A 288K CMOS pseudostatic RAM

A 288-kb pseudostatic RAM with high density and ease of use has been fabricated using polycide-gate n-well CMOS technology. For high speed and low power dissipation, a half-V/SUB cc/ precharging scheme, with CMOS back biased to V/SUB BB/, was used. For easier use, an address transition detector, plus auto-refresh and self-refresh, were adopted. Organized as 32K/spl times/9 bits, the RAM occupies an area of 55 mm/SUP 2/ and has a cell size of 6.8/spl times/13.6 /spl mu/m/SUP 2/, which was achieved using the 2-/spl mu/m design rule. A typical address access time is 125 ns, and the operating current is 60 mA at a 125-ns cycle time. Standby power is 2 mA.     

A 1-Mbit CMOS DRAM with fast page mode and static column mode

A 1-Mb words/spl times/1-bit CMOS dynamic RAM fabricated with an advanced n-well CMOS technology is described. More than 2.2 million devices are integrated on a 62.5 mm/SUP 2/ silicon chip by utilizing an n-channel memory cell of triple-level poly Si structure and a 1.2-/spl mu/m feature size VLSI process. Novel CMOS circuit design techniques such as the half V/SUB cc/ bitline precharge scheme are successfully applied to realize the excellent performance combination of high-speed operation and low-power dissipation. The CMOS peripheral circuitry is capable of the new operating functions, fast page mode, or static column mode with metal mask options. The typical RAS access time is 56 ns, the active current is 30 mA at a 190-ns cycle time, and the standby current is 0.2 mA.     

1-Mbit virtually static RAM

The 1-Mb RAM utilizes a one-transistor, one-capacitor dynamic memory cell. Since all the refresh-related operations are done on chip, the RAM acts as a virtually static RAM (VSRAM). The refresh operations are merged into the normal operation, called a background refresh, the main feature of the VSRAM. Since the fast operation of the core part of the RAM is crucial to minimize the access-time overhead by the background refresh, 16 divided bit lines and parallel processing techniques are utilized. Novel hot-carrier resistant circuits are applied selectively to bootstrapped nodes for high hot-carrier reliability. N-channel memory cells are embedded in a p-well, which gives a low soft error rate of less than 10 FIT. 1-/spl mu/m NMOSFETs with moderately lightly doped drain structures offer fast 5-V operation with sufficient reliability. An advanced double-level poly-Si and double-level Al twin-well CMOS technology is developed for fast circuit speed and high packing density. The memory cell size is 3.5/spl times/8.4 /spl mu/m/SUP 2/, and the chip size is 5.99/spl times/13.8 mm./SUP 2/. Address access time is typically 62 ns, with 21-mA operating current and 30-/spl mu/A standby current at room temperature.     

A 20 ns 64K (4K/spl times/16) NMOS RAM

A 64K (4K/spl times/16) NMOS RAM is described which uses new circuit techniques and design concepts to achieve an average nominal access time of 20 ns. The RAM was built using a relatively straightforward NMOS technology with single-level metal, single-level polycide, an average minimum feature size of 1.7 /spl mu/m, and an effective channel length of 1.2 /spl mu/m. The chip is organized physically into four 16K blocks. Cell area is 292 /spl mu/m/SUP 2/ with a chip area of 32.6 mm/SUP 2/. A four-device split-wordline cell was used to reduce the wordline delay. Chip organization, simplified clocking and timing, and new circuits were especially important for improved performance. An address buffer with internal reference, a switched decoupled bootstrapped decoder, and a self-timed sense amplifier are described.     

A 45-ns 256K CMOS static RAM with a tri-level word line

A 32K words by 8-bit static RAM fabricated with a CMOS technology is described. The key feature of the RAM is a tri-level word-line, in which an automatic power down by a pulsed word-line in the READ cycle and a power saving by a middle-level word-line in the WRITE cycle are combined. This circuit technique minimizes bitline swing, shortens the precharging time, and depresses the transient current. An improved address transition detection circuit reduces the chip select access time. The sense amplifier uses internally synchronized signals for improved operation. The RAM has a typical access time of 45 ns with an active power dissipation of 7 mW. The peak transient current is less than 40 mA. A double-level polysilicon technology with a 1.3-/spl mu/m design rule allowed layout of the NMOS memory cell in an area of 116.0 /spl mu/m/SUP 2/ and the die in 49.6 mm/SUP 2/.     

