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.     

Substrate-triggered SCR device for on-chip ESD protection in fully silicided sub-0.25-/spl mu/m CMOS process

The turn-on mechanism of a silicon-controlled rectifier (SCR) device is essentially a current triggering event. While a current is applied to the base or substrate of the SCR device, it can be quickly triggered into its latching state. In this paper, a novel design concept to turn on the SCR device by applying the substrate-triggered technique is first proposed for effective on-chip electrostatic discharge (ESD) protection. This novel substrate-triggered SCR device has the advantages of controllable switching voltage and adjustable holding voltage and is compatible with general CMOS processes without extra process modification such as the silicide-blocking mask and ESD implantation. Moreover, the substrate-triggered SCR devices can be stacked in ESD protection circuits to avoid the transient-induced latch-up issue. The turn-on time of the proposed substrate-triggered SCR devices can be reduced from 27.4 to 7.8 ns by the substrate-triggering technique. The substrate-triggered SCR device with a small active area of only 20 /spl mu/m /spl times/ 20 /spl mu/m can sustain the HBM ESD stress of 6.5 kV in a fully silicided 0.25-/spl mu/m CMOS process.     

Electrostatic discharge protection design for mixed-voltage CMOS I/O buffers

A new electrostatic discharge (ESD) protection circuit, using the stacked-nMOS triggered silicon controlled rectifier (SNTSCR) as the ESD clamp device, is designed to protect the mixed-voltage I/O buffers of CMOS ICs. The new proposed ESD protection circuit, which combines the stacked-nMOS structure with the gate-coupling circuit technique into the SCR device, is fully compatible to general CMOS processes without causing the gate-oxide reliability problem. Without using the thick gate oxide, the experimental results in a 0.35 /spl mu/m CMOS process have proven that the human-body-model ESD level of the mixed-voltage I/O buffer can be successfully increased from the original /spl sim/2 kV to >8 kV by using this proposed ESD protection circuit.     

Implementation of Initial-On ESD Protection Concept With PMOS-Triggered SCR Devices in Deep-Submicron CMOS Technology

In order to enhance the applications of SCR devices for deep-submicron CMOS technology, a novel SCR design with "initial-on" function is proposed to achieve the lowest trigger voltage and the highest turn-on efficiency of SCR device for effective on-chip ESD protection. Without using the special native device (NMOS with almost zero or even negative threshold voltage) or any process modification, this initial-on SCR design is implemented by PMOS-triggered SCR device, which can be realized in general CMOS processes. This initial-on SCR design has a high enough holding voltage to avoid latchup issues in a VDD operation voltage of 2.5 V. The new proposed initial-on ESD protection design with PMOS-triggered SCR device has been successfully verified in a fully-silicided 0.25-mum CMOS process     

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.     

Substrate-triggered ESD protection circuit without extra process modification

A substrate-triggered technique is proposed to improve electrostatic discharge (ESD) protection efficiency of ESD protection circuits without extra salicide blocking and ESD-implantation process modifications in a salicided shallow-trench-isolation CMOS process. By using the layout technique, the whole ESD protection circuit can be merged into a compact device structure to enhance the substrate-triggered efficiency. This substrate-triggered design can increase ESD robustness and reduce the trigger voltage of the ESD protection device. This substrate-triggered ESD protection circuit with a field oxide device of channel width of 150 /spl mu/m can sustain a human-body-model ESD level of 3250 V without any extra process modification. Comparing to the traditional ESD protection design of gate-grounded nMOS (ggnMOS) with silicide-blocking process modification in a 0.25-/spl mu/m salicided CMOS process, the proposed substrate-triggered design without extra process modification can improve ESD robustness per unit silicon area from the original 1.2 V//spl mu/m/sup 2/ of ggnMOS to 1.73 V//spl mu/m/sup 2/.     

ESD protection design for I/O cells with embedded SCR structure as power-rail ESD clamp device in nanoscale CMOS technology

This paper presents a new electrostatic discharge (ESD) protection design for input/output (I/O) cells with embedded silicon-controlled rectifier (SCR) structure as power-rail ESD clamp device in a 130-nm CMOS process. Two new embedded SCR structures without latchup danger are proposed to be placed between the input (or output) pMOS and nMOS devices of the I/O cells. Furthermore, the turn-on efficiency of embedded SCR can be significantly increased by substrate-triggered technique. Experimental results have verified that the human-body-model (HBM) ESD level of this new proposed I/O cells can be greater than 5 kV in a 130-nm fully salicided CMOS process. By including the efficient power-rail ESD clamp device into each I/O cell, whole-chip ESD protection scheme can be successfully achieved within a small silicon area of the I/O cell.     

