Analysis and control of floating-body bipolar effects in fullydepleted submicrometer SOI MOSFET's

Floating-body effects triggered by impact ionization in fully depleted submicrometer silicon-on-insulator (SOI) MOSFETs are analyzed based on two-dimensional device simulations. The parasitic bipolar junction transistor (BJT) effects are emphasized, but the kink effect and its disappearance in the fully depleted device are first explained physically to provide a basis for the BJT analysis. The results of simulations of the BJT-induced breakdown and latch phenomena are given, and parametric dependences are examined to give physical insight for optimal design. The analysis further relates the DC breakdown and latch mechanisms in the fully depleted submicrometer SOI MOSFET to actual BJT-related problems in an operating SOI CMOS circuit. A comprehensive understanding of the floating-body effects is attained, and a device design to control them utilizing a lightly doped source (LDS) is suggested and shown to be feasible     

High-gain lateral bipolar action in a MOSFET structure

A hybrid-mode device based on a standard submicrometer CMOS technology is presented. The device is essentially a MOSFET in which the gate and the well are internally connected to form the base of a lateral bipolar junction transistor (BJT). At low collector current levels, lateral bipolar action with a current gain higher than 1000 is achieved. No additional processing steps are needed to obtain the BJT when the MOSFET is properly designed. n-p-n BJTs with a 0.25-μm base width have been successfully fabricated in a p-well 0.25-μm bulk n-MOSFET process. The electrical characteristics of the n-MOSFET and the lateral n-p-n BJT at room and liquid nitrogen temperatures are reported     

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     

High-gain lateral p-n-p bipolar action in a p-MOSFET structure

Lateral p-n-p bipolar junction transistors (BJTs) fabricated using a bulk 0.25 μm CMOS technology are presented. The devices are structurally the same as p-MOSFETs in which the gate and the n-well are internally connected to form the base. The p-n-p BJT has an adjustable current gain which can be higher than 1000 and its peak cutoff frequency is 3.7 GHz. Since the lateral p-n-p BJT is fully process compatible with submicrometer CMOS and/or BiCMOS technologies, extension to a BiCMOS and/or complementary BiCMOS process is readily achieved     

High-power SOI vertical DMOS transistors with lateral drain contacts: Process developments, characterization, and modeling

Silicon-on-insulator (SOI) high-power vertical double-diffused MOS (VDMOS) transistors are demonstrated with a CMOS compatible fabrication process. A new backend trench formation process ensures a defect free device layer. Scanning electron microscope micrographs show that it is nearly free of defects. This has been achieved by moving the trench formation steps toward the end of the process. Our electrical measurements indicate that the transistors are fully functional. Electrothermal simulations show that unclamped inductive switching (UIS) test involves a substantial risk of turning the parasitic bipolar transistor (BJT) on. The UIS test is used to characterize the performance of power devices under unclamped inductive loading conditions. Extreme operating condition can be expected when all the energy stored in the inductor is released directly into device. Our measurements of the fabricated SOI VDMOSFET in the static region are in good agreement with the expected impact of the self-heating on the saturation behavior. The experiments at ambient temperature of 100/spl deg/C show that the break down voltage decreases as the drain voltage increases. This indicates that a parasitic BJT has been turned on.     

An accurate analytical BiCMOS delay expression and its applicationto optimizing high-speed BiCMOS circuits

A scheme for optimizing the overall delay of BiCMOS driver circuits is proposed in this paper. Using this optimization scheme, it is found that the delay is minimized when the maximum collector current of the bipolar transistors is equal to the onset of high current effects. Using this assumption, an accurate BiCMOS delay expression is derived in terms of the bipolar and MOS device parameters. The critical device parameters are then identified and their influence on the circuit speed discussed. An overall circuit delay expression for optimizing BiCMOS buffers is derived and a comparison made with CMOS buffers. It is shown that BiCMOS circuits have a speed advantage of 1.7 or an area advantage of about 5 for 2-μm feature sizes. In order to predict the future performance of BiCMOS circuits, a figure of merit is derived from the delay expression. Using the figure-of-merit expression, it is seen that future BiCMOS circuits can keep the speed advantage over CMOS circuits down to submicrometer dimensions under constant load capacitance assumption     

Low-voltage transient bipolar effect induced by dynamicfloating-body charging in scaled PD/SOI MOSFETs

An increased significance of the parasitic bipolar transistor (BJT) in scaled floating-body partially depleted SOI MOSFETs under transient conditions is described. The transient parasitic BJT effect is analyzed using both simulations and high-speed pulse measurements of pass transistors in a sub-0.25 μm SOI technology. The transient BJT current can be significant even at low drain-source voltages, well below the device breakdown voltage, and does not scale with technology. Our analysis shows that it can be problematic in digital circuit operation, possibly causing write disturbs in SRAMs and decreased retention times for DRAMs. Proper device/circuit design, suggested by our analysis, can however control the problems     

