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documentcl
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@ -3,9 +3,6 @@ import matplotlib
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import numpy as np
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import numpy as np
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import json
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import json
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matplotlib.rc('font', **{'family': 'serif', 'serif': ['Computer Modern']})
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matplotlib.rc('text', usetex=True)
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matplotlib.rcParams.update({'errorbar.capsize': 2})
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matplotlib.rcParams.update({'errorbar.capsize': 2})
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results_naive = np.genfromtxt("qbit_scaling_naive.csv")
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results_naive = np.genfromtxt("qbit_scaling_naive.csv")
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@ -14,18 +11,18 @@ with open("qbit_scaling_meta.json") as fin:
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meta = json.load(fin)
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meta = json.load(fin)
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h0 = plt.errorbar(results_naive[:, 0], results_naive[:, 2]*1000, results_naive[:, 3]*1000
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h0 = plt.errorbar(results_naive[:, 0], results_naive[:, 2], results_naive[:, 3]
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, label=f"Dense Vector Simulator $N_c={int(results_naive[:, 1][0])}$ Circuits"
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, label=f"Dense Vector Simulator $N_c={int(results_naive[:, 1][0])}$ Circuits"
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, marker="o"
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, marker="o"
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, color="black")
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, color="black")
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h1 = plt.errorbar(results_graph[:, 0], results_graph[:, 2]*1000, results_graph[:, 3]*1000
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h1 = plt.errorbar(results_graph[:, 0], results_graph[:, 2], results_graph[:, 3]
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, label=f"Graphical Simulator $N_c={int(results_graph[:, 1][0])}$ Circuits"
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, label=f"Graphical Simulator $N_c={int(results_graph[:, 1][0])}$ Circuits"
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, marker="^"
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, marker="^"
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, color="black")
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, color="black")
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plt.legend(handles=[h0, h1])
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plt.legend(handles=[h0, h1])
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plt.xlabel("Number of Qbits $N_q$")
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plt.xlabel("Number of Qbits $N_q$")
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plt.ylabel("Execution Time per Circuit [ms]")
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plt.ylabel("Execution Time per Circuit [s]")
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plt.title(f"Execution Time for ${meta['ngates_per_qbit']}\\times N_q$ Gates with Random Circuits (Rescaled)")
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plt.title(f"Execution Time for ${meta['ngates_per_qbit']}\\times N_q$ Gates with Random Circuits (Rescaled)")
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plt.savefig("scaling_qbits_linear.png", dpi=400)
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plt.savefig("scaling_qbits_linear.png", dpi=400)
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@ -3,9 +3,6 @@ import matplotlib
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import numpy as np
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import numpy as np
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import json
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import json
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matplotlib.rc('font', **{'family': 'serif', 'serif': ['Computer Modern']})
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matplotlib.rc('text', usetex=True)
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matplotlib.rcParams.update({'errorbar.capsize': 2})
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matplotlib.rcParams.update({'errorbar.capsize': 2})
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results_naive = np.genfromtxt("qbit_scaling_naive.csv")
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results_naive = np.genfromtxt("qbit_scaling_naive.csv")
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@ -1,12 +1,12 @@
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@ -1,12 +1,12 @@
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@ -1,44 +1,48 @@
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@ -1,44 +1,48 @@
|
||||||
4.000000000000000000e+02 5.000000000000000000e+01 1.707738740005879585e-03 7.100286700408404613e-06
|
4.000000000000000000e+02 1.000000000000000000e+02 1.674102860051789347e-03 6.228299552356924658e-06
|
||||||
4.500000000000000000e+02 5.000000000000000000e+01 1.906502640049438820e-03 9.853300832137104791e-06
|
4.500000000000000000e+02 1.000000000000000000e+02 1.903562340048665577e-03 1.316833211606872975e-05
|
||||||
5.000000000000000000e+02 5.000000000000000000e+01 2.194008100050268747e-03 2.225048323246775191e-05
|
5.000000000000000000e+02 1.000000000000000000e+02 2.123120620053669041e-03 1.197622936239156575e-05
|
||||||
5.500000000000000000e+02 5.000000000000000000e+01 2.483741079940955578e-03 2.902929435898853839e-05
|
5.500000000000000000e+02 1.000000000000000000e+02 2.480724299966823206e-03 2.750882032957220326e-05
|
||||||
6.000000000000000000e+02 5.000000000000000000e+01 2.970475479905871751e-03 5.357547401616545894e-05
|
6.000000000000000000e+02 1.000000000000000000e+02 2.895569670145050744e-03 5.288688606734717474e-05
|
||||||
6.500000000000000000e+02 5.000000000000000000e+01 3.360749460098304622e-03 7.760192059341477707e-05
|
6.500000000000000000e+02 1.000000000000000000e+02 3.315797200011729937e-03 6.324376155582976829e-05
|
||||||
7.000000000000000000e+02 5.000000000000000000e+01 4.184713580034440245e-03 1.257844672870958591e-04
|
7.000000000000000000e+02 1.000000000000000000e+02 3.988737380132079471e-03 8.966749854463253178e-05
|
||||||
7.500000000000000000e+02 5.000000000000000000e+01 5.004965839962096513e-03 1.756539085744744525e-04
|
7.500000000000000000e+02 1.000000000000000000e+02 5.103451869799755826e-03 1.584853305380074038e-04
|
||||||
8.000000000000000000e+02 5.000000000000000000e+01 5.734667459946649927e-03 1.910387597965613972e-04
|
8.000000000000000000e+02 1.000000000000000000e+02 6.057379170051717387e-03 1.642264403316068798e-04
|
||||||
8.500000000000000000e+02 5.000000000000000000e+01 7.131355419896862752e-03 1.934052327071289392e-04
|
8.500000000000000000e+02 1.000000000000000000e+02 6.927488980109046748e-03 1.944677459404338588e-04
|
||||||
9.000000000000000000e+02 5.000000000000000000e+01 8.802635380070568394e-03 3.408876648940773542e-04
|
9.000000000000000000e+02 1.000000000000000000e+02 8.814388450155093147e-03 2.330794777089288878e-04
|
||||||
9.500000000000000000e+02 5.000000000000000000e+01 1.094996251993506954e-02 3.780652528111945248e-04
|
9.500000000000000000e+02 1.000000000000000000e+02 1.064539701990725035e-02 3.041454790179711994e-04
|
||||||
1.000000000000000000e+03 5.000000000000000000e+01 1.176883709997127853e-02 3.875201443014548758e-04
|
1.000000000000000000e+03 1.000000000000000000e+02 1.240550483009428794e-02 3.095759025769566721e-04
|
||||||
1.050000000000000000e+03 5.000000000000000000e+01 1.426043346002188635e-02 4.682970383390439679e-04
|
1.050000000000000000e+03 1.000000000000000000e+02 1.434945806995529052e-02 3.462888056603818758e-04
|
||||||
1.100000000000000000e+03 5.000000000000000000e+01 1.606511461995978676e-02 4.821875787626857496e-04
|
1.100000000000000000e+03 1.000000000000000000e+02 1.677911746977770249e-02 3.749990243690372164e-04
|
||||||
1.150000000000000000e+03 5.000000000000000000e+01 1.810014320004484090e-02 5.439479727767238936e-04
|
1.150000000000000000e+03 1.000000000000000000e+02 1.831551297967962469e-02 4.604813699809882270e-04
|
||||||
1.200000000000000000e+03 5.000000000000000000e+01 2.132428097998854272e-02 5.977411510180347153e-04
|
1.200000000000000000e+03 1.000000000000000000e+02 2.237008690015500345e-02 4.574082591796148041e-04
|
||||||
1.250000000000000000e+03 5.000000000000000000e+01 2.537384307997854124e-02 6.676700647178173504e-04
|
1.250000000000000000e+03 1.000000000000000000e+02 2.469113503011612781e-02 5.159501949634852890e-04
|
||||||
1.300000000000000000e+03 5.000000000000000000e+01 2.700082207993546174e-02 6.834614338333218136e-04
|
1.300000000000000000e+03 1.000000000000000000e+02 2.771557212010520785e-02 5.422901593142985836e-04
|
||||||
1.350000000000000000e+03 5.000000000000000000e+01 2.877831694000633489e-02 6.806464215638255433e-04
|
1.350000000000000000e+03 1.000000000000000000e+02 3.089818914999341304e-02 6.274980749590892710e-04
|
||||||
1.400000000000000000e+03 5.000000000000000000e+01 3.247053898001468070e-02 7.730662439967084590e-04
|
1.400000000000000000e+03 1.000000000000000000e+02 3.351067304993193829e-02 6.258951037710455863e-04
|
||||||
1.450000000000000000e+03 5.000000000000000000e+01 3.598561208000319173e-02 8.005966432160921409e-04
|
1.450000000000000000e+03 1.000000000000000000e+02 3.672902733014780235e-02 6.463995733058402766e-04
|
||||||
1.500000000000000000e+03 5.000000000000000000e+01 3.962553389999811521e-02 9.617593729943524914e-04
|
1.500000000000000000e+03 1.000000000000000000e+02 4.152314034017763611e-02 5.716930792484469599e-04
