A robotic cart platform with a navigation and movement system that integrates into a conventional utility cart to provide both manual and autonomous modes of operation. The platform includes drive wheels replacing the front wheels of the cart. The platform and system include motors, encoders, an IMU, a processor and a microcontroller. The system has a work environment mapping sensor and a cabled array of digital cameras, proximity or radar sessors, as well as weight sensors, lights, a 15 key control panel secured throughout the cart. When in autonomous mode, the system provides navigation, movement and location tracking with or without wireless connection to a server. Destination keys allow autonomous navigation to desired destinations. Looping, boomerang and home keys facilitate autonomous navigation for a variety working environments and situations. The radar sensors provide enhanced obstacle avoidance, cart localizing, route planning and human interaction capabilities.

An active detection self-propelled artificial intelligence surgery navigation cart applied in medical institutes includes a cart body, a control unit, a signal transmission unit, a detection unit, a robotic arm and/or an optical navigation host. The cart can travel to a designated place or follow a counterpart (based on a stored map path) according to a predetermined schedule or an inputted instruction, or the cart can be controlled by an external remote control system or a counterpart to be followed, so as to achieve the effect of reducing the burden of medical staff while they are walking around, so that the medical staff can concentrate on the care of patients or improve the quality of surgical operations.

Methods and apparatuses are provided for use in monitoring product placement within a shopping facility. Some embodiments provide an apparatus configured to determine product placement conditions within a shopping facility, comprising: a transceiver configured to wirelessly receive communications; a product monitoring control circuit coupled with the transceiver; a memory coupled with the control circuit and storing computer instructions that when executed by the control circuit cause the control circuit to: obtain a composite three-dimensional (3D) scan mapping corresponding to at least a select area of the shopping facility and based on a series of 3D scan data; evaluate the 3D scan mapping to identify multiple product depth distances; and identify, from the evaluation of the 3D scan mapping, when one or more of the multiple product depth distances is greater than a predefined depth distance threshold from the reference offset distance of the product support structure.

A self-propelled cart comprising: a body having a generally rectangular prism shape with a top, bottom, front end, rear end, and two sides, the body further comprising: a battery compartment, and a utility platform comprising a plurality of connecting features for releasable attachment of one or more components to the platform; a rechargeable battery housed in the battery compartment; a controller; four arms having a first end and a second end, each pivotally attached at the first end to the body; four wheels, each connected to the second end of one of the four arms; four arm actuators, each configured to pivot one of the four arms such that each wheel can be moved closer to or further away from the body; and at least two motors powered by the battery, each configured to rotate one of the four wheels, each independently controlled by the controller, whereby the controller can move the cart and control the yaw of the cart by rotating one or more of the four wheels; at least one sensor for determining the pitch of the cart in communication with the controller, whereby the controller is able to adjust the height of the cart and the pitch of the cart by pivoting one or more of the four arm actuators is disclosed.

A cargo carrier for mounting on a mobile cart, comprising: a base configured to be releasably attached to a top surface of the mobile cart; first and second opposing side walls, each having a bottom edge attached to the base, a top edge, a front side edge running from the bottom edge to the top edge and a rear side edge running from the bottom edge to the top edge; a front end wall, having a bottom edge hingedly connected to the base so as to hinge between a closed position and an open position, wherein in the closed position, a first front end wall side edge fits against the front side edge of the first side wall, and a second front end wall side edge fits again the front side edge of the second side wall, to thereby close a front end of the cargo carrier; and in the open position, the front end wall is generally parallel to the base, to thereby open a front end of the cargo carrier; a front end wall lock for releasably locking the front end wall in the closed position; a rear end wall, having a bottom edge hingedly connected to the base so as to hinge between a closed position and an open position, wherein: in the closed position, a first rear end wall side edge fits against the rear side edge of the first side wall, and a second rear end wall side edge fits again the rear side edge of the second side wall, to thereby close a rear end of the cargo carrier; and in the open position, the rear end wall is generally parallel to the base, to thereby open a rear end of the cargo carrier; a rear end wall lock for releasably locking the rear end wall in the closed position; whereby the cargo carrier can be converted between a four-walled bin, for containing objects within its four walls, to an open ended cargo carrier, allowing elongated objects in the cargo carrier to extend beyond the front end wall and/or the rear end wall by hingedly moving the front end wall and/or the rear end wall, respectively, between the closed and open positions is disclosed.

