Analysis of a Parasitic‐Diode‐Triggered Electrostatic Discharge Protection Circuit for 12 V Applications

In this paper, an electrostatic discharge (ESD) protection circuit is designed for use as a 12 V power clamp by using a parasitic‐diode‐triggered silicon controlled rectifier. The breakdown voltage and trigger voltage (V_t) of the proposed ESD protection circuit are improved by varying the length between the n‐well and the p‐well, and by adding n+/p+ floating regions. Moreover, the holding voltage (V_h) is improved by using segmented technology. The proposed circuit was fabricated using a 0.18‐μm bipolar‐CMOS‐DMOS process with a width of 100 μm. The electrical characteristics and robustness of the proposed ESD circuit were analyzed using transmission line pulse measurements and an ESD pulse generator. The electrical characteristics of the proposed circuit were also analyzed at high temperature (300 K to 500 K) to verify thermal performance. After optimization, the V_t of the proposed circuit increased from 14 V to 27.8 V, and V_h increased from 5.3 V to 13.6 V. The proposed circuit exhibited good robustness characteristics, enduring human‐body‐model surges at 7.4 kV and machine‐model surges at 450 V.     

Design of fabrication of ESD protection circuit with high holding voltage for power IC

In this paper, A newly Silicon Controlled Rectifier (SCR)-based Electric Static Discharge (ESD) protection circuit is proposed. The proposed circuit has the latch-up immunity in normal operating conditions with the high holding voltage by inserting the floating regions. To verify the electrical characteristics, a Technology Computer Aided Design (TCAD) simulation is performed by setting each of variables: D1, D2, D3, and D4. The results of the simulation show that the proposed protection circuit has the holding voltage 5 V higher than the conventional circuits and has the same level of robustness properties as the existing SCR. In addition, the proposed circuit is fabricated through a 0.18 μm Bipolar-CMOS-DMOS process. The electrical characteristics are confirmed by measuring Transmission Line Pulse, and the robustness properties are measured through Human Body Model (HBM) and Machine Model (MM). The holding voltage is about 20 V, which has the increases above 18 V or more compared to the conventional SCR. Therefore, the proposed circuit is proved to have the better ESD protection performance than HBM 8 kV and MM 800 V higher than HBM 2 kV and MM 200 V, the commercial standard.     

Design of SCR‐Based ESD Protection Circuit for 3.3 V I/O and 20 V Power Clamp

In this paper, MOS‐triggered silicon‐controlled rectifier (SCR)–based electrostatic discharge (ESD) protection circuits for mobile application in 3.3 V I/O and SCR‐based ESD protection circuits with floating diffusion regions for inverter and light‐emitting diode driver applications in 20 V power clamps were designed. The breakdown voltage is induced by a grounded‐gate NMOS (ggNMOS) in the MOS‐triggered SCR‐based ESD protection circuit for 3.3 V I/O. This lowers the breakdown voltage of the SCR by providing a trigger current to the P‐well of the SCR. However, the operation resistance is increased compared to SCR, because additional diffusion regions increase the overall resistance of the protection circuit. To overcome this problem, the number of ggNMOS fingers was increased. The ESD protection circuit for the power clamp application at 20 V had a breakdown voltage of 23 V; the product of a high holding voltage by the floating diffusion region. The trigger voltage was improved by the partial insertion of a P‐body to narrow the gap between the trigger and holding voltages. The ESD protection circuits for low‐ and high‐voltage applications were designed using 0.18 µm Bipolar‐CMOS‐DMOS technology, with 100 µm width. Electrical characteristics and robustness are analyzed by a transmission line pulse measurement and an ESD pulse generator (ESS‐6008).     

0.18μm RF CMOS双向可控硅ESD防护器件的研究(英文)

基于传统双向可控硅(DDSCR)提出了两种静电放电(ESD)保护器件,可应对正、负ESD应力从而在2个方向上对电路进行保护。传统的DDSCR通过N-well与P-well之间的雪崩击穿来触发,而提出的新器件则通过嵌入的NMOS/PMOS来改变触发机制、降低触发电压。两种改进结构均在0.18μmRFCMOS下进行流片,并使用传输线脉冲测试系统进行测试。实验数据表明,这两种新器件具有低触发电压、低漏电流(～nA),抗ESD能力均超过人体模型2kV,同时具有较高的维持电压(均超过3.3V),可保证其可靠地用于1.8V、3.3V I/O端口而避免出现闩锁问题。     

