Abstract: An SRAM memory cell structure utilizing a read driver transistor and a column select write transistor, and a method of operating the same. The SRAM memory cell comprises first and second cross-coupled inverters, having a first and second latch nodes, respectively. The cell further comprises a first write pass transistor connected between the first latch node of the first inverter and a first pass node, and a first wordline pass transistor connected between the first pass node and a first bitline. The cell also includes a first read driver connected between the first pass node and a source potential, and a control terminal of the first read driver connected to the second latch node of the second inverter.

Abstract: A method of operating a memory circuit to reduce standby current is disclosed. The method includes applying a first voltage (Vdd) to a power terminal (224) of a memory cell having a first (612) and a second (614) data terminal. A data bit is stored in a memory cell (600,602,604,606). A second voltage (VDA) different from the first voltage is applied to the power terminal. A third voltage (Ground) is applied to the first and second data terminals. The first voltage is applied to the power terminal.

Abstract: An integrated circuit interconnect structure is provided, along with a method of forming the integrated circuit interconnect structure. A semiconductor material layer has an elongate trench formed therein. A conducting region is disposed in the trench. An insulator region overlies the conducting region. One or more contact regions are disposed through the insulator region to contact the conducting region.

Abstract: A power MOSFET device formed in a face of a semiconductor layer of a first conductivity type is provided. A first, second and third source region of a second conductivity type are formed in the face of the semiconductor layer within a moat and adjacent to its edges. A source conductor is insulatively disposed adjacent the face of the semiconductor layer and contacts the first, second and third source regions at a plurality of locations. A first and second drain region of a second conductivity type is also formed in the face of the semiconductor layer disposed spaced from and between the first and second source regions and the second and third source regions, respectively. A drain conductor is insulatively disposed adjacent the face of the semiconductor layer and contacts the first and second drain regions at a plurality of locations.

Abstract: In a video-type computer system and the like, an improved memory circuit is provided for adapting the system to CRT screens having different resolutions. The memory circuit includes a bit-mapped RAM unit or chip having sufficient cells to accommodate any CRT screen sought to be used, and also a serial shift register having taps at a plurality of different locations corresponding to different columns of cells in the RAM unit. When the RAM unit is in serial mode, a row of data is transferred into the serial shift register. Then the column address applied to the RAM unit is used to instruct and actuate a suitable decoder circuit to select the tap appropriate to unload the portion of the serial shift register containing the data bits of interest.

Abstract: A transistor device 10 formed in a semiconductor layer 12 is disclosed herein. A first source/drain region 14 is formed in the semiconductor layer 12. A second source/drain region 16 is also formed in the semiconductor layer 12 and is spaced from the first source/drain region 14 by a channel region 18. The second source/drain region 16 includes (1) a lightly doped portion 16b adjacent the channel region 18 and abutting the top surface, (2) a main portion 16a abutting the top surface and spaced from the channel region 18 by the lightly doped portion 16b, and (3) a deep portion 16c formed within the layer 12 and spaced from the top surface by the lightly doped portion 16b and the main portion 16a. A gate electrode 20 is formed over at least a portion of the channel region 18 and insulated therefrom.

Abstract: A circuit for producing a power up detection signal for use in, and being integrated onto the same semiconductor substrate as a dynamic memory device is disclosed. The circuit has a first node and a circuit to promote a low voltage on the first node when a voltage obtained from a supply voltage applied to the dynamic memory is below a predetermined level. It has a second node from which the power up detection signal can be removed. Included is a circuit to promote the obtained voltage on said second node when the obtained voltage is below the predetermined level, whereby the power up detection signal can be used to isolate the obtained voltage from the dynamic memory device. Included is a circuit to maintain a high voltage on the first node when the obtained voltage exceeds the predetermined level.

Abstract: A power MOSFET device formed in a face of a semiconductor layer of a first conductivity type is provided. A first, second and third source region of a second conductivity type are formed in the face of the semiconductor layer within a moat and adjacent to its edges. A source conductor is insulatively disposed adjacent the face of the semiconductor layer and contacts the first, second and third source regions at a plurality of locations. A first and second drain region of a second conductivity type is also formed in the face of the semiconductor layer disposed spaced from and between the first and second source regions and the second and third source regions, respectively. A drain conductor is insulatively disposed adjacent the face of the semiconductor layer and contacts the first and second drain regions at a plurality of locations.

Abstract: In a video computer system having a dual-port bit-mapped RAM unit incorporating a shift register, provision is made for coupling data between column lines and the shift register, and for simultaneously preventing any column line from being coupled with the random data output terminal of the RAM unit. Accordingly, this prevents two or more different data bits from appearing simultaneously from the RAM unit and causing confusion as to which is the valid signal and which is a spurious signal.

Abstract: In a video-type computer system and the like, an improved memory circuit is provided for adapting the system to CRT screens having different resolutions. The memory circuit includes a bit-mapped RAM unit or chip having sufficient cells to accommodate any CRT screen sought to be used, and also a serial shift register having taps at a plurality of different locations corresponding to different columns of cells in the RAM unit. When the RAM unit is in serial mode, a row of data is transferred into the serial shift register. Then the column address applied to the RAM unit is used to instruct and actuate a suitable decoder circuit to select the tap appropriate to unload the portion of the serial shift register containing the data bits of interest.

