Person:
Brown,
Kenneth R.
Brown,
Kenneth R.
Permanent Link
Associated Organization(s)
Organizational Unit
ORCID
ArchiveSpace Name Record
Publication Search Results
Now showing
1 - 4 of 4
-
ItemQuantum Computing for Science(Georgia Institute of Technology, 2017-09-26) Brown, Kenneth R.Quantum computation promises to provide scientists and engineers a new tool for accurately and efficiently calculating the properties of materials and molecules. The challenge is how to build a sufficiently large quantum computer that can compete with today's classical computer systems. After introducing the promises and challenges of quantum computers, I will discuss my group's approach to making robust quantum computers via quantum control and quantum error correction.
-
ItemChallenges of laser-cooling molecular ions(Georgia Institute of Technology, 2011-06) Nguyen, Jason H.V. ; Viteri, C. Ricardo ; Hohenstein, Edward G. ; Sherrill, C. David ; Brown, Kenneth R. ; Odom, BrianThe direct laser cooling of neutral diatomic molecules in molecular beams suggests that trapped molecular ions can also be laser cooled. The long storage time and spatial localization of trapped molecular ions provides an opportunity for multi-step cooling strategies, but also requires careful consideration of rare molecular transitions. We briefly summarize the requirements that a diatomic molecule must meet for laser cooling, and we identify a few potential molecular ion candidates. We then carry out a detailed computational study of the candidates BH+ and AlH+, including improved ab initio calculations of the electronic state potential energy surfaces and transition rates for rare dissociation events. On the basis of an analysis of the population dynamics, we determine which transitions must be addressed for laser cooling, and compare experimental schemes using continuous-wave and pulsed lasers.
-
ItemReal Time Intelligent Target Detection and Analysis with Machine Vision(Georgia Institute of Technology, 2000-06) Howard, Ayanna M. ; Padgett, Curtis ; Brown, Kenneth R.This paper presents an algorithm for detecting a specified set of target objects embedded in visual imagery for an Automatic Target Recognition (ATR) application. ATR involves processing images for detecting, classifying, and tracking targets embedded in a background scene. We address the problem of discriminating between targets and non-target objects located within a cluttered environment by evaluating 40x40 image blocks belonging to a segmented image scene. Using directed principal component analysis, the data dimensionality of an image block is first reduced and then clustered into one of n classes based on a minimum distance to a set of n cluster prototypes. Following clustering, each image pattern is fed into an associated trained neural network for classification. A detailed description of our algorithm will be given in this paper. Evaluation of the overall algorithm demonstrates that our detection rates approach 96% with a false positive rate of less than 0.03%.
-
ItemIntelligent Target Detection in Hyperspectral Imagery(Georgia Institute of Technology, 1999-03) Howard, Ayanna M. ; Padgett, Curtis ; Brown, Kenneth R.Many applications that use hyperspectral imagery focus on detection and recognition of targets that occupy a portion of a hyperspectral pixel. We address the problem of sub-pixel target detection by evaluating individual pixels belonging to a hyperspectral image scene. We begin by clustering each pixel into one of n classes based on the minimum distance to a set of n cluster prototypes. These cluster prototypes have previously been identified using a modified clustering algorithm based on prior sensed data. Associated with each cluster is a set of linear filters specifically designed to separate signatures derived from a target embedded in a background pixel from other typical signatures belonging to that cluster. The filters are found using directed principal component analysis which maximally separates the two groups. Each pixel is projected on this set of filters and the result is fed into a trained neural network for classification. A detailed description of our algorithm will be given in this paper. We outline our methodology for generating training and testing data, describe our modified clustering algorithm, explain how the linear filters are designed, and provide details on the neural network classifier. Evaluation of the overall algorithm demonstrates that for pixels with embedded targets taking up no more than 10% of the area, our detection rates approach 99.9% with a false positive rate of less than 10 ⁻⁴.