A modular auxiliary power module is described for a modular autonomous bot apparatus that transports an item being shipped. The modular auxiliary power module includes a base adapter platform, a cargo door, an auxiliary power source, and an output power outlet disposed on the base adapter platform as part of a modular component electronics interface. A top side of the base adapter platform has a cargo support area configured to support the item being shipped. Interlocking alignment interfaces (such as channels or latches) are on the top and bottom of the platform. The cargo door is movably attached to and extending from an edge of the base adapter platform, and the output power outlet is coupled to the auxiliary power source and provides access to power for other components of the modular autonomous bot apparatus from the auxiliary power source.

A modular cargo storage system (CSS) is described for use on a base platform of a modular autonomous bot apparatus that transports an item being shipped. The modular CSS includes a set of folding structural walls, an interlocking alignment interface on at least one of the walls, and a modular component power and data transport bus. The walls at least partially enclose a payload area above the base platform. The interlocking alignment interface has a set of latches and a locking handle coupled to the set of latches that actuates the latches to interlock with the base platform. The power and data transport bus have top and bottom side modular component electronics interfaces where each interface has a power conduit outlet and a command and data communication interface.

A modular autonomous cart assembly for transporting an item being shipped is described with a sensor-equipped mobility base that carries the item(s), a modular cart handle, a sensor-equipped modular mobile cart autonomy control module detachably attached to the modular handle, all sharing a modular common power and data transport bus. The autonomous controller of the modular control module is programmatically adapted operative to establish a secure connection to a wireless mobile courier node, locate the courier node and the cart assembly, receive sensor data from the base and control module sensors, generate steering and propulsion control commands using the locations and sensor data and send them to a controller on the mobility base so that the assembly can autonomously track and follow the current location of the courier node as the courier node moves and while maintaining a predetermined follow distance from the current location of the courier node.

A modular autonomous bot apparatus assembly is described for transporting an item being shipped. The assembly includes a modular mobility base having propulsion, steering, sensors for collision avoidance, and suspension actuators; a modular auxiliary power module with a power source and cargo door; a modular cargo storage system with folding structural walls and a latching system; and a modular mobile autonomy module that covers the cargo storage system and provides human interaction interfaces, externals sensors, a wireless interface, and an autonomous controller with interfacing circuitry coupled to the human interaction interfaces and sensors on the mobile autonomy module. The assembly has a power and data transport bus that provides a communication and power conduit across the different modular components. A method for on-demand assembly of such a bot apparatus is further described with steps for authenticating the different modular components during assembly.

Methods and systems are described that use multiple node-enabled autonomous transport vehicles on a single logistics operation having multiple legs performed by different transport vehicles with enhanced transfer of the item being shipped between such vehicles. A first or primary master node on a first node-enabled autonomous transport vehicle detects a signal from the second master node on a second transport vehicle, navigates to the second transport vehicle based on the detected signal and its direction, and may dock in a transfer configuration. At least one item (or a container with an item) is transferred as payload from the first to the second vehicle using one or more object manipulation systems on respective ones of the first and second transport vehicles. The second vehicle then detects a signal from another node, and navigates to that node as another leg in the multi-leg operation.

A modular multiple mobility base assembly apparatus is described for transporting an item being shipped having a base adapter plate and two cooperating and coordinating modular mobility bases that are each coupled to the bottom of the base adapter plate and collectively support the base adapter plate. One of the modular mobility bases operations a master autonomous mobile vehicle, while the other operates as a slave autonomous mobile vehicle that receives propulsion and steering control signals from the master while providing feedback sensor data to the master for use in coordinated and cooperative movement of the assembly apparatus. Each of the modular mobility bases also including respective wireless transceivers through which at least the control signals and sensor data are provided between mobility base units.

Methods are described that perform dispatched store-to-consumer logistics operations for an ordered item using a modular autonomous bot apparatus assembly and a dispatch server. A dispatch command is received from the dispatch server. The different modular components of the bot assembly are verified to be compatible with the dispatched operation and the ordered item is received in a payload area of a modular cargo storage system. The bot assembly autonomously moves from an origin location to a destination location and notifies the delivery recipient of the approach delivery. When delivery recipient authentication input is received that correlates to the authentication information, selective access is provided to the ordered item within the cargo storage system at the destination location. The bot apparatus monitors unloading, and autonomously moves back to the origin location after the ordered item is detected as removed from the cargo storage system.

A modular structure for being at least partly submerged in a body of water, is disclosed. The modular structure comprises structure elements and strengthening elements providing structural integrity and flexibility, and can typically be a closed structure like e.g. a tank structure. Further, macro structures comprising attached modular structures are presented. Finally, methods for construction of such structures are disclosed.

Methods of performing a dispatched logistics operation for delivery/pickup of items using a modular autonomous bot apparatus assembly (with a modular autonomy module, cargo storage system, auxiliary power module, and mobility base) and a dispatch server. The modular autonomy control module receives a dispatch command from the dispatch server and authenticates that each of the modular components in the assembly are compatible with the particular dispatched logistics operation. The bot assembly receives the transported item, autonomously moves from an origin location to a destination per the dispatch command using the mobility base autonomously controlled by the modular autonomy control module, receives authentication input that at least correlates to authentication information in the dispatch comment to allow selective access to the modular cargo storage system of the bot assembly, and then autonomously returns to the origin after the item is detected removed from the cargo storage system.

Methods perform one or more dispatched medical logistics operations using a modular autonomous bot apparatus assembly and a dispatch server where the operations are related to a diagnosis kit for treating a patient. The MAM of the bot receives a dispatch command, verifies compatibility of the bot assembly with the dispatched operation(s), receives a diagnosis kit in the CSS, has the MAM autonomously causing the MB to move to a destination location while notifying the authorized delivery recipient for the diagnosis kit of the approaching delivery. With appropriate authentication input received, the MAM coordinates with the CSS to provide access to the kit, monitor unloading of the kit, provide instructional information on use of the kit, and autonomously cause the MB to return to the original location with a return item related to the diagnosis kit with notification to personnel at the medical entity about the return item.