A system for mounting a stowed component on a self-propelled cart, comprising: the self-propelled cart comprising: a body having a top, bottom, front end, rear end, left side, and right side, and further comprising: a battery compartment, and a platform; a battery housed in the battery compartment; a controller; four arms, each pivotably attached at a first end to the body; four wheels, each connected to a second end of one of the four arms; four arm actuators, each configured to pivot one of the four arms such that each wheel can be moved closer to or further away from the body; and at least two motors, each configured to rotate one wheel and each independently controlled by the controller, whereby the controller can move the cart; at least one sensor for determining the position of the component to be mounted on the cart; wherein the controller can adjust the height of the cart by pivoting one or more of the four arm actuators and control the yaw of the cart by rotating one or more of the wheels; and wherein the cart is configured to approach a location of a component and adjust its orientation to compliment an orientation of the component to thereby facilitate mounting of the component on the cart is disclosed.

A self-docking, motorized cart, comprising: a body comprising a battery compartment and a platform; a battery housed in the battery compartment; a cart docking attachment arm; a controller; four arms, each pivotably attached at a first end to the body; four wheels, each connected to a second end of one of the four arms; four arm actuators, each configured to pivot one of the four arms such that each wheel can be moved closer to or further away from the body; wherein the controller adjusts the height of the cart by pivoting one or more of the four arms; and at least two motors, each configured to rotate one of the four wheels, each independently controlled by the controller, whereby the controller can move the cart and control the yaw of the cart by rotating one or more of the four wheels; whereby the cart can be moved into an appropriate position and orientation for connecting the docking arm attachment to a docking station by the controller selectively pivoting the arms and rotating the wheels; and wherein the docking attachment arm comprises connections for electricity or data is disclosed.

A crane for lifting and transporting loads includes a handling element, for supporting and handling the loads, and a chassis for transferring the loads of the crane onto a support surface by a contact arranged in contact with the surface, such as wheels. A drive transmission, such as a drive wheel, moves the crane on the support surface. The drive transmission is capable of translating relative to the chassis to adjust the force exerted by the drive transmission upon the support surface. The crane includes a sensor for detecting the force exerted by the drive transmission upon the support surface; and a control unit configured for adjusting the position of the drive transmission relative to the chassis, based on the detection of the sensor.

A motorized cart assembly includes a cart that has a basket, a collapsible frame and a plurality of wheels. The basket has a height that is greater than a width of the basket to accommodate tent poles and a tent. The frame includes a pole support for insertably receiving a respective one of the tent poles to vertically orient the respective tent pole. A drive unit is coupled to the cart and the drive unit is in mechanical communication with respective ones of the wheels. The drive unit rotates the respective wheels when the drive unit is turned on thereby facilitating the cart to be self propelled. The drive unit is in wireless communication with a personal electronic device for remotely controlling the drive unit.

Systems, apparatuses, and methods for determining item availability are provided. A computer implemented method for determining item availability in a shopping space comprising: receiving a request for an item for purchase from a customer, querying an inventory database to determine whether the item for purchase is in stock, in an event that the item for purchase is not in stock according to the inventory database: determining an out of stock response to present to the customer, in an event that the item for purchase is in stock according the inventory database: instructing a motorized transport unit to travel to a display space in the shopping space corresponding to the item for the purchase, determining whether the item is available in the display space based on information captured by one or more sensors of the motorized transport unit, and in an event that the item for purchase is not available in the display space: determining an item unavailable response to present to the customer.