Abstract: Large area chip functionality is tested at an intermediate level in the manufacturing process. A process sequence is implemented in which a layer of insulator material is deposited over the chip. This layer is then processed to selectively open areas over existing vias which are to be used for chip level testing. The other vias remain covered with insulator. A sacrificial metal level is then deposited on the insulator layer and patterned to create adequately large test pad areas connected to exposed vias. This metal layer and the insulator layer covering the other buried vias are removed after testing to re-establish the full via set. As an extension to this basic test process, test circuits can be formed around or beside the chip to be tested in the kerf areas separating the chip from other chips on the semiconductor wafer. Connections to the test circuits is with a sacrificial metal layer over an insulator layer. The sacrificial metal layer and insulator layer are removed after testing.

Abstract: A densely packed array of vertical semiconductor devices having pillars and methods of making thereof are disclosed. The array has rows of wordlines and columns of bitlines. The array has vertical pillars, each having two wordlines, one active and the other passing for each, cell. Two wordlines are formed per pillar on opposite pillar sidewalls which are along the row direction. The threshold voltage of the pillar device is raised on the side of the pillar touching the passing wordline, thereby permanently shutting off the pillar device during the cell operation and isolating the pillar from the voltage variations on the passing wordline. The isolated wordlines allow individual cells to be addressed and written via direct tunneling, in both volatile and non-volatile memory cell configurations. For Gbit DRAM application, stack or trench capacitors may be formed on the pillars, or in trenches surrounding the pillars, respectively.

Abstract: A multi-level memory cell capable of storing two or three bits of digital data occupies only four lithographic squares and requires only one or two logic level voltage sources, respectively. High noise immunity derives from integration of the multi-level signal in the memory cell directly from logic level digital signals applied to two capacitors (as well as the bit line for the eight level mode of operation) by using capacitors having different values in order to avoid digital-to-analog conversion during writing. The capacitors can be simultaneously written and read to reduce memory cycle time. Transistor channels and capacitor connections are formed on adjacent semiconductor pillars using plugs of semiconductor material between pillars as common gate structures and connections. Opposite surfaces of the pillars also serve as storage nodes with common capacitor plates formed by conformal deposition between rows of plugs and pillars.

Abstract: Wafer test and burn-in is accomplished with state machine or programmable test engines located on the wafer being tested. Each test engine requires less than 10 connections and each test engine can be connected to a plurality of chips, such as a row or a column of chips on the wafer. Thus, the number of pads of the wafer that must be connected for test is substantially reduced while a large degree of parallel testing is still provided. The test engines also permit on-wafer allocation of redundancy in parallel so that failing chips can be repaired after burn-in is complete. In addition, the programmable test engines can have their code altered so test programs can be modified to account for new information after the wafer has been fabricated. The test engines are used during burn-in to provide high frequency write signals to DRAM arrays that provide a higher effective voltage to the arrays, lowering the time required for burn-in.

Abstract: A semiconductor structure having a substrate, an insulator above a portion of the substrate, a conductor above the insulator; and at least two contact regions in the substrate on opposite sides of the portion of the substrate, wherein a voltage between the contact regions modulates a capacitance of the conductor.

Abstract: Wafer test and burn-in is accomplished with state machine or programmable test engines located on the wafer being tested. Each test engine requires less than 10 connections and each test engine can be connected to a plurality of chips, such as a row or a column of chips on the wafer. Thus, the number of pads of the wafer that must be connected for test is substantially reduced while a large degree of parallel testing is still provided. The test engines also permit on-wafer allocation of redundancy in parallel so that failing chips can be repaired after burn-in is complete. In addition, the programmable test engines can have their code altered so test programs can be modified to account for new information after the wafer has been fabricated. The test engines are used during burn-in to provide high frequency write signals to DRAM arrays that provide a higher effective voltage to the arrays, lowering the time required for burn-in.

