A 0.65-ns, 72-kb ECL-CMOS RAM macro for a 1-Mb SRAM

An ultrahigh-speed 72-kb ECL-CMOS RAM macro for a 1-Mb SRAM with 0.65-ns address-access time, 0.80-ns write-pulse width, and 30.24-μm ² memory cells has been developed using 0.3-μm BiCMOS technology. Two key techniques for achieving ultrahigh speed are an ECL decoder/driver circuit with a BiCMOS inverter and a write-pulse generator with a replica memory cell. These circuit techniques can reduce access time and write-pulse width of the 72-kb RAM macro to 71% and 58% of those of RAM macros with conventional circuits. In order to reduce crosstalk noise for CMOS memory-cell arrays driven at extremely high speeds, a twisted bit-line structure with a normally on MOS equalizer is proposed. These techniques are especially useful for realizing ultrahigh-speed, high-density SRAM's, which have been used as cache and control storages in mainframe computers     

An 18-ns 1-Mbit CMOS SRAM

A 1-Mb (256 K×4 b) CMOS static random-access memory with a high-resistivity load cell was developed with 0.7-μm CMOS process technology. This SRAM achieved a high-speed access of 18 ns. The SRAM uses a three-phase back-bias generator, a bus level-equalizing circuit and a four-stage sense amplifier. A small 4.8×8.5-μm² cell was realized by the use of a triple-polysilicon structure. The grounded second-polysilicon layer increases cell capacitance and suppresses α-particle-induced soft errors. The chip size measures 7.5×12 mm²     

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 1.1 GHz 12 μA/Mb-Leakage SRAM Design in 65 nm Ultra-Low-Power CMOS Technology With Integrated Leakage Reduction for Mobile Applications

A low-power, high-speed SRAM macro is designed in a 65 nm ultra-low-power (ULP) logic technology for mobile applications. The 65 nm strained silicon technology improves transistor performance/leakage tradeoff, which is essential to achieve fast SRAM access speed at substantially low operating voltage and standby leakage. The 1 Mb SRAM macro features a 0.667 mum² low-leakage memory cell and can operate over a wide range of supply voltages from 1.2 V to 0.5 V. It achieves operating frequency of 1.1 GHz and 250 MHz at 1.2 V and 0.7 V, respectively. The SRAM leakage is reduced to 12 muA/Mb at the data retention voltage of 0.5 V. The measured bitcell leakage from the SRAM array is ~2 pA/bit at retention voltage with integrated leakage reduction schemes.     

A 7-ns 140-mW 1-Mb CMOS SRAM with current sense amplifier

A 7-ns 140-mW 1-Mb CMOS SRAM was developed to provide fast access and low power dissipation by using high-speed circuits for a 3-V power supply: a current-sense amplifier and pre-output buffer. The current-sense amplifier shows three times the gain of a conventional voltage-sense amplifier and saves 60% of power dissipation while maintaining a very short sensing delay. The pre-output buffer reduces output delays by 0.5 ns to 0.75 ns. The 6.6-μm² high-density memory cell uses a parallel transistor layout and phase-shifting photolithography. The critical charge that brings about soft error in a memory cell can be drastically increased by adjusting the resistances of poly-PMOS gate electrodes. This can be done without increasing process complexity or memory cell area. The 1-Mb SRAM was fabricated using 0.3-μm CMOS quadrupole-poly and double-metal technology. The chip measures 3.96 mm×7.4 mm (29 mm²)     

High-speed sensing techniques for ultrahigh-speed SRAMs

Two high-speed sensing techniques suitable for ultrahigh-speed SRAMs are proposed. These techniques can reduce a 64-kb SRAM access time to 71~89% of that of conventional high-speed bipolar SRAMs. The techniques use a small CMOS memory cell instead of the bipolar memory cell that has often been used in conventional bipolar SRAMs for cache and control memories of mainframe computers. Therefore, the memory cell size can also be reduced to 26~43% of that of conventional cells. A 64-kb SRAM fabricated with one of the sensing techniques using 0.5-μm BiCMOS technology achieved a 1.5-ns access time with a 78-μm² memory cell size. The techniques are especially useful in the development of both ultrahigh-speed and high-density SRAMs, which have been used as cache and control memories of mainframe computers     

An experimental 1-Mbit CMOS SRAM with configurable organization andoperation

A 1-Mb SRAM (static random-access memory) configurable as a 128-kb×8, 256-kb×4, or 1-Mb×1 memory featuring asynchronous operation with static-column and chip-enable-access speedup modes or synchronous operation with a fast-page (toggle) or static-column mode is described. It has been fabricated in a double-metal, double-polysilicon CMOS process with 0.7-μm geometry and special SRAM structures. The measured synchronous access of 29 ns with a fast-page mode access of 22 ns. Measured asynchronous access is 34 ns with a static-column access of 33 ns and a chip-select speedup access of 29 ns. The SRAMs six-transistor CMOS memory cell is 58.24 μm²     

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 46-ns 1-Mbit CMOS SRAM

A 1-Mb (128 K×8-bit) CMOS static RAM (SRAM) with high-resistivity load cell has been developed with 0.8-μm CMOS process technology. Standby power is 25 μW, active power 80 mW at 1-MHz WRITE operation, and access time 46 ns. The SRAM uses a PMOS bit-line DC load to reduce power dissipation in the WRITE cycle, and has a four-block access mode to reduce the testing time. A small 4.8×8.5-μm² cell has been realized by triple-polysilicon layers. The grounded second polysilicon layer increases cell capacitance and suppresses α-particle-induced soft errors. The chip size is 7.6×12.4 mm²     