A 35-ns 128K/spl times/8 CMOS SRAM

A 128 K/spl times/8-b CMOS SRAM with TTL input/output levels and a typical address access time of 35 ns is described. A novel data transfer circuit with dual threshold level is utilized to obtain improved noise immunity. A divided-word-line architecture and an automatic power reduction function are utilized to achieve a low operational power of 10 mW at 1 MHz, and 100 mW at 10 MHz. A novel fabrication technology, including improved LOCOS and highly stable polysilicon loads, was introduced to achieve a compact memory cell which measures 6.4/spl times/11.5 /spl mu/m/SUP 2/. Typical standby current is 2 /spl mu/A. The RAM was fabricated with 1.0-/spl mu/m design rules, double-level polysilicon, and double-level aluminum CMOS technology. The chip size of the RAM is 8/spl times/13.65 mm/SUP 2/.     

A 256K dynamic RAM with page-nibble mode

A 5-V 256K /spl times/ 1 bit NMOS dynamic RAM with page-nibble mode is designed and fabricated using 2-/spl mu/m design rules and folded bit-line configuration. Molybdenum disilicided polysilicon is used as the second-level gate to reduce the word-line signal delay. A large 98 /spl mu/m/SUP 2/ cell with Hi-C structure stores the signal charge of 210 fC and provides this memory with wide operating margin. The device is immune to voltage bumping and uses laser programmable redundancy. Typical RAS/CAS access times are 80 ns/40 ns. An average operating current of 50 mA with 80 mA peak at 230 ns cycle time and standby current of 2 mA are achieved.     

A 16 DIP, 64 kbit, static MOS-RAM

A 64K/spl times/1 bit fully static MOS-RAM has been fabricated. For the purpose of replacement of 64 kbit dynamic RAM, this static RAM has been designed to be assembled in a standard 300 mil 16 pin DIP. It is the first time address multiplexing has been in static RAMs. The device with multiple addressing and improved row decoder employs a double poly Si layer and a 1.5 /spl mu/m design rule which is achieved by advanced process technology. As a result, the RAM has a 11.0 /spl mu/m/spl times/26.5 /spl mu/m (291.5 /spl mu/m/SUP 2/) cell size and a 3.84 mm/spl times/7.40 mm (28.40 mm/SUP 2/) chip size. The address access time is less than 150 ns with an active power dissipation of 400 mW.     

A 60-ns 4-Mbit CMOS DRAM with built-in selftest function

A 4-Mb CMOS DRAM measuring 6.9/spl times/16.11 mm/SUP 2/ has been fabricated using a 0.9-/spl mu/m twin-tub CMOS, triple-poly, single-metal process technology. N-channel depletion-type trench cells, 2.5/spl times/5.5 /spl mu/m/SUP 2/ each, are incorporated in a p-well. A novel built-in selftest (BIST) function which enables a simultaneous and automatic test of all the memory devices on a board is introduced to reduce the RAM testing time in a system. This function is effective for system maintenance and a daily start-up test even in a relatively small system. A high-speed low-power 4-Mb CMOS DRAM with 60-ns access time, 50-mA active current, and 200-/spl mu/A standby current is realized by widening the DQ line bus which connects the sense amplifiers with DQ buffers, thereby reducing the parasitic capacitance of the DQ lines.     

A high-speed 16-kbit n-MOS random-access memory

This paper presents one version of a high-speed 16-kbit dynamic MOS random-access memory (RAM). This memory utilizes a one transistor cell with an area of 22/spl times/36 /spl mu/m/SUP 2/ which is fabricated using advanced n-channel silicon-gate MOS technology (5-/spl mu/m photolithography). The main feature of the design is a sense circuitry scheme, which allows a high speed (read access time of 200 ns) with low-power dissipation (600 mW at the 400-ns cycle time). The fully decoded memory is fabricated on a 5/spl times/7 mm/SUP 2/ chip and is assembled in a 22-lead ceramic dual-in-line package.     