|
||||||
1.550000000000000000e+03 5.000000000000000000e+01 4.163353030004145888e-02 9.548479191853584576e-04
|
1.550000000000000000e+03 1.000000000000000000e+02 4.438926930015441030e-02 6.721290882549972113e-04
|
||||||
1.600000000000000000e+03 5.000000000000000000e+01 4.562790117995973310e-02 7.835441508272948316e-04
|
1.600000000000000000e+03 1.000000000000000000e+02 4.552266089023760537e-02 7.453956208500090320e-04
|
||||||
1.650000000000000000e+03 5.000000000000000000e+01 4.898105746005967237e-02 8.710963335263738599e-04
|
1.650000000000000000e+03 1.000000000000000000e+02 5.021009291991504475e-02 6.862840120510182822e-04
|
||||||
1.700000000000000000e+03 5.000000000000000000e+01 5.169834830003310067e-02 9.651211683144866882e-04
|
1.700000000000000000e+03 1.000000000000000000e+02 5.453786087025946222e-02 6.546641481410810049e-04
|
||||||
1.750000000000000000e+03 5.000000000000000000e+01 5.374540261993388662e-02 1.000999207215783841e-03
|
1.750000000000000000e+03 1.000000000000000000e+02 5.628588498999306799e-02 8.462562766021738741e-04
|
||||||
1.800000000000000000e+03 5.000000000000000000e+01 6.012160696005594551e-02 9.086338428378314819e-04
|
1.800000000000000000e+03 1.000000000000000000e+02 6.095474819019727764e-02 7.517515934752839373e-04
|
||||||
1.850000000000000000e+03 5.000000000000000000e+01 6.043908248007937717e-02 1.230395679723121118e-03
|
1.850000000000000000e+03 1.000000000000000000e+02 6.366028950997133784e-02 8.152459203989234496e-04
|
||||||
1.900000000000000000e+03 5.000000000000000000e+01 6.464911280001615912e-02 8.604282740948831793e-04
|
1.900000000000000000e+03 1.000000000000000000e+02 6.785009805011213424e-02 7.698881522351951924e-04
|
||||||
1.950000000000000000e+03 5.000000000000000000e+01 6.818929374001526933e-02 1.115434394007077832e-03
|
1.950000000000000000e+03 1.000000000000000000e+02 7.188723056995513505e-02 6.833998803979537658e-04
|
||||||
2.000000000000000000e+03 5.000000000000000000e+01 7.424652839998088782e-02 1.071955559986128735e-03
|
2.000000000000000000e+03 1.000000000000000000e+02 7.566429144997527390e-02 8.365863514799617290e-04
|
||||||
2.050000000000000000e+03 5.000000000000000000e+01 7.574371884000356825e-02 9.012814866758098739e-04
|
2.050000000000000000e+03 1.000000000000000000e+02 7.861056976002146757e-02 8.193592148539533947e-04
|
||||||
2.100000000000000000e+03 5.000000000000000000e+01 8.000210310005058389e-02 1.157114746495429376e-03
|
2.100000000000000000e+03 1.000000000000000000e+02 8.247058204007771953e-02 8.197200493282149258e-04
|
||||||
2.150000000000000000e+03 5.000000000000000000e+01 8.131804838001699398e-02 1.246651522871319254e-03
|
2.150000000000000000e+03 1.000000000000000000e+02 8.493876021024333867e-02 8.342453122990786934e-04
|
||||||
2.200000000000000000e+03 5.000000000000000000e+01 8.642062879996956215e-02 1.198064886081493755e-03
|
2.200000000000000000e+03 1.000000000000000000e+02 8.813758615971892252e-02 7.911501815949151164e-04
|
||||||
2.250000000000000000e+03 5.000000000000000000e+01 9.114948505999563577e-02 8.960646114521502153e-04
|
2.250000000000000000e+03 1.000000000000000000e+02 9.468871829980343713e-02 9.350049573202011063e-04
|
||||||
2.300000000000000000e+03 5.000000000000000000e+01 9.217601664009635043e-02 9.503993848618267530e-04
|
2.300000000000000000e+03 1.000000000000000000e+02 9.786318559981736775e-02 9.314812240165508146e-04
|
||||||
2.350000000000000000e+03 5.000000000000000000e+01 9.563625923990912159e-02 1.108765711978444571e-03
|
2.350000000000000000e+03 1.000000000000000000e+02 1.018545777700273908e-01 9.261618059141366391e-04
|
||||||
2.400000000000000000e+03 5.000000000000000000e+01 1.013627541600544690e-01 1.295486325060567429e-03
|
2.400000000000000000e+03 1.000000000000000000e+02 1.051895230298396239e-01 8.616776153947947308e-04
|
||||||
2.450000000000000000e+03 5.000000000000000000e+01 1.034756118799668861e-01 1.204635265310459924e-03
|
2.450000000000000000e+03 1.000000000000000000e+02 1.070327199899838849e-01 9.274632293436604977e-04
|
||||||
2.500000000000000000e+03 5.000000000000000000e+01 1.065721216400379451e-01 9.677911226791394888e-04
|
2.500000000000000000e+03 1.000000000000000000e+02 1.112921274800100918e-01 8.472622784928632040e-04
|
||||||
2.550000000000000000e+03 5.000000000000000000e+01 1.141797984599725174e-01 1.006250648249219911e-03
|
2.550000000000000000e+03 1.000000000000000000e+02 1.145994285400956936e-01 9.315154484987448174e-04
|
||||||
|
2.600000000000000000e+03 1.000000000000000000e+02 1.193636358499861605e-01 9.910600547399727421e-04
|
||||||
|
2.650000000000000000e+03 1.000000000000000000e+02 1.218935546997090558e-01 8.861179673363818541e-04
|
||||||
|
2.700000000000000000e+03 1.000000000000000000e+02 1.261190436399556303e-01 9.270747298007727191e-04
|
||||||
|
2.750000000000000000e+03 1.000000000000000000e+02 1.291786062698520310e-01 9.713837766685412545e-04
|
||||||
|
|
|
|
@ -1 +1 @@
|
||||||
{"nstart": 400, "nstop": 2600, "step": 50, "ncircuits": 50, "nqbits0": 100, "nqbits1": 50, "seed": 3735928559}
|
{"nstart": 400, "nstop": 2800, "step": 50, "ncircuits": 100, "nqbits0": 100, "nqbits1": 50, "seed": 3735928559}
|
|
@ -51,9 +51,9 @@ def test_scaling_circuits(state_factory
|
||||||
|
|
||||||
if __name__ == "__main__":
|
if __name__ == "__main__":
|
||||||
nstart = 400
|
nstart = 400
|
||||||
nstop = 2600
|
nstop = 2800
|
||||||
step = 50
|
step = 50
|
||||||
ncircuits = 50
|
ncircuits = 100
|
||||||
nqbits0 = 100
|
nqbits0 = 100
|
||||||
nqbits1 = 50
|
nqbits1 = 50
|
||||||
seed = 0xdeadbeef
|
seed = 0xdeadbeef
|
||||||
|
@ -65,7 +65,7 @@ if __name__ == "__main__":
|
||||||
, step
|
, step
|
||||||
, nqbits0
|
, nqbits0
|
||||||
, ncircuits
|
, ncircuits
|
||||||
, repeat=5)
|
, repeat=10)
|
||||||
np.random.seed(seed)
|
np.random.seed(seed)
|
||||||
results_graph1 = test_scaling_circuits(GraphState.new_zero_state
|
results_graph1 = test_scaling_circuits(GraphState.new_zero_state
|
||||||
, nstart
|
, nstart
|
||||||
|
@ -73,7 +73,7 @@ if __name__ == "__main__":
|
||||||
, step
|
, step
|
||||||
, nqbits1
|
, nqbits1
|
||||||
, ncircuits
|
, ncircuits
|
||||||
, repeat=4)
|
, repeat=10)
|
||||||
|
|
||||||
np.savetxt("circuit_scaling_graph0.csv", results_graph0)
|
np.savetxt("circuit_scaling_graph0.csv", results_graph0)
|
||||||
print("saved results0 to circuit_scaling_graph0.csv")
|
print("saved results0 to circuit_scaling_graph0.csv")
|
||||||
|
|
|
@ -1,34 +0,0 @@
|
||||||
from collections import deque
|
|
||||||
import matplotlib.pyplot as plt
|
|
||||||
import numpy as np
|
|
||||||
import json
|
|
||||||
|
|
||||||
from pyqcs import State, H, X, S, CZ
|
|
||||||
from pyqcs.graph.state import GraphState
|
|
||||||
from pyqcs.util.random_circuits import random_circuit
|
|
||||||
|
|
||||||
def S_with_extra_arg(act, i):
|
|
||||||
return S(act)
|
|
||||||
|
|
||||||
np.random.seed(0xdeadbeef)
|
|
||||||
|
|
||||||
circuit = random_circuit(50, 700, X, H, S_with_extra_arg, CZ)
|
|
||||||
|
|
||||||
state = circuit * GraphState.new_plus_state(50)
|
|
||||||
|
|
||||||
vops, edges = state._g_state.to_lists()
|
|
||||||
|
|
||||||
handled_edges = set()
|
|
||||||
dot_edges = deque()
|
|
||||||
|
|
||||||
for i, ngbhd in enumerate(edges):
|
|
||||||
for j in ngbhd:
|
|
||||||
if((i,j) not in handled_edges):
|
|
||||||
dot_edges.append(f"{i} -- {j}")
|
|
||||||
handled_edges |= {(i,j), (j,i)}
|
|
||||||
|
|
||||||
dot_edges_str = "\n".join(dot_edges)
|
|
||||||
|
|
||||||
dot_str = "graph graphical_state{\n" + dot_edges_str + "\n}"
|
|
||||||
|
|
||||||
print(dot_str)
|
|
|
@ -4,8 +4,6 @@ import matplotlib.pyplot as plt
|
||||||
import numpy as np
|
import numpy as np
|
||||||
import json
|
import json
|
||||||
|
|
||||||
matplotlib.rc('font', **{'family': 'serif', 'serif': ['Computer Modern']})
|
|
||||||
matplotlib.rc('text', usetex=True)
|
|
||||||
matplotlib.rcParams.update({'errorbar.capsize': 2})
|
matplotlib.rcParams.update({'errorbar.capsize': 2})
|
||||||
|
|
||||||
results_graph0 = np.genfromtxt("circuit_scaling_graph1.csv")
|
results_graph0 = np.genfromtxt("circuit_scaling_graph1.csv")
|
||||||
|
@ -14,7 +12,7 @@ with open("circuit_scaling_meta.json") as fin:
|
||||||
|
|
||||||
h0 = plt.errorbar(results_graph0[:, 0], results_graph0[:, 2], results_graph0[:, 3]
|
h0 = plt.errorbar(results_graph0[:, 0], results_graph0[:, 2], results_graph0[:, 3]
|
||||||
, label=f"Graphical Simulator $N_q={meta['nqbits1']}$ Qbits"
|
, label=f"Graphical Simulator $N_q={meta['nqbits1']}$ Qbits"
|
||||||
, marker="o"
|
, marker="^"
|
||||||
, color="black")
|
, color="black")
|
||||||
|
|
||||||
plt.legend(handles=[h0])
|
plt.legend(handles=[h0])
|
||||||
|
|
|
@ -4,8 +4,6 @@ import matplotlib.pyplot as plt
|
||||||
import numpy as np
|
import numpy as np
|
||||||
import json
|
import json
|
||||||
|
|
||||||
matplotlib.rc('font', **{'family': 'serif', 'serif': ['Computer Modern']})
|
|
||||||
matplotlib.rc('text', usetex=True)
|
|
||||||
matplotlib.rcParams.update({'errorbar.capsize': 2})
|
matplotlib.rcParams.update({'errorbar.capsize': 2})
|
||||||
|
|
||||||
results_graph0 = np.genfromtxt("circuit_scaling_graph0.csv")
|
results_graph0 = np.genfromtxt("circuit_scaling_graph0.csv")
|
||||||
|
@ -15,11 +13,11 @@ with open("circuit_scaling_meta.json") as fin:
|
||||||
|
|
||||||
h0 = plt.errorbar(results_graph0[:, 0], results_graph0[:, 2], results_graph0[:, 3]
|
h0 = plt.errorbar(results_graph0[:, 0], results_graph0[:, 2], results_graph0[:, 3]
|
||||||
, label=f"Graphical Simulator $N_q={meta['nqbits0']}$ Qbits"
|
, label=f"Graphical Simulator $N_q={meta['nqbits0']}$ Qbits"
|
||||||
, marker="o"
|
, marker="^"
|
||||||
, color="black")
|
, color="black")
|
||||||
h1 = plt.errorbar(results_graph1[:, 0], results_graph1[:, 2], results_graph1[:, 3]
|
h1 = plt.errorbar(results_graph1[:, 0], results_graph1[:, 2], results_graph1[:, 3]
|
||||||
, label=f"Graphical Simulator $N_q={meta['nqbits1']}$ Qbits"
|
, label=f"Graphical Simulator $N_q={meta['nqbits1']}$ Qbits"
|
||||||
, marker="^"
|
, marker="o"
|
||||||
, color="black")
|
, color="black")
|
||||||
|
|
||||||
plt.legend(handles=[h0, h1])
|
plt.legend(handles=[h0, h1])
|
||||||
|
