Abstract: In some embodiments, systems, apparatuses and methods are provided herein that enable delivery of retail products. Some embodiments provide delivery systems comprising: a package support frame comprising first and second package supports, and a pivot coupler pivotably securing the first package support with the second package support; and a first release plate positioned across a separation between the first and second package supports, and comprising: a set of at least one angled locking grooves; a set of at least one groove pins slidably positioned within a respective one of the locking grooves; and a release tab configured to contact a surface and cause an unlocking of the first release plate such that the release plate moves with the locking grooves sliding along respective groove pins such that the base of the package support pivots away from the base of the second package support enlarging a package release aperture.

Abstract: In some embodiments, systems, apparatuses and methods are provided herein that enable delivery of retail products. Some embodiments provide retail product delivery transport packages, comprising: a base; a first set of tapered walls comprising at least two side walls that are separated by a length of the base and extend from the base at an angle such that a distance between the first tapered wall and the second tapered wall at the opening is greater than a distance between the first tapered wall and the second tapered wall at the base, and wherein the first and second tapered walls are configured to frictionally engage first and second tapered package support walls, respectively, of a delivery package carrier system; and a second set of at least one wall comprising at least a first vertical wall.

Abstract: Systems, apparatuses, and methods are provided herein for providing audio notification. A system for providing audio notification comprises a communication device configured to communicate with a delivery arrival detection system, a doorbell coupler configured to couple to a stationary doorbell device, and a control circuit coupled to the communication device and the doorbell coupler. The control circuit being configured to receive a delivery notification from the delivery arrival detection system via the communication device and cause the stationary doorbell device to produce an audible sound via the doorbell coupler.

Abstract: Methods and apparatuses are provided, some apparatuses comprise: a location controller separate from a motorized transport unit, comprising: a transceiver configured to receive communications from the motorized transport unit; a control circuit; a memory storing computer instructions that when executed by the control circuit cause the control circuit to perform the steps of: obtain, from the communications, a unique light source identifier of a light source detected by the motorized transport unit, and relative distance information determined by the motorized transport unit through an optical measurement; process the at least one unique light source identifier and the relative distance information relative to a mapping of the shopping facility; and determine, in response to the processing, a location of the motorized transport unit within the shopping facility as a function of the at least one unique light source identifier and the relative distance information.

Abstract: Systems, apparatuses, and methods are provided herein for unmanned aerial vehicle (UAV) control. A system for UAV control comprises a flight control system of a UAV, an image sensor on the UAV, an aircraft marshaling signal database, and a control circuit coupled to the flight control system, the image sensor, and the aircraft marshaling signal database. The control circuit being configured to: detect, with the image sensor, a gesture from a ground crew member, verify that the ground crew member is an authorized controller of the UAV, compare the gesture with marshaling signals in the aircraft marshaling signal database to determine a corresponding marshaling signal, determine a flight command based on the corresponding marshaling signal, and execute the flight command with the flight control system of the UAV.

Abstract: Described in detail herein are systems and methods for tracking clusters of user devices within a facility. In exemplary embodiments, a plurality of network devices are distributed within a facility. The network devices may receive connection data indicating probing by at least one of a plurality of user devices within the facility. A processing unit may be coupled to the network devices and the processing unit may extract location data from the connection data received by the network devices. The location data may indicate the location of the user devices with respect in the facility. The processing unit may determine a projected path for the plurality of user devices based on the location data. The processing unit may generate a response based on then projected path of the plurality of user device.

Abstract: In some embodiments, apparatuses and methods are provided herein useful for receiving and storing delivered items. In some embodiments, a secured delivery locker is described herein that can communicate with delivery vehicles and/or users. In several embodiments, an autonomous delivery vehicle can communicate with a secured delivery locker to authenticate itself. The secured delivery locker can then grant access to the delivery vehicle, such as by opening a door to an interior thereof, so that the delivery vehicle can deposit a package therein. The locker can then confirm receipt of the package and close the door. Thereafter, the locker and/or the delivery vehicle can update a system to indicate that the package was delivered.

