Abstract: In some aspects, the invention relates to a porous implant, comprising a resorbable or bio-erodible porous silicon-based carrier material; a reservoir formed within the body of the porous silicon-based carrier material; and a beneficial substance disposed within the reservoir.

Abstract: In some aspects, the invention relates to a porous implant, comprising a resorbable or bio-erodible porous silicon-based carrier material; a reservoir formed within the body of the porous silicon-based carrier material; and a beneficial substance disposed within the reservoir.

Abstract: A porous silicon implant impregnated with a beneficial substance, such as a micromineral required for healthy physiology, is implanted subcutaneously and is entirely corroded away over the following months/year to release the beneficial substance in a controlled manner. In a second embodiment the implant may have a large number of holes which contain beneficial substance and which are closed by bio-erodible doors of different thickness so as to stagger the release of the beneficial substance over time as the doors are breached.

Abstract: A porous silicon implant impregnated with a beneficial substance, such as a micromineral required for healthy physiology, is implanted subcutaneously and is entirely corroded away over the following months/year to release the beneficial substance in a controlled manner. In a second embodiment the implant may have a large number of holes which contain beneficial substance and which are closed by bio-erodible doors of different thickness so as to stagger the release of the beneficial substance over time as the doors are breached.

Abstract: A porous silicon implant impregnated with a beneficial substance, such as a micromineral required for healthy physiology, is implanted subcutaneously and is entirely corroded away over the following months/year to release the micromineral in a controlled manner. In a second embodiment the implant may have a large number of holes which contain beneficial substance and which are closed by bio-erodible doors of different thickness so as to stagger the release of the beneficial substance over time as the doors are breached.

Abstract: A porous silicon implant impregnated with a beneficial substance, such as a micromineral required for healthy physiology, is implanted subcutaneously and is entirely corroded away over the following months/year to release the micromineral in a controlled manner. In a second embodiment the implant may have a large number of holes which contain beneficial substance and which are closed by bio-erodible doors of different thickness so as to stagger the release of the beneficial substance over time as the doors are breached.

Abstract: A porous silicon implant impregnated with a beneficial substance, such as a micromineral required for healthy physiology, is implanted subcutaneously and is entirely corroded away over the following months/year to release the micromineral in a controlled manner. In a second embodiment the implant may have a large number of holes which contain beneficial substance and which are closed by bio-errordable doors of different thickness so as to stagger the release of the beneficial substance over time as the doors are breached.

Abstract: A porous silicon implant impregnated with a beneficial substance, such as a micromineral required for healthy physiology, is implanted subcutaneously and is entirely corroded away over the following months/year to release the micromineral in a controlled manner. In a second embodiment the implant may have a large number of holes which contain beneficial substance and which are closed by bio-errordable doors of different thickness so as to stagger the release of the beneficial substance over time as the doors are breached.

Abstract: A porous silicon implant impregnated with a beneficial substance, such as a micromineral required for healthy physiology, is implanted subcutaneously and is entirely corroded away over the following months/year to release the micromineral in a controlled manner. In a second embodiment the implant may have a large number of holes which contain beneficial substance and which are closed by bio-errordable doors of different thickness so as to stagger the release of the beneficial substance over time as the doors are breached.

Abstract: A porous silicon implant impregnated with a beneficial substance, such as a micromineral required for healthy physiology, is implanted subcutaneously and is entirely corroded away over the following months/year to release the micromineral in a controlled manner. In a second embodiment the implant may have a large number of holes which contain beneficial substance and which are closed by bio-errordable doors of different thickness so as to stagger the release of the beneficial substance over time as the doors are breached.

Abstract: A porous silicon implant impregnated with a beneficial substance, such as a micromineral required for healthy physiology, is implanted subcutaneously and is entirely corroded away over the following months/year to release the micromineral in a controlled manner. In a second embodiment the implant may have a large number of holes which contain beneficial substance and which are closed by bio-errordable doors of different thickness so as to stagger the release of the beneficial substance over time as the doors are breached.

