759 results about "Blade server" patented technology

A mechanism for controlling the hardware resources on a blade server, and thereby limiting the power consumption of the blade server is disclosed. The enforceable hardware resources that are controlled include the base frequency of the central processing unit (CPU) as well as power to individual banks of physical memory, for example dual-inline memory modules (DIMMs). The hardware resources are tuned in dependence on actual server utilization such that applications running on the blade only have the allocated hardware resources available to them. Deactivated hardware resources are powered off and are so ‘hidden’ from the operating system when they are not required. In this manner, power consumption in the entire chassis can be managed such that all server blades can be powered on and operate at higher steady-state utilization. The utilization of the powered on resources in a blade center is also improved.

This specification describes techniques for manufacturing an electronic system module. The module includes flexible multi-layer interconnection circuits with trace widths of 5 microns or less. A glass panel manufacturing facility, similar to those employed for making liquid crystal display, LCD, panels is used to fabricate the interconnection circuits. A polymer base layer is formed on a glass carrier with an intermediate release layer. Alternate layers of metal and dielectric are formed on the base layer, and patterned to create an array of multi-layer interconnection circuits on the glass panel. A thick layer of polymer is deposited on the interconnection circuit, and openings formed at input / output (I / O) pad locations. Solder paste is deposited in the openings to form wells filled with solder. After dicing the glass carrier to form separated interconnection circuits, IC chips are stud bumped and assembled using flip chip bonding, wherein the stud bumps on the components are inserted into corresponding wells on the interconnection circuits. The IC chips are tested and reworked to form tested circuit assemblies. Methods for connecting to testers and to other modules and electronic systems are described. Module packaging layers are provided for hermetic sealing and for electromagnetic shielding. A blade server embodiment is also described.

A system and method for automatically allocating computing resources of a rack-and-blade computer assembly. The method includes receiving server performance information from an application server pool disposed in a rack of a rack-and-blade computer assembly, and determining at least one QoS attribute for the application server pool. If the QoS attribute is below a standard, a blade server is allocated from a free server pool for use by the application server pool. If the QoS attribute is above a standard, at least one server is removed from the application server pool. An article of manufacture including a machine-readable medium having stored thereon instructions for automatically allocating computing resources of a rack-and-blade computer assembly.

A blade server system with a management bus and method for managing the same. The blade server system includes a connection board and a management module. The connection board is used for modular interconnection, including communication paths for conducting signals including a management bus signal group and a first bus signal group. The management module is used for management of the blade server system using signals including the management bus signal group and the first bus signal group. If a module is detected, the management module selects the detected module through the management bus and acquires module configuration information of the detected module through the first bus signal group. Distribution of power from a power source to the blade server system is determined according to system configuration information including the module configuration information of the module so that the power source is prevented from being overloaded.

A system remotely boots a plurality of server blades in a blade center to update each blade. A temporary network is created to provide an out-of-band communication channel between a management module and the plurality of server blades. The management module receives and saves the original boot sequence for each server blade and alters each boot sequence such that each server blade begins with a network boot. After receiving an initial transmission over the network containing server blade boot instructions and storing the boot instructions in a temporary boot server, subsequent server blade boot requests from the network are intercepted and the stored boot instructions are re-routed from the temporary boot server to each of the remaining blades in the blade server thus removing the need for repeated boot packet transmission over the network.