3.3-V BiCMOS current-mode logic circuits for high-speed adders

New high-speed BiCMOS current mode logic (BCML) circuits for fast carry propagation and generation are described. These circuits are suitable for reduced supply voltage of 3.3-V. A 32-b BiCMOS carry select adder (CSA) is designed using 0.5-μm BiCMOS technology. The BCML circuits are used for the correct carry path for high-speed operation while the rest of the adder is implemented in CMOS to achieve high density and low power dissipation. Simulation results show that the BiCMOS CSA outperforms emitter coupled logic (ECL) and CMOS adders     

BiCMOS circuit technology for a 704 MHz ATM switch LSI

This paper describes BiCMOS level-converter circuits and clock circuits that increase VLSI interface speed to 1 GHz, and their application to a 704 MHz ATM switch LSI. An LSI with a high speed interface requires a BiCMOS multiplexer/demultiplexer (MUX/DEMUX) on the chip to reduce internal operation speed. A MUX/DEMUX with minimum power dissipation and a minimum pattern area can be designed using the proposed converter circuits. The converter circuits, using weakly cross-coupled CMOS inverters and a voltage regulator circuit, can convert signal levels between LCML and positive CMOS at a speed of 500 MHz. Data synchronization in the high speed region is ensured by a new BiCMOS clock circuit consisting of a pure ECL path and retiming circuits. The clock circuit reduces the chip latency fluctuation of the clock signal and absorbs the delay difference between the ECL clock and data through the CMOS circuits. A rerouting-Banyan (RRB) ATM switch, employing both the proposed converter circuits and the clock circuits, has been fabricated with 0.5 μm BiCMOS technology. The LSI, composed of CMOS 15 K gate logic, 8 Kb RAM, I Kb FIFO and ECL 1.6 K gate logic, achieved an operation speed of 704-MHz with power dissipation of 7.2 W     

2.5-V bipolar/CMOS circuits for 0.25-μm BiCMOS technology

An ECL circuit with an active pull-down device, operated from a CMOS supply voltage, is described as a high-speed digital circuit for a 0.25-μm BiCMOS technology. A pair of ECL/CMOS level converters with built-in logic capability is presented for effective intermixing of ECL with CMOS circuits. Using a 2.5-V supply and a reduced-swing BiNMOS buffer, the ECL circuit has reduced power dissipation, while still providing good speed. A design example shows the implementation of complex logic by emitter and collector dottings and the selective use of ECL circuits to achieve high performance     

Novel high speed circuit structures for BiCMOS environment

Novel high speed BiCMOS circuits including ECL/CMOS, CMOS/ECL interface circuits and a BiCMOS sense amplifier are presented. A generic 0.8 μm complementary BiCMOS technology has been used in the circuit design. Circuit simulations show superior performance of the novel circuits over conventional designs. The time delays of the proposed ECL/CMOS interface circuits, the dynamic reference voltage CMOS/ECL interface circuit and the BiCMOS sense amplifier are improved by 20, 250, and 60%, respectively. All the proposed circuits maintain speed advantage until the supply voltage is scaled down to 3.3 V     

0.5-μm 3.3-V BiCMOS standard cells with 32-kilobyte cache andten-port register file

BiCMOS standard cell macros, including a 0.5-W 3-ns register file, a 0.6-W 5-ns 32-kbyte cache, a 0.2-W 3-ns table look-aside buffer (TLB), and a 0.1-W 3-ns adder, are designed with a 0.5-μm BiCMOS technology. A supply voltage of 3.3 V is used to achieve low power consumption. Several BiCMOS/CMOS circuits, such as a self-aligned threshold inverter (SATI) sense amplifier and an ECL HIT logic are used to realize high-speed operation at the low supply voltage. The performance of the BiCMOS macros is verified using a fabricated test chip     

A new true-single-phase-clocking BiCMOS dynamic pipelined logicfamily for high-speed, low-voltage pipelined system applications

