Various embodiments of the present disclosure relate to an electronic device and a method, whereby various elements having the same function can be efficiently controlled through a serial interface. The electronic device may include at least one control unit and an interface or a group of peripheral devices. The group of peripheral devices may include a plurality of peripheral devices (e.g., an input module, a sound output module, a display module, an audio module, a haptic module, a sensor module, a camera module, a power management module, and a communication module). The electronic device includes a plurality of peripheral devices and at least one processor connected to the plurality of peripheral devices via a serial interface, wherein the at least one processor may be configured to control the electronic device to continuously transmit, via the serial interface, a single command frame including a single serial control command, and data frames to be delivered to at least two peripheral devices among the plurality of peripheral devices.

A memory module is provided, comprising a connector and a plurality of memory devices. Each memory device includes a memory array and a plurality of data connections, wherein a first subset of the plurality of data connections are configured to communicate data with a first portion of the memory array, and a second subset of the plurality of data connections are configured to communicate data with a second portion of the memory array. The first subset of the plurality of data connections of each of the plurality of memory devices are connected in parallel to first external contacts of the connector in a first addressable pseudo-channel, and the second subset of the plurality of data connections of each of the plurality of memory devices are connected in parallel to second external contacts of the connector in a second addressable pseudo-channel.

Embodiments are generally directed apparatuses, methods, techniques and so forth to select two or more processing units of the plurality of processing units to process a workload, and configure a circuit switch to link the two or more processing units to process the workload, the two or more processing units each linked to each other via paths of communication and the circuit switch.

An automation device has a main module and an interchangeable connection module in which a fieldbus port of the automation device is located. The automation device is characterized in that the interchangeable connection module contains a non-volatile memory which can be read out by the main module of the automation device. A method for operating the automation device includes the steps of connecting a main module of the automation device with a connection module, reading the non-volatile memory of the connection module, detecting any incompatibilities between the main module and the connection module, and placing the automation device in operation if no incompatibilities are detected.

An electrical device and a video camera system for transmitting and receiving data to at least one auxiliary device is provided. The electrical device includes electrical components for receiving, transmitting and processing the data. The electrical components are further configured to transmit power. The electrical device includes a housing for accommodating the electrical components. An interface is disposed on the housing. The interface includes a plurality of data ports, a first power port and a second power port. The plurality of data ports is disposed between the first power port and the second power port. The interface is configured to mate with a plurality of connectors, each of which are coupled to the auxiliary device so as to power the respective auxiliary device and transmit and receive data to and from the auxiliary device.

A system and method for managing memory resources. In some embodiments the system includes a first server, a second server, and a server-linking switch connected to the first server and to the second server. The first server may include a stored-program processing circuit, a cache-coherent switch, and a first memory module. In some embodiments, the first memory module is connected to the cache-coherent switch, the cache-coherent switch is connected to the server-linking switch, and the stored-program processing circuit is connected to the cache-coherent switch.

Methods and apparatus to implement communications via a remote terminal unit are disclosed. An example apparatus includes a first central processing unit module to be in communication with a host of a process control system. The example apparatus also includes a first rack including a backplane and a plurality of slots. The plurality of slots includes a master slot to receive the first central processing unit module. The backplane communicatively couples the first central processing unit module to at least one of a first communication module or a first input/output (I/O) module inserted in a second one of the slots. The backplane includes a first communication bus for communication of I/O data and a second communication bus for communication of at least one of maintenance data, pass-through data, product information data, archival data, diagnostic data, or setup data. The first communication bus is independent of the second communication bus.

Examples described herein relate to a tool-less manner of forming an assembly with a circuit board carrier enclosure that provide leaf springs that provide a force against a circuit board to maintain a level surface of the circuit board. Multiple leaf springs can be used to apply a desired force to the circuit board. A heat sink can be mounted in the enclosure at a distance from the circuit board. The circuit board with carrier can be inserted without tools into an electrical connection for communications with other devices.

In computing scenarios involving multiple computational units, an enclosure (e.g., a rack or server cabinet) may store the units and provide resources such as shared power and network connectivity. Additionally, the components of the units may communicate through a Serial Attached SCSI (SAS) bus, but many such enclosures provide little or no integration with the SAS buses, thus entailing extensive SCSI cabling. Presented herein are architectures for enclosures presenting a set of slots for trays storing respective computing blades, where such trays include SAS connectors that connect directly (i.e., without cabling) with connectors on a midplane that interconnects the blades into a SAS bus featuring at least one integrated SAS expander. Additional architectural variations involve providing SAS expander on one or both of the midplane and the blades; grouping blades into subsets having distinct SAS buses; and interconnecting the SAS buses and expanders of multiple midplanes in the enclosure.

A method and apparatus for setting an internal register of an integrated circuit (IC) via a multiplexed pin which also passes an RF signal is provided. An internal RF signal path couples the pin to an internal terminal for the RF signal, and a register setting signal path couples the pin to an internal register. The internal register may be an address register, such as a USID address register of a MIPI RFFE bus. A capacitor on the RF signal path may block the constant voltage, and a resistor or inductor on the register setting signal path may block the RF signal. The integrated circuit may include an RF section and a controller section, where the controller section may be used to control the RF section. The controller section is responsive to an address associated with the address register.