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Quantum Annealing Math Library

A package for programming general least squares problems on Quantum annealers.

INSTALLATION:

$ pip install git+https://github.com/tchlux/qaml.git

USAGE:

Python

This module makes the construction of least-squares energy landscapes for a quantum annealing framework easily accessible. See qaml/examples for demonstrations of how to setup and solve fixed-point least squares problems.

In order to construct arbitrary least squares circuits, this module provides a qaml.Circuit object that allows the allocations of numbers via the function Circuit.Number. The Number objects can be added, subtracted, multiplied, and exponentiated in standard Python syntax.

After manipulating (a sequence of) Number(s) into an equation, use Circuit.add( <Number> ). Multiple equations can be added to the same circuit. Once ready to minimize, construct and run the circuit with Circuit.run().

This will produce a QUBO whose energy function is the summed squared value of all equations provided. That squared-value QUBO will be executed on the selected quantum annealing system (could be a simulator like QBSolve or real D-Wave hardware). After execution, the results will be post-processed for logical consistency and presented in a human-readable format.

import qaml

# Construct a circuit with two signed 4-bit fixed precision numbers.
#   a = (  a0 * 2^[-1]  +  a1 * 2^[0]  +  a2 * 2^[1]  -  a3 * 2^[2]  )
circ = qaml.Circuit()
a = circ.Number(bits=4, exponent=-1, signed=True)
b = circ.Number(bits=4, exponent=-1, signed=True)

# Add the equations:
#     ( a + b - 6 )^2
#   + ( a - 2 )^2
circ.add( a + b - 6 )
circ.add( a - 2 )
circ.run( min_only=False, display=True )
#         ^^ Show all results, not just minimum solutions.

#                         SAMPLE OUTPUT
# ____________________________________________________________________
# 
#  QUBO with 8 bits in range [-32, 96].
#  -------------------------------------------------
#   -7.50
#    2.00   -14 
#    4.00    8     -24 
#   -8.00   -16    -32    96  
#    0.50   1.00   2.00  -4.00  -5.75
#    1.00    2      4     -8     1.00  -11
#    2.00    4      8     -16    2.00   4   -20
#   -4.00   -8     -16    32    -4.00  -8   -16  64
#  -------------------------------------------------
# 
# a    	b    	Energy 	
#   2.0	  3.5	   0.25	
#   2.5	  3.5	   0.25	
#   2.5	  3.0	    0.5	
#   2.0	  3.0	    1.0	
#   3.0	  3.0	    1.0	
#    .     .         .
#    .     .         .

Additional Information

This code is associated with a research paper. To cite, please use

Chang, T. H., Lux, T. C. H. & Tipirneni, S. S. Quantum Inf Process (2019) 18: 374.

Available from Springer, Quantum Information Processing

Please create an issue for usage questions and bug reporting.