A 45 nm 2-port 8T-SRAM Using Hierarchical Replica Bitline Technique With Immunity From Simultaneous R/W Access Issues

We propose a new 2-port SRAM with a single read bit line (SRBL) eight transistors (8 T) memory cell for a 45 nm system-on-a-chip (SoC). Access time tends to be slower as a fabrication is scaled down because of threshold voltage (V_t) random variations. A divided read bit line scheme with shared local amplifier (DBSA) realizes fast access time without increasing area penalty. We also show an additional important issue of a simultaneous read and write (R/W) access at the same row by using DBSA with the SRBL-8T cell. A rise of the storage node causes misreading. A read end detecting replica circuit (RER) and a local read bit line dummy capacitance (LDC) are introduced to solve this issue. A 128 bit lines - 512 word lines 64 kb 2-port SRAM macro using these schemes was fabricated by a 45 nm bulk CMOS low-standby-power (LSTP) CMOS process technology [1]. The memory cell size is 0.597 mum². This 2-port SRAM macro achieves 7 times faster access time without misreading.     

A 7.5-ns 32 K×8 CMOS SRAM

A 256 K (32 K×8) CMOS static RAM (SRAM) which achieves an access time of 7.5 ns and 50-mA active current at 50-MHz operation is described. A 32-block architecture is used to achieve high-speed access and low power dissipation. To achieve faster access time, a double-activated-pulse circuit which generates the word-line-enable pulse and the sense-amplifier-enable pulse has been developed. The data-output reset circuit reduces the transition time and the noise generated by the output buffer. A self-aligned contact technology reduces the diffused region capacitance. This RAM has been fabricated in a twin-tub CMOS 0.8-μm technology with double-level polysilicon (the first level is polycide) and double-level metal. The memory cell size is 6.0×11.0 μm² and the chip size is 4.38×9.47 mm ²     

A 14-ns 1-Mbit CMOS SRAM with variable bit organization

The authors describe a 14-ns 1-Mb CMOS SRAM (static random-access memory) with both 1M word×1-b and 256 K word×4-b organizations. The desired organization is selected by forcing the state of an external pin. The fast access time is achieved by the use of a shorter divided-word-line (DWL) structure, a highly sensitive sense amplifier, a gate-controlled data-bus driver, and a dual-level precharging technique. The 0.7-μm double-aluminum and triple-polysilicon process technology with trench isolation offers a memory cell size of 41.6 μm² and a chip size of 86.6 mm ². The variable bit-organization function reduces the testing time while keeping the measurement accuracy of the access times     

An 8-ns 256K ECL SRAM with CMOS memory array and battery backupcapability

The authors describe the first high-performance, high-density ECL SRAM (emitter-coupled-logic static random-access memory) compatible with battery backup techniques. The 256K device has a measured access time of 8 ns. Fabricated in a 0.8-μm BiCMOS process, the chip uses 117-μm ², full-CMOS, six-transistor memory cells and measures 6.5×8.15 mm². The design methodology described here illustrates the extent to which bipolar devices can be integrated into the periphery of a CMOS memory array. This integration was achieved through the use of a novel sensing scheme which provided three stages of bipolar differential sensing, with the first stage of sensing taking place directly on the bit lines     

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 1.5-ns 256-kb BiCMOS SRAM with 60-ps 11-K logic gates

A 1.5-ns address access time, 256-kb BiCMOS SRAM has been developed. To attain this ultra-high-speed access time, an emitter-coupled logic (ECL) word driver is used to access 6-T CMOS memory cells, eliminating the ECL-MOS level-shifter time delay. The RAM uses a low-power active pull down ECL decoder. The chip contains 11-K, 60-ps ECL circuit gates. It provides variable RAM configurations and general logic functions. RAM power consumption is 18 W; chip power consumption is 35 W. The chip is fabricated by using a 0.5-μm BiCMOS process. The memory cell size is 58 μm² and the chip size is 11×11 mm     

A 1.5-ns access time, 78-μm2 memory-cell size, 64-kbECL-CMOS SRAM

A 1.5-ns access time, 78-μm² memory-cell size, 64-kb ECL-CMOS SRAM has been developed. This high-performance device is achieved by using a novel ECL-CMOS SRAM circuit technique: a combination of CMOS cell arrays and ECL word drivers and write circuits. These ECL word drivers and write circuits drive the CMOS cell arrays directly without any intermediate MOS level converter. In addition to the ultrahigh-speed access time and relatively small memory-cell size, a very short write-pulse width of 0.8 ns and sufficient soft-error immunity are obtained. This ECL-CMOS SRAM circuit technique is especially useful for realizing ultrahigh-speed high-density SRAMs, which have been used as cache and control storages of mainframe computers     

A 7.1-GB/s low-power rendering engine in 2-D array-embedded memorylogic CMOS for portable multimedia system

A single-chip rendering engine that consists of a DRAM frame buffer, a SRAM serial access memory, pixel/edge processor array and 32-b RISC core is proposed for low-power three-dimensional (3-D) graphics in portable systems. The main features are two-dimensional (2-D) hierarchical octet tree (HOT) array structure with bandwidth amplification, three dedicated network schemes, virtual page mapping, memory-coupled logic pipeline, low-power operation, 7.1-GB/s memory bandwidth, and 11.1-Mpolygon/s drawing speed. The 56-mm² prototype die integrating one edge processor, eight pixel processors, eight frame buffers, and a RISC core are fabricated using 0.35-μm CMOS embedded memory logic (EML) technology with four poly layers and three metal layers. The fabricated test chip, 590 mW at 100 MHz 3.3 V operation, is demonstrated with a host PC through a PCI bridge     

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     

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