Design on Power-Rail ESD Clamp Circuit for 3.3-V I/O Interface by Using Only 1-V/2.5-V Low-Voltage Devices in a 130-nm CMOS Process

A new power-rail electrostatic discharge (ESD) clamp circuit for application in 3.3-V mixed-voltage input–output (I/O) interface is proposed and verified in a 130-nm 1-V/2.5-V CMOS process. The devices in this power-rail ESD clamp circuit are all 1-V or 2.5-V low-voltage nMOS/pMOS devices, which are specially designed without suffering the gate-oxide reliability issue under 3.3-V I/O interface applications. A special ESD detection circuit realized with the low-voltage devices is designed and added in the power-rail ESD clamp circuit to improve ESD robustness of ESD clamp devices by substrate-triggered technique. The experimental results verified in a 130-nm CMOS process have proven the excellent effectiveness of this new proposed power-rail ESD clamp circuit.     

Low-capacitance ESD protection design for high-speed I/O interfaces in a 130-nm CMOS process

Electrostatic discharge (ESD) protection design for high-speed input/output (I/O) interface circuits in a 130-nm CMOS process is presented in this paper. First, the ESD protection diodes with different dimensions were designed and fabricated to evaluate their ESD levels and parasitic effects in gigahertz frequency band. With the knowledge of the dependence of device dimensions on ESD robustness and the parasitic capacitance, whole-chip ESD protection scheme were designed for the general receiver and transmitter interface circuits. Besides, an ESD protection scheme is proposed to improve the ESD robustness under the positive-to-V_SS (PS-mode) ESD test, which is the most critical ESD-test pin combination. With a silicon-controlled rectifier (SCR) between the I/O pad and V_SS, the clamping voltage along the PS-mode ESD current path can be reduced, so the PS-mode ESD level can be improved. Besides, the parasitic P-well/N-well diode in the SCR can provide the NS-mode ESD current path. Thus, SCR is the most promising ESD protection device in ESD protection design with low-capacitance consideration. The ESD protection scheme presented in this paper has been practically applied to an IC product with 2.5-Gb/s high-speed front-end interface.     

ESD protection design for CMOS RF integrated circuits using polysilicon diodes

ESD protection design for CMOS RF integrated circuits is proposed in this paper by using the stacked polysilicon diodes as the input ESD protection devices to reduce the total input capacitance and to avoid the noise coupling from the common substrate. The ESD level of the stacked polysilicon diodes on the I/O pad is restored by using the turn-on efficient power-rail ESD clamp circuit, which is constructed by substrate-triggered technique. This polysilicon diode is fully process compatible to general sub-quarter-micron CMOS processes.     

ESD protection design on analog pin with very low input capacitancefor high-frequency or current-mode applications

An electrostatic discharge (ESD) protection design is proposed to solve the ESD protection challenge to the analog pins: for high-frequency or current-mode applications, By including an efficient power-rails clamp circuit in the analog input/output (I/O) pin, the device dimension (W/L) of an ESD clamp device connected to the I/O pad in the analog ESD protection circuit can be reduced to only 50/0.5 (μm/μm) in a 0.35-μm silicided CMOS process, but it can sustain the human body model (HBM) and machine model (MM) ESD level of up to 6 kV (400 V). With such a smaller device dimension, the input capacitance of this analog ESD protection circuit can be significantly reduced to only ~1.0 pF (including the bond-pad capacitance) for high-frequency applications     

Design of differential low-noise amplifier with cross-coupled-SCR ESD protection scheme

The pin-to-pin electrostatic discharge (ESD) stress was one of the most critical ESD events for differential input pads. The pin-to-pin ESD issue for a differential low-noise amplifier (LNA) was studied in this work. A new ESD protection scheme for differential input pads, which was realized with cross-coupled silicon-controlled rectifier (SCR), was proposed to protect the differential LNA. The cross-coupled-SCR ESD protection scheme was modified from the conventional double-diode ESD protection scheme without adding any extra device. The SCR path was established directly from one differential input pad to the other differential input pad in this cross-coupled-SCR ESD protection scheme, so the pin-to-pin ESD robustness can be improved. The test circuits had been fabricated in a 130-nm CMOS process. Under pin-to-pin ESD stresses, the human-body-model (HBM) and machine-model (MM) ESD levels of the differential LNA with the cross-coupled-SCR ESD protection scheme are >8 kV and 800 V, respectively. Experimental results had shown that the new proposed ESD protection scheme for the differential LNA can achieve excellent ESD robustness and good RF performances.     

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.      