|
|
@ -4,8 +4,6 @@ import matplotlib.pyplot as plt
|
||||||
import numpy as np
|
import numpy as np
|
||||||
import json
|
import json
|
||||||
|
|
||||||
matplotlib.rc('font', **{'family': 'serif', 'serif': ['Computer Modern']})
|
|
||||||
matplotlib.rc('text', usetex=True)
|
|
||||||
matplotlib.rcParams.update({'errorbar.capsize': 2})
|
matplotlib.rcParams.update({'errorbar.capsize': 2})
|
||||||
|
|
||||||
results_graph0 = np.genfromtxt("circuit_scaling_graph0_measurements.csv")
|
results_graph0 = np.genfromtxt("circuit_scaling_graph0_measurements.csv")
|
||||||
|
@ -15,11 +13,11 @@ with open("circuit_scaling_measurements_meta.json") as fin:
|
||||||
|
|
||||||
h0 = plt.errorbar(results_graph0[:, 0], results_graph0[:, 2], results_graph0[:, 3]
|
h0 = plt.errorbar(results_graph0[:, 0], results_graph0[:, 2], results_graph0[:, 3]
|
||||||
, label=f"Graphical Simulator $N_q={meta['nqbits0']}$ Qbits"
|
, label=f"Graphical Simulator $N_q={meta['nqbits0']}$ Qbits"
|
||||||
, marker="o"
|
, marker="^"
|
||||||
, color="black")
|
, color="black")
|
||||||
h1 = plt.errorbar(results_graph1[:, 0], results_graph1[:, 2], results_graph1[:, 3]
|
h1 = plt.errorbar(results_graph1[:, 0], results_graph1[:, 2], results_graph1[:, 3]
|
||||||
, label=f"Graphical Simulator $N_q={meta['nqbits1']}$ Qbits"
|
, label=f"Graphical Simulator $N_q={meta['nqbits1']}$ Qbits"
|
||||||
, marker="^"
|
, marker="o"
|
||||||
, color="black")
|
, color="black")
|
||||||
|
|
||||||
plt.legend(handles=[h0, h1])
|
plt.legend(handles=[h0, h1])
|
||||||
|
|
Before Width: | Height: | Size: 133 KiB After Width: | Height: | Size: 167 KiB |
Before Width: | Height: | Size: 160 KiB After Width: | Height: | Size: 196 KiB |
Before Width: | Height: | Size: 164 KiB After Width: | Height: | Size: 227 KiB |
Before Width: | Height: | Size: 133 KiB After Width: | Height: | Size: 183 KiB |
Before Width: | Height: | Size: 142 KiB After Width: | Height: | Size: 173 KiB |
|
@ -10,48 +10,21 @@ graph_pngs= graphs/valid_graph.png \
|
||||||
graphs/clear_vop_05.png \
|
graphs/clear_vop_05.png \
|
||||||
graphs/clear_vop_06.png
|
graphs/clear_vop_06.png
|
||||||
|
|
||||||
example_graphpngs= example_graphs/graph_apply_CZ.png \
|
|
||||||
example_graphs/graph_two_qbit_CZ_after.png \
|
|
||||||
example_graphs/graph_two_qbit_CZ_before.png \
|
|
||||||
example_graphs/graph_update_VOP.png\
|
|
||||||
example_graphs/graph_EPR_state.png\
|
|
||||||
example_graphs/graph_clear_VOPs_CZ_after.png\
|
|
||||||
example_graphs/graph_clear_VOPs_CZ_before.png\
|
|
||||||
example_graphs/graph_clear_VOPs_CZ_cleared.png
|
|
||||||
|
|
||||||
|
|
||||||
all: main_long.pdf main.pdf
|
all: main.pdf
|
||||||
|
|
||||||
main_long.pdf: main_long.tex $(graph_pngs)
|
main.pdf: main.tex $(graph_pngs)
|
||||||
$(latex) main_long
|
|
||||||
#$(bibtex) main_long
|
|
||||||
$(latex) main_long
|
|
||||||
$(pdflatex) main_long
|
|
||||||
|
|
||||||
main.pdf: main.tex $(graph_pngs) $(example_graphpngs)
|
|
||||||
$(latex) main
|
$(latex) main
|
||||||
#$(bibtex) main
|
#$(bibtex) main
|
||||||
$(latex) main
|
$(latex) main
|
||||||
$(pdflatex) main
|
$(pdflatex) main
|
||||||
|
|
||||||
|
|
||||||
graphs/%.png: graphs/%.dot
|
graphs/%.png: graphs/%.dot
|
||||||
dot $< -Tpng -o $@
|
dot $< -Tpng -o $@
|
||||||
example_graphs/%.png:example_graphs/%.py
|
|
||||||
python3 $< > tmp.dot
|
|
||||||
dot -Tpng tmp.dot -o $@
|
|
||||||
rm tmp.dot
|
|
||||||
|
|
||||||
clean:
|
clean:
|
||||||
-rm main_long.aux
|
|
||||||
-rm main_long.blg
|
|
||||||
-rm main_long.dvi
|
|
||||||
-rm main_long.log
|
|
||||||
-rm main_long.out
|
|
||||||
-rm main_long.pdf
|
|
||||||
-rm main_long.toc
|
|
||||||
-rm main_long.bbl
|
|
||||||
-rm $(graph_pngs)
|
|
||||||
-rm $(example_graphpngs)
|
|
||||||
-rm main.aux
|
-rm main.aux
|
||||||
-rm main.blg
|
-rm main.blg
|
||||||
-rm main.dvi
|
-rm main.dvi
|
||||||
|
@ -60,4 +33,4 @@ clean:
|
||||||
-rm main.pdf
|
-rm main.pdf
|
||||||
-rm main.toc
|
-rm main.toc
|
||||||
-rm main.bbl
|
-rm main.bbl
|
||||||
-(cd example_graphs && make clean)
|
-rm $(graph_pngs)
|
||||||
|
|
|
@ -1,17 +0,0 @@
|
||||||
from collections import deque
|
|
||||||
import matplotlib.pyplot as plt
|
|
||||||
import numpy as np
|
|
||||||
import json
|
|
||||||
|
|
||||||
from pyqcs import State, H, X, S, CZ, CX, list_to_circuit
|
|
||||||
from pyqcs.graph.state import GraphState
|
|
||||||
from pyqcs.util.to_diagram import circuit_to_diagram
|
|
||||||
|
|
||||||
circuit = (H(0)
|
|
||||||
| list_to_circuit([CX(i, 0) for i in range(1, 5)]))
|
|
||||||
|
|
||||||
#circuit = (list_to_circuit([H(i) for i in range(0, 5)])
|
|
||||||
# | list_to_circuit([CZ(i, 0) for i in range(1, 5)])
|
|
||||||
# | list_to_circuit([H(i) for i in range(1, 5)]))
|
|
||||||
|
|
||||||
print(circuit_to_diagram(circuit))
|
|
Before Width: | Height: | Size: 12 KiB |
|
@ -1,35 +0,0 @@
|
||||||
from collections import deque
|
|
||||||
import matplotlib.pyplot as plt
|
|
||||||
import numpy as np
|
|
||||||
import json
|
|
||||||
|
|
||||||
from pyqcs import State, H, X, S, CZ, list_to_circuit
|
|
||||||
from pyqcs.graph.state import GraphState
|
|
||||||
|
|
||||||
|
|
||||||
circuit_CZ = list_to_circuit([CZ(0, i) for i in range(1, 5)])
|
|
||||||
circuit_H = list_to_circuit([H(i) for i in range(1, 5)])
|
|
||||||
circuit = circuit_CZ | circuit_H
|
|
||||||
|
|
||||||
state = circuit * GraphState.new_plus_state(5)
|
|
||||||
|
|
||||||
vops, edges = state._g_state.to_lists()
|
|
||||||
|
|
||||||
VOP_strs = {0: "H", 2: "I"}
|
|
||||||
|
|
||||||
dot_vertex_str = "\n".join((f"{i} [label=\"{i}, VOP = {VOP_strs[v]}\"]" for i,v in enumerate(vops)))
|
|
||||||
|
|
||||||
handled_edges = set()
|
|
||||||
dot_edges = deque()
|
|
||||||
|
|
||||||
for i, ngbhd in enumerate(edges):
|
|
||||||
for j in ngbhd:
|
|
||||||
if((i,j) not in handled_edges):
|
|
||||||
dot_edges.append(f"{i} -- {j}")
|
|
||||||
handled_edges |= {(i,j), (j,i)}
|
|
||||||
|
|
||||||
dot_edges_str = "\n".join(dot_edges)
|
|
||||||
|
|
||||||
dot_str = "graph graphical_state{\n" + dot_vertex_str + "\n" + dot_edges_str + "\n}"
|
|
||||||
|
|
||||||
print(dot_str)
|
|
Before Width: | Height: | Size: 14 KiB |
|
@ -1,35 +0,0 @@
|
||||||
from collections import deque
|
|
||||||
import matplotlib.pyplot as plt
|
|
||||||
import numpy as np
|
|
||||||
import json
|
|
||||||
|
|
||||||
from pyqcs import State, H, X, S, CZ, list_to_circuit
|
|
||||||
from pyqcs.graph.state import GraphState
|
|
||||||
|
|
||||||
|
|
||||||
circuit_CZ = list_to_circuit([CZ(0, i) for i in range(1, 5)])
|
|
||||||
circuit_H = list_to_circuit([H(i) for i in range(1, 5)])
|
|
||||||
circuit = circuit_CZ | circuit_H | (H(2) | S(2)) | CZ(2, 0)
|
|
||||||
|
|
||||||
state = circuit * GraphState.new_plus_state(5)
|
|
||||||
|
|
||||||
vops, edges = state._g_state.to_lists()
|
|
||||||
|
|
||||||
VOP_strs = {0: "H", 1: "S", 2: "I"}
|
|
||||||
|
|
||||||
dot_vertex_str = "\n".join((f"{i} [label=\"{i}, VOP = {VOP_strs[v]}\"]" for i,v in enumerate(vops)))
|
|
||||||
|
|
||||||
handled_edges = set()
|
|
||||||
dot_edges = deque()
|
|
||||||
|
|
||||||
for i, ngbhd in enumerate(edges):
|
|
||||||
for j in ngbhd:
|
|
||||||
if((i,j) not in handled_edges):
|
|
||||||
dot_edges.append(f"{i} -- {j}")
|
|
||||||
handled_edges |= {(i,j), (j,i)}
|
|
||||||
|
|
||||||
dot_edges_str = "\n".join(dot_edges)
|
|
||||||
|
|
||||||
dot_str = "graph graphical_state{\n" + dot_vertex_str + "\n" + dot_edges_str + "\n}"
|
|
||||||
|
|
||||||
print(dot_str)
|
|
Before Width: | Height: | Size: 31 KiB |
|
@ -1,35 +0,0 @@
|
||||||
from collections import deque
|
|
||||||
import matplotlib.pyplot as plt
|
|
||||||
import numpy as np
|
|
||||||
import json
|
|
||||||
|
|
||||||
from pyqcs import State, H, X, S, CZ, list_to_circuit
|
|
||||||
from pyqcs.graph.state import GraphState
|
|
||||||
|
|
||||||
|
|
||||||
circuit_CZ = list_to_circuit([CZ(0, i) for i in range(1, 5)])
|
|
||||||
circuit_H = list_to_circuit([H(i) for i in range(1, 5)])
|
|
||||||
circuit = circuit_CZ | CZ(3, 1) | CZ(2, 4) | circuit_H | CZ(2, 1)
|
|
||||||
|
|
||||||
state = circuit * GraphState.new_plus_state(5)
|
|
||||||
|
|
||||||
vops, edges = state._g_state.to_lists()
|
|
||||||
|
|
||||||
VOP_strs = {0: "H", 1: "S", 2: "I", 3:"HS", 5: "Z"}
|
|
||||||
|
|
||||||
dot_vertex_str = "\n".join((f"{i} [label=\"{i}, VOP = {VOP_strs[v]}\"]" for i,v in enumerate(vops)))
|
|
||||||
|
|
||||||
handled_edges = set()
|
|
||||||
dot_edges = deque()
|
|
||||||
|
|
||||||
for i, ngbhd in enumerate(edges):
|
|
||||||
for j in ngbhd:
|
|
||||||
if((i,j) not in handled_edges):
|
|
||||||
dot_edges.append(f"{i} -- {j}")
|
|
||||||
handled_edges |= {(i,j), (j,i)}
|
|
||||||
|
|
||||||
dot_edges_str = "\n".join(dot_edges)
|
|
||||||
|
|
||||||
dot_str = "graph graphical_state{\n" + dot_vertex_str + "\n" + dot_edges_str + "\n}"
|
|
||||||
|
|
||||||
print(dot_str)
|
|
Before Width: | Height: | Size: 27 KiB |
|
@ -1,35 +0,0 @@
|
||||||
from collections import deque
|
|
||||||
import matplotlib.pyplot as plt
|
|
||||||
import numpy as np
|
|
||||||
import json
|
|
||||||
|
|
||||||
from pyqcs import State, H, X, S, CZ, list_to_circuit
|
|
||||||
from pyqcs.graph.state import GraphState
|
|
||||||
|
|
||||||
|
|
||||||
circuit_CZ = list_to_circuit([CZ(0, i) for i in range(1, 5)])
|
|
||||||
circuit_H = list_to_circuit([H(i) for i in range(1, 5)])
|
|
||||||
circuit = circuit_CZ | CZ(3, 1) | CZ(2, 4) | circuit_H# | CZ(2, 1)
|
|
||||||
|
|
||||||
state = circuit * GraphState.new_plus_state(5)
|
|
||||||
|
|
||||||
vops, edges = state._g_state.to_lists()
|
|
||||||
|
|
||||||
VOP_strs = {0: "H", 1: "S", 2: "I", 3:"HS"}
|
|
||||||
|
|
||||||
dot_vertex_str = "\n".join((f"{i} [label=\"{i}, VOP = {VOP_strs[v]}\"]" for i,v in enumerate(vops)))
|
|
||||||
|
|
||||||
handled_edges = set()
|
|
||||||
dot_edges = deque()
|
|
||||||
|
|
||||||
for i, ngbhd in enumerate(edges):
|
|
||||||
for j in ngbhd:
|
|
||||||
if((i,j) not in handled_edges):
|
|
||||||
dot_edges.append(f"{i} -- {j}")
|
|
||||||
handled_edges |= {(i,j), (j,i)}
|
|
||||||
|
|
||||||
dot_edges_str = "\n".join(dot_edges)
|
|
||||||
|
|
||||||
