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.     

Overview on electrostatic discharge protection designs for mixed-voltage I/O interfaces: design concept and circuit implementations

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 nano-scale 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 the ESD protection designs for mixed-voltage I/O interfaces without using the additional thick gate-oxide process. The ESD design constraints in mixed-voltage I/O interfaces, the classification and analysis of ESD protection designs for mixed-voltage I/O interfaces, and the designs of high-voltage-tolerant power-rail ESD clamp circuit are presented and discussed.     

基于STNMOS的混合电压I／O接口ESD保护

混合电压I／O接口的静电放电（electrostaticdischarge,ESD）保护设计是小线宽工艺中片上系统（SoC）设计的主要挑战之一。混合电压I／O接口的片上ESD保护既要避免栅氧可靠性问题,又要防止不期望的泄漏电流路径产生。这篇论文讨论了基于堆叠NMOS（Stacked—NMOS,STNMOS）的混合电压I／O接口的ESD保护设计构思和电路实现,通过不同ESD保护设计方案的比较,提出了一个最有效的保护方案。     

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.     

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.     

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.     

Design of 2xVDD-tolerant mixed-voltage I/O buffer against gate-oxide reliability and hot-carrier degradation

A new 2xVDD-tolerant mixed-voltage I/O buffer circuit, realized with only 1xVDD devices in deep-submicron CMOS technology, to prevent transistors against gate-oxide reliability and hot-carrier degradation is proposed. The new proposed 2xVDD-tolerant I/O buffer has been designed and fabricated in a 0.13-μm CMOS process with only 1.2-V devices to serve a 2.5-V/1.2-V mixed-voltage interface, without using the additional thick gate-oxide (2.5-V) devices. This 2xVDD-tolerant I/O buffer has been successfully confirmed by simulation and experimental results with operating speed up to 133 MHz for PCI-X compatible applications.     

Overview and Design of Mixed-Voltage I/O Buffers With Low-Voltage Thin-Oxide CMOS Transistors

Overview on the prior designs of the mixed-voltage I/O buffers is provided in this work. A new 2.5/5-V mixed-voltage I/O buffer realized with only thin gate-oxide devices is proposed. The new proposed mixed-voltage I/O buffer with simpler dynamic n-well bias circuit and gate-tracking circuit can prevent the undesired leakage current paths and the gate-oxide reliability problem, which occur in the conventional CMOS I/O buffer. The new mixed-voltage I/O buffer has been fabricated and verified in a 0.25-$mu$m CMOS process to serve 2.5/5-V I/O interface. Besides, another 2.5/5-V mixed-voltage I/O buffer without the subthreshold leakage problem for high-speed applications is also presented in this work. The speed, power consumption, area, and noise among these mixed-voltage I/O buffers are also compared and discussed. The new proposed mixed-voltage I/O buffers can be easily scaled toward 0.18-$mu$m (or below) CMOS processes to serve other mixed-voltage I/O interfaces, such as 1.8/3.3-V interface.     

ESD protection design for mixed-voltage I/O buffer with substrate-triggered circuit

A substrate-triggered technique is proposed to improve the electrostatic discharge (ESD) robustness of a stacked-nMOS device in the mixed-voltage I/O circuit. The substrate-triggered technique can further lower the trigger voltage of a stacked-nMOS device to ensure effective ESD protection for mixed-voltage I/O circuits. The proposed ESD protection circuit with substrate-triggered design for a 2.5-V/3.3-V-tolerant mixed-voltage I/O circuit has been fabricated and verified in a 0.25-/spl mu/m salicided CMOS process. The substrate-triggered circuit for a mixed-voltage I/O buffer to meet the desired circuit application in different CMOS processes can be easily adjusted by using HSPICE simulation. Experimental results have confirmed that the human- body-model (HBM) ESD robustness of a mixed-voltage I/O circuit can be increased /spl sim/60% by this substrate-triggered design.     

A new Schmitt trigger circuit in a 0.13-/spl mu/m 1/2.5-V CMOS process to receive 3.3-V input signals

A new Schmitt trigger circuit, which is implemented by low-voltage devices to receive the high-voltage input signals without gate-oxide reliability problem, is proposed. The new proposed circuit, which can be operated in a 3.3-V signal environment without suffering high-voltage gate-oxide overstress, has been fabricated in a 0.13-/spl mu/m 1/2.5-V 1P8M CMOS process. The experimental results have confirmed that the measured transition threshold voltages of the new proposed Schmitt trigger circuit are about 1 and 2.5 V, respectively. The new proposed Schmitt trigger circuit is suitable for mixed-voltage input-output interfaces to receive input signals and reject input noise.     