应用于片上ESD防护中新式直通型MOS触发SCR器件的研究

在基于0.13μm CMOS工艺制程下,为研究片上集成电路ESD保护,对新式直通型MOS触发SCR器件和传统非直通型MOS触发SCR进行了流片验证,并对该结构各类特性进行了具体研究分析。实验采用TLP(传输线脉冲)对两类器件进行测试验证,发现新式直通型MOS触发SCR结构要比传统非直通型MOS触发SCR具有更低的触发电压、更小的导通电阻、更好的开启效率以及更高的失效电流。     

Design and analysis of a NMOS triggered LIGBT structure for electrostatic discharge protection

A novel NMOS triggered LIGBT (NTLIGBT) structure is proposed for electrostatic discharge (ESD) protection in this paper. The structure utilizes internal NMOS to trigger SCR-like structure in LIGBT. The trigger voltage is significantly reduced because the embedded NMOS causes N⁺-drain/P-body junction being apt to avalanche breakdown. At the same time, the new parasitic PNP transistor including the newly added P⁺-region as a collector forms another path to bleed ESD current and then the conductivity modulation in the LIGBT is weakened. As a result, the holding voltage is increased. So, the proposed NTLIGBT structure has a narrow ESD design window. The simulation results show an improvement of 71.5% in trigger voltage and over 50% in holding voltage comparing with the conventional LIGBT structure.     

Electrostatic discharge (ESD) protection for CMOS output buffers in scaled-down VLSI technology

To provide area-efficient output ESD protection for the scaled-down CMOS VLSI, a new output ESD protection is proposed. In the new output ESD protection circuit, there are two novel devices, the PTLSCR (PMOS-trigger lateral SCR) and the NTLSCR (NMOS-trigger lateral SCR). The PTLSCR is in parallel and merged with the output PMOS, and the NTLSCR is in parallel and merged with the output NMOS, to provide area-efficient ESD protection for CMOS output buffers. The trigger voltages of PTLSCR and NTLSCR are lowered below the breakdown voltages of the output PMOS and NMOS in the CMOS output buffer. The PTLSCR and NTLSCR are guaranteed to be turned on first before the output PMOS or NMOS are broken down by the ESD voltage. Experimental results have shown that the PTLSCR and NTLSCR can sustain over 4000 V (700 V) of the human-body-model (machine-model) ESD stresses within a very small layout area in a 0.6 μm CMOS technology with LDD and polycide processes. The noise margin of the proposed output ESD protection design is greater than 8 V (lower than −3.3 V) to avoid the undesired triggering on the NTLSCR (PTLSCR) due to the overshooting (undershooting) voltage pulse on the output pad when the IC is under normal operating conditions with 5 V VDD and 0 V VSS power supplies.     

TFT_LCD驱动芯片GATE／SOURCE静电保护电路设计与实现

文章描述了TFT_LCD驱动芯片防静电（ESD）保护电路的布局,重点分析和设计了TFT_LCD驱动芯片GATE和SOURCE引脚的ESD保护电路。ESD保护电路布局上,采用髓排ESD电路错开呈”品字形“排列,使ESD电流均匀流通。在GATE保护电路中,采用二极管接法代替通用PMOS,防止电路产生Latch-up效应。SOURCE的保护电路中．NMOS的Drain设计了RPO（Resisl Protection Oxide）,使流经Drain的电流均匀分散,使二次击穿电压升高。     

一种基于CMOS工艺的新型结构ESD保护电路

根据伞芯片静电放电(ESD)损伤防护理论,设计了一种新犁结构保护电路,采用0.6μm标准CMOS p阱工艺进行了新型保护电路的多项目晶圆(MPW)投片验证.通过对同一MPW中的新型结构ESD保护电路和具有同样宽长比的传统栅极接地MOS(GG-nMOS)保护电路的传输线脉冲测试,结果表明在不增加额外工艺步骤的前提下,本文设计的新型结构ESD保护电路芯片面积减少了约22%,静态电流更低,而抗ESD电压提高了近32%.该保护电路通过了5kV的人体模型测试.     

