Abstract: A method of manufacturing a shallow trench isolation using a polishing step with reduced dishing. A pad layer, a polish stop layer, a buffer layer and a hard mask layer are formed over a substrate. The hard mask layer has a hard mask opening. We etch a trench opening in the buffer layer, the polish stop layer, the pad layer and form a trench in the substrate using the hard mask layer as an etch mask. We form an oxide trench liner layer along the sidewalls of the trench and an oxide buffer liner layer on the sidewalls of the buffer layer using a thermal oxidation. The hard mask layer prevents the oxidation of the top surface of the buffer layer during the oxidation of the oxide trench liner. This prevents the buffer layer from being consumed by the oxidation and leaves the buffer layer to act in the subsequent chemical-mechanical polish (CMP) step. Next, an insulating layer is formed at least partially filling the trench.

Abstract: A silicon-on-insulator semiconductor device and manufacturing method therefor is provided in which a single wafer die contains a transistor over an insulator layer to form a fully depleted silicon-on-insulator device and a transistor formed in a semiconductor island over an insulator structure on the semiconductor wafer forms a partially depleted silicon-on-insulator device.

Abstract: A method of manufacturing conductive lines that are thicker (not wider) in the critical paths areas. We form a plurality of first level conductive lines over a first dielectric layer. The first conductive lines run in a first direction. The first level conductive lines are comprised of a first level first conductive line and a second first level conductive line. We form a second dielectric layer over the first level conductive lines and the first dielectric layer. Next, we form a via opening in the second dielectric layer over a portion of the first level first conductive line. A plug is formed filling the via opening. We form a trench pattern in the second dielectric layer. The trench pattern is comprised of trenches that are approximately orthogonal to the first level conductive lines. We fill the trenches with a conductive material to form supplemental second lines. We form second level conductive lines over the supplemental second lines and the plug.

Abstract: An improved technique of utilizing a centralized control protocol for lighting devices such as DALI. A technique is disclosed for utilizing such protocols in a wireless environment. The first step involves associating particular slave devices with a specified master control device, and a second step involves associating specific functions within the master device with specific slave devices.

Abstract: A method to form a silicon on insulator (SOI) device using wafer bonding. A first substrate is provided having an insulating layer over a first side. A second substrate is provided having first isolation regions (e.g., STI) that fill first trenches in the second substrate. Next, we bond the first and second substrate together by bonding the insulating layer to the first isolation regions and the second substrate. Then, a stop layer is formed over the second side of the second substrate. The stop layer and the second side of the second substrate are patterned to form second trenches in the second substrate. The second trenches have sidewalls at least partially defined by the isolation regions and the second trenches expose the second insulating layer. The second trenches define first active regions over the first isolation regions (STI) and define second active regions over the insulating layer. Next, the second trenches are filled with an insulator material to from second isolation regions.

Abstract: A method to form SOI devices using wafer bonding. A first substrate is provided having trenches in a first side. A first insulating layer is formed over the first side of the first substrate and filling the trenches. We planarize the first insulating layer to form isolation regions (e.g., STI). The three embodiments of the invention planarize the first insulating layer to different levels. In the second embodiment, the first insulating layer is etched back to form a recess. This recess later forms an air gap. We provide a second substrate having a second insulating layer over a first side of the second substrate. We bond the second insulating layer to the first insulating layer. Next, we thin the first substrate from the second side to expose the first insulating layer to form active areas between the isolation regions. Lastly, devices are formed in and on the active areas.

Abstract: A method of manufacturing conductive lines that are thicker (not wider) in the critical paths areas. We form a plurality of first level conductive lines over a first dielectric layer. The first conductive lines run in a first direction. The first level conductive lines are comprised of a first level first conductive line and a second first level conductive line. We form a second dielectric layer over the first level conductive lines and the first dielectric layer. Next, we form a via opening in the second dielectric layer over a portion of the first level first conductive line. A plug is formed filling the via opening. We form a trench pattern in the second dielectric layer. The trench pattern is comprised of trenches that are approximately orthogonal to the first level conductive lines. We fill the trenches with a conductive material to form supplemental second lines. We form second level conductive lines over the supplemental second lines and the plug.

Abstract: A silicon-on-insulator semiconductor device and manufacturing method therefor is provided in which a single wafer die contains a transistor over an insulator layer to form a fully depleted silicon-on-insulator device and a transistor formed in a semiconductor island over an insulator structure on the semiconductor wafer forms a partially depleted silicon-on-insulator device.

