Abstract: A support structure for use with a semiconductor substrate in thinning, or backgrinding, thereof, as well as during post-thinning processing of the semiconductor substrate includes a portion that extends substantially along and around an outer periphery of the semiconductor substrate to impart the thinned semiconductor substrate with rigidity. The support structure may be configured as a ring or as a member that substantially covers an active surface of the semiconductor substrate and forms a protective structure over each semiconductor device carried by the active surface.

Abstract: Techniques for memory management or analysis with conservative garbage collectors is provided. The native stack is analyzed during runtime to identify within frames references to objects in the heap space. An amount of memory is calculated that represents the memory implicated by the reference. A log can be generated that conveys the frame, location of the reference in the frame and amount of memory implicated by the reference.

Abstract: A support structure for use with a semiconductor substrate in thinning, or backgrinding, thereof, as well as during post-thinning processing of the semiconductor substrate includes a portion which extends substantially along and around an outer periphery of the semiconductor substrate to impart the thinned semiconductor substrate with rigidity. The support structure may be configured as a ring or as a member which substantially covers an active surface of the semiconductor substrate and forms a protective structure over each semiconductor device carried by the active surface. Assemblies that include the support structure and a semiconductor substrate are also within the scope of the present invention, as are methods for forming the support structures and thinning and post-thinning processes that include use of the support structures.

Abstract: An interlocking panel, and structures formed therefrom, are described herein. Embodiments of the present invention provide a panel including a protruding end including a receiving member for engaging a complementary engaging member of a first adjacent panel, and a receiving end including two flanges, at least one of the two flanges including an engaging member for engaging a complementary receiving member of a second adjacent panel, one or both of the two flanges configured to flex to allow the complementary receiving member of the second adjacent panel to engage the engaging member.

Abstract: A method and software for managing class variables is described in which a variable-format container for static class variables is provided such that numeric class variables can be accessed directly while other kinds of class variables are accessed via a reference to an object.

Abstract: Low temperature processed back side redistribution lines (RDLs) are disclosed. Low temperature processed back side RDLs may be electrically connected to the active surface devices of a semiconductor substrate using through wafer interconnects (TWIs). The TWIs may be formed prior to forming the RDLs, after forming the RDLs, or substantially simultaneously to forming the RDLs. The material for the back side RDLs and various other associated materials, such as dielectrics and conductive via filler materials, are processed at temperatures sufficiently low so as to not damage the semiconductor devices or associated components contained on the active surface of the semiconductor substrate. The low temperature processed back side RDLs of the present invention may be employed with optically interactive semiconductor devices and semiconductor memory devices, among many others. Semiconductor devices employing the RDLs of the present invention may be stacked and electrically connected theretogether.

Abstract: A programmed material consolidation apparatus includes at least one fabrication site and a material consolidation system associated with the at least one fabrication site. The at least one fabrication site may be configured to receive one or more fabrication substrates, such as semiconductor substrates. A machine vision system with a translatable or locationally fixed camera may be associated with the at least one fabrication site and the material consolidation system. A cleaning component may also be associated with the at least one fabrication site. The cleaning component may share one or more elements with the at least one fabrication site, or may be separate therefrom. The programmed material consolidation apparatus may also include a substrate handling system, which places fabrication substrates at appropriate locations of the programmed material consolidation apparatus.

Abstract: Microelectronic imager assemblies comprising a workpiece including a substrate and a plurality of imaging dies on and/or in the substrate. The substrate includes a front side and a back side, and the imaging dies comprise imaging sensors at the front side of the substrate and external contacts operatively coupled to the image sensors. The microelectronic imager assembly further comprises optics supports superimposed relative to the imaging dies. The optics supports can be directly on the substrate or on a cover over the substrate. Individual optics supports can have (a) an opening aligned with one of the image sensors, and (b) a bearing element at a reference distance from the image sensor. The microelectronic imager assembly can further include optical devices mounted or otherwise carried by the optics supports.

Abstract: A heap analyzer that processes a snapshot of the heap contained in a dump file is described. The heap analyzer tool can be configured to relocate the pointers in the dumped heap and allow developers to examine the heap in web browser by presenting markup for displaying a heap object in the browser and rendering pointers in the object as clickable links. When a link is selected, the pointer is followed to another object and markup is generated for rendering that object with its links. Furthermore, callbacks may be provided through an application programming interface (API) to allow developers to furnish their own code for analyzing and displaying their data structures.

Abstract: Methods for supporting substrates during programmed material consolidation include securing a substrate in position over a support with a surface and, optionally, other features that receive the at least one substrate and prevent unconsolidated material from contacting undesired regions, such as the bottom surface, of the at least one substrate.

Abstract: A method for scanning objects as for garbage collection is described that employ an ancillary data structure to describe the format of an object. Specifically, the data structure lists which parts of the object are references and how large each part of the object is. Scanning the object can efficiently occur by stepping through the object and the data structure in parallel.

