Abstract: A printed circuit board is fabricated so contacts for tight-pitch components are at an angle with respect to the bundles of glass fibers in the epoxy-glass printed circuit board such that adjacent component contacts do not contact the same bundle of glass fibers. This angle may be accomplished by manufacturing a printed circuit board panel with the glass fibers at an angle with respect to its edges. This angle may also be accomplished by placing parts on a printed circuit board panel that has a traditional X-Y orthogonal weave of glass fiber bundles at an angle with respect to the edges of the panel. This angle may also be accomplished by starting with a traditional panel that has an X-Y orthogonal weave, laying out parts on the panel along the X-Y weave, then placing components on the parts at an angle with respect to the edges of the parts.

Abstract: A printed circuit board is fabricated so contacts for tight-pitch components are at an angle with respect to the bundles of glass fibers in the epoxy-glass printed circuit board such that adjacent component contacts do not contact the same bundle of glass fibers. This angle may be accomplished by manufacturing a printed circuit board panel with the glass fibers at an angle with respect to its edges. This angle may also be accomplished by placing parts on a printed circuit board panel that has a traditional X-Y orthogonal weave of glass fiber bundles at an angle with respect to the edges of the panel. This angle may also be accomplished by starting with a traditional panel that has an X-Y orthogonal weave, laying out parts on the panel along the X-Y weave, then placing components on the parts at an angle with respect to the edges of the parts.

Abstract: A printed circuit board is fabricated so contacts for tight-pitch components are at an angle with respect to the bundles of glass fibers in the epoxy-glass printed circuit board such that adjacent component contacts do not contact the same bundle of glass fibers. This angle may be accomplished by manufacturing a printed circuit board panel with the glass fibers at an angle with respect to its edges. This angle may also be accomplished by placing parts on a printed circuit board panel that has a traditional X-Y orthogonal weave of glass fiber bundles at an angle with respect to the edges of the panel. This angle may also be accomplished by starting with a traditional panel that has an X-Y orthogonal weave, laying out parts on the panel along the X-Y weave, then placing components on the parts at an angle with respect to the edges of the parts.

Abstract: A printed circuit board is fabricated so contacts for tight-pitch components are at an angle with respect to the bundles of glass fibers in the epoxy-glass printed circuit board such that adjacent component contacts do not contact the same bundle of glass fibers. This angle may be accomplished by manufacturing a printed circuit board panel with the glass fibers at an angle with respect to its edges. This angle may also be accomplished by placing parts on a printed circuit board panel that has a traditional X-Y orthogonal weave of glass fiber bundles at an angle with respect to the edges of the panel. This angle may also be accomplished by starting with a traditional panel that has an X-Y orthogonal weave, laying out parts on the panel along the X-Y weave, then placing components on the parts at an angle with respect to the edges of the parts.

Abstract: A method and structures are provided for implementing enhanced reliability for printed circuit board high power dissipation applications. An external return current member provides a return current path outside of the printed circuit board, thereby minimizing power dissipation within the printed circuit board. The external return current member can be implemented with an associated stiffener formed of electrically conductive material. Alternatively, the external return current member can be implemented with a sheet of electrically conductive material with an insulator provided between the sheet and the associated stiffener.

Abstract: A method and apparatus are provided for implementing finished printed circuit board high potential testing to identify latent defects. A printed circuit board to be tested includes adjacent surface features having opposing applied voltages. An electrically non-conductive material is disposed between at least some of said adjacent surface features. A predefined voltage potential is applied between predefined power connections of the printed circuit board to identify the latent defects. The electrically non-conductive material prevents surface arcing between the adjacent surface features at the applied predefined voltage potential.

Abstract: A method and apparatus are provided for implementing finished printed circuit board high potential testing to identify latent defects. A printed circuit board to be tested includes adjacent surface features having opposing applied voltages. An electrically non-conductive material is disposed between at least some of said adjacent surface features. A predefined voltage potential is applied between predefined power connections of the printed circuit board to identify the latent defects. The electrically non-conductive material prevents surface arcing between the adjacent surface features at the applied predefined voltage potential.