Abstract: A new method of forming shallow trench isolations has been described. A silicon semiconductor substrate is provided. A silicon nitride layer is deposited overlying the substrate. A polysilicon layer is deposited overlying the silicon nitride layer. An oxidation mask is deposited overlying the polysilicon layer. The oxidation mask, polysilicon layer, silicon nitride layer, and the silicon semiconductor substrate are patterned to form trenches for planned shallow trench isolations. The silicon semiconductor substrate exposed within the trenches is oxidized to form an oxide liner layer within the trenches wherein the oxidation mask prevents oxidation of the polysilicon layer. Thereafter the oxidation mask is removed. A trench oxide layer is deposited overlying the liner oxide layer and filling the trenches.

Abstract: A method of forming shallow trench isolations is described. A plurality of isolation trenches are etched through a first etch stop layer into the underlying semiconductor substrate. An oxide layer is deposited over the first etch stop layer and within the isolation trenches using a high density plasma chemical vapor deposition process (HDP-CVD) wherein after the oxide layer fills the isolation trenches, the deposition component is discontinued while continuing the sputtering component until corners of the first etch stop layer are exposed at edges of the isolation trenches whereby the oxide layer within the isolation trenches is disconnected from the oxide layer overlying the first etch stop layer. Thereafter, a second etch stop layer is deposited overlying the oxide layer within the isolation trenches, the oxide layer overlying the first etch stop layer, and the exposed first etch stop layer corners.

Abstract: A method of manufacturing conductive lines that are thicker (not wider) in the critical paths areas. We form a plurality of first level conductive lines over a first dielectric layer. The first conductive lines run in a first direction. The first level conductive lines are comprised of a first level first conductive line and a second first level conductive line. We form a second dielectric layer over the first level conductive lines and the first dielectric layer. Next, we form a via opening in the second dielectric layer over a portion of the first level first conductive line. A plug is formed filling the via opening. We form a trench pattern in the second dielectric layer. The trench pattern is comprised of trenches that are approximately orthogonal to the first level conductive lines. We fill the trenches with a conductive material to form supplemental second lines. We form second level conductive lines over the supplemental second lines and the plug.

Abstract: A method to form robust dual damascene interconnects by decoupling via and connective line trench filling has been achieved. A first dielectric layer is deposited overlying a silicon nitride layer. A shielding layer is deposited. The shielding layer, the first dielectric layer, and the silicon nitride layer are patterned to form via trenches. A first barrier layer is deposited to line the trenches. The via trenches are filled with a first copper layer by a single deposition or by depositing a seed layer and then electroless or electrochemical plating. The first copper layer is polished down to complete the vias. A second barrier layer is deposited. The second barrier layer is patterned to form via caps. A second dielectric layer is deposited. A capping layer is deposited. The capping layer and the second dielectric layer are patterned to form connective line trenches that expose a part of the via caps. A third barrier layer is deposited to line the connective line trenches.

Abstract: A new method of copper damascene metallization utilizing an additional oxide layer between the nitride and the barrier layers to prevent dishing of the copper line after CMP is described. An insulating layer is provided covering semiconductor device structures in and on a semiconductor substrate. A polish stop layer is deposited overlying the insulating layer. An oxide layer is deposited overlying the polish stop layer. An opening is etched through the oxide layer, the polish stop layer, and the insulating layer to one of the semiconductor device structures. A barrier metal layer is deposited over the surface of the oxide layer and within the opening. A copper layer is deposited over the surface of the barrier metal layer. The copper layer and the barrier metal layer not within the opening are polished away wherein the barrier metal layer polishes more slowly than the copper layer whereby dishing of the copper layer occurs.

Abstract: The invention relates to a method for transmitting packet data in a cellular system. The number of time slots in a TDMA frame dedicated for packet transmission varies according to transmission needs and each logical channel consisting of corresponding time slots in consecutive TDMA frames is independent of the other logical channels. A data packet is encoded in an information channel frame consisting of N-1 information bursts, and between the frames there can be an acknowledge/retransmission request burst (ARQ) reporting that a received frame was error-free or requesting retransmission. Thus, the information channel consists of repeated sequences of N bursts. Also disclosed are the structure of a packet paging burst (PP), packet random access burst (PRA), packet access grant burst (PAG), acknowledge/retransmission request burst (ARQ) as well as the use of the bursts in starting and maintaining the transmission.