Abstract: A circuit to generate a power up reset pulse for a semiconductor device, such as a dynamic random access memory (DRAM) that may utilize an on chip voltage generator is disclosed. The circuit generates a positive going pulse when the external power supply ramps up. The pulse disappears when the voltage level within the device reaches a predetermined value of the external supply voltage. The circuit includes a CMOS inverter that is biased between the external voltage and ground and has its input coupled to the internally regulated voltage. The gate of a pull down transistor may couple the input of the CMOS inverter to the internally regulated voltage. A pull up transistor that is biased by the external voltage and whose gate is connected to the output of the CMOS inverter, is connected to the input of the CMOS inverter. Other elements may be added to enhance the circuits performance.

Abstract: A dynamic read/write memory cell for the one transistor N-channel silicon gate type is made by an improved process employing selective oxidation of polysilicon using. PN junction capacitors. A relatively flat surface results from the process, which is favorable to patterning small geometries. The PN junction storage capacitors have improved alpha particle protection. Metal-to-polysilicon gate contacts are made at silicide areas over polysilicon gates; the silicide lowers resistance of the poly elements.

Abstract: A dynamic random access memory cell array is disclosed which has storage capacitors and access transistors formed on the sidewalls of pillars created by trenches etched into the face of a semiconductor bar. A storage capacitor for a cell uses the sidewalls of the pillar as one plate and a polysilicon plug or web as the other plate. The channel of each access transistor is formed in the upper part of the sidewall of only a portion of the pillar, using an upper edge of the capacitor region as the source region of the transistor and having an N+ drain region at the top of the pillar. A cross-point array is made possible by merging two adjacent wordlines as a pair of overlying conductor strips extending along the face over the trenches, between pillars, and forming the transistor gates by alternate protrusions from these strips, extending down into the trenches at the channel area.

Abstract: The described embodiments of the present invention provide a dynamic random access memory cell and array. The memory cell provides a three transistor storage device where the storage signal is stored on the gate of a storage transistor. All three transistors are integrated into a trench thereby providing the density equal to that of the densest of modern day DRAM cells. By using the three transistor concept, the first embodiment of the present invention provides a gain for the stored charge. Because the storage transistor amplifies the stored charge, the reduced capacitance of ultra-dense DRAM cells is overcome and adequate data sensing may be accomplished using capacitances much smaller than those useful in the single transistor, single capacitor DRAM cell.

Abstract: A dynamic random access memory cell array is disclosed which has storage capacitors and access transistors formed on the sidewalls of pillars created by trenches etched into the face of a semiconductor bar. A storage capacitor for a cell uses the sidewalls of the pillar as one plate and a polysilicon plug or web as the other plate. The channel of each access transistor is formed in the upper part of the sidewall of only a portion of the pillar, using an upper edge of the capacitor region as the source region of the transistor and having an N+ drain region at the top of the pillar. A cross-point array is made possible by merging two adjacent wordlines as a pair of overlying conductor strips extending along the face over the trenches, between pillars, and forming the transistor gates by alternate protrusions from these strips, extending down into the trenches at the channel area.

Abstract: In video computer system having a dual-port bit-mapped RAM unit incorporating a shift register, provision is made for coupling data between column lines and the shift register, and for simultaneously preventing any column line from being coupled with the random data output terminal of the RAM unit. Accordingly, this prevents two or more different data bits from appearing simultaneously from the RAM unit and causing confusion as to which is the valid signal and which is a spurious signal.

Abstract: In a video-type computer system and the like, an improved memory circuit is provided for adapting the system to CRT screens having different resolutions. The memory circuit includes a bit-mapped RAM unit or chip having sufficient cells to accommodate any CRT screen sought to be used, and also a shift register having taps at a plurality of different locations corresponding to different columns of cells in the RAM unit. When the RAM unit is in serial mode, column address to the RAM unit is also used to instruct and actuate a suitable decoder circuit to select the tap appropriate to unload the portion of the shift register containing only the data bits of interest.

Abstract: In video computer system having a dual-port bit-mapped RAM unit incorporating a shift register, provision is made for coupling data between column lines and the shift register, and for simultaneously preventing any column line from being coupled with the random data output terminal of the RAM unit. Accordingly, this prevents two or more different data bits from appearing simultaneously from the RAM unit and causing confusion as to which is the valid signal and which is a spurious signal.

Abstract: In a video computer system having a RAM chip with a shift register connected to its serial output terminal and actuated by a first clock circuit, a second different clock circuit is included to cause the data bit in the first stage of the register to also appear at the serial output terminal of the chip. Accordingly, signals from the first clock circuit will then sequentially transfer data bits from the shift register, to the output terminal of the RAM chip, without omitting or losing a clock cycle, or a portion thereof.

Abstract: In a computer system, an improved memory circuit is provided for accomodating video display circuits with CRT screens having different resolutions. The memory circuit includes a bit-mapped RAM unit or chip having sufficient cells to accomodate any CRT screen intended to be used, and it further includes a serial shift register having a plurality of taps at locations corresponding to different preselected columns of cells in the chip. In the system, provision is included for selecting taps to unload only the portion of the shift register containing the bits of interest, whereby unused portions of the chip may be effectively excluded and the time for transferring data of interest to the CRT screen is reduced.