A 440-ps 64-bit adder in 1.5-V/0.18-μm partially depleted SOItechnology

A 64-bit adder in 1.5-V/0.18-μm partially depleted SOI technology, CMOS8S, and techniques to maintain performance are described. CMOS7S SOI, a 1.8-V/0.22-μm partially depleted SOI technology, achieves a 28% speed increase over bulk CMOS7S, and CMOS8S SOI delivers an additional 21%. In a 660-MHz CMOS8S SOI processor, the adder compensates for floating body effects in SOI devices which cause history effects, bipolar currents, and lower noise margins on dynamic circuits     

Fault detection in CMOS/SOI mixed-signal circuits using the quiescent current test

Main stream bulk CMOS and the variants of silicon-on-insulator (SOI) CMOS technologies are discussed with respect to testing for the quiescent current of mixed-signal integrated SOI circuits. The 2–3 times lower static power consumption in fully depleted CMOS/SOI compared to bulk CMOS allows quiescent current testing also for high performance analogue circuits at an acceptable defect resolutions. From first simulations and technological considerations, it turned out that quiescent current tests are able to detect not only commonly known defects, but also SOI specific defects such as self-heating, kink-effect or the parasitic bipolar behaviour. It is further shown that in partially depleted thick-film SOI, the kink-effect and parasitic bipolar transistor support the quiescent current test for some specific defects as they elevate the defective quiescent current level. In fully depleted kink-free SOI circuits, the kink-effect may occur due to process failures but then can be detected by quiescent current tests. A special fault simulation model for the kink-effect is presented. The I_ccq test technique is studied for a CMOS/SOI Miller operational amplifier. Normal 6-σ variation of the aspect ratio and the threshold voltage do not jeopardise the defect detection in the quiescent current. First, results confirm the good detection capabilities of the quiescent current test, in particular, of failures which are not visible in the output voltage.     

A floating-body charge monitoring technique for partially depleted SOI technology

This paper presents a floating-body charge monitoring technique, which does not require the use of body contacts on the device being monitored. A charge monitor is placed along side with the circuit that is susceptible to the floating-body effects in partially depleted (PD) SOI CMOS circuits. It mimics the circuit topology and operating history of a concerned circuit, specifically the worst-case body voltage of the critical device(s) under consideration. The monitoring is achieved by intentionally triggering a parasitic bipolar current pulse and setting the a state recording latch, which subsequently activates the speed recovering circuitry that compensates the loss of performance at critical circuit nets due to the presence of parasitic bipolar current. Implementation examples are given and described. This technique restores performance and improves timing robustness of the MUX-type and SRAM bit line circuits by minimizing the delay degradation or variation from parasitic bipolar currents.     

Critical evaluation of SOI design guidelines

Design guidelines for static and domino silicon-on-insulator (SOI) CMOS circuits are evaluated. Restructuring the logic to eliminate gates with large fan-ins is almost as beneficial for SOI as for bulk-silicon. Most published design fixes for eliminating parasitic bipolar induced upset are shown to aggravate the charge sharing problem. A new and improved predischarge method for enhancing the noise tolerance of SOI domino circuits is thus proposed . The topic of multiple output domino logic in SOI technology is addressed for the first time. Multiple output domino logic is shown to be more prone to bipolar leakage induced upset than regular domino. Many of the design practices used to alleviate bipolar leakage in regular domino are no longer valid due to the multiple output domino logic's inherent design requirements. A novel SOI-specific multiple output domino logic, particularly suitable for adder designs, is introduced to minimize the bipolar leakage risk.     

SOI器件中瞬态浮体效应的模拟与分析

针对 SOI器件中的瞬态浮体效应进行了一系列的数值模拟 ,通过改变器件参数 ,比较系统地考察了 SOI器件中瞬态浮体效应 ,同时也研究和分析了瞬态浮体效应对 CMOS/SOI电路 (以环振电路为例 )的影响 ,并提出了抑制器件浮体效应的器件结构和参数优化设计 .     