Abstract: Methods for cleaning consolidatable material from substrates or from features that have been fabricated with the material include application of pressure, force, or a cleaning agent to the substrate or feature. The pressure, force, or cleaning agent may be applied in a variety of ways. The unconsolidated material that has been removed from the substrate or feature may also be collected, optionally filtered, and reused in a subsequent programmed material consolidation process.

Abstract: A method and software for analyzing a heap is described, in which a snapshot is made of a heap, which can be later analyzed by an analysis tool when a program that had run out of memory is no longer running. In one embodiment, an object allocated by the program is accessed and copied into a file, and an address of the object allocated by the process is recorded in association with an offset in the file of the copy of the object. The copy of the object copied into the file has preferably the same size as the object allocated by the process. A heap analysis tool may then be run on the objects copied into the file.

Abstract: Disclosed herein are methods for forming photolithography alignment markers on the back side of a substrate, such as a crystalline silicon substrate used in the manufacture of semiconductor integrated circuits. According to the disclosed techniques, laser radiation is used to remove the material (e.g., silicon) from the back side of a substrate to form the back side alignment markers at specified areas. Such removal can comprise the use of laser ablation or laser-assisted etching. The substrate is placed on a motor-controlled substrate holding mechanism in a laser removal chamber, and the areas are automatically moved underneath the laser radiation to removal the material. The substrate holding mechanism can comprise a standard chuck (in which case use of a protective layer on the front side of the substrate is preferred), or a substrate clamping assembly which suspends the substrate at its edges (in which case the protective layer is not necessary).

Abstract: A method for forming at least one conductive element is disclosed. Particularly, a semiconductor substrate, including a plurality of semiconductor dice thereon, may be provided and a dielectric layer may be formed thereover. At least one depression may be laser ablated in the dielectric layer and an electrically conductive material may be deposited thereinto. Also, a method for assembling a semiconductor die having a plurality of bond pads and a dielectric layer formed thereover to a carrier substrate having a plurality of terminal pads is disclosed. At least one depression may be laser ablated into the dielectric layer and a conductive material may be deposited thereinto for electrical communication between the semiconductor die and the carrier substrate. The semiconductor die may be affixed to the carrier substrate and at least one of the dielectric layer and the conductive material may remain substantially solid during affixation therebetween. The methods may be implemented at the wafer level.

Abstract: Systems and methods for retrieving residual liquid during immersion lens photolithography are disclosed. A method in accordance with one embodiment includes directing radiation along a radiation path, through a lens and through a liquid volume in contact with the lens, to a microfeature workpiece in contact with the liquid volume. The method can further include, while moving at least one of the microfeature workpiece and the lens relative to the other, recovering liquid from the liquid volume and replenishing liquid in the liquid volume. A spacing between the lens and the microfeature workpiece can be controlled by providing a gas bearing between the lens and the microfeature workpiece. Residual liquid remaining on a surface on the microfeature workpiece can be directed back into the liquid volume, for example, by injecting a gas through at least one injection port that is oriented annularly inwardly toward the liquid volume.

Abstract: A method and software for managing pointers to external objects in a run-time environment are described in which eager external references are provided that allow session memory objects to point directly to certain call memory objects with machine pointers. The eager external references contain enough information to recreate the call memory objects in call memory at the beginning of the call and fix the session memory objects to point to the new locations of the recreated call memory objects.

Abstract: Microelectronic imagers and methods for packaging microelectronic imagers are disclosed herein. In one embodiment, a microelectronic imaging unit can include a microelectronic die, an image sensor, an integrated circuit electrically coupled to the image sensor, and a bond-pad electrically coupled to the integrated circuit. An electrically conductive through-wafer interconnect extends through the die and is in contact with the bond-pad. The interconnect can include a passage extending completely through the substrate and the bond-pad with conductive fill material at least partially disposed in the passage. An electrically conductive support member is carried by and projects from the bond-pad. A cover over the image sensor is coupled to the support member.

Abstract: Microelectronic devices, methods for packaging microelectronic devices, and methods for forming vias and conductive interconnects in microfeature workpieces and dies are disclosed herein. In one embodiment, a method includes forming a bond-pad on a die having an integrated circuit, the bond-pad being electrically coupled to the integrated circuit. A conductive line is then formed on the die, the conductive line having a first end portion attached to the bond-pad and a second end portion spaced apart from the bond-pad. The method can further include forming a via or passage through the die, the bond-pad, and the first end portion of the conductive line, and depositing an electrically conductive material in at least a portion of the passage to form a conductive interconnect extending at least generally through the microelectronic device.

Abstract: Microelectronic imaging devices and methods of packaging microelectronic imaging devices are disclosed herein. In one embodiment, a microelectronic imaging device includes a microelectronic die having an integrated circuit, an image sensor electrically coupled to the integrated circuit, and a plurality of bond-pads electrically coupled to the integrated circuit. The imaging device further includes a cover over the image sensor and a plurality of interconnects in and/or on the cover that are electrically coupled to corresponding bond-pads of the die. The interconnects provide external electrical contacts for the bond-pads of the die. The interconnects can extend through the cover or along a surface of the cover.