Abstract: A bonded assembly includes an interposer; a semiconductor die that is attached to the interposer and including a planar horizontal bottom surface and a contoured sidewall; a high bandwidth memory (HBM) die that is attached to the interposer; and a dielectric material portion contacting the semiconductor die and the interposer. The contoured sidewall includes a vertical sidewall segment and a non-horizontal, non-vertical surface segment that is adjoined to a bottom edge of the vertical sidewall segment and is adjoined to an edge of the planar horizontal bottom surface of the semiconductor die. The vertical sidewall segment and the non-horizontal, non-vertical surface segment are in contact with the dielectric material portion. The contoured sidewall may provide a variable lateral spacing from the HBM die to reduce local stress in a portion of the HBM die that is proximal to the interposer.

Abstract: A dual-polarized antenna includes a ground plane, an inverted-F conductor unit with an inverted-F plane, an inverted-L conductor unit with an inverted-L plane and a stretched ground conductor unit with a T-shaped plane. The inverted-F plane is vertically connected to the inverted-L plane, the T-shaped plane and the ground plane respectively, and the T-shaped plane is vertically connected with the ground plane. Therefore, the inverted-F plane, the inverted-L plane and the stretched ground conductor unit correspond to each side of the ground plane respectively to form a dual-polarized radiation field.

Abstract: A dual-polarized antenna includes a ground plane, an inverted-F conductor unit with an inverted-F plane, an inverted-L conductor unit with an inverted-L plane and a stretched ground conductor unit with a T-shaped plane. The inverted-F plane is vertically connected to the inverted-L plane, the T-shaped plane and the ground plane respectively, and the T-shaped plane is vertically connected with the ground plane. Therefore, the inverted-F plane, the inverted-L plane and the stretched ground conductor unit correspond to each side of the ground plane respectively to form a dual-polarized radiation field.

Abstract: This invention provides a method for forming ribs in a plasma display panel (PDP). The PDP includes a glass substrate, and a plurality of address electrodes are formed on the glass substrate. A dielectric layer is formed above the address electrodes and the glass substrate. A plurality of sandblasting stoppers are formed on the dielectric layer, and the positions of these stoppers are corresponded to that of the address electrodes. The rib material layer is further formed to cover the dielectric layer and the sandblasting stoppers, and then a plurality of sand-resists are patterned on the rib material layer. By using the sand-resists as a mask, a sandblasting process is executed to form a plurality of ribs and expose the sandblasting stoppers. After removing the sand-resists and the sandblasting stoppers, the structures of the ribs are fixed by a sinter process.

Abstract: A sand blasting device utilized in a sand blasting process has a base, a passageway installed on the base, and a sand blasting nozzle installed above the passageway. A conducting carrier is mounted on the passageway and is capable of sliding along the passageway. The conducting carrier has a plate for supporting a substrate needing to be sand blasted, and a pair of first and second electrically conducting clippers respectively installed on a first side and a second side of the plate for fixing the substrate to the plate and removing electrostatic charges generated during the sand blasting process.

Abstract: This invention provides a rear plate of a plasma display panel (PDP) and the method for forming PDP ribs thereon. The address electrodes and the base plates are formed on a glass substrate. The address electrodes and the base plates are formed alternately. A rib material layer is formed over the address electrodes, the base plates and the glass substrate. A patterned mask layer is formed on the rib material layer. The rib material layer is further sandblasted to form the ribs according to the shape of the base plates. The rib material directly located on the glass substrate is easily removed because the adhesion between the rib material layer and the base plates is better than the adhesion between the rib material layer and the glass substrate.

Abstract: The present PDP includes a rear plate, a plurality of barrier ribs on the rear plate, and a front plate in parallel with the rear plate. The front plate includes a transparent dielectric layer, a plurality of joint notches on the transparent dielectric layer, and a protective layer on the transparent dielectric layer that covers the joint notches. The position of each of the joint notches is aligned with the position of one corresponding barrier rib, and each joint notch has a filler to affix within the joint notch corresponding the barrier rib. When the front plate is mounted onto the rear plate, the top of each of the barrier ribs of the rear plate is pushed through the protective layer and is embedded in the corresponding joint notch of the front plate. The filler within each of the joint notches fills the gap between the top of the barrier rib embedded in the joint notch and the joint notch so that the front plate is tightly fixed to the rear plate.

Abstract: This invention provides a rear plate of a plasma display panel (PDP) and the method for forming PDP ribs thereon. The address electrodes and the base plates are formed on a glass substrate. The address electrodes and the base plates are formed alternately. A rib material layer is formed over the address electrodes, the base plates and the glass substrate. A patterned mask layer is formed on the rib material layer. The rib material layer is further sandblasted to form the ribs according to the shape of the base plates. The rib material directly located on the glass substrate is easily removed because the adhesion between the rib material layer and the base plates is better than the adhesion between the rib material layer and the glass substrate.

Abstract: This invention provides a method for forming ribs in a plasma display panel (PDP). The PDP includes a glass substrate, and a plurality of address electrodes are formed on the glass substrate. A dielectric layer is formed above the address electrodes and the glass substrate. A plurality of sandblasting stoppers are formed on the dielectric layer, and the positions of these stoppers are corresponded to that of the address electrodes. The rib material layer is further formed to cover the dielectric layer and the sandblasting stoppers, and then a plurality of sand-resists are patterned on the rib material layer. By using the sand-resists as a mask, a sandblasting process is executed to form a plurality of ribs and expose the sandblasting stoppers. After removing the sand-resists and the sandblasting stoppers, the structures of the ribs are fixed by a sinter process.