A novel, highly SEU tolerant digital circuit design approach

In this paper, we present a new radiation tolerant CMOS standard cell library, and demonstrate its effectiveness in implementing radiation hardened digital circuits. We exploit the fact that if a gate is implemented using only PMOS (NMOS) transistors then a radiation particle strike can result only in logic a 0 to 1 (1 to 0) flip. Based on this observation, we derive our radiation hardened gates from regular static CMOS gates. In particular, we separate the PMOS and NMOS devices, and split the gate output into two signals. One of these outputs of our radiation tolerant gate is generated using PMOS transistors, and it drives other PMOS transistors (only) in its fanout. Similarly, the other output (generated from NMOS transistors) drives only other NMOS transistors in its fanout. Now, if a radiation particle strikes one of the outputs of the radiation tolerant gate, then the gates in the fanout enter a high-impedance state, and hence preserve their output values. Our radiation hardened gates exhibit an extremely high degree of SEU tolerance, which is validated at the circuit level. Using these gates, we also implement circuit level hardening based on logical masking, to selectively harden those gates in a circuit which contribute most to the soft error failure of the circuit. The gates with a low probability of logical masking are replaced by SEU tolerant gates from our new library, such that the digital design achieves a 90% soft error rate reduction. Experimental results demonstrate that this reduction is achieved with a modest layout area and delay penalty of 62% and 29% respectively, for area mapped designs. In contrast with existing approaches, our approach results in SEU immunity for extremely large critical charge values (>650fC).

[1]  G. C. Messenger,et al.  Collection of Charge on Junction Nodes from Ion Tracks , 1982, IEEE Transactions on Nuclear Science.

[2]  Joan Feynman,et al.  New interplanetary proton fluence model , 1990 .

[3]  J. Canaris An SEU immune logic family , 1991 .

[4]  J. C. Pickel,et al.  CMOS RAM Cosmic-Ray-Induced-Error-Rate Analysis , 1981, IEEE Transactions on Nuclear Science.

[5]  J. Canaris,et al.  Design And Testing Of SEU/ SEL Immune Memory And Logic Circuits In A Commercial Cmos Process , 1993, 1993 IEEE Radiation Effects Data Workshop.

[6]  Lloyd W. Massengill,et al.  Basic mechanisms and modeling of single-event upset in digital microelectronics , 2003 .

[7]  Lloyd W. Massengill,et al.  SEU error rates in advanced digital CMOS , 1993, RADECS 93. Second European Conference on Radiation and its Effects on Components and Systems (Cat. No.93TH0616-3).

[8]  A. Johnston Scaling and Technology Issues for Soft Error Rates , 2000 .

[9]  Kartik Mohanram,et al.  Gate sizing to radiation harden combinational logic , 2006, IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems.

[10]  Gwan S. Choi,et al.  A design approach for radiation-hard digital electronics , 2006, 2006 43rd ACM/IEEE Design Automation Conference.

[11]  J. Canaris,et al.  SEU hardened memory cells for a CCSDS Reed-Solomon encoder , 1991 .

[12]  Sunil P. Khatri,et al.  A Delay-efficient Radiation-hard Digital Design Approach Using CWSP Elements , 2008, 2008 Design, Automation and Test in Europe.

[13]  K. J. Hass,et al.  Single event transients in deep submicron CMOS , 1999, 42nd Midwest Symposium on Circuits and Systems (Cat. No.99CH36356).

[14]  Lorenzo Alvisi,et al.  Modeling the effect of technology trends on the soft error rate of combinational logic , 2002, Proceedings International Conference on Dependable Systems and Networks.

[15]  M. Baze,et al.  Attenuation of single event induced pulses in CMOS combinational logic , 1997 .

[16]  S. Whitaker,et al.  Low power SEU immune CMOS memory circuits , 1992 .

[17]  T. May,et al.  Alpha-particle-induced soft errors in dynamic memories , 1979, IEEE Transactions on Electron Devices.

[18]  Christos A. Papachristou,et al.  An efficient BICS design for SEUs detection and correction in semiconductor memories , 2005, Design, Automation and Test in Europe.

[19]  S. B. Gabriel,et al.  Interplanetary proton fluence model: JPL 1991 , 1993 .