dot_str = "graph graphical_state{\n" + dot_vertex_str + "\n" + dot_edges_str + "\n}"
|
|
||||||
|
|
||||||
print(dot_str)
|
|
Before Width: | Height: | Size: 32 KiB |
|
@ -1,35 +0,0 @@
|
||||||
from collections import deque
|
|
||||||
import matplotlib.pyplot as plt
|
|
||||||
import numpy as np
|
|
||||||
import json
|
|
||||||
|
|
||||||
from pyqcs import State, H, X, S, CZ, list_to_circuit
|
|
||||||
from pyqcs.graph.state import GraphState
|
|
||||||
|
|
||||||
|
|
||||||
circuit_CZ = list_to_circuit([CZ(0, i) for i in range(1, 5)])
|
|
||||||
circuit_H = list_to_circuit([H(i) for i in range(1, 5)])
|
|
||||||
circuit = circuit_CZ | CZ(3, 1) | CZ(2, 4) | circuit_H | CZ(2, 1) | CZ(2, 1)
|
|
||||||
|
|
||||||
state = circuit * GraphState.new_plus_state(5)
|
|
||||||
|
|
||||||
vops, edges = state._g_state.to_lists()
|
|
||||||
|
|
||||||
VOP_strs = {0: "H", 1: "S", 2: "I", 3:"HS", 5: "Z"}
|
|
||||||
|
|
||||||
dot_vertex_str = "\n".join((f"{i} [label=\"{i}, VOP = {VOP_strs[v]}\"]" for i,v in enumerate(vops)))
|
|
||||||
|
|
||||||
handled_edges = set()
|
|
||||||
dot_edges = deque()
|
|
||||||
|
|
||||||
for i, ngbhd in enumerate(edges):
|
|
||||||
for j in ngbhd:
|
|
||||||
if((i,j) not in handled_edges):
|
|
||||||
dot_edges.append(f"{i} -- {j}")
|
|
||||||
handled_edges |= {(i,j), (j,i)}
|
|
||||||
|
|
||||||
dot_edges_str = "\n".join(dot_edges)
|
|
||||||
|
|
||||||
dot_str = "graph graphical_state{\n" + dot_vertex_str + "\n" + dot_edges_str + "\n}"
|
|
||||||
|
|
||||||
print(dot_str)
|
|
Before Width: | Height: | Size: 8.2 KiB |
|
@ -1,34 +0,0 @@
|
||||||
from collections import deque
|
|
||||||
import matplotlib.pyplot as plt
|
|
||||||
import numpy as np
|
|
||||||
import json
|
|
||||||
|
|
||||||
from pyqcs import State, H, X, S, CZ, list_to_circuit
|
|
||||||
from pyqcs.graph.state import GraphState
|
|
||||||
|
|
||||||
|
|
||||||
circuit = (S(0) | H(1) | S(1) | H(1)) | CZ(0, 1)
|
|
||||||
|
|
||||||
state = circuit * GraphState.new_plus_state(2)
|
|
||||||
|
|
||||||
vops, edges = state._g_state.to_lists()
|
|
||||||
|
|
||||||
VOP_strs = {0: "H", 2: "I", 3: "HS", 12: "HSH", 1: "S"}
|
|
||||||
|
|
||||||
dot_vertex_str = "\n".join((f"{i} [label=\"{i}, VOP = {VOP_strs[v]}\"]" for i,v in enumerate(vops)))
|
|
||||||
|
|
||||||
handled_edges = set()
|
|
||||||
dot_edges = deque()
|
|
||||||
|
|
||||||
for i, ngbhd in enumerate(edges):
|
|
||||||
for j in ngbhd:
|
|
||||||
if((i,j) not in handled_edges):
|
|
||||||
dot_edges.append(f"{i} -- {j}")
|
|
||||||
handled_edges |= {(i,j), (j,i)}
|
|
||||||
|
|
||||||
dot_edges_str = "\n".join(dot_edges)
|
|
||||||
|
|
||||||
dot_str = "graph graphical_state{\n" + dot_vertex_str + "\n" + dot_edges_str + "\n}"
|
|
||||||
|
|
||||||
print(dot_str)
|
|
||||||
|
|
Before Width: | Height: | Size: 7.6 KiB |
|
@ -1,34 +0,0 @@
|
||||||
from collections import deque
|
|
||||||
import matplotlib.pyplot as plt
|
|
||||||
import numpy as np
|
|
||||||
import json
|
|
||||||
|
|
||||||
from pyqcs import State, H, X, S, CZ, list_to_circuit
|
|
||||||
from pyqcs.graph.state import GraphState
|
|
||||||
|
|
||||||
|
|
||||||
circuit = S(0) | H(1) | S(1) | H(1)
|
|
||||||
|
|
||||||
state = circuit * GraphState.new_plus_state(2)
|
|
||||||
|
|
||||||
vops, edges = state._g_state.to_lists()
|
|
||||||
|
|
||||||
VOP_strs = {0: "H", 2: "I", 3: "HS", 12: "HSH", 1: "S"}
|
|
||||||
|
|
||||||
dot_vertex_str = "\n".join((f"{i} [label=\"{i}, VOP = {VOP_strs[v]}\"]" for i,v in enumerate(vops)))
|
|
||||||
|
|
||||||
handled_edges = set()
|
|
||||||
dot_edges = deque()
|
|
||||||
|
|
||||||
for i, ngbhd in enumerate(edges):
|
|
||||||
for j in ngbhd:
|
|
||||||
if((i,j) not in handled_edges):
|
|
||||||
dot_edges.append(f"{i} -- {j}")
|
|
||||||
handled_edges |= {(i,j), (j,i)}
|
|
||||||
|
|
||||||
dot_edges_str = "\n".join(dot_edges)
|
|
||||||
|
|
||||||
dot_str = "graph graphical_state{\n" + dot_vertex_str + "\n" + dot_edges_str + "\n}"
|
|
||||||
|
|
||||||
print(dot_str)
|
|
||||||
|
|
Before Width: | Height: | Size: 18 KiB |
|
@ -1,35 +0,0 @@
|
||||||
from collections import deque
|
|
||||||
import matplotlib.pyplot as plt
|
|
||||||
import numpy as np
|
|
||||||
import json
|
|
||||||
|
|
||||||
from pyqcs import State, H, X, S, CZ, list_to_circuit
|
|
||||||
from pyqcs.graph.state import GraphState
|
|
||||||
|
|
||||||
|
|
||||||
circuit_CZ = list_to_circuit([CZ(0, i) for i in range(1, 5)])
|
|
||||||
circuit_H = list_to_circuit([H(i) for i in range(1, 5)])
|
|
||||||
circuit = circuit_CZ | circuit_H | (H(2) | S(2))
|
|
||||||
|
|
||||||
state = circuit * GraphState.new_plus_state(5)
|
|
||||||
|
|
||||||
vops, edges = state._g_state.to_lists()
|
|
||||||
|
|
||||||
VOP_strs = {0: "H", 1: "S", 2: "I"}
|
|
||||||
|
|
||||||
dot_vertex_str = "\n".join((f"{i} [label=\"{i}, VOP = {VOP_strs[v]}\"]" for i,v in enumerate(vops)))
|
|
||||||
|
|
||||||
handled_edges = set()
|
|
||||||
dot_edges = deque()
|
|
||||||
|
|
||||||
for i, ngbhd in enumerate(edges):
|
|
||||||
for j in ngbhd:
|
|
||||||
if((i,j) not in handled_edges):
|
|
||||||
dot_edges.append(f"{i} -- {j}")
|
|
||||||
handled_edges |= {(i,j), (j,i)}
|
|
||||||
|
|
||||||
dot_edges_str = "\n".join(dot_edges)
|
|
||||||
|
|
||||||
dot_str = "graph graphical_state{\n" + dot_vertex_str + "\n" + dot_edges_str + "\n}"
|
|
||||||
|
|
||||||
print(dot_str)
|
|
Before Width: | Height: | Size: 145 KiB |
|
@ -16,7 +16,7 @@ def Mi(nqbits, i, M):
|
||||||
|
|
||||||
|
|
||||||
def H_interaction(nqbits):
|
def H_interaction(nqbits):
|
||||||
interaction_terms = [Mi(nqbits, i, Z) @ Mi(nqbits, i+1, Z) for i in range(nqbits - 1)]
|
interaction_terms = [Mi(nqbits, i, Z) @ Mi(nqbits, i+1, Z) for i in range(nqbits)]
|
||||||
return sum(interaction_terms)
|
return sum(interaction_terms)
|
||||||
|
|
||||||
def H_field(nqbits, g):
|
def H_field(nqbits, g):
|
||||||
|
|
|
@ -20,8 +20,8 @@ matplotlib.rcParams.update(
|
||||||
nqbits = 6
|
nqbits = 6
|
||||||
g = 3
|
g = 3
|
||||||
N_trot = 80
|
N_trot = 80
|
||||||
t_stop = 29
|
t_stop = 9
|
||||||
delta_t = 0.1
|
delta_t = 0.09
|
||||||
qbits = list(range(nqbits))
|
qbits = list(range(nqbits))
|
||||||
|
|
||||||
n_sample = 2200
|
n_sample = 2200
|
||||||
|
@ -33,7 +33,6 @@ measure_coefficient_mask = [False if (i & measure) else True for i in range(2**n
|
||||||
results_qc = []
|
results_qc = []
|
||||||
results_np = []
|
results_np = []
|
||||||
errors_sampling = []
|
errors_sampling = []
|
||||||
amplitudes_qc = []
|
|
||||||
|
|
||||||
print()
|
print()
|
||||||
for t in np.arange(0, t_stop, delta_t):
|
for t in np.arange(0, t_stop, delta_t):
|
||||||
|
@ -47,10 +46,10 @@ for t in np.arange(0, t_stop, delta_t):
|
||||||
result = sample(state, measure, n_sample)
|
result = sample(state, measure, n_sample)
|
||||||
results_qc.append(result[0] / n_sample)
|
results_qc.append(result[0] / n_sample)
|
||||||
|
|
||||||
errors_sampling.append(bootstrap(result[0], n_sample, n_sample, n_sample // 2, np.average))
|
errors_sampling.append(bootstrap(result[0], n_sample, n_sample // 4, n_sample // 10, np.average))
|
||||||
|
|
||||||
amplitude = np.sum(np.abs(state._qm_state[measure_coefficient_mask])**2)
|
#amplitude = np.sqrt(np.sum(np.abs(state._qm_state[measure_coefficient_mask])**2))
|
||||||
amplitudes_qc.append(amplitude)
|
#results_qc.append(amplitude)
|
||||||
|
|
||||||
# Simulation using matrices
|
# Simulation using matrices
|
||||||
np_zero_state = np.zeros(2**nqbits)
|
np_zero_state = np.zeros(2**nqbits)
|
||||||
|
@ -68,24 +67,17 @@ print()
|
||||||
print("done.")
|
print("done.")
|
||||||
|
|
||||||
results_qc = np.array(results_qc)
|
results_qc = np.array(results_qc)
|
||||||
amplitudes_qc = np.array(amplitudes_qc)
|
|
||||||
|
|
||||||
errors_trotter = (np.arange(0, t_stop, delta_t))**3 / N_trot**3
|
errors_trotter = (np.arange(0, t_stop, delta_t) * g)**2 / N_trot**2
|
||||||
errors_sampling = np.array(errors_sampling)
|
errors_sampling = np.array(errors_sampling)
|
||||||
#errors_sampling = np.abs(results_qc - amplitudes_qc)
|
|
||||||
#errors_sampling = (amplitudes_qc * (1 - amplitudes_qc))**2 / n_sample
|
|
||||||
|
|
||||||
#hm1 = plt.errorbar(np.arange(0, t_stop, delta_t)
|
|
||||||
# , results_qc
|
|
||||||
# , yerr=(errors_sampling + errors_trotter)
|
|
||||||
# , color="red")
|
|
||||||
h0 = plt.errorbar(np.arange(0, t_stop, delta_t)
|
h0 = plt.errorbar(np.arange(0, t_stop, delta_t)
|
||||||
, results_qc
|
, results_qc
|
||||||
, yerr=errors_sampling
|
, yerr=(errors_trotter + errors_sampling)
|
||||||
, label=f"Quantum computing ({n_sample} samples, {N_trot} trotterization steps)"
|
, label=f"Quantum computing ({n_sample} samples, {N_trot} trotterization steps)"
|
||||||
, )
|
, )
|
||||||
h1, = plt.plot(np.arange(0, t_stop, delta_t), results_np, label="Classical simulation using explicit transfer matrix")
|
h1, = plt.plot(np.arange(0, t_stop, delta_t), results_np, label="Classical simulation using explicit transfer matrix")
|
||||||
#h2, = plt.plot(np.arange(0, t_stop, delta_t), amplitudes_qc, label="QC amplitude")
|
|
||||||
plt.xlabel("t")
|
plt.xlabel("t")
|
||||||
plt.ylabel(r"$|0\rangle$ probability amplitude for second spin")
|
plt.ylabel(r"$|0\rangle$ probability amplitude for second spin")
|
||||||
plt.title(f"{nqbits} site spin chain with g={g} coupling to external field")
|
plt.title(f"{nqbits} site spin chain with g={g} coupling to external field")
|
||||||
|
|
2
pyqcs
|
@ -1 +1 @@
|
||||||
Subproject commit 51efe195fe0378b0b9c4bad0ff6eefb1f17e4b3a
|
Subproject commit bcebc7860c47e4d8d1f5ec79b816032f31d8138d
|
|
@ -4,11 +4,11 @@
|
||||||
\section{Source Code for the Benchmarks}
|
\section{Source Code for the Benchmarks}
|
||||||
\label{ref:code_benchmarks}
|
\label{ref:code_benchmarks}
|
||||||
|
|
||||||
The benchmarks used in \ref{ref:performance} are based on this code. Note
|
The benchmarks used in \ref{ref:performance} are done using this code. Note
|
||||||
that the execution time is measured which is inherently noisy. To account for
|
that the execution time is measured which is inherently noisy. To account for
|
||||||
the noise several strategies are used:
|
the noise several strategies are used:
|
||||||
|
|
||||||
\begin{enumerate}[1.]