New true-single-phase-clocking (TSPC) BiCMOS/BiNMOS/BiPMOS dynamic logic circuits and BiCMOS/BiNMOS dynamic latch logic circuits for high-speed dynamic pipelined system applications are proposed and analyzed. In the proposed circuits, the bootstrapping technique is utilized to achieve fast near-full-swing operation. The circuit performance of the proposed new dynamic logic circuits and dynamic latch logic circuits in both domino and pipelined applications are simulated by using HSPICE with 1 μm BiCMOS technology. Simulation results have shown that the new dynamic logic circuits and dynamic latch logic circuits in both domino and pipelined applications have better speed performance than that of CMOS and other BiCMOS dynamic logic circuits as the supply voltage is scaled down to 2 V. The operating frequency and power dissipation/MHz of the pipelined system, which is constructed by the new clock-high-evaluate-BiCMOS dynamic latch logic circuit and clock-low-evaluate-BiCMOS (BiNMOS) dynamic latch logic circuit, and the logic units with two stacked MOS transistors, are about 2.36 (2.2) times and 1.15 (1.1) times those of the CMOS TSPC dynamic logic under 1.5-pF output loading at 2 V, respectively. Moreover, the chip area of these two BiCMOS pipelined systems is about 1.9 times and 1.7 times as compared with that of the CMOS TSPC pipelined system. A two-input dynamic AND gate fabricated with 1 μm BiCMOS technology verifies the speed advantage of the new BiNMOS dynamic logic circuit. Due to the excellent circuit performance in high-speed, low-voltage operation, the proposed new dynamic logic circuits and dynamic latch logic circuits are feasible for high-speed, low-voltage dynamic pipelined system applications     

Power reduction techniques for a 1-Mb ECL-CMOS SRAM with an accesstime of 550 ps and an operating frequency of 900 MHz

This paper describes power reduction circuit techniques in an ultra-high-speed emitter-coupled logic (ECL)-CMOS SRAM. Introduction of a 0.25-μm MOS transistor allows a Y decoder and a bit-line driver to be composed of CMOS circuits, resulting in a power reduction of 34%. Moreover, a variable-impedance load has been proposed to reduce cycle time. A 1-Mb ECL-CMOS SRAM was developed by using these circuit techniques and 0.2-μm BiCMOS technology. The fabricated SRAM has an ultrafast access time of 550 ps and a high operating frequency of 900 MHz with a power dissipation of 43 W     

Bootstrapped full-swing BiCMOS/BiNMOS logic circuits for 1.2-3.3 Vsupply voltage regime

Novel full-swing BiCMOS/BiNMOS logic circuits using bootstrapping in the pull-up section for low supply voltage down to 1 V are reported. These circuit configurations use noncomplementary BiCMOS technology. Simulations have shown that they outperform other BiCMOS circuits at low supply voltage using 0.35 μm BiCMOS process. The delay and power dissipation of several NAND configurations have been compared. The new circuits offer delay reduction between 40 and 66% over CMOS in the range 1.2-3.3 V supply voltage. The minimum fanout at which the new circuits outperform CMOS gate is 5, which is lower than that of other gates particularly for sub-2.5 V operation     

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     

Optimization-based placement algorithm for BiCMOS leaf cellgeneration

We present a transistor placement algorithm for the automatic layout synthesis of logic and interface cells comprised of a mixture of MOS and bipolar devices. Our algorithm is applicable to BiCMOS logic cells, ECL logic cells as well as TTL, CMOS and ECL compatible input/output (I/O) cells. The transistor placement problem is transformed into a layout floorplan design problem with a mixture of rigid and flexible modules. A constructive “branch-and-bound” algorithm is used to minimize the area of synthesized circuits subject to pre-placement constraints. Experimental results indicate that the algorithm can produce efficient placements under fixed-height constraints. The design space exploration mechanism can be controlled by the user so as to apportion computing resources judiciously     

多端I/O系统用BiCMOS连线逻辑电路

为了满足数字通信和信息处理系统多端输入/输出(I/O)、高速、低耗的性能要求,笔者设计了几例BiCMOS连线逻辑电路,并提出了采用0.5 mm BiCMOS工艺,制备所设计的连线逻辑电路的技术要点和元器件参数。所做实验表明了设计的连线逻辑电路既具有双极型逻辑门电路快速、大电流驱动能力的特点,又具备CMOS逻辑门低压、低功耗的长处,而且其扇入数可达3~16,扇出数可达1~18,因而它们特别适用于多端I/O高速数字通信和信息处理系统中。     

