Fault simulation model for i/sub DDT/ testing: an investigation

In today's technologies, resistive shorting and open defects are becoming more predominant. Conventional fault models, and tools based on these models are becoming inadequate in addressing these defects resulting from new failure mechanisms. In prior works i/sub DDT/ testing techniques have been shown to detect resistive defects. However, in order to incorporate i/sub DDT/ based methods into production test flows, it is necessary to develop a fault simulation strategy to enable ATPG and fault coverage to be determined. To our knowledge, no practical technique exists to perform fault simulation for i/sub DDT/ based methods. At the heart of the difficulty of developing a fault simulation strategy is the analog nature of the test observable. In this paper we investigate a fault simulation model that partitions the task of simulating the CUT (chip under test) into linear and non-linear components. We also propose a path isolation strategy for core-logic as a means of reducing the computational complexity involved in deriving i/sub DDT/ signals in the non-linear portion. More specifically an Impulse Response based method is derived to eliminate the need for transient simulations of the entire CUT.

[1]  Bapiraju Vinnakota Monitoring power dissipation for fault detection , 1996, Proceedings of 14th VLSI Test Symposium.

[2]  Georges Gielen,et al.  Fault Detection And Input Stimulus Determination For The Testing Of Analog Integrated Circuits Based On Power-supply Current Monitoring , 1994, IEEE/ACM International Conference on Computer-Aided Design.

[3]  Jaime Ramírez-Angulo,et al.  I/sub DD/ pulse response testing on analog and digital CMOS circuits , 1993, Proceedings of IEEE International Test Conference - (ITC).

[4]  Sani R. Nassif,et al.  Fast power grid simulation , 2000, Proceedings 37th Design Automation Conference.

[5]  Yu-Min Lee,et al.  The power grid transient simulation in linear time based on 3D alternating-direction-implicit method , 2003, 2003 Design, Automation and Test in Europe Conference and Exhibition.

[6]  James F. Plusquellic,et al.  Detecting delay faults using power supply transient signal analysis , 2001, Proceedings International Test Conference 2001 (Cat. No.01CH37260).

[7]  Shyang-Tai Su,et al.  Transient power supply current testing of digital CMOS circuits , 1995, Proceedings of 1995 IEEE International Test Conference (ITC).

[8]  Yu-Min Lee,et al.  Power grid transient simulation in linear time based on transmission-line-modeling alternating-direction-implicit method , 2001, ICCAD 2001.

[9]  Keunmyung Lee,et al.  A bare-chip probe for high I/O, high speed testing , 1994 .

[10]  Masaki Hashizume,et al.  Fault detection of combinational circuits based on supply current , 1988, International Test Conference 1988 Proceeding@m_New Frontiers in Testing.

[11]  Jyh Herng Wang Current Wavwform Simulation for CMOS ULSI Circuits Considering Event-Overlapping , 2000 .

[12]  Alkis A. Hatzopoulos,et al.  Analogue fault identification based on power supply current spectrum , 1993 .

[13]  Luca Benini,et al.  Gate-level power and current simulation of CMOS integrated circuits , 1997, IEEE Trans. Very Large Scale Integr. Syst..

[14]  A. P. Dorey,et al.  Reliability testing by precise electrical measurement , 1988, International Test Conference 1988 Proceeding@m_New Frontiers in Testing.

[15]  Edward J. McCluskey,et al.  DELAY TESTING OF DIGITAL CIRCUITS BY OUTPUT WAVEFORM ANALYSIS , 1991, 1991, Proceedings. International Test Conference.

[16]  Charlie Chung-Ping Chen,et al.  3D thermal-ADI: an efficient chip-level transient thermal simulator , 2003, ISPD '03.

[17]  Larry D. Smith,et al.  Power distribution system design methodology and capacitor selection for modern CMOS technology , 1999 .

[18]  Wu-Shiung Feng,et al.  An accurate time-domain current waveform simulator for VLSI circuits , 1994, Proceedings of European Design and Test Conference EDAC-ETC-EUROASIC.