一个LVTSCR并联PMOS的高维持电压ESD防护器件

为了在5 V片上输入输出端进行静电放电(ESD)防护,提出了一种新型的LVTSCR结构。使用Silvaco 2D TCAD软件对此器件进行包含电学及热学特性的仿真。此新型器件交换了LVTSCR中N-Well的N+、P+掺杂区并引入了一个类PMOS结构用来在LVTSCR工作前释放ESD电流。器件仿真结果显示,与LVTSCR相比,该器件获得了更高的维持电压(10.51 V),以及更高的开启速度(1.05×10-10 s),同时触发电压仅仅从12.45 V增加到15.35 V。并且,如果加入的PMOS结构选择与NMOS相同的沟道长度,器件不会引起热失效问题。     

Investigation and Design of On-Chip Power-Rail ESD Clamp Circuits Without Suffering Latchup-Like Failure During System-Level ESD Test

On-chip power-rail electrostatic discharge (ESD) protection circuit designed with active ESD detection function is the key role to significantly improve ESD robustness of CMOS integrated circuits (ICs). Four power-rail ESD clamp circuits with different ESD-transient detection circuits were fabricated in a 0.18-$mu{hbox{m}}$ CMOS process and tested to compare their system-level ESD susceptibility, which are named as power-rail ESD clamp circuits with typical RC-based detection, PMOS feedback, NMOS+PMOS feedback, and cascaded PMOS feedback in this work. During the system-level ESD test, where the ICs in a system have been powered up, the feedback loop used in the power-rail ESD clamp circuits provides the lock function to keep the ESD-clamping NMOS in a “latch-on” state. The latch-on ESD-clamping NMOS, which is often drawn with a larger device dimension to sustain high ESD level, conducts a huge current between the power lines to perform a latchup-like failure after the system-level ESD test. A modified power-rail ESD clamp circuit is proposed to solve this problem. The proposed power-rail ESD clamp circuit can provide high enough chip-level ESD robustness, and without suffering the latchup-like failure during the system-level ESD test.      

Optimized ESD protection circuits for high-speed MOS/VLSI

New electrostatic discharge (ESD) protection circuits for MOPS/VLSI provide typical 2.7-ns delays and protection against voltage spikes up to 2200 V (limit of test circuit) in some cases. These circuits contain some traditional elements plus new features including a gate-drain connected thin-oxide device to achieve the very low protected node voltage (~2 V) required for advanced thin gate oxide technologies. In addition, for CMOS application, these all-NMOS (or PMOS) circuits would offer a high degree of latchup immunity. For both positive and negative spikes, single-pulse and repeated-pulse test data were obtained for six different test conditions. Electrical and physical analyses show dominant failure modes. Because techniques used to improve protection tend to degrade speed, a figure of merit is proposed to assist a fair comparison between different ESD protection circuit designs.     

On-chip ESD protection design with substrate-triggered technique for mixed-Voltage I/O circuits in subquarter-micrometer CMOS Process

A new electrostatic discharge (ESD) protection design, by using the substrate-triggered stacked-nMOS device, is proposed to protect the mixed-voltage I/O circuits of CMOS ICs. The substrate-triggered technique is applied to lower the trigger voltage of the stacked-nMOS device to ensure effective ESD protection for the mixed-voltage I/O circuits. The proposed ESD protection circuit with the substrate-triggered technique is fully compatible to general CMOS process without causing the gate-oxide reliability problem. Without using the thick gate oxide, the new proposed design has been fabricated and verified for 2.5/3.3-V tolerant mixed-voltage I/O circuit in a 0.25-/spl mu/m salicided CMOS process. The experimental results have confirmed that the human-body-model ESD level of the mixed-voltage I/O buffers can be successfully improved from the original 3.4 to 5.6 kV by using this new proposed ESD protection circuit.     

一种用于高压防护的新型闩锁免疫LDMOS

横向双扩散MOSFET(LDMOS)由于其高击穿电压特性而被认为是适合在高压中应用的防止静电放电(ESD)现象的保护器件.在传统结构中,LDMOS的鲁棒性相对较差,这是器件自身固有的不均匀导通特性和Kirk效应导致的.可将可控硅整流器(SCR)嵌入到LDMOS结构(即NPN_LDMOS)中.然而,SCR固有的正反馈效应...     

A Low Supply Voltage VCO Implemented by a Single Common-Source 90 nm CMOS Transistor

A novel voltage controlled oscillation (VCO) topology using 90-m CMOS technology is demonstrated. The common-source PMOS single transistor integrated with an inductor leads to negative resistance for the VCO that minimizes the transistor size and decreases the flicker noise sources. To our knowledge, the topology of the core VCO is the most compact configuration ever reported. The fabricated VCO consumes 6.26mW with a supply voltage of 1 V and has a 1.68times1.41 mm² chip area, including the ESD protection circuit. At 1.77 GHz, PMOS VCO features an output power in the range of -5.2 dBm, and exhibits a phase noise of -94 dBc/Hz at the offset frequency of 300 kHz and -107 dBc/Hz at 1MHz     

Latchup-free ESD protection design with complementary substrate-triggered SCR devices

