Abstract: An apparatus and method providing flexibility to a silicon chip carrier which, in at least one embodiment, comprises multiple chips and a silicon chip carrier having thinned regions between some adjacent chips, thus, allowing for increased flexibility and reduced package warpage.

Abstract: A structure for cooling an electronic device is disclosed. The structure includes a top layer disposed over the electronic device. The structure further includes a plurality of spring elements disposed between the top layer and the electronic device for providing a heat path from the electronic device and wherein the plurality of spring elements provide mechanical compliance. In one alternative, the structure further includes a solid heat-conducting layer disposed over the electronic device, wherein the plurality of spring elements are coupled to the solid heat-conducting layer.

Abstract: A structure for cooling an electronic device is disclosed. The structure includes a compressible top layer disposed over the electronic device. The structure further includes a plurality of rigid elements disposed between the top layer and the electronic device for providing a heat path from the electronic device and wherein the plurality of rigid elements provide mechanical compliance. In another alternative, the structure further includes a conformable heat-conducting layer disposed over the electronic device, wherein a bottom end of the plurality of rigid elements is coupled to the conformable heat-conducting layer.

Abstract: A structure for cooling an electronic device is disclosed. The structure includes a top layer disposed over the electronic device. The structure further includes a plurality of spring elements disposed between the top layer and the electronic device, wherein at least one of the spring elements comprises a spring portion and a fin portion. At least one of the spring elements provides a heat path from the electronic device and provides mechanical compliance. In another embodiment, the structure further includes a heat-conducting layer disposed over the electronic device, wherein the fin portion of each of at least one of the spring elements is coupled to the heat-conducting layer.

Abstract: A structure for cooling an electronic device is disclosed. The structure includes a top layer disposed over the electronic device. The structure further includes a plurality of spring elements disposed between the top layer and the electronic device, wherein at least one spring element comprises a spring portion, provides a heat path from the electronic device and provides mechanical compliance. The structure further includes a seal for containing a space between the top layer and the electronic device, wherein the space contained includes the plurality of spring elements, and a liquid with vaporizing capability disposed with the space contained.

Abstract: Improvements in placement of timing patterns in self-servowriting include correcting for systematic errors due to geometric effects. A correction is made for varying systematic errors, such as when the recording head has spatially separate read and write elements. Further, servopattern rotation due to residual or unmeasured systematic errors is reduced by using a once per revolution clock index derived from the motor drive current waveform or any other sensor. In one aspect of correcting for systematic errors in the writing of timing patterns on a storage medium of a storage device, a time interval between a trigger pattern written at a first radial position of the storage medium and a rotational index is measured. The rotational index is related to the rotational orientation of the storage medium with respect to a fixed frame of the storage device.

Abstract: A system and method for improved self-servo-writing of multi-slot timing patterns is described. Individual timing marks are replaced with groups of timing mark slots. At each timing mark location, a time measurement is made by detecting a timing mark in one of the slots. Also, extensions to the existing timing marks are written in other slots. The combination of timing measurements at every timing mark and extensions to those timing marks written at every opportunity improves the overall precision of the timing propagation. The improved accuracy of timing mark placement produces a commensurate improvement in the placement of the concomitantly written servo-data. In addition, the alignment accuracy of the written pattern is less sensitive to variations in rotation speed and variations in the shape of written transitions. Moreover, only a single disk revolution is required at each servo radius to write servo data and propagate the timing marks to maintain timing alignment.