Abstract: Systems, methods, and computer-readable media for providing a signaling location beacon are provided. Specifically, a collection location for collecting, by an agent, an item is determined. Also, a physical beacon associated with the pickup location can be identified. Further, an interaction between the physical beacon and the agent can be detected. For example, the interaction can occur based on the physical beacon and the agent being in physical proximity to each other during a process of the agent collecting the item at the collection location. As follows, in response to the interaction, transmission of a sensory signal to the agent can be facilitated to provide perceivable direction information associated with the physical location to the agent. The sensory signal can be specific to the agent based on the interaction between the physical beacon and the agent.

Abstract: Systems, methods, and computer-readable media for providing a signaling location beacon are provided. Specifically, a collection location for collecting, by an agent, an item is determined. Also, a physical beacon associated with the pickup location can be identified. Further, an interaction between the physical beacon and the agent can be detected. For example, the interaction can occur based on the physical beacon and the agent being in physical proximity to each other during a process of the agent collecting the item at the collection location. As follows, in response to the interaction, transmission of a sensory signal to the agent can be facilitated to provide perceivable direction information associated with the physical location to the agent. The sensory signal can be specific to the agent based on the interaction between the physical beacon and the agent.

Abstract: Systems, methods, and computer-readable media for providing a signaling location beacon are provided. Specifically, a physical location for transferring a delivery from a delivery person to a customer can be determined. Also, a physical beacon associated with the physical location can be identified. Further, an interaction between the physical beacon and the delivery person can be detected. For example, the interaction can occur based on the physical beacon and the delivery person being in physical proximity to each other. As follows, in response to the interaction, transmission of a sensory signal to the delivery person can be facilitated to provide perceivable direction information associated with the physical location to the delivery person.

Abstract: Described herein are various systems and processes for vehicles for delivery of real-time, on-demand orders for perishable goods, and operations thereof. The automated delivery vehicle may include a food transport container and various sensors configured to determine the location and/or surroundings of the vehicle. The automated delivery vehicle may further include a display and/or other output source configured to provide outputs to persons surrounding the automated delivery vehicle. Such outputs may include, for example, an information graphical representation (e.g., provided on a display), an audio output, and/or data communicated to a wireless device.

Abstract: Described herein are various systems and processes for vehicles for delivery of real-time, on-demand orders for perishable goods, and operations thereof. The vehicles may each include a plurality of different modules that couple to a chassis. The modules may include battery modules, drive modules, cargo modules, and other modules. Each drive module may include wheels and motors and steering mechanisms that control the wheels. A plurality of such modules may be disposed on the chassis. The modules may be disposed on different portions of the chassis and be given different operational commands accordingly. Furthermore, operation of the vehicle may be adjusted based on the cargo carried by the vehicle.

Abstract: Described herein are various systems and processes for vehicles for delivery of real-time, on-demand orders for perishable goods, and operations thereof. The vehicles may each include a plurality of different modules that couple to a chassis. The modules may include battery modules, drive modules, cargo modules, and other modules. Each drive module may include wheels and motors and steering mechanisms that control the wheels. A plurality of such modules may be disposed on the chassis. The modules may be disposed on different portions of the chassis and be given different operational commands accordingly. Furthermore, operation of the vehicle may be adjusted based on the cargo carried by the vehicle.

Abstract: Described herein are various systems and processes for vehicles for delivery of real-time, on-demand orders for perishable goods, and operations thereof. The automated delivery vehicle may include a food transport container and various sensors configured to determine the location and/or surroundings of the vehicle. The automated delivery vehicle may further include a display and/or other output source configured to provide outputs to persons surrounding the automated delivery vehicle. Such outputs may include, for example, an information graphical representation (e.g., provided on a display), an audio output, and/or data communicated to a wireless device.

Abstract: Systems, methods, and computer-readable media for providing a signaling location beacon are provided. Specifically, a collection location for collecting, by an agent, an item is determined. Also, a physical beacon associated with the pickup location can be identified. Further, an interaction between the physical beacon and the agent can be detected. For example, the interaction can occur based on the physical beacon and the agent being in physical proximity to each other during a process of the agent collecting the item at the collection location. As follows, in response to the interaction, transmission of a sensory signal to the agent can be facilitated to provide perceivable direction information associated with the physical location to the agent. The sensory signal can be specific to the agent based on the interaction between the physical beacon and the agent.

