I. Johnson scite author profile

We demonstrate a hard-x-ray microscope that does not use a lens and is not limited to a small field of view or an object of finite size. The method does not suffer any of the physical constraints, convergence problems, or defocus ambiguities that often arise in conventional phase-retrieval diffractive imaging techniques. Calculation times are about a thousand times shorter than in current iterative algorithms. We need no a priori knowledge about the object, which can be a transmission function with both modulus and phase components. The technique has revolutionary implications for x-ray imaging of all classes of specimen.

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How to Use t-SNE Effectively

Wattenberg

Viégas

Johnson

2016

Distill

635

489

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We present a new technique called "t-SNE" that visualizes high-dimensional data by giving each datapoint a location in a two or three-dimensional map. The technique is a variation of Stochastic Neighbor Embedding (Hinton and Roweis, 2002) that is much easier to optimize, and produces significantly better visualizations by reducing the tendency to crowd points together in the center of the map. t-SNE is better than existing techniques at creating a single map that reveals structure at many different scales. This is particularly important for high-dimensional data that lie on several different, but related, low-dimensional manifolds, such as images of objects from multiple classes seen from multiple viewpoints. For visualizing the structure of very large data sets, we show how t-SNE can use random walks on neighborhood graphs to allow the implicit structure of all of the data to influence the way in which a subset of the data is displayed. We illustrate the performance of t-SNE on a wide variety of data sets and compare it with many other non-parametric visualization techniques, including Sammon mapping, Isomap, and Locally Linear Embedding. The visualizations produced by t-SNE are significantly better than those produced by the other techniques on almost all of the data sets.

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The Building Blocks of Interpretability

Olah

Satyanarayan

Johnson

et al. 2018

Distill

487

388

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STAR detector overview

Ackermann

Adams

Adler

et al. 2003

Nuclear Instruments and Methods in Physics Research Section A:

657

383

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Elliptic Flow inAu+AuCollisions at√sNN=130

Ackermann¹,

Adams²,

Adler³

et al. 2001

Phys. Rev. Lett.

631

320

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Performance of single-photon-counting PILATUS detector modules

Kraft

Bergamaschi

Broennimann³

et al. 2009

J Synchrotron Radiat

389

269

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PILATUS is a silicon hybrid pixel detector system, operating in single-photoncounting mode, that has been developed at the Paul Scherrer Institut for the needs of macromolecular crystallography at the Swiss Light Source (SLS). A calibrated PILATUS module has been characterized with monochromatic synchrotron radiation. The influence of charge sharing on the count rate and the overall energy resolution of the detector were investigated. The dead-time of the system was determined using the attenuated direct synchrotron beam. A single module detector was also tested in surface diffraction experiments at the SLS, whereby its performance regarding fluorescence suppression and saturation tolerance were evaluated, and have shown to greatly improve the sensitivity, reliability and speed of surface diffraction data acquisition.

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Three-Pion Hanbury Brown–Twiss Correlations in Relativistic Heavy-Ion Collisions from the STAR Experiment

Adams¹,

Adler²,

Ahammed³

et al. 2003

Phys. Rev. Lett.

187

246

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Data from the first physics run at the Relativistic Heavy-Ion Collider at Brookhaven National Laboratory, Au+Au collisions at √ sNN = 130 GeV, have been analyzed by the STAR Collaboration using three-pion correlations with charged pions to study whether pions are emitted independently at freezeout. We have made a high-statistics measurement of the three-pion correlation function and calculated the normalized three-particle correlator to obtain a quantitative measurement of the degree of chaoticity of the pion source. It is found that the degree of chaoticity seems to increase with increasing particle multiplicity.

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Publisher's Note:d¯and3He
Adler¹,
Ahammed²,
Allgower³
et al. 2001
Phys. Rev. Lett.
158
19
235
1
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I. Johnson

Hard-X-Ray Lensless Imaging of Extended Objects

How to Use t-SNE Effectively

The Building Blocks of Interpretability

STAR detector overview

Elliptic Flow inAu+AuCollisions at√sNN=130

Performance of single-photon-counting PILATUS detector modules

Three-Pion Hanbury Brown–Twiss Correlations in Relativistic Heavy-Ion Collisions from the STAR Experiment

Publisher's Note:d¯and3He
Adler¹,
Ahammed²,
Allgower³
et al. 2001
Phys. Rev. Lett.
158
19
235
1
View full text Add to dashboard Cite

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About

I. Johnson

Hard-X-Ray Lensless Imaging of Extended Objects

How to Use t-SNE Effectively

The Building Blocks of Interpretability

STAR detector overview

Elliptic Flow inAu+AuCollisions at√sNN=130

Performance of single-photon-counting PILATUS detector modules

Three-Pion Hanbury Brown–Twiss Correlations in Relativistic Heavy-Ion Collisions from the STAR Experiment

Publisher's Note:d¯and3HeAdler1, Ahammed2, Allgower3 et al. 2001Phys. Rev. Lett.158192351View full textAdd to dashboardCite

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Publisher's Note:d¯and3He
Adler¹,
Ahammed²,
Allgower³
et al. 2001
Phys. Rev. Lett.
158
19
235
1
View full text Add to dashboard Cite