|
\begin{enumerate}[1]
|
||||||
\item{The same circuit is applied to the starting state several times. The
|
\item{The same circuit is applied to the starting state several times. The
|
||||||
minimal result is used as the noise must be positive}
|
minimal result is used as the noise must be positive}
|
||||||
\item{Several circuits are applied to the starting state. The remaining
|
\item{Several circuits are applied to the starting state. The remaining
|
||||||
|
@ -30,9 +30,15 @@ The code used to benchmark the three regimes is analogous and not included here.
|
||||||
|
|
||||||
Because the whole graphs are barely percetible windows have been used
|
Because the whole graphs are barely percetible windows have been used
|
||||||
in Figure \ref{fig:graph_high_linear_regime} and Figure \ref{fig:graph_intermediate_regime}.
|
in Figure \ref{fig:graph_high_linear_regime} and Figure \ref{fig:graph_intermediate_regime}.
|
||||||
For the sake of completeness the whole graphs are included here in
|
For the sake of completeness the whole graphs are included here in Figure \ref{fig:graph_low_linear_regime_full},
|
||||||
Figure \ref{fig:graph_intermediate_regime_full} and Figure \ref{fig:graph_high_linear_regime_full}.
|
Figure \ref{fig:graph_intermediate_regime_full} and Figure \ref{fig:graph_high_linear_regime_full}.
|
||||||
|
|
||||||
|
\begin{figure}[H]
|
||||||
|
\centering
|
||||||
|
\includegraphics[width=\linewidth]{graphics/graph_low_linear_regime.png}
|
||||||
|
\caption[Typical Graphical State in the Low-Linear Regime]{Typical Graphical State in the Low-Linear Regime}
|
||||||
|
\label{fig:graph_low_linear_regime_full}
|
||||||
|
\end{figure}
|
||||||
|
|
||||||
\begin{figure}[H]
|
\begin{figure}[H]
|
||||||
\centering
|
\centering
|
||||||
|
@ -51,9 +57,9 @@ Figure \ref{fig:graph_intermediate_regime_full} and Figure \ref{fig:graph_high_l
|
||||||
\section{Code to Generate the Example Graphs}
|
\section{Code to Generate the Example Graphs}
|
||||||
\label{ref:code_example_graphs}
|
\label{ref:code_example_graphs}
|
||||||
|
|
||||||
This code has been used to generate the example graphs in \ref{ref:performance}
|
This code has been used to generate the example graphs used in
|
||||||
and \ref{ref:complete_graphs}. Note that generating the graph is done with
|
\ref{ref:performance}. Note that generating the graph is done using a random
|
||||||
a random circuit as in \ref{ref:code_benchmarks}. The generated \lstinline{dot}
|
circuit as used in \ref{ref:code_benchmarks}. The generated \lstinline{dot}
|
||||||
code is converted to an image using
|
code is converted to an image using
|
||||||
\lstinline{dot i_regime.dot -Tpng -o i_regime.png}.
|
\lstinline{dot i_regime.dot -Tpng -o i_regime.png}.
|
||||||
|
|
||||||
|
@ -63,17 +69,17 @@ code is converted to an image using
|
||||||
\section{Code to Benchmark \lstinline{ufunc} Gates against Python}
|
\section{Code to Benchmark \lstinline{ufunc} Gates against Python}
|
||||||
\label{ref:benchmark_ufunc_py}
|
\label{ref:benchmark_ufunc_py}
|
||||||
|
|
||||||
It has been mentioned several times that the implementation with
|
It has been mentioned several times that the implementation using
|
||||||
\lstinline{ufuncs} as gates is faster than a pure \lstinline{python}
|
\lstinline{ufuncs} as gates is faster than using a \lstinline{python}
|
||||||
implementation. To support this statement a simple benchmark is written. The
|
implementation. To support this statement a simple benchmark can be used. The
|
||||||
relatively simple Pauli $X$ gate is implemented, more complicated gates like $CX$ or $H$
|
relatively simple Pauli $X$ is used, more complicated gates like $CX$ or $H$
|
||||||
have worse performance when written in \lstinline{python}. The performance
|
have worse performance when implemented in \lstinline{python}. The performance
|
||||||
improvement in this example is a factor around $6.4$.
|
improvement when using the \lstinline{ufunc} is a factor around $6.4$ in this tested
|
||||||
One must note that the tested \lstinline{python} code is not
|
case. One must however note that the tested \lstinline{python} code is not
|
||||||
realistic and in a possible application there would be a significant overhead.
|
realistic and in a possible applications there would be a significant overhead.
|
||||||
|
|
||||||
\lstinputlisting[title={Code to Benchmark \lstinline{ufunc} Gates against Python}, language=Python, breaklines=True]{extra_benchmark/benchmark.py}
|
\lstinputlisting[title={Code to Benchmark \lstinline{ufunc} Gates against Python}, language=Python, breaklines=True]{extra_benchmark/benchmark.py}
|
||||||
|
|
||||||
When using \lstinline{result_py[0::2] = qm_state[1::2]} the result is identical and
|
When using \lstinline{result_py[0::2] = qm_state[1::2]} the result is identical and
|
||||||
the performance is only increased by a factor around $1.7$. This method is not
|
the performance is only increased by a factor around $1.7$. This method is however not
|
||||||
applicable to general act-qbits and the bit mask has to be used.
|
applicable to general act-qbits and the bit mask has to be used.
|
||||||
|
|
|
@ -2,10 +2,10 @@
|
||||||
\chapter{Conclusion and Outlook}
|
\chapter{Conclusion and Outlook}
|
||||||
|
|
||||||
As seen in \ref{ref:performance} simulation using stabilizers is exponentially
|
As seen in \ref{ref:performance} simulation using stabilizers is exponentially
|
||||||
faster than simulating with dense state vectors. The graphical representation
|
faster than simulating using state vectors. Using a graphical representation
|
||||||
for stabilizer states is in realistic cases more efficiently than the
|
for the stabilizers is on average more efficiently than using a stabilizer
|
||||||
stabilizer tableaux \cite{andersbriegel2005}. In particular one can simulate
|
tableaux. In particular one can simulate more qbits while only applying
|
||||||
more qbits while only applying Clifford gates.
|
Clifford gates.
|
||||||
|
|
||||||
This is considerably useful when working on quantum error correcting strategies
|
This is considerably useful when working on quantum error correcting strategies
|
||||||
as they often include many qbits; the smallest quantum error correcting
|
as they often include many qbits; the smallest quantum error correcting
|
||||||
|
@ -13,7 +13,7 @@ stabilizer code requires $5$ qbits to encode one logical qbit
|
||||||
\cite{nielsen_chuang_2010}. Several layers of data encoding increase the
|
\cite{nielsen_chuang_2010}. Several layers of data encoding increase the
|
||||||
number of required qbits exponentially.
|
number of required qbits exponentially.
|
||||||
|
|
||||||
Simulating in the stabilizer formalism is uninteresting from a physical
|
Simulating in the stabilizer formalism is rather uninteresting from a physical
|
||||||
point of view as basically no physically interesting simulations can be
|
point of view as basically no physically interesting simulations can be
|
||||||
performed: As shown in \ref{ref:meas_stab} probability amplitudes have to be
|
performed: As shown in \ref{ref:meas_stab} probability amplitudes have to be
|
||||||
$0, \frac{1}{2}, 1$; this leaves very few points in time that could be
|
$0, \frac{1}{2}, 1$; this leaves very few points in time that could be
|
||||||
|
@ -21,7 +21,7 @@ simulated by applying a transfer matrix. Algorithms like the quantum fourier
|
||||||
transform also require non-Clifford gates for qbit counts $n \neq 2, 4$.
|
transform also require non-Clifford gates for qbit counts $n \neq 2, 4$.
|
||||||
|
|
||||||
The basic idea of not simulating a state but (after imposing some conditions on
|
The basic idea of not simulating a state but (after imposing some conditions on
|
||||||
the Hilbert space) other objects that describe the state is
|
the Hilbert space) other objects that describe the state is extremely
|
||||||
interesting for physics as often the exponentially large or infinitely large
|
interesting for physics as often the exponentially large or infinitely large
|
||||||
Hilbert spaces cannot be mapped to a classical (super) computer. One key idea
|
Hilbert spaces cannot be mapped to a classical (super) computer. One key idea
|
||||||
to take from the stabilizer formalism is to simulate the Hamiltonian instead of
|
to take from the stabilizer formalism is to simulate the Hamiltonian instead of
|
||||||
|
@ -34,14 +34,14 @@ ground state of this Hamiltonian.
|
||||||
|
|
||||||
While trying to extend the stabilizer formalism one inevitably hits the
|
While trying to extend the stabilizer formalism one inevitably hits the
|
||||||
question:\\ \textit{Why is there a constraint on the $R_\phi$ angle? Why is it
|
question:\\ \textit{Why is there a constraint on the $R_\phi$ angle? Why is it
|
||||||
$\frac{\pi}{2}$?}\\ The answer to this question can be found by taking a look
|
$\frac{\pi}{2}$?}\\ The answer to this question is hidden in the Clifford
|
||||||
at the Clifford group. Recalling Definition \ref{def:clifford_group} the
|
group. Recalling Definition \ref{def:clifford_group} the Clifford group is not
|
||||||
Clifford group is not defined to be generated by $H, S, CZ$, but by its property
|
defined to be generated by $H, S, CZ$ but by its property of normalizing the
|
||||||
of normalizing the multilocal Pauli group. Storing and manipulating the
|
multilocal Pauli group. Storing and manipulating the multilocal Pauli group is
|
||||||
multilocal Pauli group is only so efficient (or possible) because it is the
|
only so efficient (or possible) because it is the tensor product of Pauli
|
||||||
tensor product of Pauli matrices. A general unitary on $n$ qbits would be
|
matrices. A general unitary on $n$ qbits would be a $2^{n} \times 2^{n}$ matrix
|
||||||
a $2^{n} \times 2^{n}$ matrix which requires more space than a dense state
|
which requires more space than a dense state vector. The Clifford group is
|
||||||
vector. The Clifford group is a group preserving this tensor product property.
|
a group preserving this tensor product property.
|
||||||
|
|
||||||
%{{{
|
%{{{
|
||||||
%When lifting the constraint that $\ket{\varphi}$ is stabilized by the multilocal Pauli
|
%When lifting the constraint that $\ket{\varphi}$ is stabilized by the multilocal Pauli
|
||||||
|
@ -103,10 +103,10 @@ vector. The Clifford group is a group preserving this tensor product property.
|
||||||
The stabilizer formalism as introduced in \ref{ref:stab_states} has since been
|
The stabilizer formalism as introduced in \ref{ref:stab_states} has since been
|
||||||
generalized to normalizers of a finite Abelian group over the Hilbert space
|
generalized to normalizers of a finite Abelian group over the Hilbert space
|
||||||
\cite{bermejovega_lin_vdnest2015}\cite{bermejovega_vdnest2018}\cite{vandennest2019}\cite{vandennest2018}.
|
\cite{bermejovega_lin_vdnest2015}\cite{bermejovega_vdnest2018}\cite{vandennest2019}\cite{vandennest2018}.
|
||||||
This allows to simulate more classes of circuits efficiently on classical
|
This allows to simulate more classes of circuits efficiently on classical computers
|
||||||
computers including the Quantum Fourier Transforms which is often believed to
|
including the Quantum Fourier Transforms which is often believed to be
|
||||||
be responsible for exponential speedups. One must note that in the definition
|
responsible for exponential speedups. One must note that in the definition of
|
||||||
of the QFTs as in \cite{vandennest2018} the QFT depends on the Abelian group it
|
the QFTs as in \cite{vandennest2018} the QFT depends on the Abelian group it
|
||||||
acts on. In particular the QFT on the group that decomposes the Hilbert space
|
acts on. In particular the QFT on the group that decomposes the Hilbert space
|
||||||
as seen in this paper ($Z_2^n$) is just the tensor product of the $H$ gates.
|
as seen in this paper ($Z_2^n$) is just the tensor product of the $H$ gates.
|
||||||
The QFT as used in \ref{ref:quantum_algorithms} for the phase estimation
|
The QFT as used in \ref{ref:quantum_algorithms} for the phase estimation
|
||||||
|
@ -117,7 +117,6 @@ the Clifford group \cite{vandennest2018}.
|
||||||
|
|
||||||
The exponential speedup of quantum computing is often attributed to
|
The exponential speedup of quantum computing is often attributed to
|
||||||
entanglement, superposition and interference effects
|
entanglement, superposition and interference effects
|
||||||
\cite{uwaterloo}\cite{21732}\cite{vandennest2018}. Stabilizer states show
|
\cite{uwaterloo}\cite{21732}\cite{vandennest2018}. Stabilizer states
|
||||||
entanglement, superposition and interference effects; as do computations using
|
however show both entanglement, superposition and interference effects;
|
||||||
general normalizers \cite{vandennest2018}. The question why quantum computing
|
as do computations done using general normalizers \cite{vandennest2018}.
