Technologies for switching network traffic include a network switch. The network switch includes one or more processors and communication circuitry coupled to the one or more processors. The communication circuitry is capable of switching network traffic of multiple link layer protocols. Additionally, the network switch includes one or more memory devices storing instructions that, when executed, cause the network switch to receive, with the communication circuitry through an optical connection, network traffic to be forwarded, and determine a link layer protocol of the received network traffic. The instructions additionally cause the network switch to forward the network traffic as a function of the determined link layer protocol. Other embodiments are also described and claimed.

A shell structure including a shell, a baffle plate, and a positioning member is provided. The shell has a first surface, a second surface opposite to the first surface, and an expansion opening and a first mounting hole penetrating the first and second surfaces. The baffle plate is detachably mounted to the shell and includes a body portion located in the expansion opening and a side wing portion located outside the expansion opening and in contact with the second surface. The side wing portion includes a second mounting hole overlapped with the first mounting hole. The positioning member passes through the first and second mounting holes, and includes a first positioning portion in contact with the first surface and a second positioning portion passing through the second mounting hole. A maximum outer diameter of the second positioning portion is greater than an inner diameter of the second mounting hole.

A server configured to accommodate a storage device includes a chassis, an electronic component, a first positioning pin, a second positioning pin, and a slide rail. The chassis includes a first bottom plate, a first side plate, a first side wall, a first partition and a second partition that are disposed on the first bottom plate. The first bottom plate is divided into a first area, a second area and a third area. The third area is configured for the storage device to be placed thereon. The electronic component is disposed in the first area and configured to be electrically connected to the storage device. The first positioning pin is disposed on the first side wall. The second positioning pin is disposed in the third area. The slide rail has a first positioning groove and is detachably disposed on the first positioning pin via the first positioning groove.

An electronic device includes: a housing which has two side walls which are spaced apart from one another along an apposition direction and form an accommodation space between them; a printed circuit board which is insertable into the accommodating space of the housing along an insertion direction pointing transversely to the apposition direction and, in a mounting position, is accommodated in the accommodating space in a position perpendicular to the apposition direction and has a side edge extending along the insertion direction; and at least one attachment part which has at least one engagement receptacle by which the at least one attachment part is attachable to the side edge of the printed circuit board and, in an attached position, is connected to the printed circuit board.

A modular system for producing an electronic device includes: a housing, which forms an accommodating space; a printed circuit board which is insertable along an insertion direction into the accommodating space of the housing and, in a mounting position, is accommodated in the accommodating space; and a plurality of attachment parts, which are connectable to the printed circuit board and which, when viewed along the insertion direction, each have a division corresponding to a predetermined smallest dividing unit or an integral multiple of the predetermined smallest dividing unit. Each attachment part has a first guide device for guiding on a second guide device of the housing and a combination of attachment parts is connectable to the printed circuit board in a manner arranged next to one another along the insertion direction such that when the printed circuit board is inserted into the accommodating space, the combination is guided.

A frame module is provided, which is adapted to connect to an object unit. The frame module includes a module housing, a latch, and a cover. The object unit is connected to the module housing. The latch is connected to the module housing, which is adapted to be moved between the first latch position and the second latch position. When the latch is in the first latch position, the latch is connected to the object unit to restrict the object unit. When the latch is in the second latch position, the latch is separated from the object unit. The cover pivots on the module housing, which is adapted to be rotated between the first cover orientation and the second cover orientation. When the cover is in the first cover orientation, the cover presses the latch and keeps the latch in the first latch position.

A graphics processing unit (GPU) server having a GPU host head with one or more host graphics processing units (GPUs). The GPU server further has a GPU system with a plurality of system GPUs that are separate from the host GPUs, and that are configured to rapidly accelerate creation of images for output to a display device. The GPU server also has a mounting assembly that integrates the GPU host head and the GPU system into a single GPU server unit. The GPU host head is independently movable relative to the GPU system.

The present invention provides a housing having a housing shell with an opening, a guidance component and a door leaf set. The guidance component is arranged in the housing shell and extending along the direction away from the opening. The door leaf set has a first door leaf and a second door leaf. The first door leaf is pivotally connected the housing shell to enable the first door leaf to rotate to a first position or a second position relative to the opening. Wherein when the first door leaf is positioned at the first position, the first door leaf shields a portion of the opening; when the first door leaf is positioned at the second position, the first door leaf extends into the housing shell and defines the first installation space with the guiding component. Wherein when the first door leaf is positioned at the first position, the second door leaf can rotate to a third position or a fourth position relative to the first door leaf; when the second door leaf is positioned at the third position, the second door leaf shields another portion of the opening; when the second door leaf is positioned at the fourth position, the second door leaf extends into the housing shell and defines the second installation space with the guiding component.

A fixing device includes a base, a fastening assembly, a fixing assembly and a first recovery member. The base has a rail be inserted by a board card. The fastening assembly is movably coupled to the base and detachably secures the board card. The fastening assembly includes a sliding member and a rotation member. The sliding member is slidably connected to the base. The rotation member is pivotally connected to the sliding member and includes an abutting end and a latch end. The rotation member selectively causes the abutting end and the latch end to be inserted into the rail. The fixing assembly is connected to the base and the fastening assembly, and secures the fastening assembly in a locked status. The first recovery member moves the fastening assembly from the fixed position toward an entrance of the rail when the locked status is released.

Technologies for allocating resources of managed nodes to workloads to balance multiple resource allocation objectives include an orchestrator server to receive resource allocation objective data indicative of multiple resource allocation objectives to be satisfied. The orchestrator server is additionally to determine an initial assignment of a set of workloads among the managed nodes and receive telemetry data from the managed nodes. The orchestrator server is further to determine, as a function of the telemetry data and the resource allocation objective data, an adjustment to the assignment of the workloads to increase an achievement of at least one of the resource allocation objectives without decreasing an achievement of another of the resource allocation objectives, and apply the adjustments to the assignments of the workloads among the managed nodes as the workloads are performed. Other embodiments are also described and claimed.