A gate-coupled PTLSCR/NTLSCR ESD protection circuit fordeep-submicron low-voltage CMOS ICs

A novel electrostatic discharge (ESD) protection circuit, which combines complementary low-voltage-triggered lateral SCR (LVTSCR) devices and the gate-coupling technique, is proposed to effectively protect the thinner gate oxide of deep submicron CMOS ICs without adding an extra ESD-implant mask. Gate-coupling technique is used to couple the ESD-transient voltage to the gates of the PMOS-triggered/NMOS-triggered lateral silicon controlled rectifier (SCR) (PTLSCR/NTLSCR) devices to turn on the lateral SCR devices during an ESD stress. The trigger voltage of gate-coupled lateral SCR devices can be significantly reduced by the coupling capacitor. Thus, the thinner gate oxide of the input buffers in deep-submicron low-voltage CMOS ICs can be fully protected against ESD damage. Experimental results have verified that this proposed ESD protection circuit with a trigger voltage about 7 V can provide 4.8 (3.3) times human-body-model (HBM) [machine-model (MM)] ESD failure levels while occupying 47% of layout area, as compared with a conventional CMOS ESD protection circuit     

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     

2.4GHz低噪声放大器的全芯片ESD保护设计

设计并流片验证了一种0.18μmRFCMOS工艺的2.4GHz低噪声放大器的全芯片静电放电(ESD)保护方案。对于射频(RF)I/O口的ESD防护,主要对比了二极管、可控硅(SCR)以及不同版图的互补型SCR,经流片与测试,发现岛屿状互补型SCR对I/O端口具有很好的ESD防护综合性能。对于电源口的ESD防护,主要研究了不同触发方式的ESD保护结构,结果表明,RCMOS触发SCR结构(RCMOS-SCR)具有良好的ESD鲁棒性和开启速度。基于上述结构的全芯片ESD保护设计,RF I/O口采用岛屿状布局的互补SCR结构的ESD防护设计,该ESD防护电路引入0.16dB的噪声系数和176fF的寄生电容,在人体模型(HBM)下防护能力可达6kV;电源口采用了RCMOS-SCR,实现了5kV HBM的ESD保护能力,该设计方案已经在有关企业得到应用。     

一种用于提高ESD保护器件开启速度的新型变化横向基区 掺杂结构双触发晶闸管

The turn-on speed of electrostatic discharge （ESD） protection devices is very important for the protection of the ultrathin gate oxide. A double trigger silicon controlled rectifier device （DTSCR） can be used effectively for ESD protection because it can turn on relatively quickly. The turn-on process of the DTSCR is first studied, and a formula for calculating the turn-on time of the DTSCR is derived. It is found that the turn-on time of the DTSCR is determined mainly by the base transit time of the parasitic p-n-p and n-p-n transistors. Using the variation lateral base doping （VLBD） structure can reduce the base transit time, and a novel DTSCR device with a VLBD structure （VLBD_DTSCR） is proposed for ESD protection applications. The static-state and turn-on characteristics of the VLBD DTSCR device are simulated. The simulation results show that the VLBD structure can introduce a built-in electric field in the base region of the parasitic n-p-n and p--n-p bipolar transistors to accelerate the transport of free-carriers through the base region. In the same process and layout area, the turn-on time of the VLBD DTSCR device is at least 27% less than that of the DTSCR device with the traditional uniform base doping under the same value of the trigger current.     

A novel SCR ESD protection for triple well CMOS technologies

A novel SCR structure for on-chip ESD protection implemented with a deep submicron triple well CMOS technology is presented. The triple well technology offers the possibility of biasing the p-well, on which the structure is built, under transient ESD stress conditions and independently from the substrate. This greatly affects the turn on mechanism of the structure. Unlike conventional SCR devices, the proposed p-well coupled SCR offers a reduced triggering voltage level as well as the enhanced ESD performance of the SCR devices. The turn on of this structure is realized with a common RC trigger network. The concept is supported by device simulation results     

A new on-chip ESD protection circuit with dual parasitic SCRstructures for CMOS VLSI

A new CMOS on-chip electrostatic discharge (ESD) protection circuit which consists of dual parasitic SCR structures is proposed and investigated. Experimental results show that with a small layout area of 8800 μ², the protection circuit can successfully perform negative and positive ESD protection with failure thresholds greater than ±1 and ±10 kV in machine-mode (MM) and human-body-mode (HBM) testing, respectively. The low ESD trigger voltages in both SCRs can be readily achieved through proper circuit design and without involving device or junction breakdown. The input capacitance of the proposed protection circuit is very low and no diffusion resistor between I/O pad and internal circuits is required, so it is suitable for high-speed applications. Moreover, this ESD protection circuit is fully process compatible with CMOS technologies     

Optimization on MOS-Triggered SCR Structures for On-Chip ESD Protection

MOS-triggered silicon-controlled rectifier (SCR) devices have been reported to achieve efficient on-chip electrostatic discharge (ESD) protection in deep-submicrometer CMOS technology. The channel length of the embedded MOS transistor in the MOS-triggered SCR device dominates the trigger mechanism and current distribution to govern the trigger voltage, holding voltage, on resistance, second breakdown current, and ESD robustness of the MOS-triggered SCR device. The embedded MOS transistor in the MOS-triggered SCR device should be optimized to achieve the most efficient ESD protection in advanced CMOS technology. In addition, the layout style of the embedded MOS transistor can be adjusted to improve the MOS-triggered SCR device for ESD protection.     

