An 18-Mb, 12.3-GB/s CMOS pipeline-burst cache SRAM with 1.54Gb/s/pin

An 18-Mbit CMOS pipeline-burst cache SRAM achieves a 12.3-Gbyte/s data transfer rate with 1.54-Gbit/s/pin I/O's. The SRAM is fabricated on a 0.18-μm CMOS technology. The 14.3×14.6-mm² SRAM chip uses a 5.59-μm², six-transistor cell. Circuit techniques used for achieving high bandwidth include fully self-timed array architecture, segmented hierarchical sensing with separated global read/write bitlines in different metal layers, a high-speed data-capture technique, a reduced-swing output buffer, and a high-sensitivity, high-bandwidth input buffer     

A 300-MHz 4-Mb wave-pipeline CMOS SRAM using a multiphase PLL

A 4-Mb (64 k×64) synchronous wave-pipeline CMOS SRAM is fabricated by 0.25-μm CMOS technology. Multiphase active pulse control (MPAC) enables fully random 300 MHz operation at 2.5 V, resulting in a bandwidth of 2.4 GB/s. The pulse is generated by multiphase PLL (MPPLL) using an array oscillator with current consumption of 7.5 mA     

A 16-Mb 400-MHz loadless CMOS four-transistor SRAM macro

We have used a 5-metal 0.18-μm CMOS logic process to develop a 16-Mb 400-MHz loadless CMOS four-transistor SRAM macro. The macro contains: (1) end-point dual-pulse drivers for accurate timing control; (2) a wordline-voltage-level compensation circuit for stable data retention; and (3) an all-adjoining twisted bitline scheme for reduced bitline coupling capacitance. The macro is capable of 400-MHz high-speed access at 1.8-V supply voltage and is 66% the size of a conventional six-transistor SRAM macro. We have also developed a higher-performance 500-MHz loadless four-transistor SRAM macro in a CMOS process using 0.13-μm gate length     

A 15-ns 4-Mb CMOS SRAM

A 4-Mb SRAM with a 15-ns access time and a uniquely selectable (×4 or ×1) bit organization has been developed based on a 0.55-μm triple-polysilicon double-metal CMOS technology. An input-controlled PMOS-load (ICPL) sense amplifier, Y-controlled bit-line loads (YCLs), and a transfer word driver (TDW) are three key circuits which have been utilized in addition to the 0.55-μm CMOS technology to achieve the remarkable access time of 15 ns. Bit organization of either ×4 or ×1 can be selected purely electrically, and does not require any pin connection procedure     

A 1.8-ns access, 550-MHz, 4.5-Mb CMOS SRAM

An ultrahigh-speed 4.5-Mb CMOS SRAM with 1.8-ns clock-access time, 1.8-ns cycle time, and 9.84-μm² memory cells has been developed using 0.25-μm CMOS technology. Three key circuit techniques for achieving this high speed are a decoder using source-coupled-logic (SCL) circuits combined with reset circuits, a sense amplifier with nMOS source followers, and a sense-amplifier activation-pulse generator that uses a duplicate memory-cell array. The proposed decoder can reduce the delay time between the address input and the word-line signal of the 4.5-Mb SRAM to 68% of that of an SRAM with conventional circuits. The sense amplifier with nMOS source followers can reduce not only the delay time of the sense amplifier but also the power dissipation. In the SRAM, the sense-amplifier activation pulse must be input into the sense amplifier after the signal from the memory cell is input into the sense amplifier. A large timing margin required between these signals results in a large access time in the conventional SRAM. The sense-amplifier activation pulse generator that uses a duplicate memory-cell array can reduce the required timing margin to less than half of the conventional margin. These three techniques are especially useful for realizing ultrahigh-speed SRAM's, which will be used as on-chip or off-chip cache memories in processor systems     

A 100-MHz 4-Mb cache DRAM with fast copy-back scheme

A 4-Mb cache dynamic random access memory (CDRAM), which integrates 16-kb SRAM as a cache memory and 4-Mb DRAM into a monolithic circuit, is described. This CDRAM has a 100-MHz operating cache, newly proposed fast copy-back (FCB) scheme that realizes a three times faster miss access time over with the conventional copy-back method, and maximized mapping flexibility. The process technology is a quad-polysilicon double-metal 0.7-μm CMOS process, which is the same as used in a conventional 4-Mb DRAM. The chip size of 82.9 mm² is only a 7% increase over the conventional 4-Mb DRAM. The simulated system performance indicated better performance than a conventional cache system with eight times the cache capacity     