An experimental 80-ns 1-Mbit DRAM with fast page operation

An experimental general purpose 5-V 1-Mb dynamic RAM has been designed for increased performance, high density, and enhanced reliability. The array consists of a one-device overlapped I/O cell with a metal bitline architecture. The cell measures 4.1 /spl mu/m by 8.8 /spl mu/m, which yields a chip size of 5.5 mm by 10.5 mm with an array to chip area ratio of 65.5%. The chip was designed in a double-poly single-metal NMOS technology with selected 1-/spl mu/m levels and an average feature size of 1.5 /spl mu/m. Key design features include a fast page mode cycle with minimum column precharge delay and improved protection for short error rate using a boosted word-line after sense amplifier set scheme. The CAS access time is 40 ns and the cycle is 65 ns at 4.5 V and 85/spl deg/C. The RAS access time is 80 ns and the cycle is 160 ns at 4.5 V and 85/spl deg/C with a typical active power of 625 mW. The chip is usable as a X1, X2, or X4 with the use of block select inputs and the selected package option. The package options include a 500-mil/SUP 2/ pin grid array module with 23 pins, and a 22 pin or 26 pin 300-mil surface solder plastic package.     

A 1.0-ns 5-kbit ECL RAM

A bipolar 512/spl times/10-bit emitter-coupled logic (ECL) RAM with an access time of 1.0 ns and a power dissipation of 2.4 W, achieving an access-time power/bit product of 0.48 pJ/bit, has been developed. The RAM was fabricated using an advanced bipolar technology featuring poly-base self-alignment, poly-emitter shallow profile, and silicon-filled trench isolation with a minimum mask dimension of 1.2 /spl mu/m. A Schottky-clamped multiemitter cell with a cell size of 760 /spl mu/m/SUP 2/ is obtained as a result of compact cell layout and the use of 1.2-/spl mu/m trench isolation.     

A 50 ns 4K static DSA MOS RAM

An advanced DSA MOS (DMOS) technology is discussed as it applies to a high-speed 4K bit semiconductor static memory. It uses a polysilicon gate length of 4 /spl mu/m, a gate oxide thickness less than 800 /spl Aring/, and a shallow junction depth (<0.6 /spl mu/m) using conventional photolithographic methods. With these features, the effective channel length of the DSA MOST was reduced to 0.5 /spl mu/m and a smaller junction capacitance was obtained by the use of a high-resistivity (100-200 /spl Omega/.cm) substrate without a substrate bias generator. Combined with the depletion load transistors and selective oxidation processing, a static RAM of 50 ns access time at 630 mW power dissipation, die size of 5.24/spl times/5.36 mm/SUP 2/, and cell size of 53/spl times/62 /spl mu/m/SUP 2/ was obtained.     

An 8K/spl times/8 bit static MOS RAM fabricated by n-MOS/n-well CMOS technology

A 64 kbit fully static MOS RAM which contains about 402500 elements on the chip area of 5.44/spl times/5.80 mm has been designed. The memory cell is a basic cross-coupled flip-flop with four n-MOSFETs and two polysilicon load resistors. The memory cell size is decreased to 16/spl times/19 /spl mu/m (304 /spl mu/m/SUP 2/) by using advanced n-MOS technology with double-level polysilicon films and photolithography of 2 /spl mu/m dimensions. By applying n-well CMOS technology fabricated on a high-resistivity p-type silicon substrate to peripheral circuits of the RAM, high performance characteristics with high speed access times and low power dissipation are obtained. The RAM is designed for single 5 V operation. Address and chip select access times are typically 80 ns. Power dissipation in the active and standby mode is typically 300 and 75 mW, respectively.     

