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test_jamiolkowski.py
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test_jamiolkowski.py
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import numpy as np
import pygsti.tools.basistools as bt
from pygsti.models.modelconstruction import create_operation
from pygsti.modelpacks.legacy import std1Q_XYI as std1Q
from pygsti.models import ExplicitOpModel
from pygsti.baseobjs import statespace
from pygsti.baseobjs import Basis
from pygsti.tools import jamiolkowski as j
from ..util import BaseCase
class JamiolkowskiBasisTester(BaseCase):
def setUp(self):
#Set Model objects to "strict" mode for testing
ExplicitOpModel._strict = True
# density matrix == 3x3 block diagonal matrix: a 2x2 block followed by a 1x1 block
self.stateSpaceDims = [(4,), (1,)]
self.stateSpaceUDims = [(2,), (1,)]
self.std = Basis.cast('std', 9)
self.gm = Basis.cast('gm', 9)
self.stdSmall = Basis.cast('std', [4, 1])
self.gmSmall = Basis.cast('gm', [4, 1])
#labels which give a tensor product interp. for the states within each density matrix block
self.stateSpaceLabels = [('Qhappy',), ('Lsad',)]
# Adjust for deprecation of _create_operation
self.sslbls = statespace.ExplicitStateSpace(self.stateSpaceLabels, self.stateSpaceUDims)
#Build a test gate -- old # X(pi,Qhappy)*LX(pi,0,2)
self.testGate = create_operation("LX(pi,0,2)", self.sslbls, self.stdSmall)
self.testGateGM_mx = bt.change_basis(self.testGate, self.stdSmall, self.gmSmall)
self.expTestGate_mx = bt.flexible_change_basis(self.testGate, self.stdSmall, self.std)
self.expTestGateGM_mx = bt.change_basis(self.expTestGate_mx, self.std, self.gm)
def checkBasis(self, cmb):
#Op with Jamio map on gate in std and gm bases
Jmx1 = j.jamiolkowski_iso(self.testGate, op_mx_basis=self.stdSmall,
choi_mx_basis=cmb)
Jmx2 = j.jamiolkowski_iso(self.testGateGM_mx, op_mx_basis=self.gmSmall,
choi_mx_basis=cmb)
#print("Jmx1.shape = ", Jmx1.shape)
#Make sure these yield the same trace == 1 matrix
self.assertArraysAlmostEqual(Jmx1, Jmx2)
self.assertAlmostEqual(np.trace(Jmx1), 1.0)
#Op on expanded gate in std and gm bases
JmxExp1 = j.jamiolkowski_iso(self.expTestGate_mx, op_mx_basis=self.std, choi_mx_basis=cmb)
JmxExp2 = j.jamiolkowski_iso(self.expTestGateGM_mx, op_mx_basis=self.gm, choi_mx_basis=cmb)
#print("JmxExp1.shape = ", JmxExp1.shape)
#Make sure these are the same as operating on the contracted basis
self.assertArraysAlmostEqual(Jmx1, JmxExp1)
self.assertArraysAlmostEqual(Jmx1, JmxExp2)
#Reverse transform should yield back the operation matrix
revTestGate_mx = j.jamiolkowski_iso_inv(Jmx1, choi_mx_basis=cmb,
op_mx_basis=self.gmSmall)
self.assertArraysAlmostEqual(revTestGate_mx, self.testGateGM_mx)
#Reverse transform without specifying stateSpaceDims, then contraction, should yield same result
revExpTestGate_mx = j.jamiolkowski_iso_inv(Jmx1, choi_mx_basis=cmb, op_mx_basis=self.std)
self.assertArraysAlmostEqual(bt.resize_std_mx(revExpTestGate_mx, 'contract', self.std, self.stdSmall),
self.testGate)
def test_std_basis(self):
#mx_dim = sum([ int(np.sqrt(d)) for d in ])
cmb = Basis.cast('std', self.stateSpaceDims)
self.checkBasis(cmb)
def test_gm_basis(self):
#mx_dim = sum([ int(np.sqrt(d)) for d in self.stateSpaceDims])
cmb = Basis.cast('gm', self.stateSpaceDims)
self.checkBasis(cmb)
class JamiolkowskiOpsTester(BaseCase):
def setUp(self):
self.gm = Basis.cast('gm', 4)
self.pp = Basis.cast('pp', 4)
self.std = Basis.cast('std', 4)
self.mxGM = np.array([[1, 0, 0, 0],
[0, 0, 1, 0],
[0,-1, 0, 0],
[0, 0, 0, 1]], 'complex')
self.mxStd = bt.change_basis(self.mxGM, self.gm, self.std)
self.mxPP = bt.change_basis(self.mxGM, self.gm, self.pp)
def test_sum_of_negative_choi_evals(self):