Abstract: Some embodiments include apparatuses to fulfill customer orders comprising a motorized transport unit; a product pick unit (PPU) that cooperate with the motorized transport unit; a wireless communication network; and a central computer system configured to communicate with the multiple motorized transport units and the plurality of product pick units, and comprises a control circuit and memory storing instructions executed to cause the control circuit to: communicate an instruction to the motorized transport unit and direct the motorized transport unit to transport the product pick unit to a determined first location within the shopping facility proximate to where a first product having been ordered is located; and communicate an instruction to the product pick unit cooperated with the motorized transport unit and direct the product pick unit to retrieve the first product.

Abstract: An additive manufacturing method includes receiving an identification of a particular additive manufacturing model from a user along with a plurality of espoused manufacturing preferences. These teachings provide for automatically selecting a particular additive manufacturing platform from amongst a plurality of available additive manufacturing platforms as a function, at least in part, of the plurality of manufacturing preferences. The selected additive manufacturing platform is then used to manufacture an item based upon the particular additive manufacturing model identified by the user.

Abstract: In some embodiments, unmanned aerial task systems are provided that comprise multiple unmanned aerial vehicles (UAV) each comprising: a UAV control circuit; a motor; and a propulsion system coupled with the motor and configured to enable the respective UAVs to move themselves; and wherein a first UAV control circuit of a first UAV of the multiple UAVs is configured to access power level data corresponding to each of the multiple UAVs, and select a second UAV of the multiple UAVs based at least in part on a power level of the second UAV relative to a threshold power level corresponding to a first task to be performed and a predicted power usage by the second UAV while utilizing a first tool system temporarily cooperated with the second UAV in performing the first task.

Abstract: Systems, apparatuses, and methods are provided herein for field monitoring. A system for field monitoring comprises a plurality of types of sensor modules, an unmanned vehicle comprising a sensor system, and a control circuit configured to: receive onboard sensor data from the sensor system of the unmanned vehicle, detect an alert condition at a monitored area based on the onboard sensor data, select one or more types of sensor modules from the plurality of types of sensor modules to deploy at the monitored area based on the onboard sensor data, and cause the unmanned vehicle and/or one or more other unmanned vehicles to transport one or more sensor modules of the one or more types of sensor modules to the monitored area and deploy the one or more sensor modules by detaching from the one or more sensor modules at the monitored area.

Abstract: In some embodiments, unmanned aerial task systems are provided that include a first unmanned aerial vehicle (UAV) comprising: a UAV control circuit; a motor; and a propulsion system coupled with the motor and configured to enable the first UAV to move itself; and wherein the UAV control circuit when implementing code stored in memory is configured to identify, based at least in part on a first task performed using a first tool system temporarily coupled with the first UAV, a second task to be performed by the first UAV and to identify a different second tool system to be used to perform the second task.

Abstract: In some embodiments, unmanned aerial task systems are provided that comprise: multiple unmanned aerial vehicles (UAV) each comprising: a UAV control circuit; a motor; and a propulsion system; and wherein data acquired through a first set of at least one of the multiple UAVs while performing a first set of at least one task is caused to be distributed to a second set of at least two of the multiple UAVs, and cause cooperative computational processing of the data through the UAV control circuits of the second set of UAVs and cooperatively identify based on the cooperative computational processing a second set of at least one task to be performed, and identify a set of at least two tool systems to be utilized by a third set of at least two of the multiple UAVs in cooperatively performing the second set of at least one task.

Abstract: In some embodiments, unmanned aerial task systems are provided that comprise: multiple unmanned aerial vehicles (UAV) each comprising: a UAV control circuit; a motor; and a propulsion system coupled with the motor and configured to enable UAV to move itself; and wherein a first UAV control circuit of a first UAV of the multiple UAVs, when implementing code stored in memory, is configured to identify, based at least in part on a first task performed using a first tool system temporarily coupled with the first UAV, a set of at least one task to be cooperatively performed by the first UAV and at least a second UAV of the multiple UAVs.