ESD Protection Design With On-Chip ESD Bus and High-Voltage-Tolerant ESD Clamp Circuit for Mixed-Voltage I/O Buffers

Considering gate-oxide reliability, a new electrostatic discharge (ESD) protection scheme with an on-chip ESD bus (ESD_BUS) and a high-voltage-tolerant ESD clamp circuit for 1.2/2.5 V mixed-voltage I/O interfaces is proposed. The devices used in the high-voltage-tolerant ESD clamp circuit are all 1.2 V low-voltage N- and P-type MOS devices that can be safely operated under the 2.5-V bias conditions without suffering from the gate-oxide reliability issue. The four-mode (positive-to-V_SS, negative-to-V_SS, positive-to-V_DD, and negative-to-V_DD) ESD stresses on the mixed-voltage I/O pad and pin-to-pin ESD stresses can be effectively discharged by the proposed ESD protection scheme. The experimental results verified in a 0.13-mum CMOS process have confirmed that the proposed new ESD protection scheme has high human-body model (HBM) and machine-model (MM) ESD robustness with a fast turn-on speed. The proposed new ESD protection scheme, which is designed with only low- voltage devices, is an excellent and cost-efficient solution to protect mixed-voltage I/O interfaces.     

Capacitor-couple ESD protection circuit for deep-submicronlow-voltage CMOS ASIC

Capacitor-couple technique used to lower snapback-trigger voltage and to ensure uniform ESD current distribution in deep-submicron CMOS on-chip ESD protection circuit is proposed. The coupling capacitor is realized by a poly layer right under the wire-bonding metal pad without increasing extra layout area to the pad. A timing-original design model has been derived to calculate the capacitor-couple efficiency of this proposed ESD protection circuit. Using this capacitor-couple ESD protection circuit, the thinner gate oxide of CMOS devices in deep-submicron low-voltage CMOS ASIC can be effectively protected     

ESD implantations for on-chip ESD protection with layout consideration in 0.18-/spl mu/m salicided CMOS technology

One method to enhance electrostatic discharge (ESD) robustness of the on-chip ESD protection devices is through process design by adding an extra "ESD implantation" mask. In this work, ESD robustness of nMOS devices and diodes with different ESD implantation solutions in a 0.18-/spl mu/m salicided CMOS process is investigated by experimental testchips. The second breakdown current (I/sub t2/) of the nMOS devices with these different ESD implantation solutions for on-chip ESD protection are measured by a transmission line pulse generator (TLPG). The human-body-model (HBM) and machine-model (MM) ESD levels of these devices are also investigated and compared. A significant improvement in ESD robustness is observed when an nMOS device is fabricated with both boron and arsenic ESD implantations. The ESD robustness of the N-type diode under the reverse-biased stress condition can also be improved by the boron ESD implantation. The layout consideration in multifinger MOSFETs and diodes for better ESD robustness is also investigated.     

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.     

A new multi-finger SCR-based structure for efficient on-chip ESD protection

This paper introduces a new SCR-based (silicon controlled rectifier) structure for on-chip ESD protection. The STMSCR (smart triggered multi-finger SCR) relies on the bimodal operation of a LSCR (lateral SCR) using an external triggering circuitry that permits switching from a transparency mode to a protection mode as soon as an ESD event is detected. The trigger voltage can be adjusted by design without any impact on the ESD performance. The STMSCR is multi-finger compliant, thus allowing area-efficient design of pad-located ESD protection. The STMSCR is demonstrated in a 0.18 μm CMOS technology without any process customization; an HBM failure threshold over 115 V/μm is reached while always ensuring current uniformity in multi-finger structures.     

New fast turn-on speed SCR device for electrostatic discharge protection

A new SCR with the variation lateral base doping (VLBD) structure (VSCR) is proposed to improve the turn-on speed for electrostatic discharge (ESD) protection. The turn-on speed of the SCR was determined mainly by the base transit time of the parasitic p-n-p and n-p-n transistors of the SCR, and the VLBD structure can reduce the base transit time of the bipolar transistors to improve the turn-on speed of the SCR. The experimental and simulation results show that the turn-on time of the VSCRs with the VLBD structure is 12% less than that of the MLSCR with the traditional uniform base doping without adding extra process masks and increasing the chip area.