|
||||||
can speed up computations exponentially is non-trivial.
|
|
||||||
|
|
|
@ -2,19 +2,15 @@
|
||||||
\chapter{Implementation}
|
\chapter{Implementation}
|
||||||
|
|
||||||
This chapter discusses how the concepts introduced before are implemented into
|
This chapter discusses how the concepts introduced before are implemented into
|
||||||
a simulator. Further the infrastructure around the simulation and some tools are
|
a simulator. Futher the infrastructure around the simulation and some tools are
|
||||||
explained.
|
explained.
|
||||||
|
|
||||||
The implementation is written as the \lstinline{python3} package \lstinline{pyqcs} \cite{pyqcs}. This allows
|
The implementation is written as the \lstinline{python3} package \lstinline{pyqcs} \cite{pyqcs}. This allows
|
||||||
users to quickly construct circuits, apply them to states and measure
|
users to quickly construct circuits, apply them to states and measure
|
||||||
amplitudes. Full access to the states (including intermediate states) has been
|
amplitudes. Full access to the state (including intermediate states) has been
|
||||||
prioritized over execution speed. To keep the simulation speed as high as
|
priorized over execution speed. To keep the simulation speed as high as
|
||||||
possible under these constraints some parts are implemented in \lstinline{C}.
|
possible under these constraints some parts are implemented in \lstinline{C}.
|
||||||
|
|
||||||
This document is based on \lstinline{pyqcs} \lstinline{2.1.0} that
|
|
||||||
can be downloaded under \\
|
|
||||||
\href{https://github.com/daknuett/PyQCS/releases/tag/v2.1.0}{https://github.com/daknuett/PyQCS/releases/tag/v2.1.0}.
|
|
||||||
|
|
||||||
\section{Dense State Vector Simulation}
|
\section{Dense State Vector Simulation}
|
||||||
|
|
||||||
\subsection{Representation of Dense State Vectors}
|
\subsection{Representation of Dense State Vectors}
|
||||||
|
@ -27,29 +23,30 @@ useful features when it comes to computations:
|
||||||
\item{The projection on the integer states is trivial.}
|
\item{The projection on the integer states is trivial.}
|
||||||
\item{For any qbit $j$ and $0 \le i \le 2^n-1$ the coefficient $c_i$ is part of the $\ket{1}_j$ amplitude iff
|
\item{For any qbit $j$ and $0 \le i \le 2^n-1$ the coefficient $c_i$ is part of the $\ket{1}_j$ amplitude iff
|
||||||
$i \& (1 << j)$ and part of the $\ket{0}_j$ amplitude otherwise.}
|
$i \& (1 << j)$ and part of the $\ket{0}_j$ amplitude otherwise.}
|
||||||
\item{For a qbit $j$ the coefficients $c_i$ and $c_{i \wedge (1 << j)}$ are the conjugated coefficients.}
|
\item{For a qbit $j$ the coefficients $c_i$ and $c_{i \hat{ } (1 << j)}$ are the conjugated coefficients.}
|
||||||
\end{itemize}
|
\end{itemize}
|
||||||
|
|
||||||
Where $\wedge$ is the binary XOR, $\&$ the binary AND and $<<$ the binary
|
Where $\hat{}$ is the binary XOR, $\&$ the binary AND and $<<$ the binary
|
||||||
leftshift operator.
|
leftshift operator.
|
||||||
|
|
||||||
While implementing the dense state vectors two key points were a simple way to
|
While implementing the dense state vectors two key points were allowing
|
||||||
use them and easy access to the underlaying data. To meet both requirements
|
a simple and readable way to use them and simple access to the states by users
|
||||||
the states are implemented as Python objects that provide abstract features such
|
that want more information than an abstracted view could allow. To meet both
|
||||||
as normalization checking, checking for sufficient qbit number when applying
|
requirements the states are implemented as Python objects providing abstract
|
||||||
a circuit, computing overlaps with other states, a stringify method and stored
|
features such as normalization checking, checking for sufficient qbit number
|
||||||
measurement results. To store the measurement results a NumPy \lstinline{int8}
|
when applying a circuit, computing overlaps with other states, a stringify
|
||||||
array \cite{numpy_array} is used; this is called the classical state. The
|
method and stored measurement results. To store the measurement results
|
||||||
Python states also have a NumPy \lstinline{cdouble} array that stores the
|
a NumPy \lstinline{int8} array \cite{numpy_array} is used; this is called the
|
||||||
quantum mechanical state. Using NumPy arrays has the advantage that access to
|
classical state. The Python states also have a NumPy \lstinline{cdouble} array
|
||||||
the data is simple and safe while operations on the states can be implemented
|
that stores the quantum mechanical state. Using NumPy arrays has the advantage
|
||||||
in \lstinline{C} \cite{numpy_ufunc} providing a considerable speedup
|
that access to the data is simple and safe while operations on the states can
|
||||||
(see \ref{ref:benchmark_ufunc_py}).
|
be implemented in \lstinline{C} \cite{numpy_ufunc} providing a considerable
|
||||||
|
speedup \ref{ref:benchmark_ufunc_py}.
|
||||||
|
|
||||||
This quantum mechanical state is the component vector in integer basis
|
This quantum mechanical state is the component vector in integer basis
|
||||||
therefore it has $2^n$ components. Storing those components is acceptable in
|
therefore it has $2^n$ components. Storing those components is acceptable in
|
||||||
a range from $1$ to $30$ qbits; above this range the state requires space in
|
a range from $1$ to $30$ qbits; above this range the state requires space in
|
||||||
the order of magnitude $1 \mbox{ GiB}$ which is in the range of usual RAM sizes for
|
the order of $1 \mbox{ GiB}$ which is in the range of usual RAM sizes for
|
||||||
personal computers. For higher qbit numbers moving to high performance
|
personal computers. For higher qbit numbers moving to high performance
|
||||||
computers and other simulators is necessary.
|
computers and other simulators is necessary.
|
||||||
|
|
||||||
|
@ -62,7 +59,7 @@ what qbits have been measured. Using ufuncs has the great advantage that
|
||||||
managing memory is done by NumPy and an application programmer just has to
|
managing memory is done by NumPy and an application programmer just has to
|
||||||
implement the logic of the function. Because ufuncs are written in
|
implement the logic of the function. Because ufuncs are written in
|
||||||
\lstinline{C} they provide a considerable speedup compared to an implementation
|
\lstinline{C} they provide a considerable speedup compared to an implementation
|
||||||
in Python (see \ref{ref:benchmark_ufunc_py}).
|
in Python \ref{ref:benchmark_ufunc_py}.
|
||||||
|
|
||||||
The logic of gates is usually easy to implement using the integer basis. The
|
The logic of gates is usually easy to implement using the integer basis. The
|
||||||
example below implements the Hadamard gate \ref{ref:singleqbitgates}:
|
example below implements the Hadamard gate \ref{ref:singleqbitgates}:
|
||||||
|
@ -75,7 +72,7 @@ A basic set of gates is implemented in PyQCS:
|
||||||
\item{Hadamard $H$ gate.}
|
\item{Hadamard $H$ gate.}
|
||||||
\item{Pauli $X$ or \textit{NOT} gate.}
|
\item{Pauli $X$ or \textit{NOT} gate.}
|
||||||
\item{Pauli $Z$ gate.}
|
\item{Pauli $Z$ gate.}
|
||||||
\item{Phase gate $S$.}
|
\item{The $S$ phase gate.}
|
||||||
\item{$Z$ rotation $R_\phi$ gate.}
|
\item{$Z$ rotation $R_\phi$ gate.}
|
||||||
\item{Controlled $X$ gate: $CX$.}
|
\item{Controlled $X$ gate: $CX$.}
|
||||||
\item{Controlled $Z$ gate: $CZ$.}
|
\item{Controlled $Z$ gate: $CZ$.}
|
||||||
|
@ -101,8 +98,8 @@ new_state = circuit * state
|
||||||
\end{lstlisting}
|
\end{lstlisting}
|
||||||
|
|
||||||
|
|
||||||
The elementary gates are implemented as single gate
|
The elementary gates such as $H, R_\phi, CX$ are implemented as single gate
|
||||||
circuits and can be constructed using the built-in generators. These generators
|
circuits and can be constructing using the built-in generators. The generators
|
||||||
take the act-qbit as first argument, parameters such as the control qbit or an
|
take the act-qbit as first argument, parameters such as the control qbit or an
|
||||||
angle as second argument:
|
angle as second argument:
|
||||||
|
|
||||||
|
@ -120,7 +117,7 @@ Out[2]: (0.7071067811865476+0j)*|0b0>
|
||||||
+ (0.7071067811865476+0j)*|0b11>
|
+ (0.7071067811865476+0j)*|0b11>
|
||||||
\end{lstlisting}
|
\end{lstlisting}
|
||||||
|
|
||||||
Large circuits can be built using the binary OR operator \lstinline{|} in
|
Large circuits can be constructed using the binary OR operator \lstinline{|} in
|
||||||
an analogy to the pipeline operator on many *NIX shells. As usual circuits are
|
an analogy to the pipeline operator on many *NIX shells. As usual circuits are
|
||||||
read from left to right similar to pipelines on *NIX shells:
|
read from left to right similar to pipelines on *NIX shells:
|
||||||
|
|
||||||
|
@ -144,7 +141,7 @@ Out[2]: (0.7071067811865477+0j)*|0b0>
|
||||||
\end{lstlisting}
|
\end{lstlisting}
|
||||||
%}
|
%}
|
||||||
|
|
||||||
A quick way to generate circuits programmatically is to use the \lstinline{list_to_circuit}
|
A quick way to generate circuits programatically is to use the \lstinline{list_to_circuit}
|
||||||
function:
|
function:
|
||||||
|
|
||||||
%\adjustbox{max width=\textwidth}{
|
%\adjustbox{max width=\textwidth}{
|
||||||
|
@ -166,19 +163,12 @@ Out[2]: (0.7071067811865476+0j)*|0b0>
|
||||||
\section{Graphical State Simulation}
|
\section{Graphical State Simulation}
|
||||||
|
|
||||||
\subsection{Graphical States}
|
\subsection{Graphical States}
|
||||||
\label{ref:impl_g_states}
|
|
||||||
|
|
||||||
For the graphical state $(V, E, O)$ the list of vertices $V$ can be stored implicitly
|
For the graphical state $(V, E, O)$ the list of vertices $V$ can be stored implicitly
|
||||||
by demanding $V = \{0, ..., n - 1\}$. This leaves two components that have to be stored:
|
by demanding $V = \{0, ..., n - 1\}$. This leaves two components that have to be stored:
|
||||||
The edges $E$ and the vertex operators $O$. Storing the vertex operators is
|
The edges $E$ and the vertex operators $O$. Storing the vertex operators is
|
||||||
done using a \lstinline{uint8_t} array. Every local Clifford operator is
|
done using a \lstinline{uint8_t} array. Every local Clifford operator is
|
||||||
associated with an integer ranging from $0$ to $23$
|
associated with an integer ranging from $0$ to $24$, their order is
|
||||||
\footnote{
|
|
||||||
\cite{andersbriegel2005} also uses integers from $0$ to $23$ to represent
|
|
||||||
the Clifford operators. The authors do not describe the mapping from integer
|
|
||||||
to operator and the order might be different.
|
|
||||||
}
|
|
||||||
. Their order is
|
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
|
@ -226,28 +216,27 @@ The edges are stored in an adjacency matrix
|
||||||
Recalling some operations on the graph as described in
|
Recalling some operations on the graph as described in
|
||||||
\ref{ref:dynamics_graph}, \ref{ref:meas_graph} or Lemma \ref{lemma:M_a} one
|
\ref{ref:dynamics_graph}, \ref{ref:meas_graph} or Lemma \ref{lemma:M_a} one
|
||||||
sees that it is important to efficiently access and modify the neighbourhood of
|
sees that it is important to efficiently access and modify the neighbourhood of
|
||||||
a vertex. Also one must take care to keep the memory required to store a state
|
a vertex. To ensure good performance when accessing the neighbourhood while
|
||||||
low. To meet both requirements a linked list-array hybrid is used. For every
|
keeping the required memory low a linked list-array hybrid is used to store
|
||||||
vertex the neighbourhood is stored in a sorted linked list (which is a sparse
|
the adjacency matrix. For every vertex the neighbourhood is stored in a sorted
|
||||||
representation of a column vector) and these adjacency lists are stored in
|
linked list (which is a sparse representation of a column vector) and these
|
||||||
a length $n$ array. \cite{andersbriegel2005} uses the same representation for
|
adjacency lists are stored in a length $n$ array.
