Piet Demeester scite author profile

The number of markers measured in both flow and mass cytometry keeps increasing steadily. Although this provides a wealth of information, it becomes infeasible to analyze these datasets manually. When using 2D scatter plots, the number of possible plots increases exponentially with the number of markers and therefore, relevant information that is present in the data might be missed. In this article, we introduce a new visualization technique, called FlowSOM, which analyzes Flow or mass cytometry data using a Self-Organizing Map. Using a two-level clustering and star charts, our algorithm helps to obtain a clear overview of how all markers are behaving on all cells, and to detect subsets that might be missed otherwise. R code is available at https://github.com/SofieVG/FlowSOM and will be made available at Bioconductor. Key termsKey terms: polychromatic flow cytometry; mass cytometry; exploratory data analysis; visualization method; self-organizing map; bioinformatics AT the moment, many flow cytometry experiments are performed with seven colors or more. For mass cytometry experiments, this number is even higher. Analyzing these high-dimensional datasets is not always easy, as traditional gating relies on selection of defined cell populations. It is difficult and time-consuming to keep an overview of how markers are behaving for all these defined cell types. In practice, not all combinations of markers are examined and therefore, valuable information can remain unexamined and unnoticed.A solution to this problem is the use of advanced visualization techniques in which more information is provided than in the traditionally used scatter plots.Examples of new visualization techniques developed specifically for this purpose are Visne (1) and SPADE (2). Whereas Visne will plot all cells in a transformed twodimensional space, SPADE will cluster cells in many groups and visualize the results in a minimal spanning tree. SPADE is, however, quite slow, especially for larger datasets. For both Visne and SPADE, many plots need to be investigated to get a correct annotation of cluster boundaries and cell types.Completely automatic clustering algorithms like flowMeans, SWIFT and others (3-10) are another solution that might be considered. Yet, even when using these algorithms, it is necessary to visualize the results clearly to interpret them correctly. The problems we described before are intrinsic to using scatter plots, so the same problems remain as with traditional gating if these automatic techniques are not combined with new visualization algorithms.A self-organizing map (SOM) is an unsupervised technique for clustering and dimensionality reduction, in which a discretized representation of the input space is trained. This technique has already been used on flow cytometry data by the Flow-

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Enabling fast failure recovery in OpenFlow networks

Sharma

et al. 2011

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Abstract-OpenFlow is a novel technology designed at Stanford University which aims at decoupling the controller software from the forwarding hardware of a router or switch. The OpenFlow concept is based on the approach that the forwarding information base (FIB) of a switch can be programmed via a controller which resides at a separate hardware. The goal is to provide a standardized open management interface to the forwarding hardware of a router or switch. The aim of a project SPARC "SPlit ARchitecture Carrier grade networks" is to deploy OpenFlow in carrier grade networks. Reliability is a major issue to deploy OpenFlow in this networks. This work proposes the addition of a fast restoration mechanism in OpenFlow and evaluates the performance by comparing the switchover time and packet loss to existing restoration options in a current OpenFlow implementation.

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Power consumption modeling in optical multilayer networks

et al. 2012

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-The evaluation and reduction of energy consumption of backbone telecommunication networks has been a popular subject of academic research for the last decade. A critical parameter in these studies is the power consumption of the individual network devices. It appears that across different studies, a wide range of power values for similar equipment is used. This is a result of the scattered and limited availability of power values for optical multilayer network equipment. We propose reference power consumption values for Internet protocol/multiprotocol label switching (IP/MPLS), Ethernet, optical transport networking (OTN) and wavelength division multiplexing (WDM) equipment. In addition we present a simplified analytical power consumption model that can be used for large networks where simulation is computationally expensive or unfeasible. For illustration and evaluation purpose, we apply both calculation approaches to a case study, which includes an optical bypass scenario. Our results show that the analytical model approximates the simulation result to over 90% or higher, and that optical bypass potentially can save up to 50% of power over a non-bypass scenario.

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Radio-over-fiber-based solution to provide broadband internet access to train passengers [Topics in Optical Communications]

et al. 2007

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Piet Demeester

FlowSOM: Using self‐organizing maps for visualization and interpretation of cytometry data

Enabling fast failure recovery in OpenFlow networks

Power consumption modeling in optical multilayer networks

Radio-over-fiber-based solution to provide broadband internet access to train passengers [Topics in Optical Communications]

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