Overview on ESD protection design for mixed-voltage I/O interfaces with high-voltage-tolerant power-rail ESD clamp circuits in low-voltage thin-oxide CMOS technology

Electrostatic discharge (ESD) protection design for mixed-voltage I/O interfaces has been one of the key challenges of system-on-a-chip (SOC) implementation in nanoscale CMOS processes. The on-chip ESD protection circuit for mixed-voltage I/O interfaces should meet the gate-oxide reliability constraints and prevent the undesired leakage current paths. This paper presents an overview on the design concept and circuit implementations of ESD protection designs for mixed-voltage I/O interfaces with only low-voltage thin-oxide CMOS transistors. Especially, the ESD protection designs for mixed-voltage I/O interfaces with ESD bus and high-voltage-tolerant power-rail ESD clamp circuits are presented and discussed.     

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     

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.     

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.     

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。     

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.     

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。     

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.     

Area-Efficient ESD-Transient Detection Circuit With Smaller Capacitance for On-Chip Power-Rail ESD Protection in CMOS ICs

The RC-based power-rail electrostatic-discharge (ESD) clamp circuit with big field-effect transistor (BigFET) layout style in the main ESD clamp n-channel metal–oxide–semiconductor (NMOS) transistor was widely used to enhance the ESD robustness of a CMOS IC fabricated in advanced CMOS processes. To further reduce the occupied layout area of the RC in the power-rail ESD clamp circuit, a new ESD-transient detection circuit realized with smaller capacitance has been proposed and verified in a 0.13- $muhbox{m}$ CMOS process. From the experimental results, the power-rail ESD clamp circuit with the new proposed ESD-transient detection circuit can achieve a long-enough turn-on duration and higher ESD robustness under ESD stress condition, as well as better immunity against mistrigger and latch-on event under the fast-power-on condition.      

Design and implementation of configurable ESD protection cell for 60-GHz RF circuits in a 65-nm CMOS process

The configurable electrostatic discharge (ESD) protection cells have been implemented in a commercial 65-nm CMOS process for 60-GHz RF applications. The distributed ESD protection scheme was modified to be used in this work. With the consideration of parasitic capacitance from I/O pad, the ESD protection cells have reached the 50-Ω input/output matching to reduce the design complexity for RF circuit designer and to provide suitable ESD protection. Experimental results of these ESD protection cells have successfully verified the ESD robustness and the RF characteristics in the 60-GHz frequency band. These ESD protection cells can easily be used for ESD protection design in the 60-GHz RF applications, and accelerate the design cycle.     

Design and Analysis of On-Chip ESD Protection Circuit with Very Low Input Capacitance for High-Precision Analog Applications

An ESD protection design is proposed to solve the ESD protection challenge to the analog pins for high-frequency or current-mode applications. By including an efficient power-rails clamp circuit into the analog I/O pin, the device dimension (W/L) of ESD clamp device connected to the I/O pad in the analog ESD protection circuit can be reduced to only 50/0.5 (m/m) in a 0.35-m silicided CMOS process, but it can sustain the human-body-model (machine-model) ESD level of up to 6 kV (400 V). With such a smaller device dimension, the input capacitance of this analog ESD protection circuit can be significantly reduced to only 1.0 pF (including the bond pad capacitance) for high-frequency applications. A design model to find the optimized layout dimensions and spacings on the input ESD clamp devices has been also developed to keep the total input capacitance almost constant (within 1% variation), even if the analog input signal has a dynamic range of 1 V.     

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.     

一种新型低漏电ESD电源箝位电路

在到达纳米级工艺后,传统的静电放电防护(ESD)电源箝位电路的漏电对集成电路芯片的影响越来越严重。为降低漏电,设计了一种新型低漏电ESD电源箝位电路,该箝位电路通过2个最小尺寸的MOS管形成反馈来降低MOS电容两端的电压差。采用中芯国际40 nm CMOS工艺模型进行仿真,结果表明,在相同的条件下,该箝位电路的泄漏电流仅为32.59 nA,比传统箝位电路降低了2个数量级。在ESD脉冲下,该新型ESD箝位电路等效于传统电路,ESD器件有效开启。     

Design on ESD protection scheme for IC with power-down-mode operation

This paper presents a new electrostatic discharge (ESD) protection scheme for IC with power-down-mode operation. Adding a VDD ESD bus line and diodes into the proposed ESD protection scheme can block the leakage current from I/O pin to VDD power line and avoid malfunction during power-down operation. The whole-chip ESD protection design can be achieved by insertion of ESD clamp circuits between VSS power line and both the VDD power line and VDD ESD bus line. Experiment results show that the human-body model (HBM) ESD level of this new scheme can be greater than 7.5 kV in a 0.35-/spl mu/m silicided CMOS process.