Your search keyword '"Yang, Yu"' showing total 2 results

1. Data Gathering with Tunable Compression in Sensor Networks.

Author

Yang Yu, Krishnamachari, Bhaskar, and Prasanna, Viktor K.

Subjects

*DATA transmission systems, *SENSOR networks, *TOPOLOGY, *STEINER systems, *APPROXIMATION theory, *ALGORITHMS, *LOGARITHMIC functions

Abstract

We study the problem of constructing a data gathering tree over a wireless sensor network in order to minimize the total energy for compressing and transporting information from a set of source nodes to the sink. This problem is crucial for advanced computation-intensive applications, where traditional "maximum" in-network compression may result in significant computation energy. We investigate a tunable data compression technique that enables effective tradeoffs between the computation and communication costs. We derive the optimal compression strategy for a given data gathering tree and then investigate the performance of different tree structures for networks deployed on a grid topology as well as general graphs. Our analytical results pertaining to the grid topology and simulation results pertaining to the general graphs indicate that the performance of a simple greedy approximation to the Minimal Steiner Tree (MST) provides a constant factor approximation for the grid topology and good average performance on the general graphs. Although theoretically, a more complicated randomized algorithm offers a poly-logarithmic performance bound, the simple greedy approximation of MST is attractive for practical implementation. [ABSTRACT FROM AUTHOR]

Published

2008

2. Ensembling Local Learners Through Multimodal Perturbation.

Author

Zhi-Hua Zhou and Yang Yu

Subjects

*LEARNING, *ALGORITHMS, *FORECASTING, *PERTURBATION theory, *APPROXIMATION theory, *STATISTICAL sampling

Abstract

Ensemble learning algorithms train multiple component learners and then combine their predictions. In order to generate a strong ensemble, the component learners should be with high accuracy as well as high diversity. A popularly used scheme in generating accurate but diverse component learners is to perturb the training data with resampling methods, such as the boot-strap sampling used in bagging. However, such a scheme is not very effective on local learners such as nearest-neighbor classifiers because a slight change in training data can hardly result in local learners with big differences. In this paper, a new ensemble algorithm named Filtered Attribute Subspace based Bagging with Injected Randomness (FASBIR) is proposed for building ensembles of local learners, which utilizes multimodal perturbation to help generate accurate but diverse component learners. In detail, FASBIR employs the perturbation on the training data with boot-strap sampling, the perturbation on the input attributes with attribute filtering and attribute subspace selection, and the perturbation on the learning parameters with randomly configured distance metrics. A large empirical study shows that FASBIR is effective in building ensembles of nearest-neighbor classifiers, whose performance is better than that of many other ensemble algorithms. [ABSTRACT FROM AUTHOR]

Published

2005