sumOfNeg = j.sum_of_negative_choi_eigenvalues(std1Q.target_model())
self.assertAlmostEqual(sumOfNeg, 0.0)
sumOfNegWt = j.sum_of_negative_choi_eigenvalues(std1Q.target_model(), {'Gx': 1.0, 'Gy': 0.5})
self.assertAlmostEqual(sumOfNegWt, 0.0)
sumsOfNeg = j.sums_of_negative_choi_eigenvalues(std1Q.target_model())
self.assertArraysAlmostEqual(sumsOfNeg, np.zeros(3, 'd')) # 3 gates in std.target_model()
magsOfNeg = j.magnitudes_of_negative_choi_eigenvalues(std1Q.target_model())
self.assertArraysAlmostEqual(magsOfNeg, np.zeros(12, 'd')) # 3 gates * 4 evals each = 12
def test_fast_jamiolkowski_iso(self):
choiStd = j.jamiolkowski_iso(self.mxStd, self.std, self.std)
fastChoiStd = j.fast_jamiolkowski_iso_std(self.mxStd, self.std)
fastChoiStd2 = j.fast_jamiolkowski_iso_std(self.mxGM, self.gm)
fastChoiStd3 = j.fast_jamiolkowski_iso_std(self.mxPP, self.pp)
self.assertArraysAlmostEqual(choiStd, fastChoiStd) # Test against standard call
self.assertArraysAlmostEqual(fastChoiStd, fastChoiStd2)
self.assertArraysAlmostEqual(fastChoiStd, fastChoiStd3)
fastGateStd = j.fast_jamiolkowski_iso_std_inv(fastChoiStd, self.std)
fastGateGM = j.fast_jamiolkowski_iso_std_inv(fastChoiStd, self.gm)
fastGatePP = j.fast_jamiolkowski_iso_std_inv(fastChoiStd, self.pp)
self.assertArraysAlmostEqual(fastGateStd, self.mxStd)
self.assertArraysAlmostEqual(fastGateGM, self.mxGM)
self.assertArraysAlmostEqual(fastGatePP, self.mxPP)
def test_jamiolkowski_iso(self):
choiStd = j.jamiolkowski_iso(self.mxStd, self.std, self.std)
choiStd2 = j.jamiolkowski_iso(self.mxGM, self.gm, self.std)
choiStd3 = j.jamiolkowski_iso(self.mxPP, self.pp, self.std)
choiGM = j.jamiolkowski_iso(self.mxStd, self.std, self.gm)
choiGM2 = j.jamiolkowski_iso(self.mxGM, self.gm, self.gm)
choiGM3 = j.jamiolkowski_iso(self.mxPP, self.pp, self.gm)
choiPP = j.jamiolkowski_iso(self.mxStd, self.std, self.pp)
choiPP2 = j.jamiolkowski_iso(self.mxGM, self.gm, self.pp)
choiPP3 = j.jamiolkowski_iso(self.mxPP, self.pp, self.pp)
# Reconstruct standard matrix: GS = sum_ij Jij (BSi x BSj^*)
mxReconstruct = np.zeros_like(self.mxStd)
M = mxReconstruct.shape[0]
dmDim = int(round(np.sqrt(self.mxStd.shape[0]))) # Will need to undo renormalization
Bs = self.std.elements
for i in range(M):
for k in range(M):
term = choiStd[i, k] * np.kron(Bs[i], np.conjugate(Bs[k]))
mxReconstruct += term * dmDim
self.assertArraysAlmostEqual(mxReconstruct, self.mxStd)
self.assertArraysAlmostEqual(choiStd, choiStd2)
self.assertArraysAlmostEqual(choiStd, choiStd3)
self.assertArraysAlmostEqual(choiGM, choiGM2)
self.assertArraysAlmostEqual(choiGM, choiGM3)
self.assertArraysAlmostEqual(choiPP, choiPP2)
self.assertArraysAlmostEqual(choiPP, choiPP3)
gateStd = j.jamiolkowski_iso_inv(choiStd, self.std, self.std)
gateStd2 = j.jamiolkowski_iso_inv(choiGM, self.gm, self.std)
gateStd3 = j.jamiolkowski_iso_inv(choiPP, self.pp, self.std)
gateGM = j.jamiolkowski_iso_inv(choiStd, self.std, self.gm)
gateGM2 = j.jamiolkowski_iso_inv(choiGM, self.gm, self.gm)
gateGM3 = j.jamiolkowski_iso_inv(choiPP, self.pp, self.gm)
gatePP = j.jamiolkowski_iso_inv(choiStd, self.std, self.pp)
gatePP2 = j.jamiolkowski_iso_inv(choiGM, self.gm, self.pp)
gatePP3 = j.jamiolkowski_iso_inv(choiPP, self.pp, self.pp)
self.assertArraysAlmostEqual(gateStd, self.mxStd)
self.assertArraysAlmostEqual(gateStd2, self.mxStd)
self.assertArraysAlmostEqual(gateStd3, self.mxStd)
self.assertArraysAlmostEqual(gateGM, self.mxGM)
self.assertArraysAlmostEqual(gateGM2, self.mxGM)
self.assertArraysAlmostEqual(gateGM3, self.mxGM)
self.assertArraysAlmostEqual(gatePP, self.mxPP)
self.assertArraysAlmostEqual(gatePP2, self.mxPP)
self.assertArraysAlmostEqual(gatePP3, self.mxPP)