SpecUtils

SpecUtils is a library for opening, manipulating, and exporting spectrum files produced by RadioIsotope Identification Devices (RIIDs), Radiation Portal Monitors (RPMs), radiation search systems, Personal Radiation Detectors (PRDs), and many laboratory detection systems. It opens N42 (2006 and 2012 formats), SPE, SPC, CSV, TXT, PCF, DAT, and many more files; altogether more than a 100 file format variants. The library lets you either programmatically access and/or modify the parsed information, or you can save it to any of 13 different formats.

SpecUtils provides the spectrum file format capabilities for Cambio, InterSpec, and number of other applications and websites. The library is written in cross-platform (tested on Windows, macOS, Linux, iOS, and Android) c++ with Python and Java bindings.

Using SpecUtils

If all you need is to convert spectrum files from your detector to a format you can work with, like CSV or N42, try using the command line version of Cambio - this is actually probably the most common way people and programs use SpecUtils.

But if you want to integrate SpecUtils into your program, you will need a c++11 capable compiler, boost (≥1.42), and cmake (≥3.1.). Linking your program to SpecUtils uses the standard CMake syntax, for example in your CMakeLists.txt file you would add the lines:

add_subdirectory( path/to/SpecUtils )
...
target_link_libraries( MyExe PRIVATE SpecUtils )

A minimal program to print out the channel counts of a spectrum file, and then save as a CSV data file, could then be:

#include  <stdlib.h>
#include  <iostream>
#include  "SpecUtils/SpecFile.h"

int main() {
  SpecUtils::SpecFile specfile;
  if( !specfile.load_file("input.n42", SpecUtils::ParserType::Auto) )
    return EXIT_FAILURE;
    
  for( int sample : specfile.sample_numbers() ) {
    for( std::string detector : specfile.detector_names() ) {
      std::shared_ptr<const SpecUtils::Measurement> meas = specfile.measurement( sample, detector );
      std::cout << "Sample " << sample << " detector " << detector
                << " has live time " << meas->live_time() << "s and real time "
                << meas->real_time() << "s with counts: ";
      for( size_t i = 0; i < meas->num_gamma_channels(); ++i )
        std::cout << meas->gamma_channel_content(i) << ",";
      std::cout << " with " << meas->neutron_counts_sum() << " neutrons" << std::endl;
    }
  }
  
  specfile.write_to_file( "outout,csv", SpecUtils::SaveSpectrumAsType::Csv );
  return EXIT_SUCCESS;
}

Relevant CMake Build options

• SpecUtils_ENABLE_D3_CHART [default ON]: Enabling this feature allows exporting specta to a D3.js based plotting that allows viewing and interacting with the spectra in a web browser. An example can be seen here.
  • SpecUtils_D3_SUPPORT_FILE_STATIC [default ON]: Only relevant if SpecUtils_ENABLE_D3_CHART is ON. This option determines if all the JavaScript (including D3.js, SpectrumChartD3.js, etc) and CSS should be compiled into the library, or remain as seperate files accessed at runtime.
• SpecUtils_PYTHON_BINDINGS [default OFF]: Determines if the Python bindings should be built. Boost.Python is used to generate the bindings. Have a look in test_python.py for example use of SpecUtils from python.
• SpecUtils_JAVA_SWIG [default OFF]: Determines if the Java bindings should be built. SWIG is used to generate the bindings, and an example application using them is in bindings/swig/java_example/ directory.
• PERFORM_DEVELOPER_CHECKS [default OFF]: Performs additional tests during program execution, with failed tests being output to a log file.

Features

• Parses >100 spectrum file format variants.
• Writes 13 of the most useful output file formats.
• Multithreaded and time-efficient code. For example a ~125 MB N42 file takes less than 5 seconds to parse. Accessing any of the extracted information after that is nearly instant as all the work is done upfront, and the original file is no longer referenced after the initial parse.
• Can be used from C++, Java, Python, and node.js.
• Supports Polynomial, Full Width Fraction, Lower Channel Energy, and non-Linear Deviation pair energy calibrations.
• Supports creating spectrum files from raw data (ex, can be used in a detector to write output file).
• Extracts RIID results, GPS location information, and a lot of other meta-information, depending on the input file format.
• Allows changing the meta-information.
• Tools to help rebin, re-calibrate, truncate, and combine spectra.
• And more!

Testing

This library uses a few methods to test the code, but unfortunately still likely contains bugs or issues, especially related to specific file format variants.

The testing methods are:

• Peppered throughout the code there are #if( PERFORM_DEVELOPER_CHECKS ) statements that perform additional tests at runtime that make sure the correct answer was computed or action taken. Most of these blocks of code will either recompute a quantity using an independent implementation, or in someway perform additional sanity checks, and when issues are found, they are logged to a file for fixing in the future. This seems to work well as the primary developer of this library uses the library heavily.
• An assortment of unit tests have been created and are occasionally run, but by no means offer anywhere near 100% coverage. Since many of the test contain proprietary data, they are not all distributed with the library.
• As the primary developer of this library comes across new file formats, or new variants of file formats, they get added to a library after manually verifying they are parsed sufficiently well. Then regression_test/regression_test.cpp is used to ensure the files continue to be parsed exactly the same as when they were manually verified. Any changes to the information extracted from these files will then be manually verified to be an improvement to the parsing (like adding the ability to extract GPS coordinates from a format), or the issue will be corrected. This helps keep regressions from occurring. A keystone piece to this testing is that all information extracted from any file format can be written out to a N42-2012 file; when this N42-2012 file is read back in, the exact same information is available as from the original file (this property is of course also tested for).
• Fuzz testing is periodically performed.
• Near daily use to parse a wide variety of formats by the primary developer, as well as use by users of the applications built against SpecUtils.

History

SpecUtils started to extract live-time and channel counts from two very specific detectors, for a specific application. However, over time it was split out into its own library, and new file formats and capabilities have been continually bolted on as needs arose. As such there near continual smaller changes to the interface and when resources become available larger, refactorings (there are a number planned when possible in the future). Currently the library is developed primarily as part of InterSpec, but used by a number of other applications and websites.

Authors

William Johnson is the primary author of the library. Edward Walsh wrote the Java bindings and example program, as well as lead a substantial part of the QC effort. Christian Morte is the primary developer of the D3.js charting capability. Noel Nachtigal provided extensive additional support.

License

This project is licensed under the LGPL v2.1 License - see the LICENSE.md file for details

Copyright

Copyright 2018 National Technology & Engineering Solutions of Sandia, LLC (NTESS). Under the terms of Contract DE-NA0003525 with NTESS, the U.S. Government retains certain rights in this software.

Disclaimer

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Acknowledgement

This InterSpec Software was developed with funds from the Science and Technology Directorate of the Department of Homeland Security

InterSpecSCR# 2173.1