Abstract: A system for remote tactile telepresence wherein an array of predefined touch gestures are abstracted into cataloged values and invoked either by pattern matching, by assigned name or visual indicia. A local and remote cache of the catalog reduces latency even for complicated gestures as only a gesture identifier needs to be transmitted to a haptic output destination. Additional embodiments translate gestures to different haptic device affordances. Tactile telepresence sessions are time-coded along with audiovisual content wherein playback is heard, seen, and felt. Another embodiment associates motion capture associated with the tactile profile so that remote, haptic recipients may see renderings of objects (e.g., hands) imparting vibrotactile sensations.

Abstract: Agricultural electronics include many components. The components can be connected via an electronic link that connects the various components to components of an agricultural implement. This can include the use of a component type identifier and a master module. The identifier and the module can communicate data, including identification data and instructional data, to easily acknowledge and operate various electrical components of the agricultural implement. Additional sensors can be included to provide even additional data that is communicated between the module and the components of the agricultural implement to aid in providing instructions for operation and to provide additional data information.

Abstract: Agricultural electronics include many components. The components can be connected via an electronic link that connects the various components to components of an agricultural implement. This can include the use of a component type identifier and a master module. The identifier and the module can communicate data, including identification data and instructional data, to easily acknowledge and operate various electrical components of the agricultural implement. Additional sensors can be included to provide even additional data that is communicated between the module and the components of the agricultural implement to aid in providing instructions for operation and to provide additional data information.

Abstract: A display unit is connected to an agricultural implement to provide inputs and operational controls, as well as status and set up, of the implement. The display unit can be a touchscreen or other device that can receive inputs to set up, control, store information, and recall information associated with the operation of the agricultural implement. The display unit can provide a number of different types of inputs to allow for the control of the various components of the implement. An alert system can provide tiered alerts, such as based upon the severity of the alerts, to provide for notice to a user as to one or more issues associated with the implement or an operation thereof.

Abstract: Wireless peripherals may be used by workers to facilitate communication, data entry, data visualization, safety, and security. Typically, these peripherals must communicate with a back-end system; however, direct communication is often impossible. Instead, the peripherals must communicate through an intermediary device (i.e., a base station) to reach the back-end system. To be most effective, the back-end system must be able to adapt its communication/response to a worker's identity, location, and/or peripherals. To facilitate this, the present invention embraces a peripheral hub, worn by a worker. The peripheral hub uses information regarding the worker and/or his peripherals to generate a peripheral manifest. The peripheral hub can transmit the peripheral manifest to the back-end system via the base station, and using information from the peripheral manifest, the back-end system may communicate/respond appropriately to the worker.

Abstract: Wireless peripherals may be used by workers to facilitate communication, data entry, data visualization, safety, and security. Typically, these peripherals must communicate with a back-end system; however, direct communication is often impossible. Instead, the peripherals must communicate through an intermediary device (i.e., a base station) to reach the back-end system. To be most effective, the back-end system must be able to adapt its communication/response to a worker's identity, location, and/or peripherals. To facilitate this, the present invention embraces a peripheral hub, worn by a worker. The peripheral hub uses information regarding the worker and/or his peripherals to generate a peripheral manifest. The peripheral hub can transmit the peripheral manifest to the back-end system via the base station, and using information from the peripheral manifest, the back-end system may communicate/respond appropriately to the worker.

Abstract: Agricultural electronics include many components. The components can be connected via an electronic link that connects the various components to components of an agricultural implement. This can include the use of a component type identifier and a master module. The identifier and the module can communicate data, including identification data and instructional data, to easily acknowledge and operate various electrical components of the agricultural implement. Additional sensors can be included to provide even additional data that is communicated between the module and the components of the agricultural implement to aid in providing instructions for operation and to provide additional data information.

Abstract: A mobile computing device may be configured to run more than one operating system. Each operating system may require one or more specialized buttons to perform or enable various functions. The layout, shape, and function corresponding the buttons for each operating system may be unique. Adapting the buttons for a particular operating system may be accomplished by using soft buttons displayed as part of the graphical user interface. Here, however, valuable display area must be dedicated to the buttons. Another adaptation approach requires reconfiguring the hardware. Both approaches have drawbacks. In the invention disclosed, two sets of hardware buttons are incorporated in the same touch panel. Enabling a button is based on the choice of operating system. Enabled buttons are visible and operable while not enabled buttons or not visible and not operable. In this way, the hardware buttons in the mobile computing device may be reconfigured without using display area and without requiring hardware disassembly.

Abstract: Wireless peripherals may be used by workers to facilitate communication, data entry, data visualization, safety, and security. Typically, these peripherals must communicate with a back-end system; however, direct communication is often impossible. Instead, the peripherals must communicate through an intermediary device (i.e., a base station) to reach the back-end system. To be most effective, the back-end system must be able to adapt its communication/response to a worker's identity, location, and/or peripherals. To facilitate this, the present invention embraces a peripheral hub, worn by a worker. The peripheral hub uses information regarding the worker and/or his peripherals to generate a peripheral manifest. The peripheral hub can transmit the peripheral manifest to the back-end system via the base station, and using information from the peripheral manifest, the back-end system may communicate/respond appropriately to the worker.

Abstract: Wireless peripherals may be used by workers to facilitate communication, data entry, data visualization, safety, and security. Typically, these peripherals must communicate with a back-end system; however, direct communication is often impossible. Instead, the peripherals must communicate through an intermediary device (i.e., a base station) to reach the back-end system. To be most effective, the back-end system must be able to adapt its communication/response to a worker's identity, location, and/or peripherals. To facilitate this, the present invention embraces a peripheral hub, worn by a worker. The peripheral hub uses information regarding the worker and/or his peripherals to generate a peripheral manifest. The peripheral hub can transmit the peripheral manifest to the back-end system via the base station, and using information from the peripheral manifest, the back-end system may communicate/respond appropriately to the worker.

Abstract: Information is presented relating to positions within delivery vehicles designated for transporting particular items of a multi-parcel cargo. Cargo-related information is evaluated in relation to characteristic(s) of each parcel. The information for transport-positioning the cargo item is computed based on the evaluation. Entry of the cargo item is registered upon loading and an identifier is visibly directed to its transport position. Geo-positioning of the vehicle is tracked over its route. Destination approach/arrival is detected based on the tracking and the visible identifier is redirected to the item's position. The identifier may be projected controllably by a pointer/projector, including delivery related information (e.g., related to delivery, warnings, etc.). Visibility may be enhanced using reflective surfaces.

Abstract: A mobile computing device may be configured to run more than one operating system. Each operating system may require one or more specialized buttons to perform or enable various functions. The layout, shape, and function corresponding the buttons for each operating system may be unique. Adapting the buttons for a particular operating system may be accomplished by using soft buttons displayed as part of the graphical user interface. Here, however, valuable display area must be dedicated to the buttons. Another adaptation approach requires reconfiguring the hardware. Both approaches have drawbacks. In the invention disclosed, two sets of hardware buttons are incorporated in the same touch panel. Enabling a button is based on the choice of operating system. Enabled buttons are visible and operable while not enabled buttons or not visible and not operable. In this way, the hardware buttons in the mobile computing device may be reconfigured without using display area and without requiring hardware disassembly.