Abstract: In various embodiments, circuits and semiconductor devices and structures and methods to manufacture these structures and devices are disclosed. In one embodiment, a bidirectional polarity, voltage transient protection device is disclosed. The voltage transient protection device may include a bipolar PNP transistor having a turn-on voltage of VBE1, a bipolar NPN transistor having a turn-on voltage of VBE2, and a field effect transistor (FET) having a threshold voltage of VTH, wherein a turn-on voltage VTO of the voltage transient protection device is approximately equal to the sum of VBE1, VBE2, and VTH, that is, VTO?VBE1+VBE2+VTH. Other embodiments are described and claimed.

Abstract: In various embodiments, semiconductor structures and methods to manufacture these structures are disclosed. In one embodiment, a semiconductor device includes a plurality of rectilinear structures, wherein the plurality of rectilinear structures comprise silicon dioxide and extend from a surface of a semiconductor material to a distance of at least about three microns or greater below the surface of the semiconductor material and wherein a first rectilinear structure of the plurality of rectilinear structures is perpendicular to, or substantially perpendicular to, a second rectilinear structure of the plurality of rectilinear structures. Other embodiments are described and claimed.

Abstract: In accordance with one or more embodiments, a semiconductor structure includes a semiconductor substrate, a first semiconductor material over the semiconductor substrate, and a second semiconductor material over a portion the first semiconductor material, wherein the second semiconductor material comprises silicon-germanium-carbon (SiGeC) and wherein the first semiconductor material is a silicon epitaxial layer. The semiconductor structure further includes an active device, wherein a portion of the active device is formed in the second semiconductor material and a dielectric structure extending from the first surface of the first semiconductor material into the semiconductor substrate through the first semiconductor material.

Abstract: In various embodiments, semiconductor structures and methods to manufacture these structures are disclosed. In one embodiment, a semiconductor device includes a plurality of rectilinear structures, wherein the plurality of rectilinear structures comprise silicon dioxide and extend from a surface of a semiconductor material to a distance of at least about three microns or greater below the surface of the semiconductor material and wherein a first rectilinear structure of the plurality of rectilinear structures is perpendicular to, or substantially perpendicular to, a second rectilinear structure of the plurality of rectilinear structures. Other embodiments are described and claimed.

Abstract: In various embodiments, circuits and semiconductor devices and structures and methods to manufacture these structures and devices are disclosed. In one embodiment, a bidirectional polarity, voltage transient protection device is disclosed. The voltage transient protection device may include a bipolar PNP transistor having a turn-on voltage of VBE1, a bipolar NPN transistor having a turn-on voltage of VBE2, and a field effect transistor (FET) having a threshold voltage of VTH, wherein a turn-on voltage VTO of the voltage transient protection device is approximately equal to the sum of VBE1, VBE2, and VTH, that is, VTO?VBE1+VBE2+VTH. Other embodiments are described and claimed.

Abstract: A method for forming a semiconductor device including a die attach surface having a first pedestal and a first semiconductor die having a first surface formed with a first cavity for mounting the first semiconductor die on the first pedestal. Further provision is made for the formation of a dielectric cavity in the semiconductor die, the first pedestal or both. The cavity allows for fields produced by electronic components disposed on the upper surface of the semiconductor die to penetrate into the dielectric cavity. Inclusion of a second pedestal on a common die attach surface and a second semiconductor die having second cavity for mounting provides for substantially coplanar precision alignment or the first and second semiconductor die.

Abstract: A method for forming a low dielectric constant insulator in a monolithic substrate and the dielectric formed by the method. The method includes formation and patterning of a mask on a silicon substrate followed by anisotropic etching of the silicon to provide a dense array of deep holes. Isotropic etching may be used to form a cavity beneath the dense array of holes and coupling to bottoms of the holes. Sides of the holes are then thermally oxidized. A conventional dielectric is then formed, sealing tops of the holes. The conventional dielectric is optionally densified. Conventional chemical-mechanical polishing then planarizes the dielectric and further conventional processing may be carried out on the wafer to form active circuitry together with passive components such as high Q inductors.

