Fencol C. C. Yung scite author profile

Abstract. We study the border minimization problem (BMP), which arises in microarray synthesis to place and embed probes in the array. The synthesis is based on a light-directed chemical process in which unintended illumination may contaminate the quality of the experiments. Border length is a measure of the amount of unintended illumination and the objective of BMP is to find a placement and embedding of probes such that the border length is minimized. The problem is believed to be NP-hard. In this paper we show that BMP admits an O( √ n log 2 n)-approximation, where n is the number of probes to be synthesized. In the case where the placement is given in advance, we show that the problem is O(log 2 n)-approximable. We also study a related problem called agreement maximization problem (AMP). In contrast to BMP, we show that AMP admits a constant approximation even when placement is not given in advance.

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Competitive Multi-dimensional Dynamic Bin Packing via L-Shape Bin Packing

Wong

Yung

2010

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Abstract. We study d-dimensional dynamic bin packing for general ddimensional boxes, for d ≥ 2. This problem is a generalization of the bin packing problem in which items may arrive and depart dynamically. Our main result is a 3 d -competitive online algorithm. We further study the 2-and 3-dimensional problem closely and improve the competitive ratios. Technically speaking, our d-dimensional result is due to a space efficient offline single bin packing algorithm, which is a variant of d-dimensional NFDH. We introduce an interesting notion of d-dimensional L-shape bin and show that effective offline packing into L-shape bin leads to effective online dynamic packing into unit-sized bins. We also investigate the resource augmentation version of the problem where the online algorithm can use d-dimensional bins of size s1 × s2 × · · ·×s d for si ≥ 1 while the optimal offline algorithm uses unit-sized bins. We give conditions for the online algorithm to match the performance of the optimal offline algorithm, i.e., 1-competitive.

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Hardness and Approximation of the Asynchronous Border Minimization Problem

Popa

Wong

Yung

2012

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We study a combinatorial problem arising from microarrays synthesis. The synthesis is done by a light-directed chemical process. The objective is to minimize unintended illumination that may contaminate the quality of experiments. Unintended illumination is measured by a notion called border length and the problem is called Border Minimization Problem (BMP). The objective of the BMP is to place a set of probe sequences in the array and find an embedding (deposition of nucleotides/residues to the array cells) such that the sum of border length is minimized. A variant of the problem, called P-BMP, is that the placement is given and the concern is simply to find the embedding.Approximation algorithms have been proposed for the problem [22] but it is unknown whether the problem is NP-hard or not. In this paper, we give a thorough study of different variations of BMP by giving NP-hardness proofs and improved approximation algorithms. We show that P-BMP, 1D-BMP, and BMP are all NP-hard. Contrast with the result in [22] that 1D-P-BMP is polynomial time solvable, the interesting implications include (i) the array dimension (1D or 2D) differentiates the complexity of P-BMP; (ii) for 1D array, whether placement is given differentiates the complexity of BMP; (iii) BMP is NP-hard regardless of the dimension of the array. Another contribution of the paper is improving the approximation for BMP from O(n 1/2 log 2 n) to O(n 1/4 log 2 n), where n is the total number of sequences.

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Fencol C. C. Yung

On Dynamic Bin Packing: An Improved Lower Bound and Resource Augmentation Analysis

Online optimization of busy time on parallel machines

Approximating Border Length for DNA Microarray Synthesis

Competitive Multi-dimensional Dynamic Bin Packing via L-Shape Bin Packing

Hardness and Approximation of the Asynchronous Border Minimization Problem

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