Analysis and Design of Electrostatic Discharge Protection Devices and Circuits

An electrostatic discharge (ESD) is a spontaneous electrical current that flows between two objects at different electrical potentials. ESD currents can reach several amps and are typically in the order of tens of nanoseconds. Concerning microelectronics, on-chip protection against ESD events has become a main concern on the reliability of IC as dimensions continue to shrink. ESD currents could lead to on-chip voltages that are high enough to cause MOS gate oxide breakdown. ICs can thus be damaged by human handling, contact with machinery, packaging, board assembling, etc. The main goal of this study was to analyze the effectiveness of two-stage ESD protection circuits by means of mixed mode TCAD simulations. Two-dimensional device simulations were carried out using T-Suprem4 and Taurus-Medici software from Synopsis. Also, a TCAD input deck calibration for an NXP Semiconductors¿ proprietary 0.14m¿ CMOS technology was realized. In addition, two aspects on the transparency of ESD protections were studied. An excessive leakage problem found in a real product was analyzed in TCAD. Furthermore, a new approach for distributed ESD protection design for broadband applications is also discussed, resulting in improved RF performance.Pérez Monteagudo, JM. (2010). Analysis and Design of Electrostatic Discharge Protection Devices and Circuits. http://hdl.handle.net/10251/21061.Archivo delegad

Transient Safe Operating Area (tsoa) For Esd Applications

A methodology to obtain design guidelines for gate oxide input pin protection and high voltage output pin protection in Electrostatic Discharge (ESD) time frame is developed through measurements and Technology Computer Aided Design (TCAD). A set of parameters based on transient measurements are used to define Transient Safe Operating Area (TSOA). The parameters are then used to assess effectiveness of protection devices for output and input pins. The methodology for input pins includes establishing ESD design targets under Charged Device Model (CDM) type stress in low voltage MOS inputs. The methodology for output pins includes defining ESD design targets under Human Metal Model (HMM) type stress in high voltage Laterally Diffused MOS (LDMOS) outputs. First, the assessment of standalone LDMOS robustness is performed, followed by establishment of protection design guidelines. Secondly, standalone clamp HMM robustness is evaluated and a prediction methodology for HMM type stress is developed based on standardized testing. Finally, LDMOS and protection clamp parallel protection conditions are identifie

On-Chip ESD Protection Design: Optimized Clamps

The extensive use of Integrated Circuits (ICs) means complex working conditions for these tiny chips. To guarantee the ICs could work properly in various environments, some special protection strategies are required to improve the reliability of system. From all the possible reliability issues, the electrostatics discharge (ESD) might be the most common one. The peak current of electrostatics can be as high as tens of amperes and the peak voltage can be over thousand voltages. In contrast, the size of semiconductor device fabricated is continuing to scale down, making it even more vulnerable to high level overstress and current surge induced by ESD event. To protect the on-chip semiconductor from damage, some extra clamp cells are put together to consist a network. The network can redirect the superfluous current through the ESD network and clamp the voltage to a low level. In this dissertation, one design concept is introduced that uses the combination of some basic ESD devices to meet different requirements first, and then tries to establish parasitic current path among these devices to further increase the current handling capability. Some design cases are addressed to demonstrate this design concept is valid and efficient: 1. A combination of silicon-controlled-rectifier (SCR) and diode cluster is implemented to resolve the overshoot issue under fast ESD event. 2. A new SCR structure is introduced, which can be used as padding device to increase the clamping voltage without affecting other parameters. Based on this padding device, two design cases are introduced. 3. A controllable SCR clamp structure is presented, which has high current handling capability and can be controlled with by small signal. All these structures and topologies described in this dissertation are compatible with most of popular semiconductor fabrication process

Analysis of design strategies for RF ESD problems in CMOS circuits

This thesis analyses the design strategies used to protect RF circuits that are implemented in CMOS technologies. It investigates, in detail, the physical mechanisms involved when a ggNMOS structure is exposed to an ESD event and undergoes snapback. The understanding gained is used to understand why the performance of the current RF ESD clamp is poor and suggestions are made as to how the performance of ggNMOS clamps can be improved beyond the current body of knowledge. The ultimate aim is to be able to design effective ESD protection clamps whilst minimising the effect the circuit has on RF I/O signals. A current ggNMOS based RF ESD I/O protection circuit is analysed in detail using a Transmission Line Pulse (TLP) tester. This is shown to be a very effective diagnostic tool by showing many characteristics of the ggNMOS during the triggering and conducting phase of the ESD event and demonstrate deficiencies in the clamp design. The use of a FIB enhances the analysis by allowing the isolation of individual components in the circuit and therefore their analysis using the TLP tester. SPICE simulations are used to provide further commentary on the debate surrounding the specification required of a TLP tester for there to be a good correlation between a TLP test and the industry standard Human Body Model (HBM) ESD test. Finite element simulations are used to probe deeper in to the mechanisms involved when a ggNMOS undergoes snapback especially with regard to the contribution parasitic components within the ggNMOS make to the snapback process. New ggNMOS clamps are proposed which after some modification are shown to work. Some of the finite element experiments are repeated in a 0.18μπ7. process CMOS test chip and a comparison is made between the two sets of results. In the concluding chapter understanding that has been gained from previous chapters is combined with the published body of knowledge to suggest and explain improvements in the design of a ggNMOS for RF and standard applications. These improvements will improve homogeneity of ggNMOS operation thus allowing the device size to be reduced and parasitic loading for a given ESD performance. These techniques can also be used to ensure that the ESD current does not take an unintended path through the chip

A design for testability study on a high performance automatic gain control circuit.