SOI横向栅控双极晶体管特性研究

横向SOI双极技术具有工艺简单、寄生电容小等优势,被认为是射频领域最有希望的技术之一。为了得到可用于射频领域的SOI横向栅控双极晶体管特性,采用一种SOI横向栅控双极晶体管器件结构,研究范围包括工艺实现过程和器件性能特性。实验表明,该器件工艺与平面CMOS工艺完全兼容,通过对栅端电压的控制,可以实现hFE在一个较大的范围内自由调节,具有更大的使用灵活性。     

Vertically integrated SOI circuits for low-power and high-performance applications

Vertical integration offers numerous advantages over conventional structures. By stacking multiple-material layers to form double gate transistors and by stacking multiple device layers to form multidevice-layer integration, vertical integration can emerge as the technology of choice for low-power and high-performance integration. In this paper, we demonstrate that the vertical integration can achieve better circuit performance and power dissipation due to improved device characteristics and reduced interconnect complexity and delay. The structures of vertically integrated double gate (DG) silicon-on-insulator (SOI) devices and circuits, and corresponding multidevice-layer (3-D) SOI circuits are presented; a general double-gate SOI model is provided for the study of symmetric and asymmetric SOI CMOS circuits; circuit speed, power dissipation of double-gate dynamic threshold (DGDT) SOI circuits are investigated and compared to single gate (SG) SOI circuits; potential 3-D SOI circuits are laid out. Chip area, layout complexity, process cost, and impact on circuit performance are studied. Results show that DGDT SOI CMOS circuits provide the best power-delay product, which makes them very attractive for low-voltage low-power applications. Multidevice-layer integration achieves performance improvement by shortening the interconnects. Results indicate that up to 40% of interconnect performance improvements can be expected for a 4-device-layer integration.     

全耗尽CMOS／SOI技术的研究进展

ＳＯＩ材料技术的成熟，为功耗低，抗干扰能力强，集成度高，速度快的ＣＭＯＳ／ＳＯＩ器件的研制提供了条件，分析比较了ＣＭＯＳ／ＳＯＩ器件与体硅器件的差异，介绍了国外薄膜全耗尽ＳＯＩ技术的发展和北京大学微电子所的研究成果。     

0.5μm SOI CMOS器件和电路

研究了0.5μm SOI CMOS器件和电路,开发出成套的0.5μm SOI CMOS工艺.经过工艺投片,获得了性能良好的器件和电路,其中当工作电压为3V时,0.5μm 101级环振单级延迟为42ps.同时,对部分耗尽SOI器件特性,如“浮体”效应、“kink”效应和反常亚阈值特性进行了讨论.     

An SOI LDMOS/CMOS/BJT technology for integrated power amplifiersused in wireless transceiver applications

This paper describes a SOI LDMOS/CMOS/BJT technology that can be used in portable wireless communication applications. This technology allows the complete integration of the front-end circuits with the baseband circuits for low-cost/low-power/high-volume single-chip transceiver implementation. The LDMOS transistors (0.35 μm channel length, 3.8 μm drift length, 4.5 GHz f_T and 21 V breakdown voltage), CMOS transistors (1.5 μm channel length, 0.8/-1.2 V threshold voltage), lateral NPN transistor (18 V BV_CBO and h _FE of 20), and high Q-factor (up to 6.1 at 900 MHz and 7.2 at 1.8 GHz) on-chip inductors are fabricated. A fully-functional high performance integrated power amplifier for 900 MHz wireless transceiver application is also demonstrated     

A 900-MHz fully integrated SOI power amplifier for single-chipwireless transceiver applications

This paper presents a silicon-on-insulator (SOI) fully integrated RF power amplifier for single-chip wireless transceiver applications. The integrated power amplifier (IPA) operates at 900 MHz, and is designed and fabricated using a 1.5-μm SOI LDMOS/CMOS/BJT technology. This technology is suitable for the complete integration of the front-end circuits with the baseband circuits for low-cost low-power high-volume production of single-chip transceivers. The IPA is a two-stage Class E power amplifier. It is fabricated along with the on-chip input and output matching networks. Thus, no external components are needed. At 900 MHz and with a 5-V supply, the power amplifier delivers 23-dBm output power to a 50-Ω load with 16-dB gain and 49% power-added efficiency     

Scaling of digital BiCMOS circuits

A generalized first-order scaling theory for BiCMOS digital circuit structures is presented. The effect of horizontal, vertical, and voltage scaling on the speed performance of various BiCMOS circuits is presented. The generalized scaling theory is used for the MOSFET, and the constant collector current (CIC) scaling scheme is used for the bipolar junction transistor (BJT). In scaling the bipolar transistor, polysilicon emitter contact and bandgap narrowing are taken into account. A case study for scaling BiCMOS circuits operating at 5- and 3.3-V power supplies shows that scaling improved BiCMOS buffers more significantly than CMOS buffers. Moreover, the low delay-to-load sensitivity of BiCMOS is preserved with scaling     

SOI集成光电子器件

Silicon-on-insula tor(SOI)集成光电子器件的工艺与标准CMOS工艺完全兼容,采用SOI技术可以实现低成本的整片集成光电子回路。文章回顾了近几年来SOI集成光电子器件的发展以及一些最新的研究进展。