The turn-on mechanism of silicon-controlled rectifier (SCR) devices is essentially a current triggering event. While a current is applied to the base or substrate of an SCR device, it can be quickly triggered on into its latching state. In this paper, latchup-free electrostatic discharge (ESD) protection circuits, which are combined with the substrate-triggered technique and an SCR device, are proposed. A complementary circuit style with the substrate-triggered SCR device is designed to discharge both the pad-to-V/sub SS/ and pad-to-V/sub DD/ ESD stresses. The novel complementary substrate-triggered SCR devices have the advantages of controllable switching voltage, adjustable holding voltage, faster turn-on speed, and compatible to general CMOS process without extra process modification such as the silicide-blocking mask and ESD implantation. The total holding voltage of the substrate-triggered SCR device can be linearly increased by adding the stacked diode string to avoid the transient-induced latchup issue in the ESD protection circuits. The on-chip ESD protection circuits designed with the proposed complementary substrate-triggered SCR devices and stacked diode string for the input/output pad and power pad have been successfully verified in a 0.25-/spl mu/m salicided CMOS process with the human body model (machine model) ESD level of /spl sim/7.25 kV (500 V) in a small layout area.     

一种新型的高维持电压可控硅

可控硅(SCR)作为静电放电(ESD)保护器件,因具有高的鲁棒性而被广泛应用,但其维持电压很低,容易导致闩锁问题。针对高压集成电路的ESD保护,提出了一种新颖的具有高维持电压的SCR结构(HHVSCR)。通过添加一个重掺杂的N型掺杂层(NIL),减小了SCR器件自身固有的正反馈效应,从而提高了SCR的维持电压。Sentaurus TCAD仿真结果表明,与传统的SCR相比,改进的HHVSCR无需增加额外的面积就可将维持电压从1.88 V提高到11.9 V,可应用于高压集成电路的ESD防护。     

Design of SCR-based ESD protection device for power clamp using deep-submicron CMOS technology

The proposed device has a high holding voltage and a high triggering current characteristic. These characteristics enable latch-up immune normal operation as well as superior full chip electro-static-discharge (ESD) protection. The device has a small area in requirement robustness in comparison to gate-grounded NMOS (ggNMOS). The proposed ESD protection device is designed in 0.25 μm CMOS technology. In the experimental result, the proposed ESD clamp has a double trigger characteristic, a high holding voltage of 3.8 V and a high trigger current of greater than 120 mA. The robustness has measured to HBM 8 kV (HBM: human body model) and MM 400 V (MM: machine model). The proposed device has a high-level It2 of 52 mA/μm approximately.     

CMOS on-chip electrostatic discharge protection circuit using four-SCR structures with low ESD-trigger voltage

A robust CMOS on-chip ESD protection circuit is proposed, which consists of four parasitic lateral SCR devices with low ESD trigger voltages to protect NMOS and PMOS devices of the internal circuits against the ESD pulses with both positive and negative polarities with respect to either VDD or VSS(GND) nodes. For each ESD stress with positive or negative polarity, there is an efficient and direct shunt path generated by the SCR low-impedance latching state to quickly bypass the ESD current. Thus, this four-SCR ESD protection circuit can perform very efficient protection in a small layout area. Since there is no diffusion or polysilicon resistor in the proposed ESD protection circuit, the RC delay between each I/O pad and its internal circuits is very low and high-speed applications are feasible. The experimental results show that this four-SCR protection circuit can successfully perform very effective protection against ESD damage. Moreover, the proposed ESD protection circuit is fully process-compatible with n-well or p-well CMOS and BiCMOS technologies.     

Complementary-SCR ESD protection circuit with interdigitatedfinger-type layout for input pads of submicron CMOS IC's

A new ESD protection circuit with complementary SCR structures and junction diodes is proposed. This complementary-SCR ESD protection circuit with interdigitated finger-type layout has been successfully fabricated and verified in a 0.6 μm CMOS SRAM technology with the LDD process. The proposed ESD protection circuit can be free of VDD-to-VSS latchup under 5 V VDD operation by means of a base-emitter shorting method. To compensate for the degradation on latching capability of lateral SCR devices in the ESD protection circuit caused by the base-emitter shorting method, the p-well to p-well spacing of lateral BJT's in the lateral SCR devices is reduced to lower its ESD-trigger voltage and to enhance turn-on speed of positive-feedback regeneration in the lateral SCR devices. This ESD protection circuit can perform at high ESD failure threshold in small layout areas, so it is very suitable for submicron CMOS VLSI/ULSI's in high-pin-count or high-density applications