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./wip/py-qnet, Tools for symbolically analyzing quantum feedback networks

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Branch: CURRENT, Version: 1.1.9, Package name: py310-qnet-1.1.9, Maintainer: jihbed.research

The QNET package is a set of tools created and compiled to aid
in the design and analysis of photonic circuit models.
Our proposed Quantum Hardware Description Language (cf. QHDL_)
serves to describe a circuit topology and specification of a larger
entity in terms of parametrizable subcomponents.
This is strongly analogous to the specification of electric circuitry
using the structural description elements of VHDL or Verilog.
The physical systems that can be modeled within the framework include
quantum optical experiments that can be described as nodes with internal
degrees of freedom such as interacting quantum harmonic oscillators
and/or N-level quantum systems that,
in turn are coupled to a finite number of external bosonic quantum fields.

Required to run:
[math/py-scipy] [math/py-numpy] [lang/python37]

Required to build:
[pkgtools/cwrappers]

Master sites:

https://files.pythonhosted.org/packages/source/Q/QNET/ (Download)

RMD160: b6abe7b085aff2c69c1bad06521be31e2c68b583
Filesize: 648.856 KB

Version history: (Expand)

(2023-02-13) Package has been reborn
(2023-02-13) Updated to version: py310-qnet-1.1.9
(2021-10-08) Updated to version: py39-qnet-1.1.9
(2020-09-29) Package has been reborn
(2020-09-29) Package deleted from pkgsrc
(2020-01-02) Package has been reborn

CVS history: (Expand)

2014-10-04 10:30:47 by Kamel Ibn Aziz Derouiche | Files touched by this commit (4)

Log message:
Import py27-qnet-1.1.9 as wip/py-qnet.

The QNET package is a set of tools created and compiled to aid
in the design and analysis of photonic circuit models.
Our proposed Quantum Hardware Description Language (cf. QHDL_)
serves to describe a circuit topology and specification of a larger
entity in terms of parametrizable subcomponents.
This is strongly analogous to the specification of electric circuitry
using the structural description elements of VHDL or Verilog.
The physical systems that can be modeled within the framework include
quantum optical experiments that can be described as nodes with internal
degrees of freedom such as interacting quantum harmonic oscillators
and/or N-level quantum systems that,
in turn are coupled to a finite number of external bosonic quantum fields.