Stacked-NMOS triggered silicon-controlled rectifier for ESDprotection in high/low-voltage-tolerant I/O interface

A stacked-NMOS triggered silicon-controlled rectifier (SNTSCR) is proposed as the electrostatic discharge (ESD) clamp device to protect the mixed-voltage I/O buffers of CMOS ICs. This SNTSCR device is fully compatible to general CMOS processes without using a thick gate oxide to overcome the gate-oxide reliability issue. ESD robustness of the proposed SNTSCR device with different layout parameters has been investigated in a 0.35 μm CMOS process. The HBM ESD level of the mixed-voltage I/O buffer with the stacked-NMOS channel width of 120 μm can be obviously improved from the original ~2 kV to be greater than 8 kV by this SNTSCR device with device dimensions of only 60 μm/0.35 μm     

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.     

IC设计中的ESD保护技术探讨

ESD是集成电路设计中最重要的可靠性问题之一。IC失效中约有40%与ESD/EOS(电学应力)失效有关。为了设计出高可靠性的IC,解决ESD问题是非常必要的。文中讲述一款芯片ESD版图设计,并且在0.35μm 1P3M 5V CMOS工艺中验证,成功通过HBM-3000V和MM-300V测试。这款芯片的端口可以被分成输入端口、输出端口、电源和地。为了达到人体放电模型(HBM)-3000V和机器放电模型(MM)-300V,首先要设计一个好的ESD保护网络。解决办法是先让ESD的电荷从端口流向电源或地,然后从电源或地流向其他端口。其次,给每种端口设计好的ESD保护电路,最后完成一张ESD保护电路版图。     

一种用于混合电压芯片的新型ESD防护触发电路

为了降低芯片成本,通过使用低压器件串联的方式构造静电防护触发电路,使芯片在没有使用高压I/O器件的情况下实现了高压电源域的ESD防护。由于该触发电路未使用电容器件,因此有效地降低了ESD触发电路所占用的芯片面积,并且该电路为静态电压触发,其开启时间可远长于一般电容电阻耦合的触发电路。通过在HSPICE中使用类ESD(ESD-like)的方波脉冲,可以看出该电路在发生ESD时能有效地触发ESD器件,而在芯片正常工作时不易因外界干扰而产生误触发。     

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 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.     

ESD protection to overcome internal gate-oxide damage on digital-analog interface of mixed-mode CMOS IC's

This paper reports an ESD internal gate-oxide damage occurred on the digital-analog interface of a mixed-mode CMOS IC. A new ESD protection method is proposed to rescue this internal gate-oxide damage by adding ESD-protection devices on the long metal line between digital-analog interfaces. Experimental verification has confirmed that the IC product can be rescued to pass 2-KV ESD stress from the digital/analog VDD to digital/analog VSS pads without causing any internal damage again.     

Transmission gate switch for ESD protection of RF pad

A novel transmission gate switch is proposed to effectively replace electrostatic discharge (ESD) protection resistors in CMOS I/O pads. The proposed circuit exhibits a very low on resistance, under normal operation, and a very high off resistance, in the case of ESD stresses. A triple-well CMOS implementation guarantees RF operation and enhanced ESD reliability     

Design of Mixed-Voltage-Tolerant Crystal Oscillator Circuit in Low-Voltage CMOS Technology

In the nanometer-scale CMOS technology, the gate-oxide thickness has been scaled down to provide higher operating speed with lower power supply voltage. However, regarding compatibility with the earlier defined standards or interface protocols of CMOS ICs in a microelectronics system, the chips fabricated in the advanced CMOS processes face the gate-oxide reliability problems in the interface circuits due to the voltage levels higher than normal supply voltage (1$,times,$ VDD) required by earlier applications. As a result, mixed-voltage I/O circuits realized with only thin-oxide devices had been designed with advantages of less fabrication cost and higher operating speed to communicate with the circuits at different voltage levels. In this paper, two new mixed-voltage-tolerant crystal oscillator circuits realized with low-voltage CMOS devices are proposed without suffering the gate-oxide reliability issues. The proposed mixed-voltage crystal oscillator circuits, which are one of the key I/O cells in a cell library, have been designed and verified in a 90-nm 1-V CMOS process, to serve 1-V/2-V tolerant mixed-voltage interface applications.      

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。