|
||||||
the graph.
|
|
||||||
|
|
||||||
Using this storage method all operations - including searching and toggling edges -
|
Using this storage method all operations including searching and toggling edges
|
||||||
inherit their time complexity from the sorted linked list.
|
inherite their time complexity from the sorted linked list.
|
||||||
|
|
||||||
\subsection{Operations on Graphical States}
|
\subsection{Operations on Graphical States}
|
||||||
|
|
||||||
Operations on Graphical States are divided into three classes: Local Clifford
|
Operations on Graphical States are divided into three classes: Local Clifford
|
||||||
operations, the CZ operation and measurements. The graphical states are
|
operations, the CZ operation and measurements. The graphical states are
|
||||||
implemented in \lstinline{C} and are exported to \lstinline{python3} in the class
|
implemented in \lstinline{C} and are exported to python3 in the class
|
||||||
\lstinline{RawGraphState}. This class has three main methods to implement the
|
\lstinline{RawGraphState}. This class has three main methods to implement the
|
||||||
three classes of operations.
|
three classes of operations.
|
||||||
|
|
||||||
\begin{description}
|
\begin{description}
|
||||||
\item[\hspace{-1em}]{\lstinline{RawGraphState.apply_C_L}\\
|
\item[\hspace{-1em}]{\lstinline{RawGraphState.apply_C_L}\\
|
||||||
This method implements local Clifford gates. It takes the qbit index
|
This method implements local Clifford gates. It takes the qbit index
|
||||||
and the index of the local Clifford operator (ranging from $0$ to $23$).}
|
and the index of the local Clifford operator (ranging form $0$ to $23$).}
|
||||||
\item[\hspace{-1em}]{\lstinline{RawGraphState.apply_CZ}\\
|
\item[\hspace{-1em}]{\lstinline{RawGraphState.apply_CZ}\\
|
||||||
Applies the $CZ$ gate to the state. The first argument is the
|
Applies the $CZ$ gate to the state. The first argument is the
|
||||||
act-qbit, the second the control qbit (note that this is just for
|
act-qbit, the second the control qbit (note that this is just for
|
||||||
|
@ -260,7 +249,7 @@ three classes of operations.
|
||||||
returns either $1$ or $0$ as a measurement result.}
|
returns either $1$ or $0$ as a measurement result.}
|
||||||
\end{description}
|
\end{description}
|
||||||
|
|
||||||
Because this way of modifying the state is inconvenient and might lead to many
|
Because this way of modifying the state is rather unconvenient and might lead to many
|
||||||
errors the \lstinline{RawGraphState} is wrapped by the pure python class\\
|
errors the \lstinline{RawGraphState} is wrapped by the pure python class\\
|
||||||
\lstinline{pyqcs.graph.state.GraphState}. It allows the use of circuits as
|
\lstinline{pyqcs.graph.state.GraphState}. It allows the use of circuits as
|
||||||
described in \ref{ref:pyqcs_circuits} and provides the method
|
described in \ref{ref:pyqcs_circuits} and provides the method
|
||||||
|
@ -269,7 +258,7 @@ vector state.
|
||||||
|
|
||||||
\subsection{Pure C Implementation}
|
\subsection{Pure C Implementation}
|
||||||
|
|
||||||
Because python tends to be slow \cite{benchmarkgame} and might not run on any architecture
|
Because python tends to be rather slow \cite{benchmarkgame} and might not run on any architecture
|
||||||
a pure \lstinline{C} implementation of the graphical simulator is also provided.
|
a pure \lstinline{C} implementation of the graphical simulator is also provided.
|
||||||
It should be seen as a reference implementation that can be extended to the needs
|
It should be seen as a reference implementation that can be extended to the needs
|
||||||
of the user.
|
of the user.
|
||||||
|
@ -277,44 +266,38 @@ of the user.
|
||||||
This implementation reads byte code from a file and executes it. The execution is
|
This implementation reads byte code from a file and executes it. The execution is
|
||||||
always done in three steps:
|
always done in three steps:
|
||||||
|
|
||||||
\begin{enumerate}[1.]
|
\begin{enumerate}[1]
|
||||||
\item{Initializing the state according to the header of the byte code file.}
|
\item{Initializing the state according the the header of the bytecode file.}
|
||||||
\item{Applying operations given by the byte code to the state. This includes local
|
\item{Applying operations given by the bytecode to the state. This includes local
|
||||||
Clifford gates, $CZ$ gates and measurements (the measurement outcome is ignored).}
|
Clifford gates, $CZ$ gates and measurements (the measurement outcome is ignored).}
|
||||||
\item{Sampling the state according to the description in the header of the byte code
|
\item{Sampling the state according the the description given in the header of the byte code
|
||||||
file and writing the sampling results to either a file or \lstinline{stdout}. }
|
file and writing the sampling results to either a file or \lstinline{stdout}. }
|
||||||
\end{enumerate}
|
\end{enumerate}
|
||||||
|
|
||||||
\section{Utilities}
|
\section{Utilities}
|
||||||
|
|
||||||
The package \lstinline{pyqcs} ships with several utilities that are supposed to
|
To make both using the simulators more convenient and to help with using them
|
||||||
make using the simulators more convenient. Some utilities are designed to help
|
in as scientific or educational context several utilities have been written.
|
||||||
in a scientific and educational context. This chapter explains some of them.
|
This chapter explains some of them.
|
||||||
|
|
||||||
\subsection{Sampling and Circuit Generation}
|
\subsection{Sampling and Circuit Generation}
|
||||||
|
|
||||||
The function \lstinline{pyqcs.sample} provides a simple way to sample from
|
The function \lstinline{pyqcs.sample} provides a simple way to sample from
|
||||||
a state. Copies of the state are made when necessary, and the results are
|
a state. Copies of the state are made when necessary and the results are
|
||||||
returned in a \lstinline{collections.Counter} object. Several qbits can be
|
returned in a \lstinline{collections.Counter} object. Several qbits can be
|
||||||
sampled at once; they can be passed to the function either as an integer which
|
sampled at once; they can be passed to the function either as an integer which
|
||||||
will be interpreted as a bit mask, and the least significant bit will be sampled
|
will be interpreted as a bit mask and the least significant bit will be sampled
|
||||||
first. When passing the qbits to sample as a list of integers the integers are
|
first. When passing the qbits to sample as a list of integers the integers are
|
||||||
interpreted as qbit indices and are measured in the order they appear.
|
interpreted as qbit indices and are measured in the order they appear.
|
||||||
|
|
||||||
If the keyword argument \lstinline{keep_states} is \lstinline{True} the
|
If the keyword argument \lstinline{keep_states} is \lstinline{True} the
|
||||||
sampling function will include the collapsed states in the result. At the
|
sampling function will include the resulting states in the result. At the
|
||||||
moment this works for dense vectors only. Checking for equality on graphical
|
moment this works for dense vectors only. Checking for equality on graphical
|
||||||
states is not implemented due to the computational hardness.
|
states has yet to be implemented but has $NP$ computational hardness
|
||||||
\cite{bouchet1991} introduced an algorithm to test whether two VOP-free graph states
|
\cite{dahlberg_ea2019}.
|
||||||
are equivalent with complexity $\mathcal{O}\left(n^4\right)$.
|
|
||||||
So checking for equivalency is $c-NP$ complete because the vertex operators have
|
|
||||||
to be checked as well. It might be necessary to compute all equivalent graphical
|
|
||||||
states. \cite{dahlberg_ea2019} showed that counting equivalent VOP-free
|
|
||||||
graphical states is $\#P$ complete. Showing that two graphical states are
|
|
||||||
equivalent might considerably hard.
|
|
||||||
|
|
||||||
Writing circuits out by hand can be inconvenient. The function\\
|
Writing circuits out by hand can be rather painful. The function\\
|
||||||
\lstinline{pyqcs.list_to_circuit} converts a list of circuits to a circuit.
|
\lstinline{pyqcs.list_to_circuit} Converts a list of circuits to a circuit.
|
||||||
This is particularly helpful in combination with python's
|
This is particularly helpful in combination with python's
|
||||||
\lstinline{listcomp}:
|
\lstinline{listcomp}:
|
||||||
|
|
||||||
|
@ -325,40 +308,41 @@ circuit_H = list_to_circuit([H(i) for i in range(nqbits)])
|
||||||
The module \lstinline{pyqcs.util.random_circuits} provides the method described
|
The module \lstinline{pyqcs.util.random_circuits} provides the method described
|
||||||
in \ref{ref:performance} to generate random circuits for both graphical and
|
in \ref{ref:performance} to generate random circuits for both graphical and
|
||||||
dense vector simulation. Using the module \lstinline{pyqcs.util.random_graphs}
|
dense vector simulation. Using the module \lstinline{pyqcs.util.random_graphs}
|
||||||
one can generate random graphical states which is faster than using random
|
one can generate random graphical states which is more performant than using
|
||||||
circuits.
|
random circuits.
|
||||||
|
|
||||||
The function \lstinline{pyqcs.util.to_circuit.graph_state_to_circuit} converts
|
The function \lstinline{pyqcs.util.to_circuit.graph_state_to_circuit} converts
|
||||||
graphical states to circuits (mapping the $\ket{0b0..0}$ to this state).
|
graphical states to circuits (mapping the $\ket{0b0..0}$ to this state).
|
||||||
By utilization of these circuits the graphical state can be copied or converted to a
|
Using these circuits the graphical state can be copied or converted to a
|
||||||
dense vector state. Further it is a way to optimize circuits and later run them on
|
dense vector state. Further it is a way to optimize circuits and later run them on
|
||||||
other simulators. Also the circuits can be exported to \lstinline{qcircuit} code
|
other simulators. Also the circuits can be exported to \lstinline{qcircuit} code
|
||||||
(see below) which is a way to represent graphical states.
|
(see below) which is a relatively readable way to represent graphical states.
|
||||||
|
|
||||||
\subsection{Exporting and Flattening Circuits}
|
\subsection{Exporting and Flattening Circuits}
|
||||||
|
|
||||||
Circuits can be drawn with the \LaTeX package \lstinline{qcircuit}; all
|
Circuits can be drawn using the \LaTeX package \lstinline{qcircuit}; all
|
||||||
circuits in this documents use \lstinline{qcircuit}. To visualize
|
circuits in this documents use \lstinline{qcircuit}. To visualize the circuits
|
||||||
\lstinline{pyqcs} circuits the function\\
|
built using \lstinline{pyqcs} the function\\
|
||||||
\lstinline{pyqcs.util.to_diagram.circuit_to_diagram} can be used to generate
|
\lstinline{pyqcs.util.to_diagram.circuit_to_diagram} can be used to generate
|
||||||
\lstinline{qcircuit} code. The diagrams produced by this function are not
|
\lstinline{qcircuit} code that can be used in \LaTeX documents or exported to
|
||||||
optimized, and the diagrams can be unnecessary long. Usually this can be fixed
|
PDFs directly. The diagrams produced by this function are not optimized and the
|
||||||
easily by editing the resulting code manually.
|
diagrams can be unnecessary long. Usually this can be fixed easily by editing
|
||||||
|
the produced code manually.
|
||||||
|
|
||||||
The circuits constructed using the \lstinline{|} operator have a tree structure
|
The circuits constructed using the \lstinline{|} operator have a tree structure
|
||||||
which is rather inconvenient when optimizing circuits or exporting them.
|
which is rather unconvenient when optimizing circuits or exporting them.
|
||||||
The function \\
|
The function \\
|
||||||
\lstinline{pyqcs.util.flatten.flatten} converts a circuit
|
\lstinline{pyqcs.util.flatten.flatten} converts a circuit
|
||||||
to a list of single gate circuits that can be simply analyzed or exported.
|
to a list of single gate circuits that can be analyzed or exported easily.
|
||||||
|
|
||||||
|
|
||||||
\section{Performance}
|
\section{Performance}
|
||||||
\label{ref:performance}
|
\label{ref:performance}
|
||||||
|
|
||||||
Testing the performance and comparing the graphical with the dense vector
|
To test the performance and compare it to the dense vector simulator the python
|
||||||
simulator is done with the python module. Although the pure \lstinline{C}
|
module is used. Although the pure \lstinline{C} implementation has potential
|
||||||
implementation has potential for better performance the python module is better
|
for better performance the python module is better comparable to the dense
|
||||||
comparable to the dense vector simulator which is a python module as well.
|
vector simulator which is a python module as well.