Abstract: A multi-level memory cell capable of storing two or three bits of digital data occupies only four lithographic squares and requires only one or two logic level voltage sources, respectively. High noise immunity derives from integration of the multi-level signal in the memory cell directly from logic level digital signals applied to two capacitors (as well as the bit line for the eight level mode of operation) by using capacitors having different values in order to avoid digital-to-analog conversion during writing. The capacitors can be simultaneously written and read to reduce memory cycle time. Transistor channels and capacitor connections are formed on adjacent semiconductor pillars using plugs of semiconductor material between pillars as common gate structures and connections. Opposite surfaces of the pillars also serve as storage nodes with common capacitor plates formed by conformal deposition between rows of plugs and pillars.

Abstract: A multi-level memory cell capable of storing two or three bits of digital data occupies only four lithographic squares and requires only one or two logic level voltage sources, respectively. High noise immunity derives from integration of the multi-level signal in the memory cell directly from logic level digital signals applied to two capacitors (as well as the bit line for the eight level mode of operation) by using capacitors having different values in order to avoid digital-to-analog conversion during writing. The capacitors can be simultaneously written and read to reduce memory cycle time. Transistor channels and capacitor connections are formed on adjacent semiconductor pillars using plugs of semiconductor material between pillars as common gate structures and connections. Opposite surfaces of the pillars also serve as storage nodes with common capacitor plates formed by conformal deposition between rows of plugs and pillars.

Abstract: An assembly is provided that includes an interposer having first and second substantially flat, opposed surfaces, and at least one speed critical signal line extending directly through the interposer from the first surface to the second surface. A first IC is coupled to the first surface of the interposer and has a first external connection mechanism coupled to the at least one speed critical signal line. A second IC is coupled to the second surface of the interposer and has a first external connection mechanism coupled to the at least one speed critical signal line. Preferably at least one non-speed critical signal line is provided within the interposer and is coupled to a second external connection mechanism of the first IC and/or the second IC for delivering non-speed critical signals thereto or for receiving such signals therefrom.

Abstract: Wafer test and burn-in is accomplished with state machine or programmable test engines located on the wafer being tested. Each test engine requires less than 10 connections and each test engine can be connected to a plurality of chips, such as a row or a column of chips on the wafer. Thus, the number of pads of the wafer that must be connected for test is substantially reduced while a large degree of parallel testing is still provided. The test engines also permit on-wafer allocation of redundancy in parallel so that failing chips can be repaired after burn-in is complete. In addition, the programmable test engines can have their code altered so test programs can be modified to account for new information after the wafer has been fabricated. The test engines are used during burn-in to provide high frequency write signals to DRAM arrays that provide a higher effective voltage to the arrays, lowering the time required for burn-in.

Abstract: A first, “known good” reference off-chip driver circuit actuated by an initial logic program (IPL) input signal has an output lead connected as one of the inputs to a comparator circuit for providing a reference off-chip driver output signal. A second off-chip driver circuit including a plurality of “n” separate driver circuit paths connected to input signal and produces output signals connected to a common node to provide output driver signals to the common node. The common node is connected to the second input of the comparator circuit for comparison with the reference off-chip driver output signal from the first off-chip driver circuit to determine the operating state of the second off-chip driver circuit with respect to the operating state of the first off-chip driver circuit.

Abstract: An off-chip driver circuit including an enhancement PFET, a depletion PFET, a depletion NFET and an enhancement NFET connected in series. The large enhancement PFET and large enhancement NFET turn off the OCD in tri-state and to turn off the unused half of the OCD to prevent overlap current when driving a ‘0’ or a ‘1’. A first gate signal is applied to the gate of the enhancement PFET and a second gate signal is applied to the enhancement NFET. A fixed voltage is connected to the gate of the depletion NFET and ground to gate of the depletion PFET. An output signal is obtained from a node between the depletion PFET and depletion NFET devices. In another embodiment, a reflection/overshoot sensor 60 is added. The output of sensor is connected to the body of a depletion PFET and an NFET. The feedback from sensor is such that the threshold voltage of the depletion devices are made more positive if the sensor detects that the output is being over-driven.

