A processing robot system includes a connection setting information group storage device provided inside a robot control device, a teaching operation panel, and a PC. The connection setting information group storage device stores a connection setting information group including information on settings for a digital communication standard between a processing device and the robot control device, and information on the allocation of I/O signals to be transmitted between the processing device and the robot control device via digital communication and which outputs the connection setting information group as one file. The teaching operation panel and the PC have a screen on which each piece of setting information included in the connection setting information group can be displayed and edited. Such a processing robot system can easily make settings for connection with a digital-controlled processing device.

A system and method for emulating a universal serial bus device is disclosed. An example embodiment may include an emulated USB (EUP) device that can emulate a host side of a USB connection. This device may have a microcontroller that is programmable with software to emulate a host connection of a physical USB device. In order to emulate a host connection of a USB device, the EUP device may configure USB host mode bus signals, initiate USB frames on the bus, indicate device status to an emulation process, and relay packets between a device and the emulation process.

A module for a data bus comprises a terminal. The terminal comprises two opposite outer faces, each comprising at least one contact, wherein the two contacts are connected by means of an internal data-bus line for forwarding data through the terminal via said internal data bus. The module further comprises a software-protection unit which is integrated into the terminal and connected to said data-bus line.

Some embodiments provide a method of providing distributed storage services to a host computer from a network interface card (NIC) of the host computer. At the NIC, the method accesses a set of one or more external storages operating outside of the host computer through a shared port of the NIC that is not only used to access the set of external storages but also for forwarding packets not related to an external storage. In some embodiments, the method accesses the external storage set by using a network fabric storage driver that employs a network fabric storage protocol to access the external storage set. The method presents the external storage as a local storage of the host computer to a set of programs executing on the host computer. In some embodiments, the method presents the local storage by using a storage emulation layer on the NIC to create a local storage construct that presents the set of external storages as a local storage of the host computer.

A user terminal emulation server maintains a database identifying network addresses, UI capabilities, and communication protocols of I/O user devices. Communication sessions are established between a user terminal emulation application and a network entity and I/O user devices proximately located to a user and provide a combined I/O user interface. Delay profiles are determined between the application and the I/O user devices. A downlink flow from the network entity is split into a plurality of downlink flow components assigned to the I/O user devices. For each of the downlink flow components, the server formats the component for transmission to the assigned I/O user device, initiates transmission of the formatted downlink flow component to the assigned I/O user device, and controls timing for when the formatted downlink flow component is transmitted to the assigned I/O user device based on the delay profile associated with the assigned I/O user device.

A portable computer-peripheral apparatus comprises a Universal Serial Bus (USB) connector. The apparatus is operable to communicate with a computer terminal (e.g. a ‘PC’). Following connection to the PC, the apparatus initialises (i.e. presents or enumerates itself) as a HID keyboard and then sends to the terminal a first predefined sequence of keycodes automatically without manual interaction; the keycodes complying with the human interface device (HID) keyboard standard protocol. Each keycode represents and simulates a keystroke, such as those performed when a user strikes a key on the PC keyboard. The keycode sequence automates the direct access to content, and/or or the initiation of a task or other process.

A portable computer-peripheral apparatus comprises a Universal Serial Bus (USB) connector. The apparatus is operable to communicate with a computer terminal (e.g. a ‘PC’). Following connection to the PC, the apparatus initialises (i.e. presents or enumerates itself) as a HID keyboard and then sends to the terminal a first predefined sequence of keycodes automatically without manual interaction; the keycodes complying with the human interface device (HID) keyboard standard protocol. Each keycode represents and simulates a keystroke, such as those performed when a user strikes a key on the PC keyboard. The keycode sequence automates the direct access to content, and/or or the initiation of a task or other process.

An information handling system may include a host system that includes a host system processor and a host system memory coupled to the host system processor. The information handling system may further include a management controller configured to provide out-of-band management of the host system. The management controller may be configured to establish a virtual console session between the host system and a remote terminal. The management controller may further be configured to, in response to a command from the remote terminal to send data from the remote terminal to the host system, receive the data from the remote terminal; and transmit the data to the host system character-by-character via a keyboard interface of the host system.

An expander I/O module discovery/management system includes a secondary system chassis housing an expander I/O module coupled to a server device. The server device identifies the secondary system chassis and an expander I/O module port utilized by that server device, and then generates and transmits an expander I/O module reporting communication identifying the secondary system chassis and the expander I/O module port. A primary system chassis houses a switching I/O module coupled to the expander I/O module. The switching I/O module receives the expander I/O module reporting communication and determines that the secondary system chassis identified in the expander I/O module reporting communication is different than the primary system chassis. In response, the switching I/O module assigns a virtual slot to the expander I/O module, and assigns a virtual port associated with the virtual slot to the expander I/O module port identified in the expander I/O module reporting communication.

An expander I/O module discovery/management system includes a secondary system chassis housing an expander I/O module coupled to a server device. The server device identifies the secondary system chassis and an expander I/O module port utilized by that server device, and then generates and transmits an expander I/O module reporting communication identifying the secondary system chassis and the expander I/O module port. A primary system chassis houses a switching I/O module coupled to the expander I/O module. The switching I/O module receives the expander I/O module reporting communication and determines that the secondary system chassis identified in the expander I/O module reporting communication is different than the primary system chassis. In response, the switching I/O module assigns a virtual slot to the expander I/O module, and assigns a virtual port associated with the virtual slot to the expander I/O module port identified in the expander I/O module reporting communication.