Optimal Tree Contraction in the EREW Model

High-G accelerometers are mainly used for motion measurement in some special fields, such as projectile penetration and aerospace equipment. This paper mainly explores the wavelet threshold denoising and wavelet packet threshold denoising in wavelet analysis, which is more suitable for high-G piezoresistive accelerometers. In this paper, adaptive decomposition and Shannon entropy criterion are used to find the optimal decomposition layer and optimal tree. Both methods use the Stein unbiased likelihood estimation method for soft threshold denoising. Through numerical simulation and Machete hammer test, the wavelet threshold denoising is more suitable for the dynamic calibration of a high-G accelerometer. The wavelet packet threshold denoising is more suitable for the parameter extraction of the oscillation phase.

Download Full-text

OPTIMAL TREE RANKING IS IN $\mathcal{NC}$

Parallel Processing Letters ◽

10.1142/s0129626492000155 ◽

1992 ◽

Vol 02 (01) ◽

pp. 31-41 ◽

Cited By ~ 12

Author(s):

PILAR DE LA TORRE ◽

RAYMOND GREENLAW ◽

TERESA M. PRZYTYCKA

Keyword(s):

General Problem ◽

Sequential Algorithm ◽

Natural Numbers ◽

Ranking Problem ◽

Crew Pram ◽

Optimal Tree ◽

Optimal Ranking

This paper places the optimal tree ranking problem in [Formula: see text]. A ranking is a labeling of the nodes with natural numbers such that if nodes u and v have the same label then there exists another node with a greater label on the path between them. An optimal ranking is a ranking in which the largest label assigned to any node is as small as possible among all rankings. An O(n) sequential algorithm is known. Researchers have speculated that this problem is P-complete. We show that for an n-node tree, one can compute an optimal ranking in O( log n) time using n2/ log n CREW PRAM processors. In fact, our ranking is super critical in that the label assigned to each node is absolutely as small as possible. We achieve these results by showing that a more general problem, which we call the super critical numbering problem, is in [Formula: see text]. No [Formula: see text] algorithm for the super critical tree ranking problem, approximate or otherwise, was previously known; the only known [Formula: see text] algorithm for optimal tree ranking was an approximate one.

Download Full-text

Worst-Case Optimal Tree Layout in External Memory

Algorithmica ◽

10.1007/s00453-013-9856-2 ◽

2014 ◽

Vol 72 (2) ◽

pp. 369-378 ◽

Cited By ~ 3

Author(s):

Erik D. Demaine ◽

John Iacono ◽

Stefan Langerman

Keyword(s):

External Memory ◽

Worst Case ◽

Optimal Tree

Download Full-text

Memory-constrained ML-optimal tree search detection

2008 42nd Annual Conference on Information Sciences and Systems ◽

10.1109/ciss.2008.4558671 ◽

2008 ◽

Author(s):

Yongmei Dai ◽

Zhiyuan Yan

Keyword(s):

Tree Search ◽

Optimal Tree

Download Full-text

FPGA Realization of the Reconfigurable Mesh Counting Algorithm

Journal of Circuits System and Computers ◽

10.1142/s0218126621501577 ◽

2021 ◽

pp. 2150157

Author(s):

Yosi Ben-Asher ◽

Esti Stein ◽

Vladislav Tartakovsky

Keyword(s):

Lower Bound ◽

Neural Nets ◽

Processing Elements ◽

Large Numbers ◽

Unrealistic Assumption ◽

Reconfigurable Mesh ◽

Speed Up ◽

Optimal Tree ◽

Pass Transistor ◽

Signal Switching

Pass transistor logic (PTL) is a circuit design technique wherein transistors are used as switches. The reconfigurable mesh (RM) is a model that exploits the power of PTLs signal switching, by enabling flexible bus connections in a grid of processing elements containing switches. RM algorithms have theoretical results proving that [Formula: see text] can speed up computations significantly. However, the RM assumes that the latency of broadcasting a signal through [Formula: see text] switches (bus length) is 1. This is an unrealistic assumption preventing physical realizations of the RM. We propose the restricted-RM (RRM) wherein the bus lengths are restricted to [Formula: see text], [Formula: see text]. We show that counting the number of 1-bits in an input of [Formula: see text] bits can be done in [Formula: see text] steps for [Formula: see text] by an [Formula: see text] RRM. An almost matching lower bound is presented, using a technique which adds to the few existing lower-bound techniques in this area. Finally, the algorithm was directly coded over an FPGA, outperforming an optimal tree of adders. This work presents an alternative way of counting, which is fundamental for summing, beating regular Boolean circuits for large numbers, where summing a vast amount of numbers is the basis of any accelerator in embedded systems such as neural-nets and streaming. a

Download Full-text