An 833-MHz 1.5-W 18-Mb CMOS SRAM with 1.67 Gb/s/pin

This paper describes an 833-MHz 18-Mb CMOS SRAM with a 1.67-Gb/s/pin data rate. Issues that had to be overcome from previous-generation SRAMs to meet the performance goals are addressed. The SRAM has been successfully fabricated using a 0.18-μm CMOS process with copper interconnects. It operates in two user-selectable double-data-rate modes (DDR and DDR2) and consumes 1.5 W of power at 833 MHz. In addition to the performance benefits resulting from this 0.18-μm copper technology, architecture improvements, a data-to-echo-clock tracking system, and data symmetric output drivers made possible the high frequency of operation     

一种4-Mb高速低功耗CMOS SRAM的设计

高性能的系统芯片对数据存取速度有了更严格的要求,同时低功耗设计已成为VLSI的研究热点和挑战.本文设计了一款4-Mb(512K×8bit)的高速、低功耗静态存储器(SRAM).它采用0.25μm CMOS标准工艺和传统的六管单元.文章分析了影响存储器速度和功耗的原因,重点讨论了存储器的总体结构、灵敏放大器及位线电路.通过系统优化,达到15ns的存取时间.     

A 4-Mb CMOS SRAM with a PMOS thin-film-transistor load cell

A 4-Mb (512 K words by 8-b) CMOS static RAM (SRAM) with a PMOS thin-film transistor (TFT) has been developed. The RAM can obtain a much larger data-retention margin than a conventional high-resistive load-type well by using the PMOS TFT as a memory cell load. An internal voltage down-converter architecture with an external supply voltage-level sensor not only realizes a highly reliable 0.5-μm MOS transistor operation but also a sufficiently low standby-power dissipation characteristic for data battery-backup application. A self-aligned equalized level sensing scheme can minimize the sensing delay for a local sense amplifier to drive a large load capacitance of a global sensing bus line. The RAM is fabricated using a 0.5 μm, triple-poly, and double-aluminum with dual gate-oxide-thickness CMOS process technology. The RAM operates under a single 5-V supply voltage with 23-ns typical address access time and 20- and 70-mA operation current at 10 and 40 MHz, respectively     

A 6-ns 4-Mb CMOS SRAM with offset-voltage-insensitive current senseamplifiers

A 4-Mb CMOS SRAM with 3.84 μm² TFT load cells is fabricated using 0.25-μm CMOS technology and achieves an address access time of 6 ns at a supply voltage of 2.7 V. The use of a current sense amplifier that is insensitive to its offset voltage enables the fast access time. A boosted cell array architecture allows low voltage operation of fast SRAM's using TFT load cells     

A 21-mW 4-Mb CMOS SRAM for battery operation

The authors describe a 21-mW 4-mB CMOS SRAM for the application of memory systems which operate on 3-V batteries. A low active power is achieved by novel circuit technologies. A thin-film transistor (TFT) load memory cell effectively reduces standby current to 0.4 μA. A new multibit test circuit, which permits measurement of access time, is also introduced for a reduction of the test time. The authors describe the characteristics of the TFT memory cell and the improved memory cell design for stable cell operation. The 0.6-μm process technology used to fabricate the 4-Mb SRAM and the chip performance are outlined     

A 20-ns 4-Mb CMOS SRAM with hierarchical word decoding architecture

A 20 ns 4-Mb CMOS SRAM operating at a single supply voltage of 3.3 V is described. The fast access time has been achieved by a newly proposed word-decoding architecture and a high-speed sense amplifier combined with the address transition detection (ATD) technique. The RAM has the fast address mode, which achieves quicker than 10-ns access, and the 16-b parallel test mode for the reduction of test time. A 0.6-μm process technology featuring quadruple-polysilicon and double-metal wiring is adopted to integrate more than 16 million transistors in a 8.35-mm×18.0-mm die     

A 4-kB 500-MHz 4-T CMOS SRAM using low-V/sub THN/ bitline drivers and high-V/sub THP/ latches

The design and physical implementation of a prototypical 500-MHz CMOS 4-T SRAM is presented in this work. The latch of the proposed SRAM cell is realized by a pair of cross coupled high-V/sub THP/ pMOS transistors, while the bitline drivers are realized by a pair of low-V/sub THN/ nMOS transistors. The wordline voltage compensation circuit and bitline boosting circuit, then, are neither needed to enhance the data retention of memory cells. Built-in self-refreshing paths make the data retention possible without the appearance of any external refreshing mechanism. The advantages of dual threshold voltage transistors can be used to reduce the access time, and maintain data retention at the same time. Besides, a new design of cascaded noise-immune address transition detector is also included to filter out the unwanted chip select glitches when the SRAM is asynchronously operated.     

