Abstract: A semiconductor memory device includes a die having a semiconductor memory circuit formed thereon and a plurality of pads at the periphery of the die that are electrically coupled to the circuit. Electrically conductive leads have a pin end for external coupling, and a free end electrically connected by bond wires to certain pads on the die. An encapsulating material such as epoxy encapsulates the die, bond wires and free ends of the leads to form a packaged chip. A superfluous lead such as an address lead unused during testing, redundant voltage supply lead or non-connected lead is coupled, by means of a bond wire, to a pad that, in turn, is coupled through a switching transistor to a common cell plate or DVC2 node for all storage capacitors in the memory circuit. External power can thereby be provided to the DVC2 node to simultaneously apply a high voltage to this node of all capacitors during stress testing of the chip.

Abstract: A semiconductor memory device includes a die having a semiconductor memory circuit formed thereon and a plurality of pads at the periphery of the die that are electrically coupled to the circuit. Electrically conductive leads have a pin end for external coupling, and a free end electrically connected by bond wires to certain pads on the die. An encapsulating material such as epoxy encapsulates the die, bond wires and free ends of the leads to form a packaged chip. A superfluous lead such as an address lead unused during testing, redundant voltage supply lead or non-connected lead is coupled, by means of a bond wire, to a pad that, in turn, is coupled through a switching transistor to a common cell plate or DVC2 node for all storage capacitors in the memory circuit. External power can thereby be provided to the DVC2 node to simultaneously apply a high voltage to this node of all capacitors during stress testing of the chip.

Abstract: A memory self-stress mode capable of use during wafer burn-in such as for dynamic random access memory (DRAM) integrated circuits. A burn-in power supply voltage and ground voltage delivered to a common node of a plurality of memory cell storage capacitors and to an equilibrate node coupled to bit lines. An all row high test cycles word lines between a binary low logic level and a binary high logic level, thereby stressing the dielectric of the memory cell storage capacitors by imposing stress voltages of differing polarity. A half row high test cycles alternate word lines of a word line sequence thereby stressing undesired short circuit connections between adjacent word lines.

Abstract: A semiconductor memory device includes a die having a semiconductor memory circuit formed thereon and a plurality of pads at the periphery of the die that are electrically coupled to the circuit. Electrically conductive leads have a pin end for external coupling, and a free end electrically connected by bond wires to certain pads on the die. An encapsulating material such as epoxy encapsulates the die, bond wires and free ends of the leads to form a packaged chip. A superfluous lead such as an address lead unused during testing, redundant voltage supply lead or non-connected lead is coupled, by means of a bond wire, to a pad that, in turn, is coupled through a switching transistor to a common cell plate or DVC2 node for all storage capacitors in the memory circuit. External power can thereby be provided to the DVC2 node to simultaneously apply a high voltage to this node of all capacitors during stress testing of the chip.

Abstract: A method and apparatus for testing semiconductor memory chips, such as DRAMs, having a plurality of memory cells or bits. Each memory chip has a unique identifier stored in a database. Tests are performed on the memory chips and when a memory chip fails a test, the memory chip is placed in a repair bin and a test identifier is stored in the database in association with the memory chip identifier. In order to repair the memory chip, failed tests are read out of the database and such tests are again performed on the failed memory chip in order to determine which memory cell in the memory chip is faulty. The failed memory cells are then repaired.

Abstract: A memory self-stress mode capable of use during wafer burn-in such as for dynamic random access memory (DRAM) integrated circuits. A burn-in power supply voltage and ground voltage delivered to a common node of a plurality of memory cell storage capacitors and to an equilibrate node coupled to bit lines. An all row high test cycles word lines between a binary low logic level and a binary high logic level, thereby stressing the dielectric of the memory cell storage capacitors by imposing stress voltages of differing polarity. A half row high test cycles alternate word lines of a word line sequence thereby stressing undesired short circuit connections between adjacent word lines.

Abstract: A sense amplifier senses and stores data from a memory cell in an array of memory cells arranged in rows and columns. The sense amplifier includes a sense circuit having a pair of first and second complementary digit lines which senses a voltage differential between the first and second complementary digit lines and in response to the sensed voltage differential drives the first and second complementary digit lines to voltage levels corresponding to complementary logic states. An isolation circuit is coupled between the pair of first and second complementary digit lines of the sense amplifier and a pair of first and second complementary digit lines associated with a column of memory cells. The isolation circuit is operable to couple the first complementary digit line of the sense amplifier to the first complementary digit line of the column of memory cells and the second complementary digit line of the sense amplifier to the secondary complementary digit line of the column of memory cells.

Abstract: A semiconductor memory device includes a die having a semiconductor memory circuit formed thereon and a plurality of pads at the periphery of the die that are electrically coupled to the circuit. Electrically conductive leads have a pin end for external coupling, and a free end electrically connected by bond wires to certain pads on the die. An encapsulating material such as epoxy encapsulates the die, bond wires and free ends of the leads to form a packaged chip. A superfluous lead such as a redundant voltage supply lead or non-connected lead is coupled, by means of a bond wire, to a pad that, in turn, is coupled to a voltage boosting circuit on the die. The voltage boosting circuit is coupled to row lines in the semiconductor memory circuit to provide boosted voltage thereto. External power can thereby be provided to the row lines, through the voltage boosting circuits, to simultaneously enable at least half of the row lines during stress testing of the chip.