A comprehensive testability study on a commercial automatic gain control circuit is presented which aims to identify design for testability (DfT) modifications to both reduce production test cost and improve test quality. A fault simulation strategy based on layout extracted faults has been used to support the study. The paper proposes a number of DfT modifications at the layout, schematic and system levels together with testability. Guidelines that may well have generic applicability. Proposals for using the modifications to achieve partial self test are made and estimates of achieved fault coverage and quality levels presente

Analog-Digital System Modeling for Electromagnetic Susceptibility Prediction

The thesis is focused on the noise susceptibility of communication networks. These analog-mixed signal systems operate in an electrically noisy environment, in presence of multiple equipments connected by means of long wiring. Every module communicates using a transceiver as an interface between the local digital signaling and the data transmission through the network. Hence, the performance of the IC transceiver when affected by disturbances is one of the main factors that guarantees the EM immunity of the whole equipment. The susceptibility to RF and transient disturbances is addressed at component level on a CAN transceiver as a test case, highlighting the IC features critical for noise immunity. A novel procedure is proposed for the IC modeling for mixed-signal immunity simulations of communication networks. The procedure is based on a gray-box approach, modeling IC ports with a physical circuit and the internal links with a behavioural block. The parameters are estimated from time and frequency domain measurements, allowing accurate and efficient reproduction of non-linear device switching behaviours. The effectiveness of the modeling process is verified by applying the proposed technique to a CAN transceiver, involved in a real immunity test on a data communication link. The obtained model is successfully implemented in a commercial solver to predict both the functional signals and the RF noise immunity at component level. The noise immunity at system level is then evaluated on a complete communication network, analyzing the results of several tests on a realistic CAN bus. After developing models for wires and injection probes, a noise immunity test in avionic environment is carried out in a simulation environment, observing good overall accuracy and efficiency

Design Of Silicon Controlled Rectifers Sic] For Robust Electrostatic Discharge Protection Applications

Electrostatic Discharge (ESD) phenomenon happens everywhere in our daily life. And it can occurs through the whole lifespan of an Integrated Circuit (IC), from the early wafer fabrication process, extending to assembly operation, and finally ending at the user‟s site. It has been reported that up to 35% of total IC field failures are ESD-induced, with estimated annual costs to the IC industry running to several billion dollars. The most straightforward way to avoid the ICs suffering from the threatening of ESD damages is to develop on-chip ESD protection circuits which can afford a robust, low-impedance bypassing path to divert the ESD current to the ground. There are three different types of popular ESD protection devices widely used in the industry, and they are diodes or diodes string, Grounded-gate NMOS (GGNMOS) and Silicon Controlled Rectifier (SCR). Among these different protection solutions, SCR devices have the highest ESD current conduction capability due to the conductivity modulation effect. But SCR devices also have several shortcomings such as the higher triggering point, the lower clamping voltage etc, which will become obstacles for SCR to be widely used as an ESD protection solutions in most of the industry IC products. At first, in some applications with pin voltage goes below ground or above the VDD, dual directional protection between each two pins are desired. The traditional dual-directional SCR structures will consume a larger silicon area or lead to big leakage current issue due to the happening of punch-through effect. A new and improved SCR structure for low-triggering ESD iv applications has been proposed in this dissertation and successfully realized in a BiCMOS process. Such a structure possesses the desirable characteristics of a dual-polarity conduction, low trigger voltage, small leakage current, large failing current, adjustable holding voltage, and compact size. Another issue with SCR devices is its deep snapback or lower holding voltage, which normally will lead to the latch-up happen. To make SCR devices be immunity with latch-up, it is required to elevate its holding voltage to be larger than the circuits operational voltage, which can be several tens volts in modern power electronic circuits. Two possible solutions have been proposed to resolve this issue. One solution is accomplished by using a segmented emitter topology based on the concept that the holding voltage can be increased by reducing the emitter injection efficiency. Experimental data show that the new SCR can posses a holding voltage that is larger than 40V and a failure current It2 that is higher than 28mA/um. The other solution is accomplished by stacking several low triggering voltage high holding voltage SCR cells together. The TLP measurement results show that this novel SCR stacking structure has an extremely high holding voltage, very small snapback, and acceptable failure current. The High Holding Voltage Figure of Merit (HHVFOM) has been proposed to be a criterion for different high holding voltage solutions. The HHVFOM comparison of our proposed structures and the existing high holding voltage solutions also show the advantages of our work

Characterization of the Evolution of IC Emissions after Accelerated Aging

9 pagesInternational audienceWith the evolving technological development of integrated circuits (ICs), ensuring electromagnetic compatibility (EMC) is becoming a serious challenge for electronic circuit and system manufacturers. Although electronic components must pass a set of EMC tests to ensure safe operations, the evolution over time of EMC is not characterized and cannot be accurately forecast. This paper presents an original study about the consequences of the aging of circuits on electromagnetic emission. Different types of standard applicative and accelerated-life tests are applied on a mixed power circuit dedicated to automotive applications. Its conducted emission is measured before and after these tests showing variations in EMC performances. Comparisons between each type of aging procedure show that the emission level of the circuit under test is affected differently

ESD Protection Design Optimization Using a Mixed-Mode Simulationand

Abstract -This paper presents a new optimization method of ESD protection design using a mixed-mode ESD simulation with a calibrated model based on DC and TLP characteristics. As a result, the influence of power bus line resistance on ESD protection design is clarified using the calibrated model for each device used in ESD protection circuit. ESD surge flows into an internal circuit easily as the value of the power bus line resistance increases even if the ESD tolerance of a power clamp element is high enough