Abstract: In some embodiments, unmanned aerial task systems are provided that include a plurality of unmanned aerial vehicles (UAV) each comprising: a UAV control circuit; a motor; propulsion system; and a universal coupler configured to interchangeably couple with and decouple from one of multiple different tool systems each having different functions to be put into use while carried by a UAV, wherein a coupling system of the universal coupler is configured to secure a tool system with the UAV and enable a communication connection between a communication bus and the tool system, and wherein the multiple different tool systems comprise at least a package securing tool system configured to retain and enable transport of a package while being delivered, and a sensor tool system configured to sense a condition and communicate sensor data of the sensed condition to the UAV control circuit over the communication bus.

Abstract: Some embodiments provide an aerial monitoring system to monitor a geographic area, comprising: a unmanned aerial vehicle (UAV) comprising: a plurality of lift motors to drive a propeller; a substructural support supporting the lift motors and propellers; a UAV control circuit configured to control the operation of the lift motors; a rechargeable electrical power source that supplies electrical power to the UAV control circuit and the plurality of lift motors; a recharge control circuit; and a modifiable support system cooperated with the substructural support and supporting a set of photovoltaic cells electrically coupled with the rechargeable power source and configured to supply electrical power to the rechargeable power source, wherein the recharge control circuit is configured to control a modification of the modifiable support system to cause a physical modification of at least an orientation of the modifiable support system relative to the substructural support.

Abstract: In some embodiments, unmanned aerial task systems are provided that comprise multiple unmanned aerial vehicles (UAV) each comprising: a UAV control circuit; a motor; and a propulsion system coupled with the motor and configured to enable the respective UAVs to move themselves; and wherein a first UAV control circuit of a first UAV of the multiple UAVs is configured to identify a second UAV carrying a first tool system configured to perform a first function, cause a notification to be communicated to the second UAV directing the second UAV to transfer the first tool system to the first UAV, and direct a first propulsion system of the first UAV to couple with the first tool system being transferred from the second UAV.

Abstract: A system for securely and automatically opening an entrance to a building to receive a delivered package is described. A customer interacts with an e-commerce system to purchase a product online. The system has a delivery company deliver the product and the package to the building identified by the customer. The package has an identification device attached to it that carries unique information received from the e-commerce system. The building has a smart doorbell which can read package information from the identification device. The smart doorbell is connected to a system controller which communicates with and receives package information from the e-commerce system. If they match, the system controller opens an automated lock opening an entrance of the building to receive the package. A video camera provides images of the delivery person entering the building and leaving the package, for security.

Abstract: Some embodiments include apparatuses to fulfill customer orders comprising a motorized transport unit; a product pick unit (PPU) that cooperate with the motorized transport unit; a wireless communication network; and a central computer system configured to communicate with the multiple motorized transport units and the plurality of product pick units, and comprises a control circuit and memory storing instructions executed to cause the control circuit to: communicate an instruction to the motorized transport unit and direct the motorized transport unit to transport the product pick unit to a determined first location within the shopping facility proximate to where a first product having been ordered is located; and communicate an instruction to the product pick unit cooperated with the motorized transport unit and direct the product pick unit to retrieve the first product.

Abstract: Some embodiments provide apparatuses and methods useful to providing control over movement of motorized transport units. In some embodiments, an apparatus providing control over movement of motorized transport units at a shopping facility comprises: a central computer system comprising: a transceiver; a control circuit; a memory coupled to the control circuit and storing computer instructions that when executed by the control circuit cause the control circuit to perform the steps of: obtain, from one or more of the communications received from the motorized transport unit, route condition information comprising information corresponding to an intended route of travel; obtain additional route condition information detected by one or more detectors external to the motorized transport unit; detect an object affecting the intended route of travel; identify an action to be taken by the motorized transport unit with respect to the detected object; and communicate one or more instructions.