Abstract
Tomographic datasets collected at synchrotrons are becoming very large and complex, and, therefore, need to be managed efficiently. Raw images may have high pixel counts, and each pixel can be multidimensional and associated with additional data such as those derived from spectroscopy. In time-resolved studies, hundreds of tomographic datasets can be collected in sequence, yielding terabytes of data. Users of tomographic beamlines are drawn from various scientific disciplines, and many are keen to use tomographic reconstruction software that does not require a deep understanding of reconstruction principles. We have developed Savu, a reconstruction pipeline that enables users to rapidly reconstruct data to consistently create high-quality results. Savu is designed to work in an ‘orthogonal’ fashion, meaning that data can be converted between projection and sinogram space throughout the processing workflow as required. The Savu pipeline is modular and allows processing strategies to be optimized for users' purposes. In addition to the reconstruction algorithms themselves, it can include modules for identification of experimental problems, artefact correction, general image processing and data quality assessment. Savu is open source, open licensed and ‘facility-independent’: it can run on standard cluster infrastructure at any institution.
Highlights
Tomographic datasets collected at synchrotrons are becoming very large and complex, and, need to be managed efficiently
Users of tomographic beamlines are drawn from various scientific disciplines, and many are keen to use tomographic reconstruction software that does not require a deep understanding of reconstruction principles
The advances made on MX beamlines at Diamond Light Source (DLS) have had a clear impact on the scientific output of this community, and it follows that to deal with the large quantities of data which are being routinely collected on tomography beamlines, automation is key
Summary
The use of X-ray tomographic imaging has increased dramatically in recent years, with researchers from a broad range of scientific disciplines gaining insights from its use. Many researchers performing tomography do not have—and should not need—specialist knowledge of reconstruction methodologies in order to obtain good results and benefit from recent advances in data-processing techniques. The community is collaborating to produce common tools that can be used on all beamlines, providing users with as productive an experience as possible. There is no substitute for a clear understanding of experiments, but such automation allows experienced users to process and evaluate data at substantially increased speeds. The advances made on MX beamlines at DLS have had a clear impact on the scientific output of this community, and it follows that to deal with the large quantities of data which are being routinely collected on tomography beamlines, automation is key
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