TFSOI complementary BiCMOS technology for low power applications

A Thin-Film-Silicon-On-Insulator Complementary BiCMOS (TFSOI CBiCMOS) technology has been developed for low power applications. The technology is based on a manufacturable, near-fully-depleted 0.5 μm CMOS process with the lateral bipolar devices integrated as drop-in modules for CBiCMOS circuits. The near-fully-depleted CMOS device design minimizes sensitivity to silicon thickness variation while maintaining the benefits of SOI devices. The bipolar device structure emphasizes use of a silicided polysilicon base contact to reduce base resistance and minimize current crowding effects. A split-oxide spacer integration allows independent control of the bipolar base width and emitter contact spacing. Excellent low power performance is demonstrated through low current ECL and low voltage, low power CMOS circuits. A 70 ps ECL gate delay at a gate current of 20 μA is achieved. This represents a factor of 3 improvement over bulk trench-isolated double-polysilicon self-aligned bipolar circuits. Similarly, CMOS gate delay shows a factor of 2 improvement over bulk silicon at a power supply voltage of 3.3 V. Finally, a 460 μW 1 GHz prescaler circuit is demonstrated using this technology     

Nonoverlapping super self-aligned device structure forhigh-performance VLSI

The nonoverlapping super self-aligned structure (NOVA) is reported. Because of its nonoverlapping nature, this structure can be applied equally well to bipolar, CMOS, or BiCMOS processes. This structure effectively minimizes parasitic capacitance and resistance for both the MOS and bipolar devices. CMOS and bipolar devices are integrated into a high-performance BiCMOS technology. CMOS and emitter-coupled logic (ECL) ring oscillators with 1.5-μm lithography are reported to have delays of 128 and 87 ps/stage, respectively     

A 1.5-V differential cross-coupled bootstrapped BiCMOS logic forlow-voltage applications

Two new bipolar complementary metal-oxide-semiconductor (BiCMOS) differential logic circuits called differential cross-coupled bootstrapped BiCMOS (DC²B-BiCMOS) and differential cross-coupled BiCMOS (DC²-BiCMOS) logic are proposed and analyzed. In the proposed two new logic circuits, the novel cross-coupled BiCMOS buffer circuit structure is used to achieve high-speed operation under low supply voltage. Moreover, a new bootstrapping technique that uses only one bootstrapping capacitor is adopted in the proposed DC²B-BiCMOS logic to achieve fast near-full-swing operation at 1.5 V supply voltage for two differential outputs. HSPICE simulation results have shown that the new DC²B-BiCMOS at 1.5 V and the new DC²-BiCMOS logic at 2 V have better speed performance than that of CMOS and other BiCMOS differential logic gates. It has been verified by the measurement results on an experimental chip of three-input DC²B-BiCMOS XOR/XNOR gate chain fabricated by 0.8 μm BiCMOS technology that the speed of DC²-BiCMOS at 1.5 V is about 1.8 times of that of the CMOS logic at 1.5 V. Due to the excellent circuit performance in high-speed, low-voltage operation, the proposed DC²B-BiCMOS and DC²-BiCMOS logic circuits are feasible for low-voltage, high-speed applications     

Deep-submicron CMOS warms up to high-speed logic

The factors favoring room-temperature CMOS as a replacement for emitter-coupled logic (ECL) technology are presented. Room-temperature CMOS's integration scale. logic-function capabilities of basic circuits, wire length of logic signal nets, and power in system environments are discussed. To evaluate the possibilities of CMOS as a replacement technology, a VLSI chip model is studied     

Full-swing Schottky BiCMOS/BiNMOS and the effects of operatingfrequency and supply voltage scaling

Novel full-swing BiCMOS/BiNMOS logic circuits which use Schottky diode in the pull-up section for low supply-voltage regime are developed. The full-swing pull-up operation is performed by saturating the bipolar transistor with a base current pulse. After which, the base is isolated and bootstrapped to a voltage higher than V_DD. The BiCMOS/BiNMOS circuits do not require a PNP bipolar transistor. They outperform other BiCMOS circuits at low supply voltage, particularly at 2 V using 0.5 μm BiCMOS technology. Delay, area, and power dissipation comparisons have been performed. The new circuits offer delay reduction at 2 V supply voltage of 37% to 56% over CMOS. The minimum fanout at which the new circuits outperform CMOS gate is 2 to 3. Furthermore, the effect of the operating frequency on the delay of a wide range of BiCMOS and BiNMOS circuits is reported for the first time, showing the superiority of the Schottky circuits     

