A redundant memory for use with an instrument arranged to acquire and store data while underwater. Such an instrument comprises a main housing which contains instrument electronics that acquires and may process data received from one or more sensors, with a primary memory located within the main housing and arranged to store at least some of the acquired and/or processed data, and a secondary memory which stores a copy of the data stored in the primary memory. The instrumentation may be arranged to write data to the primary and secondary memories contemporaneously in either a burst or continuous mode, or with primary memory backed up to secondary memory periodically and/or in response to the occurrence of a triggering event. The instrument may comprise a second housing within which the secondary memory is located. The main and second housings may be contained within a common enclosure.

A display device and an electronic apparatus. The display device includes a display panel, a first circuit board and a second circuit board. The display panel includes a light-outgoing side and a non-light-outgoing side opposite to the light-outgoing side; the first circuit board is electrically connected to the display panel and positioned at the non-light-outgoing side; and the second circuit board is configured to be electrically connected to the first circuit board, and the second circuit board includes a functional circuit in signal connection with the display panel.

In one example in accordance with the present disclosure, a computing device mount is described. The computing device mount includes a stand to support a computing device and a spacer removably attached to the stand. The spacer is placed in a recess of the computing device to mount the computing device to a mounting surface. The spacer also aligns holes on the computing device with holes on the mounting surface.

An electronic device includes a housing including a translucent ceramic member; and a printing film provided on the housing, wherein the printing film includes: an adhesive layer provided on the ceramic member; a base layer including a first surface facing the adhesive layer and a second surface opposite to the first surface; a printing layer provided on the first surface or the second surface of the base layer, the printing layer being viewable through the ceramic member and the adhesive layer; and a shielding printing layer facing the second surface of the base layer.

A shielding cover and a display device are provided. The shielding cover includes: a shielding cover body; and a shielding cover accessory fixedly connected to the shielding cover body. The shielding cover accessory includes: an accessory bottom including a flat bottom; a connecting arm through which the shielding cover accessory is connected to the shielding cover body; and a positioning arm. The connecting arm and the positioning arm are connected to two opposite ends of the accessory bottom, and protrude in opposite directions from the accessory bottom. The shielding cover accessory further includes a plurality of card slots arranged at positions of the flat bottom close to the positioning arm, each card slot penetrates the flat bottom in a direction perpendicular to the flat bottom, and the plurality of card slots are arranged at intervals in a direction parallel to an extending direction of the positioning arm.

An information handling system, including a chassis; a bottom door coupled to the chassis; an assembly, including a bracket coupled to the chassis, the bracket including an opening; a slider moveably coupled within the bracket, the slider including a cavity at least partially in superimposition with the opening; a nut positioned within the cavity, the nut including a threaded opening; and a fastener positioned through an opening of the bottom door and within the threaded opening of the nut to position the bottom door such that the bottom door abuts the chassis, wherein when the slider is in a first positional state with respect to the bracket, the nut is constrained within the cavity, wherein when the slider is in a second positional state with respect to the bracket, the nut is rotatable within the cavity.

The present disclosure relates to a portable solid-state drive (SSD) module. The portable SSD module includes a case, an SSD, a light-emitting device (LED) module and a main bracket. The case may have a window. The SSD may be arranged in the case. The LED module may be arranged in the case to indicate an operation of the SSD through the window. The main bracket may be arranged in the case to support the LED module. Therefore, the LED module may be readily and firmly combined with the case.

According to one embodiment, an electronic device includes a housing formed of an insulator and including an outer surface and a mounting part opened to the outer surface, a conductor member provided in the inside of the housing, an installation component formed of an insulator and can be installed into the mounting part, and a first connector provided on the inner side of the mounting part. The mounting part includes communicating apertures at a position in contact with a gap to be formed between the mounting part and the installation component when the installation component is installed into the mounting part and on the outer surface side with respect to the first connector, and the conductor member is exposed to the gap through the communicating aperture.

A memory device includes a device housing, a memory module, and a cooling unit. The memory module is disposed in the device housing, wherein the memory module generates heat, and the heat is transmitted to the device housing. The cooling unit is thermally connected to the device housing to dissipate some of the heat. The cooling unit includes a unit housing and a working fluid. An interior space is formed in the unit housing. The working fluid is disposed in the interior space, wherein some of the heat travels from the device housing, passes through the unit housing, and is transmitted to the working fluid.

A method for environmentally managing a computing device of an information handling system includes monitoring an environmental corrosion risk associated with a component of the computing device, a corrosion management component that reduces a rate of corrosion of the component due to an ambient environment in which the component resides by removing condensation from the component is associated with the component; making a determination that the component is associated with the corrosion management component; in response to the determination: estimating a corrosion risk of the component based on: the environmental corrosion risk, and a risk reduction factor associated with the corrosion management component; making a second determination that the corrosion risk of the component indicates a premature failure of the component; and remediating, in response to the second determination, the corrosion risk of the component.