Abstract: Systems, methods, and computer-readable media for providing a signaling location beacon are provided. Specifically, a physical location for transferring a delivery from a delivery person to a customer can be determined. Also, a physical beacon associated with the physical location can be identified. Further, an interaction between the physical beacon and the delivery person can be detected. For example, the interaction can occur based on the physical beacon and the delivery person being in physical proximity to each other. As follows, in response to the interaction, transmission of a sensory signal to the delivery person can be facilitated to provide perceivable direction information associated with the physical location to the delivery person.

Abstract: Described herein are various systems and processes for vehicles for delivery of real-time, on-demand orders for perishable goods, and operations thereof. The vehicles may each include a plurality of different modules that couple to a chassis. The modules may include battery modules, drive modules, cargo modules, and other modules. Each drive module may include wheels and motors and steering mechanisms that control the wheels. A plurality of such modules may be disposed on the chassis. The modules may be disposed on different portions of the chassis and be given different operational commands accordingly. Furthermore, operation of the vehicle may be adjusted based on the cargo carried by the vehicle.

Abstract: Systems and methods for dynamic resistance training are provided that include the use of a dynamic force module. The dynamic force module includes an actuator and controller adapted to control the actuator according to a force profile that specifies the relationship between an operational parameter of the actuator and a measured parameter associated with a user performing an exercise. The dynamic force module is also capable of communicating with a broader network system to facilitate storing and distribution of force profiles and user profile information. The network system further includes features for, among other things, generating and managing force profiles, uploading multimedia content, and tracking user progress.

Abstract: Described herein are various systems and processes for vehicles for delivery of real-time, on-demand orders for perishable goods, and operations thereof. The automated delivery vehicle may include a food transport container and various sensors configured to determine the location and/or surroundings of the vehicle. The automated delivery vehicle may further include a display and/or other output source configured to provide outputs to persons surrounding the automated delivery vehicle. Such outputs may include, for example, an information graphical representation (e.g., provided on a display), an audio output, and/or data communicated to a wireless device.

Abstract: Systems and methods for dynamic resistance training are provided that include the use of a dynamic force module. The dynamic force module includes an actuator and controller adapted to control the actuator according to a force profile that specifies the relationship between an operational parameter of the actuator and a measured parameter associated with a user performing an exercise. The dynamic force module is also capable of communicating with a broader network system to facilitate storing and distribution of force profiles and user profile information. The network system further includes features for, among other things, generating and managing force profiles, uploading multimedia content, and tracking user progress.

Abstract: Systems and methods are disclosed for selecting and orienting a computing device mounted on a robotic stand for videoconferences. For example, a method for operating a robotic stand supporting a computing device is disclosed, which includes displaying, by a display of a remote device, a control interface depicting a physical location that includes a plurality of robotic stands with respective computing devices. The method further includes providing, responsive to a user of the remote device interacting with the control interface, a selection instruction selecting a region of the physical location for viewing with one of the plurality of robotic stands with respective computing devices, and generating, by the control interface, a positioning instruction based on the selected region of the physical location, the positioning instruction configured to orient the robotic stand including the computing device determined to be available to face the region of the physical location.

Abstract: Systems and methods are disclosed for selecting and orienting a computing device mounted on a robotic stand for videoconferences. For example, a method for operating a robotic stand supporting a computing device is disclosed, which includes displaying, by a display of a remote device, a control interface depicting a physical location that includes a plurality of robotic stands with respective computing devices. The method further includes providing, responsive to a user of the remote device interacting with the control interface, a selection instruction selecting a region of the physical location for viewing with one of the plurality of robotic stands with respective computing devices, and generating, by the control interface, a positioning instruction based on the selected region of the physical location, the positioning instruction configured to orient the robotic stand including the computing device determined to be available to face the region of the physical location.

Abstract: A method for fabricating electroactive polymer transducers, the includes providing an electroactive polymer film comprising an elastomeric dielectric polymer, forming an array of electrodes on the film, and sandwiching the electrode array between a top and bottom array of frame components to form an array of electroactive polymer transducers.

Abstract: The present invention includes fluid control systems employing compliant electroactive materials.