Abstract: A substrate having a bending region and conductive paths formed therethrough is provided. In one embodiment, conductive paths are formed from a first region on the bottom surface of the substrate, through the bending region and to a second region on the top surface of the substrate. Methods of using the flexible substrate are also provided.

Abstract: A circuit module testing apparatus and method are provided. According to various embodiments, a circuit module testing apparatus includes a printed circuit board, a socket receptacle adapted to be connected to the printed circuit board, a socket having pins on a first side, the pins adapted to be removably inserted into the socket receptacle, the socket adapted to receive a circuit module for testing, and a test circuit board soldered to the first side of the socket, the test circuit board having selected pins shorted for testing the module and clipped to prevent engagement with the socket receptacle. According to one embodiment, the test circuit board has selected pins shorted for interconnect built-in self-testing (IBIST). Other aspects and embodiments are provided herein.

Abstract: A substrate having a bending region and conductive paths formed therethrough is provided. In one embodiment, conductive paths are formed from a first region on the bottom surface of the substrate, through the bending region and to a second region on the top surface of the substrate. Methods of using the flexible substrate are also provided.

Abstract: Methods and apparatus for testing a semiconductor device are disclosed. A flexible circuit interposer includes a flexible circuit substrate which allows in-situ probing of an attached device during, for example, circuit debugging, assembly qualification, and the like. A first set of pads is configured in a predetermined pattern on the bottom surface of a flexible substrate. Similarly, a second set of pads is configured in substantially the same pattern on the top surface of the flexible substrate, wherein each of the pads in the second set of pads is electrically continuous with a corresponding pad in the first set of pads. A third set of pads is configured in the same pad pattern on the top surface of the flexible substrate. One or more conductive traces are formed to connect one or more pads in the first set of pads with spatially-corresponding pads in the third set of pads.

Abstract: A circuit module testing apparatus and method are provided. According to various embodiments, a circuit module testing apparatus includes a printed circuit board, a socket receptacle adapted to be connected to the printed circuit board, a socket having pins on a first side, the pins adapted to be removably inserted into the socket receptacle, the socket adapted to receive a circuit module for testing, and a test circuit board soldered to the first side of the socket, the test circuit board having selected pins shorted for testing the module and clipped to prevent engagement with the socket receptacle. According to one embodiment, the test circuit board has selected pins shorted for interconnect built-in self-testing (IBIST). Other aspects and embodiments are provided herein.

Abstract: A flexible circuit interposer includes a flexible circuit substrate which allows in-situ probing of an attached device during, for example, circuit debugging, assembly qualification, and the like. A first set of pads (and optionally a fourth set of pads) is configured in a predetermined pattern on the bottom surface of a flexible substrate. Similarly, a second set of pads is configured in substantially the same pattern on the top surface of the flexible substrate, wherein the pads in the second set of pads is electrically continuous with a pad in the first set of pads. A third set of pads is configured in substantially the same pattern on the top surface of the flexible substrate. One or more conductive traces are formed to connect one or more pads in the third set of pads with one or more pads in the first or the second set of pads.

Abstract: Methods and apparatus for testing a semiconductor device are disclosed. A flexible circuit interposer includes a flexible circuit substrate which allows in-situ probing of an attached device during, for example, circuit debugging, assembly qualification, and the like. A first set of pads is configured in a predetermined pattern on the bottom surface of a flexible substrate. Similarly, a second set of pads is configured in substantially the same pattern on the top surface of the flexible substrate, wherein each of the pads in the second set of pads is electrically continuous with a corresponding pad in the first set of pads. A third set of pads is configured in the same pad pattern on the top surface of the flexible substrate. One or more conductive traces are formed to connect one or more pads in the first set of pads with spatially-corresponding pads in the third set of pads.

Abstract: A flexible circuit interposer includes a flexible circuit substrate which allows in-situ probing of an attached device during, for example, circuit debugging, assembly qualification, and the like. In accordance with one embodiment, a first set of pads (for example, bond pads configured to interface with solder balls) are configured in a predetermined pattern on the bottom surface of a flexible substrate. Similarly, a second set of pads are configured in substantially the same pattern on the top surface of the flexible substrate, wherein each of the pads in the second set of pads is electrically continuous with a corresponding pad in the first set of pads. A third set of pads are configured in the same pad pattern on the top surface of the flexible substrate. One or more conductive traces are formed to connect one or more pads in the first set of pads with spatially-corresponding pads in the third set of pads.

Abstract: A flexible circuit interposer includes a flexible circuit substrate which allows in-situ probing of an attached device during, for example, circuit debugging, assembly qualification, and the like. In accordance with one embodiment, a first set of pads (for example, bond pads configured to interface with solder balls) are configured in a predetermined pattern on the bottom surface of a flexible substrate. Similarly, a second set of pads are configured in substantially the same pattern on the top surface of the flexible substrate, wherein each of the pads in the second set of pads is electrically continuous with a corresponding pad in the first set of pads. A third set of pads are configured in the same pad pattern on the top surface of the flexible substrate. One or more conductive traces are formed to connect one or more pads in the first set of pads with spatially-corresponding pads in the third set of pads.