Abstract: A method for forming a low dielectric constant insulator in a monolithic substrate and the dielectric formed by the method. The method includes formation and patterning of a mask on a silicon substrate followed by anisotropic etching of the silicon to provide a dense array of deep holes. Isotropic etching may be used to form a cavity beneath the dense array of holes and coupling to bottoms of the holes. Sides of the holes are then thermally oxidized. A conventional dielectric is then formed, sealing tops of the holes. The conventional dielectric is optionally densified. Conventional chemical-mechanical polishing then planarizes the dielectric and further conventional processing may be carried out on the wafer to form active circuitry together with passive components such as high Q inductors.

Abstract: A method for forming a low dielectric constant insulator in a monolithic substrate and the dielectric formed by the method. The method includes formation and patterning of a mask on a silicon substrate followed by anisotropic etching of the silicon to provide a dense array of deep holes. Isotropic etching may be used to form a cavity beneath the dense array of holes and coupling to bottoms of the holes. Sides of the holes are then thermally oxidized. A conventional dielectric is then formed, sealing tops of the holes. The conventional dielectric is optionally densified. Conventional chemical-mechanical polishing then planarizes the dielectric and further conventional processing may be carried out on the wafer to form active circuitry together with passive components such as high Q inductors.

Abstract: A method for forming a low dielectric constant insulator in a monolithic substrate and the dielectric formed by the method. The method includes formation and patterning of a mask on a silicon substrate followed by anisotropic etching of the silicon to provide a dense array of deep holes. Isotropic etching may be used to form a cavity beneath the dense array of holes and coupling to bottoms of the holes. Sides of the holes are then thermally oxidized. A conventional dielectric is then formed, sealing tops of the holes. The conventional dielectric is optionally densified. Conventional chemical-mechanical polishing then planarizes the dielectric and further conventional processing may be carried out on the wafer to form active circuitry together with passive components such as high Q inductors.

Abstract: A method and an apparatus for suppressing muzzle blast and/or muzzle crack in a weapon. An apparatus for reducing muzzle blast upon discharge of one or more projectiles from a gun includes an outer shell and a first end cap adapted to be secured to a muzzle of a weapon and including provisions for detachably coupling to a first end of the outer shell. The apparatus further includes a second end cap adapted to be secured to a distal end of the outer shell and a plurality of baffles disposed between the first end cap and the second end cap. The plurality of baffles each comprise a bore section having an inner diameter no smaller than a bore of the muzzle and a baffle section coupled to the bore section, the baffle section extending from the bore section to the outer shell.

Abstract: A method for forming a low dielectric constant insulator in a monolithic substrate and the dielectric formed by a method. The method includes formation and patterning of a mask on a silicon substrate followed by anisotropic etching of the silicon to provide a dense array of deep holes. Isotropic etching may be used to form a cavity beneath the dense array of holes and coupling to bottoms of the holes. Sides of the holes are then thermally oxidized. A conventional dielectric is then formed, sealing tops of the holes. The conventional dielectric is optionally densified. Conventional chemical-mechanical polishing then planarizes the dielectric and further conventional processing may be carried out on the wafer to form active circuitry together with passive components such as high Q inductors.

Abstract: A method and an apparatus for suppressing muzzle blast, muzzle crack and/or over penetration in a weapon. A frangible shotshell payload comprising a cup having a portion divided into petals, a payload having a mass disposed in the cup and a cap disposed at, and melted into, tips of the petals. The frangible shotshell may include a cup or wad formed from high density polyethylene. The cap may be formed from a disc of low density polyethylene having a diameter of 0.625″.

Abstract: A semiconductor device (10) is formed in a pedestal structure (16) overlying a semiconductor substrate (11). The semiconductor device (10) includes a source region (44) and a drain region (45) that contact the corners (13) of the pedestal structure (16). Electrical connection to the source region (44) and the drain region (45) is provided by a conductive layer (28) that contacts the sides (12) and corners (13) of the pedestal structure (16).

Abstract: The disclosed protection circuit which is suitable for providing protection of transistors included in integrated circuits such as regulators and power amplifiers, includes thermal shutdown, safe area and current control circuits. The current control portion includes a sense transistor connected substantially in parallel with the transistor to be protected. In monolithic integrated circuit applications, the sense transistor has an emitter area that is a predetermined ratio of the emitter area of the protected transistor. A "sense resistor" is connected to the sense transistor and develops a control signal which is proportional to the instantaneous current being conducted by the protected transistor. A threshold circuit is coupled between the sense resistor and the drive circuit for the protected transistor and responds to the magnitude of the control signal crossing a predetermined threshold to remove or reduce the drive to the protected transistor.