An 18K bipolar dynamic random access memory

A 2K/spl times/9 bipolar dynamic random access memory (RAM) experimental chip is described with a 75 ns and 300 ns access and cycle time, respectively. The design is based on a two device cell of 800 /spl mu/m/SUP 2/ size. All chip input and output signals are TTL compatible.     

A 35 ns 2K /spl times/ 8 HMOS static RAM

This paper describes the circuit design and process techniques used to produce a 35-ns 2K /spl times/ 8 HMOS static RAM aimed at future high-end microprocessor applications. The circuit design uses predecoding of the row and column decoder/driver circuits to reduce active power, address-transition detection schemes to equalize internal nodes, and dynamic depletion-mode configurations for increased drive and speed. The technology is 2.5-3.0-/spl mu/m design rule HMOS employing an L/SUB eff/ of 1.7 /spl mu/m, t/SUB ox/=400 /spl Aring/, double-poly resistor loads, RIE and plasma etching, and wafer-stepper lithography. Using these techniques an access time of 35 ns, dc active power of 65 mA, standby power of 14 mA, and die size of 37.5K mil/SUP 2/ has been achieved. The cell size is 728 /spl mu/m/SUP 2/.     

A 3.5-ns, 2-W, 20-mm/SUP 2/, 16-kbit ECL bipolar RAM

A 3.5-ns emitter-coupled logic (ECL) 16-kbit bipolar RAM with a power dissipation of 2 W, a cell size of 495 /spl mu/m/SUP 2/, and a chip size of 20 mm/SUP 2/ has been developed. High performance is achieved using a high-speed Schottky barrier diode decoder with a pull-up circuit and a double-stage discharge circuit for a word-line driver. Small cell size is obtained using ultra-thin Ta/SUB 2/O/SUB 5/ film capacitors and 1-/spl mu/m U-groove isolation technology. An access time of 3.5 ns in this 16-kb bipolar RAM is equivalent to an effective access time of 2.5 ns at the system level, due to an on-chip address buffer and latch.     

A 0.85-ns 1-kbit ECL RAM

A 1-kb ECL RAM with an address access time of 0.85 ns is described. This excellent performance is achieved by combining super self-aligned technology (SST) with 1-/spl mu/m design rules and high-speed circuit design. SST provides a narrow emitter stripe width of 0.5 /spl mu/m and a high cutoff frequency of 12.4 GHz at V/SUB CE/=3 V. A two-level metallization process is used. The minimum metallization pitches are 3 /spl mu/m in the first layer and 6 /spl mu/m in the second one. The chip size is 2.5/spl times/2.5 mm/SUP 2/ and the power dissipation is 950 mW. This RAM is promising for use in super computers and/or high-speed digital systems.     

A CMOS/SOS 4K static RAM

Discusses high density CMOS/SOS technology used to develop a fully static 4096-bit RAM with a five-transistor storage cell. Selection of a five-transistor memory cell has reduced the access to the flip-flop storage element to a single word line transistor and bit line. The word line transistor must be able to prevent data altering currents from entering the memory cell at all times except for the write operation. The write operation is enhanced by reducing the bias voltage across the memory cell, thereby making the current needed to alter the cell smaller. Through the use of a 5 /spl mu/m design rule, the memory cell occupies 2913 /spl mu/m/SUP 2/. The 4096-bit static CMOS/SOS RAM contains 22553 transistors in 20 mm/SUP 2/. Organised as 1024 4-bit words, the RAM has a read cycle time of 350 ns and standby power dissipation of 50 /spl mu/W at V/SUB cc/=5 V and temperature of 27/spl deg/C.     

VMOS technology applied to dynamic RAMs

A seven-mask VMOS process has been developed for dynamic RAMs with self-aligned VMOS and planar Al-gate transistors. Using 4 /spl mu/m photolithography, one-transistor cells with a cell size of 150 /spl mu/m/SUP 2/ have been realized. The read signal at the bit line is more than 200 mV. Implementations of a sense amplifier and a word-line driver show that those circuits determine the smallest word and bit line spacing. The paper is concluded by a proposal for a 64K RAM with a chip size of 21 mm/SUP 2/ using 4 /spl mu/m design rules.