Source: python-electrode
Section: python
Priority: optional
Maintainer: Robert Jordens <jordens@gmail.com>
Build-Depends: debhelper (>= 7), python-all-dev (>= 2.6.6-3),
 python-setuptools (>= 0.6b3), cython, python-numpy-dev, python-sphinx,
 python-nose, python-matplotlib, python-scipy, python-tk, python-numpydoc
# , python3-setuptools, python3-all-dev, python3-scipy, python3-tk
# cython3, python3-numpy-dev, python3-sphinx, python3-nose, python3-matplotlib,
X-Python-Version: >= 2.7
X-Python3-Version: < 3.0
Standards-Version: 3.9.3

Package: python-electrode-doc
Architecture: all
Section: doc
Depends: ${sphinxdoc:Depends}, ${misc:Depends}
Description: Numeric tools for RF ion traps (common documentation)
 This is the common documentation package.

Package: python-electrode
Architecture: any
Depends: ${misc:Depends}, ${python:Depends}
Recommends: mayavi2 (>= 4), python-cvxopt (>= 1), ipython-notebook (>= 0.12),
 python-shapely (>= 1.2.13), python-gdsii
Suggests: python-electrode-doc
Provides: ${python:Provides}
Description: Numeric tools for RF ion traps (Python 2)
 Electrode is a toolkit to develop and analyze RF ion traps. It
 can optimize 2D surface electrode patterns to achieve desired
 trapping properties and extract relevant parameters of the
 resulting geometry. The software also treats precomputed 3D
 volumetric field and potential data transparently.
 .
 See also:
 .
 Roman Schmied <roman.schmied@unibas.ch>, SurfacePattern
 software package.
 http://atom.physik.unibas.ch/people/romanschmied/code/SurfacePattern.php
 .
 Roman Schmied: Electrostatics of gapped and finite surface
 electrodes. New Journal of Physics 12:023038 (2010).
 http://dx.doi.org/10.1088/1367-2630/12/2/023038
 .
 Roman Schmied, Janus H. Wesenberg, and Dietrich Leibfried:
 Optimal Surface-Electrode Trap Lattices for Quantum Simulation
 with Trapped Ions. Physical Review Letters 102:233002 (2009).
 http://dx.doi.org/10.1103/PhysRevLett.102.233002
 .
 A. van Oosterom and J. Strackee: The Solid Angle of a Plane
 Triangle, IEEE Transactions on Biomedical Engineering, vol.
 BME-30, no. 2, pp. 125-126. (1983)
 http://dx.doi.org/10.1109/TBME.1983.325207
 .
 Mário H. Oliveira and José A. Miranda: Biot–Savart-like law
 in electrostatics. European Journal of Physics 22:31 (2001).
 http://dx.doi.org/10.1088/0143-0807/22/1/304

# Package: python3-electrode
# Architecture: any
# Depends: ${misc:Depends}, ${python3:Depends}
# Recommends: mayavi2 (>= 4), python3-cvxopt (>= 1), ipython3-notebook (>= 0.12),
#  python3-shapely (>= 1.2.13), python3-gdsii
# Suggests: python-electrode-doc
# Provides: ${python3:Provides}
# Description: Numeric tools for RF ion traps (Python 3)
#  Electrode is a toolkit to develop and analyze RF ion traps. It
#  can optimize 2D surface electrode patterns to achieve desired
#  trapping properties and extract relevant parameters of the
#  resulting geometry. The software also treats precomputed 3D
#  volumetric field and potential data transparently.
#  .
#  See also:
#  .
#  Roman Schmied <roman.schmied@unibas.ch>, SurfacePattern
#  software package.
#  http://atom.physik.unibas.ch/people/romanschmied/code/SurfacePattern.php
#  .
#  Roman Schmied: Electrostatics of gapped and finite surface
#  electrodes. New Journal of Physics 12:023038 (2010).
#  http://dx.doi.org/10.1088/1367-2630/12/2/023038
#  .
#  Roman Schmied, Janus H. Wesenberg, and Dietrich Leibfried:
#  Optimal Surface-Electrode Trap Lattices for Quantum Simulation
#  with Trapped Ions. Physical Review Letters 102:233002 (2009).
#  http://dx.doi.org/10.1103/PhysRevLett.102.233002
#  .
#  A. van Oosterom and J. Strackee: The Solid Angle of a Plane
#  Triangle, IEEE Transactions on Biomedical Engineering, vol.
#  BME-30, no. 2, pp. 125-126. (1983)
#  http://dx.doi.org/10.1109/TBME.1983.325207
#  .
#  Mário H. Oliveira and José A. Miranda: Biot–Savart-like law
#  in electrostatics. European Journal of Physics 22:31 (2001).
#  http://dx.doi.org/10.1088/0143-0807/22/1/304
