Monday, November 8, 2010

Maximum Error Modeling for Fault-Tolerant Computation using Maximum a posteriori (MAP) Hypothesis ( Microelectronic Reliability 2010)

Karthikeyan Lingasubramanian, Syed M. Alam, Sanjukta Bhanja, "Maximum error modeling for fault-tolerant computation using maximum a posteriori (MAP) hypothesis," Microelectronics Reliability, In Press, Corrected Proof, Available online 15 September 2010, ISSN 0026-2714, DOI: 10.1016/j.microrel.2010.07.156.

Abstract: The application of current generation computing machines in safety-centric applications like implantable biomedical chips and automobile safety has immensely increased the need for reviewing the worst-case error behavior of computing devices for fault-tolerant computation. In this work, we propose an exact probabilistic error model that can compute the maximum error over all possible input space in a circuit-specific manner and can handle various types of structural dependencies in the circuit. We also provide the worst-case input vector, which has the highest probability to generate an erroneous output, for any given logic circuit. We also present a study of circuit-specific error bounds for fault-tolerant computation in heterogeneous circuits using the maximum error computed for each circuit. We model the error estimation problem as a maximum a posteriori (MAP) estimate [28] and [29], over the joint error probability function of the entire circuit, calculated efficiently through an intelligent search of the entire input space using probabilistic traversal of a binary Join tree using Shenoy–Shafer algorithm [20] and [21]. We demonstrate this model using MCNC and ISCAS benchmark circuits and validate it using an equivalent HSpice model. Both results yield the same worst-case input vectors and the highest percentage difference of our error model over HSpice is just 1.23%. We observe that the maximum error probabilities are significantly larger than the average error probabilities, and provides a much tighter error bounds for fault-tolerant computation. We also find that the error estimates depend on the specific circuit structure and the maximum error probabilities are sensitive to the individual gate failure probabilities.

Study of Magnetization State Transistion...JAP 2011


A. Kumari, S. Sarkar, J. Pulecio, D. Karunaratne and S. Bhanja,"Study of Magnetization State Transistion in Closely-Spaced Nanomagnet 2D Array for Comuptaion", Accepted in Journal of Applied Physics, 2011.

Abstract:

The work investigated the dipole-dipole interaction for nite 2D arrays of ferromag-
netic circular nanomagnet. Starting with two basic arrangements of coupled nanomagnets namely, longitudinal and transverse, different diameter and thickness are studied. The phase plot results exhibit that for longitudinal arrangements the single domain state is pervasive over a large range of thickness values as compared to the transverse arrangement or isolated nanomagnet cases. The study is further extended to finite arrays (3 x 3 and 5 x 5) of circular nanomagnets. The magnetic force microscopy (MFM) results show that arrays of nanomagnets favors anti-ferromagnetic ordering at remanence. We have correlated our experimental results with micro-magnetic simulations. Based on our study, we can conclude that nanomagnets with 100 nm diameter, 15 nm thickness and 20 nm spacing has single domain state in an array configuration with one-step switching, which results in fast operation, a property ideal for computing.