A 550-ps access 900-MHz 1-Mb ECL-CMOS SRAM

An ultrahigh-speed 1-Mb emitter-coupled logic (ECL)-CMOS SRAM with 550-ps clock-access time, 900-MHz operating frequency, and 12-μm² memory cells has been developed using 0.2-μm BiCMOS technology. Three key techniques for achieving the ultrahigh speed are a BiCMOS word decoder/driver with an nMOS level-shift circuit, a sense amplifier with a voltage-clamp circuit, and a BiCMOS write circuit with a variable-impedance bitline load. The proposed word decoder/driver and sense amplifier can reduce the delay times of the circuits to 54% and 53% of those of conventional circuits. The BiCMOS write circuit can reduce the power dissipation of the circuit by 74% without sacrificing writing speed. These techniques are especially useful for realizing ultrahigh-spaced high-density SRAMs, which will be used as cache and control memories in mainframe computers     

A 23-ns 4-Mb CMOS SRAM with 0.2-μA standby current

A 4-Mb CMOS SRAM having 0.2-μA standby current at a supply voltage of 3 V has been developed. Current-mirror/PMOS cross-coupled cascade sense-amplifier circuits have achieved the fast address access time of 23 ns. A new noise-immune data-latch circuit has attained power-reduction characteristics at a low operating cycle time without access delay. A 0.5-μm CMOS, four-level poly, two-level metal technology with a polysilicon PMOS load memory cell, yielded a small cell area of 17 μm² and the very small standby current. A quadruple-array, word-decoder architecture allowed a small chip area of 122 mm²     

A 12.5-ns 16-Mb CMOS SRAM with common-centroid-geometry-layoutsense amplifiers

A 16-Mb CMOS SRAM using 0.4-μm CMOS technology has been developed. This SRAM features common-centroid-geometry (CCG) layout sense amplifiers which shorten the access time by 2.4 ns. A flexible redundancy technique achieves high efficiency without any access penalty. A memory cell with stacked capacitors is fabricated for high soft-error immunity. A 16-Mb SRAM with a chip size of 215 mm² is fabricated and an address access time of 12.5 ns has been achieved     

A 220-MHz pipelined 16-Mb BiCMOS SRAM with PLL proportionalself-timing generator

This 512 Kw×8 b×3 way synchronous BiCMOS SRAM uses a 2-stage wave-pipeline scheme, a PLL self-timing generator and a 0.4-μm BiCMOS process to achieve 220 MHz fully-random read/write operations with a GTL I/O interface. Newly developed circuit technologies include: 1) a zig-zag double word-line scheme, 2) a centered bit-line load layout scheme, and 3) a phase-locked-loop (PLL) with a multistage-tapped ring oscillator which generates a clock cycle proportional pulse (CCPP) and a clock edge lookahead pulse (CELP)     

A 6-ns ECL 100 K I/O and 8-ns 3.3-V TTL I/O 4-Mb BiCMOS SRAM

The authors report a 4 M word×1 b/1 M word×4 b BiCMOS SRAM that can be metal mask programmed as either a 6-ns access time for an ECL 100 K I/O interface to an 8-ns access time for a 3.3-V TTL I/O interface. Die size is 18.87 mm×8.77 mm. Memory cell size is 5.8 μm×3.2 μm. In order to achieve such high-speed address access times the following technologies were developed: (1) a BiCMOS level converter that directly connects the ECL signal level to the CMOS level; (2) a high-speed BiCMOS circuit with low threshold voltage nMOSFETs; (3) a design method for determining the optimum number of decoder gate stages and the optimum size of gate transistors; (4) high-speed bipolar sensing circuits used at 3.3-V supply voltage; and (5) 0.55-μm BiCMOS process technology with a triple-well structure     

A 500-MHz pipelined burst SRAM with improved SER immunity

This paper describes a 0.25-μm, 64 K×36 bit pipelined burst SRAM using a 6.156-μm² cell. It realizes over 500-MHz operation using a lower cost double metal process, Internal 16 K×144 organization by T-shaped bit line array reduces 20% of latency, 20% of active power, and 8.5% of die size. The low power also enables us to use lower cost thin quad flat type packages. Our solution to the soft error problem, a shallow triple well structure and four-transistor cell with stacked capacitor, improved soft error rate by 3.5 orders of magnitude compared with the conventional SRAM cell     

A 9-ns 16-Mb CMOS SRAM with offset-compensated current senseamplifier

A 9-ns 16-Mb CMOS SRAM has been developed using a 0.35-μm CMOS process, The current-mode fully nonequalized data path has been realized in a CMOS SRAM for the first time by using a stabilized feedback current-sense amplifier (SFCA) that provides a small input resistance and an offset compensation effect. To reduce the test time, a bit-line wired-OR parallel test circuit has been implemented