Examples disclosed herein relate to dual in-line memory module (DIMM) battery backup. Some examples disclosed herein describe systems that include a backup power source pluggable into a DIMM slot. The backup power source may include a plurality of battery cells electrically connected to a DIMM to provide backup power to the DIMM. Each of the plurality of battery cells supporting the DIMM may be electrically connected to a DC-to-DC converter in series and to each other in parallel.

An input/output (I/O) device for a distributed modular I/O system includes a base adapted to be connected to an associated support structure. A terminal block is connected to the base and includes a plurality of wiring connections adapted to be connected to field wiring of an associated controlled system. The I/O device further includes first and second I/O modules each including a plurality of removable single-channel I/O submodules that are each releasably connected to the base and each configured for a select I/O operation for input and output of data relative to the associated controlled system. One or more pairs of the single-channel I/O submodules can be configured to be redundant within or between the first and second I/O modules. Each of the single-channel I/O submodules is operatively connected to wiring connections of the terminal block through the base. The I/O device further includes first and second network switches connected to the base. The first and second network switches are adapted to be respectively connected to first and second backplane circuits. The I/O device further includes first and second system modules connected to the base and each respectively connected to both of the first and second network switches. The first and second system modules are also each respectively operatively connected to all of the removable single-channel I/O submodules of both of the first and second I/O modules such that the first and second system modules control communication of I/O data between the first and second network switches and the single-channel I/O submodules.

Method, apparatus, and system for improving semiconductor device writeability at row/bit level through bias temperature instability. Such a device may comprise a plurality of cells of an array, wherein each of the cells comprises a pass gate and a latch; a plurality of word lines, wherein each word line comprises a supply voltage line (VCS) which supplies voltage to each latch of a first number of cells; an array VCS driver electrically connected to each VCS; and a control line configured to provide an operational array supply voltage, a first array supply voltage, or a second array supply voltage to each VCS, wherein the first array supply voltage and the second array supply voltage are greater than the operational array supply voltage. By virtue of BTI, application of the first array supply voltage may lead to improved writeability of one or more cells of the device.

A biometrics hub may establish a session with a first biometric device, receive first biometric data of a user from the first biometric device, establish a session with a second biometric device, receive second biometric data of the user from the second biometric device, and store the first biometric data and the second biometric data at the biometrics hub. The biometrics hub may further detect a power event associated with at least one of the first biometric device or the second biometric device, and change, in response to detecting the power event, a schedule for processing at least one of the first biometric data or the second biometric data.

A system for providing redundant electric power to at least one vehicle component is disclosed. The system includes at least one power management unit connectable to a vehicle power network; and one or more storage units coupled to the at least one power management unit for receiving electric power to be stored in the one or more storage units. The at least one vehicle component is connectable to at least two of the storage units to enable a redundant electric power supply.

Various embodiments for managing data integrity in a computing storage environment, by a processor device, are provided. In one embodiment, a method comprises applying a copy-on-write technique to a cache in a computer storage system such that each write arriving in the cache is assigned to a separate new physical location and registered sequentially in an order the write arrived, for preserving a state of the computer storage system during a failure event.

A computer-implemented method, computer program product, and computer system for identifying power line segments and power line redundancies in a datacenter are provided. The computer-implemented method for identifying power line segments and power line redundancies in a datacenter include; transmitting a data packet from equipment compilers to a host program, where the data packet includes unique datacenter equipment identifiers, the datacenter equipment includes IT equipment and a power source; identifying one or more power line segments from the power source to the IT equipment; and determining an existence of a power line redundancy between the power source and the IT equipment.

Embodiments of a multiple sign controller are generally described herein. Many embodiments include a multiple sign controller system. In some embodiments, the multiple sign controller can comprise a computer, a single instance of an operating system configured to run on the computer, two or more virtual sign controller instances, one or more physical communication ports coupled to the computer, and two or more virtual ports configured to run on the single instance of the operating system. In many embodiments, a first virtual port of the two or more virtual ports can be associated with a first virtual sign controller instance of the two or more virtual sign controller instances. Other embodiments may be described and claimed.

Enhanced data storage devices in various form factors are discussed herein. In one example, a storage drive includes a plurality of storage devices configured to store and retrieve data responsive to operations received over Peripheral Component Interconnect Express (PCIe) interfaces, a PCIe switch circuit communicatively coupled to the PCIe interfaces of the storage devices and configured to receive over a host connector the operations issued by a host system and transfer the storage operations for ones of the storage devices over associated ones of the PCIe interfaces. The storage drive includes holdup circuitry configured to provide holdup power the storage devices. The storage drive includes a first circuit board assembly comprising three storage device connectors that couple to corresponding storage devices, and a second circuit board assembly comprising a further storage device connector that couples to a further storage device.

Techniques and mechanisms for providing redundancy with multiple batteries of a backup power system. In an embodiment, switch circuits are each coupled between a power bus and a different respective one of the multiple batteries. Respective nodes of the switch circuits are each to couple to a different respective power sink, wherein power delivery to the power sinks is monitored. Based on the monitoring, the switch circuits are configured for a first battery to serve a substitute for a second battery. Configuring the switch circuits includes electrically decoupling the second battery from a first node, and electrically coupling the first battery to deliver power via both a power bus and the first node. In another embodiment, multiple backup units each include a respective battery and switch circuit, wherein respective controllers of the backup units intermittently communicate monitoring information via a data bus.