and/or other data/information as described herein. In some implementations, the computing device(s)  601  can obtain data from one or more memory device(s) that are remote from the smart palette(s)  30 . 
     The computing device(s)  601  can also include a communication interface  603  used to communicate with one or more other system(s) on-board the smart palette(s)  30  and/or a remote computing device that is remote from the smart palette(s)  30  (e.g., of remote computing system(s)  610 ). The communication interface  603  can include any circuits, components, software, etc. for communicating via one or more networks (e.g.,  620 ). In some implementations, the communication interface  603  can include, for example, one or more of a communications controller, receiver, transceiver, transmitter, port, conductors, software, and/or hardware for communicating data. 
     The network(s)  620  can be any type of network or combination of networks that allows for communication between devices. In some embodiments, the network(s) can include one or more of a local area network, wide area network, the Internet, secure network, cellular network, mesh network, peer-to-peer communication link, and/or some combination thereof, and can include any number of wired or wireless links. Communication over the network(s)  620  can be accomplished, for instance, via a communication interface using any type of protocol, protection scheme, encoding, format, packaging, etc. 
     The remote computing system  610  can include one or more remote computing devices that are remote from the palette computing system  103 . The remote computing devices can include components (e.g., processor(s), memory, instructions, data) similar to that described herein for the computing device(s)  601 . Moreover, the remote computing system(s)  610  can be configured to perform one or more operations of the palette computing system  103 , as described herein. Moreover, the computing systems of other smart palette(s)  30  described herein can include components similar to that of palette computing system  103 . 
     Computing tasks discussed herein as being performed at computing device(s) remote from the vehicle can instead be performed at the vehicle (e.g., via the vehicle computing system), or vice versa. Such configurations can be implemented without deviating from the scope of the present disclosure. The use of computer-based systems allows for a great variety of possible configurations, combinations, and divisions of tasks and functionality between and among components. Computer-implemented operations can be performed on a single component or across multiple components. Computer-implemented tasks and/or operations can be performed sequentially or in parallel. Data and instructions can be stored in a single memory device or across multiple memory devices. 
     While the present subject matter has been described in detail with respect to specific example embodiments and methods thereof, it will be appreciated that those skilled in the art, upon attaining an understanding of the foregoing can readily produce alterations to, variations of, and equivalents to such embodiments. Accordingly, the scope of the present disclosure is by way of example rather than by way of limitation, and the subject disclosure does not preclude inclusion of such modifications, variations and/or additions to the present subject matter as would be readily apparent to one of ordinary skill in the art.