Noncomplementary BiCMOS logic and CMOS logic for low-voltage,low-power operation-a comparative study

This paper presents results of a comprehensive comparative study of six bipolar complementary metal-oxide-semiconductor (BiCMOS) noncomplementary logic design styles and two CMOS logic styles for low-voltage, low-power operation. These logic styles have been compared for switching power consumption and power efficiency (power-delay product). The examination offers two alternative approaches never used in other comparative studies. First, all BiCMOS-based styles are compared to low-power CMOS styles as opposed to a single conventional static CMOS style. Second, a low-power methodology has been used as opposed to performance methodology referred to in the previous logic comparisons. The styles examined are bootstrapped BiCMOS, bootstrapped full-swing BiCMOS, bootstrapped bipolar CMOS, Seng-Rofail's bootstrapped BiCMOS, modified full-swing BiCMOS, dynamic full-swing BiCMOS, double pass-transistor CMOS, and inverter-based CMOS. These design styles have been compared at various power supply voltages (0.9-3 V), with various output load capacitances (0.1-1 pF) at the frequency 50 MHz and temperature 27°C. The results clearly show which logic style is the most beneficial for which specific conditions     

Process integration and device performance of a submicrometerBiCMOS with 16-GHz ft double poly-bipolar devices

Submicrometer-channel CMOS devices have been integrated with self-aligned double-polysilicon bipolar devices showing a cutoff frequency of 16 GHz. n-p-n bipolar transistors and p-channel MOSFETs were built in an n-type epitaxial layer on an n⁺ buried layer, and n-channel MOSFETs were built in a p-well on a p⁺ buried layer. Deep trenches with depths of 4 μm and widths of 1 μm isolated the n-p-n bipolar transistors and the n- and p-channel MOSFETs from each other. CMOS, BiCMOS, and bipolar ECL circuits were characterized and compared with each other in terms of circuit speed as a function of loading capacitance, power dissipation, and power supply voltage. The BiCMOS circuit showed a significant speed degradation and became slower than the CMOS circuit when the power supply voltage was reduced below 3.3 V. The bipolar ECL circuit maintained the highest speed, with a propagation delay time of 65 ps for C_L=0 pF and 300 ps for C_L=1.0 pF with a power dissipation of 8 mW per gate. The circuit speed improvements in the CMOS circuits as the effective channel lengths of the MOS devices were scaled from 0.8 to 0.4 μm were maintained at almost the same ratio     

A 2.125-Gb/s BiCMOS fiber channel transmitter for serial datacommunications

A 2.125-Gb/s transmitter meeting the specifications of the emerging ANSI Fiber Channel standard has been developed using BiCMOS technology. This transmitter features (1) a fully bipolar 10:1 multiplexer (MUX) and a 2.125-GHz retimer for high-accuracy transmission of data, (2) an emitter-coupled logic (ECL) CMOS analog phase-locked loop, (3) pure ECL-level output for direct connection to the currently available optical modules, and (4) BiCMOS process technology that includes 0.25-μm CMOS devices and 20-GHz bipolar devices. The LSI serializes 32-bit-wide, 53.125-Mb/s data into 2.125-Gb/s data through a CMOS 8B10B encoder. The chip area is 3×2 mm², and the power dissipation is 860 mW     

An ultra-high-speed ECL-BiCMOS technology with silicon filletself-aligned contacts

We have developed a half-micron super self-aligned BiCMOS technology for high speed application. A new SIlicon Fillet self-aligned conTact (SIFT) process is integrated in this BiCMOS technology enabling high speed performances for both CMOS and ECL bipolar circuits. In this paper, we describe the process design, device characteristics and circuit performance of this BiCMOS technology. The minimum CMOS gate delay is 38 ps on 0.5 μm gate and 50 ps on 0.6 μm gate ring oscillators at 5 V. Bipolar ECL gate delay is 24 ps on 0.6 μm emitter ring oscillators with collector current density of 40 kA/cm². A single phase decision circuit operating error free over 8 Gb/s and a static frequency divider operating at 13.5 GHz is demonstrated in our BiCMOS technology