Abstract: A densely packed array of vertical semiconductor devices having pillars and methods of making thereof are disclosed. The array has rows of wordlines and columns of bitlines. The array has vertical pillars, each having two wordlines, one active and the other passing for each cell. Two wordlines are formed per pillar on opposite pillar sidewalls which are along the row direction. The threshold voltage of the pillar device is raised on the side of the pillar touching the passing wordline, thereby permanently shutting off the pillar device during the cell operation and isolating the pillar from the voltage variations on the passing wordline. The isolated wordlines allow individual cells to be addressed and written via direct tunneling, in both volatile and non-volatile memory cell configurations. For Gbit DRAM application, stack or trench capacitors may be formed on the pillars, or in trenches surrounding the pillars, respectively.

Abstract: A method for fabricating an integrated circuit package or arrangement includes providing a carrier having a surface topography of projections or recesses for supporting individual semiconductor circuit chips having conversely matching bottom surface topographies to permit self-aligned positioning of the chip on the carrier. Chips are provided such that top faces of neighboring chips lie substantially in planes separated by a distance of greater than 0.0 .mu.m. The carrier is arranged and dimensioned such that the neighboring chips are separated by a gap G or spacing in a range of 1 .mu.m<G.ltoreq.100 .mu.m. A metallic interconnect is provided over the top faces and the gap. Preferably, the interconnect has a gradual slope over the gap.

Abstract: An embedded memory macro device includes a memory system and a logic circuit constructed on a common semiconductor substrate. The memory system and logic circuit communicate through a handshake procedure via a system data interlock signal. During read cycles the memory system uses the system data interlock signal to tell the logic circuit when data at memory system data outputs is valid. In the preferred embodiment, during write cycles the memory system uses the system data interlock signal to tell the logic circuit when data has been successfully written. The logic circuit needs to wait only until the system data interlock signal permits it to proceed. It then signals the memory system to reset the system data interlock signal and can immediately initiate a new read or write cycle.

Abstract: An integrated circuit package or arrangement includes a carrier having a surface topography of projections or recesses for supporting individual semiconductor circuit chips having conversely matching bottom surface topographies to permit self-aligned positioning of the chips on the carrier. Top faces of neighboring chips lie substantially in planes separated by a distance of greater than 0.0 .mu.m. The neighboring chips are separated by a gap G or spacing in a range of approximately 1 .mu.m<G.ltoreq.approximately 100 .mu.m. A metallic interconnect is disposed over the top faces and the gap. Preferably, the interconnect has a gradual slope over the gap.

Abstract: A method of forming a self-aligned halo-isolated well with a single mask is disclosed. First, a layer of resist is disposed over at least a portion of a substrate's surface. Then, an impurity of a first polarity type is implanted at an angle into the substrate through a gap in the layer of resist, thus forming a well having the impurity of the first polarity, which extends beneath the layer of resist. An impurity of a second polarity type is also implanted, using the same mask as previously used. The second implantation forms a well of the impurity of the second polarity disposed within the well of to impurity of the first polarity.

Abstract: Large area chip functionality is tested at an intermediate level in the manufacturing process. A process sequence is implemented in which a layer of insulator material is deposited over the chip. This layer is then processed to selectively open areas over existing vias which are to be used for chip level testing. The other vias remain covered with insulator. A sacrificial metal level is then deposited on the insulator layer and patterned to create adequately large test pad areas connected to exposed vias. This metal layer and the insulator layer covering the other buried vias are removed after testing to re-establish the full via set. As an extension to this basic test process, test circuits can be formed around or beside the chip to be tested in the kerf areas separating the chip from other chips on the semiconductor wafer. Connections to the test circuits is with a sacrificial metal layer over an insulator layer. The sacrificial metal layer and insulator layer are removed after testing.

Abstract: An integrated circuit package including a carrier having a surface topography of projections or recesses for supporting individual semiconductor circuit chips having a conversely matching bottom surface topography to permit self-aligned positioning of the chip on the carrier.

Abstract: A memory system that provides extra data bits without utilizing storage capacity. A first data word is fetched from memory and corrected to remove any single-bit errors. A second data word (which is a subset of the first data word as corrected) is then fetched, and new data correction bits (parity or ECC check bits) is generated for the second data word. Both the second data word and the newly-generated data correction bits are output. This structure amortizes the expense of in-system data correction over a greater data output, and over a smaller storage capacity relative to the data output.