Abstract: A porous silicon implant impregnated with a beneficial substance, such as a micromineral required for healthy physiology, is implanted subcutaneously and is entirely corroded away over the following months/year to release the micromineral in a controlled manner. In a second embodiment the implant may have a large number of holes which contain beneficial substance and which are closed by bio-errordable doors of different thickness so as to stagger the release of the beneficial substance over time as the doors are breached.

Abstract: A porous silicon implant impregnated with a beneficial substance, such as a micromineral required for healthy physiology, is implanted subcutaneously and is entirely corroded away over the following months/year to release the micromineral in a controlled manner. In a second embodiment the implant may have a large number of holes which contain beneficial substance and which are closed by bio-errordable doors of different thickness so as to stagger the release of the beneficial substance over time as the doors are breached.

Abstract: A porous silicon implant impregnated with a beneficial substance, such as a micromineral required for healthy physiology, is implanted subcutaneously and is entirely corroded away over the following months/year to release the micromineral in a controlled manner. In a second embodiment the implant may have a large number of holes which contain beneficial substance and which are closed by bio-errordable doors of different thickness so as to stagger the release of the beneficial substance over time as the doors are breached.

Abstract: A computerized system and method for placing orders for financial instruments with an exchange or alternative trading system is provided. In accordance with this embodiment, updated order book information is received from each of a plurality of trade execution entities. An order for a first financial instrument of the plurality of financial instruments is received from a first user. The order includes a first price per unit component, and a first unit quantity. The first unit quantity includes a disclosed liquidity quantity and an undisclosed liquidity quantity. The order, including the disclosed liquidity quantity and the undisclosed liquidity quantity, is sent to a first one of the plurality of trade execution entities for execution. A reciprocal order for the first financial instrument that does not require that the trade execution entity be the first one of the trade execution entities is received from a second user.

Abstract: A method for presenting data comprises receiving the data; and deriving a multi-level dynamic hierarchical structure for the data based on drilldown sequences input from a user, wherein the drilldown sequences automatically compute a graphical visual comparison of the data and comprise: deriving a multi-pixel bar chart to display an aggregated data paradigm; and deriving a graphical illustration to display a data distribution paradigm.

Abstract: One embodiment of the present invention provides a system that associates an error in a layout with a cell. During operation, the system receives a layout which is designed to create a target feature with an intended shape. Next, the system determines an error in a critical dimension of the target feature. The system then identifies a cell in the layout based on the error's location in the layout, thereby associating the error with the cell. Note that associating errors with cells allows the errors to be summarized based on the associated cells, which can reduce the amount of time required to identify and fix the errors.

Abstract: A method and system for designing a dummy grid in an open area of a circuit adjacent to at least one metal line comprising the circuits is disclosed. The method and system include patterning dummy lines in the dummy grid adjacent to metal signal lines, and patterning non-floating dummy lines in the dummy grid adjacent to metal power lines. The method and system further include varying sizes and spacing of the dummy lines in the respective columns of the dummy grid based on the distance between each column and the adjacent metal line, to achieve a balance between planarization and performance.

Abstract: Multiple damascene layers in integrated circuits can form several advantageous designs or components that may lower cost or increase performance of certain designs. In embodiments for power bus signals, multiple damascene layers may be used to form traces with increased power capacity and lower cost. In other embodiments, multiple damascene layers may be used to form components such as capacitors and inductors with increased performance.

Abstract: A technique of fabricating a nonvolatile device includes forming a low doping region to aid in the reduction of substrate hot electrons. The nonvolatile device may be a floating gate device, such as a Flash, EEPROM, or EPROM memory cell. The low doping region has a lower doping concentration than that of the substrate. By reducing substrate hot electrons, this improves the reliability and longevity of the nonvolatile device.