|
||||||
|
|
||||||
For performance tests (and for tests against the dense vector simulator) random
|
For performance tests (and for tests against the dense vector simulator) random
|
||||||
circuits are used. Length $m$ circuits are generated from the probability space
|
circuits are used. Length $m$ circuits are generated from the probability space
|
||||||
|
@ -367,10 +351,13 @@ circuits are used. Length $m$ circuits are generated from the probability space
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\Omega = \left(\{1, ..., 4n\} \otimes \{1, ..., n-1\} \otimes [0, 2\pi)\right)^{\otimes m}
|
\Omega = \left(\{1, ..., 4n\} \otimes \{1, ..., n-1\} \otimes [0, 2\pi)\right)^{\otimes m}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
with the uniform distribution. The continuous part $[0, 2\pi)$ is ignored when
|
|
||||||
generating random circuits for the graphical simulator; in order to generate
|
with the uniform distribution. The continous part $[0, 2\pi)$ is unused when
|
||||||
random circuits for dense vector simulations this is used as the argument $\phi$ of the
|
generating random circuits for the graphical simulator; when generating random
|
||||||
$R_\phi$ gate. For $m=1$ an outcome is mapped to a gate with
|
circuits for dense vector simulations this is the argument $\phi$ of the
|
||||||
|
$R_\phi$ gate.
|
||||||
|
|
||||||
|
For $m=1$ an outcome is mapped to a gate using
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
|
@ -389,14 +376,9 @@ dense vector simulator $S$ can be replaced by $R_\phi$ with the parameter $x$.
|
||||||
|
|
||||||
Using this method circuits are generated and applied both to graphical and
|
Using this method circuits are generated and applied both to graphical and
|
||||||
dense vector states and the time required to execute the operations
|
dense vector states and the time required to execute the operations
|
||||||
\cite{timeit} is measured\footnote{
|
\cite{timeit} is measured. The resulting graph can be seen in
|
||||||
The used computer had an \lstinline{Intel(R) Core(TM) i5-4590 CPU @ 3.30GHz} processor,
|
|
||||||
\lstinline{7.7 GiB} RAM, and \lstinline{27 GiB} SSD swap space (which was unused).
|
|
||||||
The operating system was \lstinline{Linux 4.19.0-8-amd64 #1 SMP Debian 4.19.98-1 (2020-01-26) x86_64 GNU/Linux}.
|
|
||||||
|
|
||||||
}. The resulting graph can be seen in
|
|
||||||
Figure \ref{fig:scaling_qbits_linear} and Figure \ref{fig:scaling_qbits_log}.
|
Figure \ref{fig:scaling_qbits_linear} and Figure \ref{fig:scaling_qbits_log}.
|
||||||
Note that in both cases the length of the circuits have been scaled linearly
|
Note that in both cases the length of the circuits have been scaled linearely
|
||||||
with the amount of qbits and the measured time was divided by the number of
|
with the amount of qbits and the measured time was divided by the number of
|
||||||
qbits:
|
qbits:
|
||||||
|
|
||||||
|
@ -421,10 +403,10 @@ qbits:
|
||||||
\label{fig:scaling_qbits_log}
|
\label{fig:scaling_qbits_log}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|
||||||
The reason for this scaling will be clear later. From simulation data one can
|
The reason for this scaling will be clear later; one can observe that the
|
||||||
observe that the performance of the graphical simulator increases in some cases
|
performance of the graphical simulator increases in some cases with growing
|
||||||
with growing number of qbits when the circuit length is constant. The code used
|
number of qbits when the circuit length is constant. The code used to generate the
|
||||||
to generate the data for these plots can be found in \ref{ref:code_benchmarks}.
|
data for these plots can be found in \ref{ref:code_benchmarks}.
|
||||||
|
|
||||||
As described by \cite{andersbriegel2005} the graphical simulator is exponentially
|
As described by \cite{andersbriegel2005} the graphical simulator is exponentially
|
||||||
faster than the dense vector simulator. According to \cite{andersbriegel2005} it
|
faster than the dense vector simulator. According to \cite{andersbriegel2005} it
|
||||||
|
@ -432,12 +414,11 @@ is considerably faster than a simulator using the straight forward approach simu
|
||||||
the stabilizer tableaux like CHP \cite{CHP} with an average runtime behaviour
|
the stabilizer tableaux like CHP \cite{CHP} with an average runtime behaviour
|
||||||
of $\mathcal{O}\left(n\log(n)\right)$ instead of $\mathcal{O}\left(n^2\right)$.
|
of $\mathcal{O}\left(n\log(n)\right)$ instead of $\mathcal{O}\left(n^2\right)$.
|
||||||
|
|
||||||
One should be aware that the gate execution time (the time required to apply
|
One should be aware that the gate execution time (the time required to apply a gate
|
||||||
a gate to the state) highly depends on the state it is applied to \cite{andersbriegel2005}. For the
|
to the state) highly depends on the state it is applied to. For the dense vector
|
||||||
dense vector simulator and CHP this is not true: Gate execution time is
|
simulator and CHP this is not true: Gate execution time is constant for all gates
|
||||||
constant for all gates and states. Because the graphical simulator has to
|
and states. Because the graphical simulator has to toggle neighbourhoods the
|
||||||
toggle neighbourhoods the gate execution time of the $CZ$ and $M$ gates vary
|
gate execution time of the $CZ$ gate varies greatly. The plot Figure \ref{fig:scaling_circuits_linear}
|
||||||
significantly \cite{andersbriegel2005}. The plot Figure \ref{fig:scaling_circuits_linear}
|
|
||||||
shows the circuit execution time for two different numbers of qbits. One can observe three
|
shows the circuit execution time for two different numbers of qbits. One can observe three
|
||||||
regimes:
|
regimes:
|
||||||
|
|
||||||
|
@ -449,11 +430,11 @@ regimes:
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|
||||||
\begin{description}
|
\begin{description}
|
||||||
\item[Low-Linear Regime] {\textit{(Ca. $0-10N_q$ gates)} Here the circuit execution time scales approximately linear
|
\item[Low-Linear Regime] {Here the circuit execution time scales approximately linearely
|
||||||
with the number of gates in the circuit (i.e. the $CZ$ gate execution time is approximately constant).
|
with the number of gates in the circuit (i.e. the $CZ$ gate execution time is approximately constant).
|
||||||
}
|
}
|
||||||
\item[Intermediate Regime]{\textit{(Ca. $10N_q-20N_q$ gates)} The circuit execution time has a nonlinear dependence on the circuit length.}
|
\item[Intermediate Regime]{The circuit execution time has a nonlinear dependence on the circuit length.}
|
||||||
\item[High-Linear Regime]{\textit{(Above ca. $20N_q$ gates)} This regime shows a linear dependence on the circuit length; the slope is
|
\item[High-Linear Regime]{This regime shows a linear dependence on the circuit length; the slope is
|
||||||
higher than in the low-linear regime.}
|
higher than in the low-linear regime.}
|
||||||
\end{description}
|
\end{description}
|
||||||
|
|
||||||
|
@ -464,19 +445,6 @@ regimes:
|
||||||
\label{fig:scaling_circuits_measurements_linear}
|
\label{fig:scaling_circuits_measurements_linear}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|
||||||
|
|
||||||
These three regimes can be explained when considering the graphical states that
|
|
||||||
typical live in these regimes. With increased circuit length the amount of
|
|
||||||
edges increases which makes toggling neighbourhoods harder \cite{andersbriegel2005}. Graphs from the
|
|
||||||
low-linear, intermediate and high-linear regime can be seen in Figure
|
|
||||||
\ref{fig:graph_low_linear_regime}, Figure \ref{fig:graph_intermediate_regime}
|
|
||||||
and Figure \ref{fig:graph_high_linear_regime}. Due to the great amount of edges
|
|
||||||
in the intermediate and high-linear regime the pictures show a window of the
|
|
||||||
actual graph. The full images are in \ref{ref:complete_graphs}. Further the
|
|
||||||
regimes are not clearly visible for $n>30$ qbits therefore choosing smaller graphs is
|
|
||||||
not possible. The code that was used to generate these images can be found
|
|
||||||
in \ref{ref:code_example_graphs}.
|
|
||||||
|
|
||||||
\begin{figure}
|
\begin{figure}
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=\linewidth]{graphics/graph_low_linear_regime.png}
|
\includegraphics[width=\linewidth]{graphics/graph_low_linear_regime.png}
|
||||||
|
@ -498,18 +466,35 @@ in \ref{ref:code_example_graphs}.
|
||||||
\label{fig:graph_high_linear_regime}
|
\label{fig:graph_high_linear_regime}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|
||||||
|
These two regimes can be explained when considering the graphical states that
|
||||||
|
typical live in these regimes. With increased circuit length the amount of
|
||||||
|
edges increases which makes toggling neighbourhoods harder. Graphs from the
|
||||||
|
low-linear, intermediate and high-linear regime can be seen in Figure
|
||||||
|
\ref{fig:graph_low_linear_regime}, Figure \ref{fig:graph_intermediate_regime}
|
||||||
|
and Figure \ref{fig:graph_high_linear_regime}. Due to the great amount of edges
|
||||||
|
in the intermediate and high-linear regime the pictures show a window of the
|
||||||
|
actual graph. The full images are in \ref{ref:complete_graphs}. Further the
|
||||||
|
regimes are not clearly visibe for $n>30$ qbits so choosing smaller graphs is
|
||||||
|
not possible. The code that was used to generate these images can be found
|
||||||
|
in \ref{ref:code_example_graphs}.
|
||||||
|
|
||||||
The Figure \ref{fig:scaling_circuits_measurements_linear} brings more substance
|
The Figure \ref{fig:scaling_circuits_measurements_linear} brings more substance
|
||||||
to this interpretation. In this simulation the Pauli $X$ gate has been replaced
|
to this interpretation. In this simulation the Pauli $X$ gate has been replaced
|
||||||
by the measurement gate $M$, .i.e. in every gate drawn from the probability
|
by the measurement gate $M$, .i.e. in every gate drawn from the probability
|
||||||
space a qbit is measured with probability $\frac{1}{4}$. Pauli measurements
|
space a qbit is measured with probability $\frac{1}{4}$. As described in
|
||||||
decrease the entanglement (and the amount of edges) in a state
|
\cite{hein_eisert_briegel2008} the Schmidt measure for entropy is bounded from
|
||||||
|
above by Pauli persistency, i.e. the minimal amount of Pauli measurements
|
||||||
|
required to disentangle a state. This Pauli persistency is closely related to
|
||||||
|
the amount (and structure of) vertices in the graph
|
||||||
|
\cite{hein_eisert_briegel2008}. In particular Pauli measurements decrease the
|
||||||
|
entanglement (and the amount of edges) in a state
|
||||||
\cite{hein_eisert_briegel2008}\cite{li_chen_fisher2019}. The frequent
|
\cite{hein_eisert_briegel2008}\cite{li_chen_fisher2019}. The frequent
|
||||||
measurements in the simulation therefore keeps the amount of edges low thus
|
measurements in the simulation therefore keeps the amount of edges low thus
|
||||||
preventing a transition from the low linear regime to the intermediate regime.
|
preventing a transition from the low linear regime to the intermediate regime.
|
||||||
|
|
||||||
|
|
||||||
Because states with more qbits reach the intermediate regime at higher circuit
|
Because states with more qbits reach the intermediate regime at higher circuit
|
||||||
lengths it is important to compensate this virtual performance boost when
|
lengths it is important to account for this virtual performance boost when
|
||||||
comparing with other simulation methods. This explains why the circuit length
|
comparing with other simulation methods. This explains why the circuit length
|
||||||
in Figure \ref{fig:scaling_qbits_linear} had to be scaled with the qbit number.
|
in Figure \ref{fig:scaling_qbits_linear} had to be scaled with the qbit number.
|
||||||
|
|
||||||
|
@ -517,15 +502,15 @@ in Figure \ref{fig:scaling_qbits_linear} had to be scaled with the qbit number.
|
||||||
|
|
||||||
Although the simulator(s) are in a working state and have been tested there is
|
Although the simulator(s) are in a working state and have been tested there is
|
||||||
still some work that can be done. A noise model helping to teach and analyze
|
still some work that can be done. A noise model helping to teach and analyze
|
||||||
noisy execution would be an interesting improvement to implement. In order to
|
noisy execution is one particularly interesting piece of work. To allow a user
|
||||||
allow a user to execute circuits on other machines, including both real
|
to execute circuits on other machines, including both real hardware and
|
||||||
hardware and simulators, a module that exports circuits to OpenQASM
|
simulators, a module that exports circuits to OpenQASM \cite{openqasm} seems
|
||||||
\cite{openqasm} seems useful.
|
useful.
|
||||||
|
|
||||||
The current implementation of some graphical operations can be optimized. While
|
The current implementation of some graphical operations can be optimized. While
|
||||||
clearing VOPs as described in \ref{ref:dynamics_graph} the neighbourhood of
|
clearing VOPs as described in \ref{ref:dynamics_graph} the neighbourhood of
|
||||||
a vertex is toggled for every $L_a$ transformation. This is the most straight
|
a vertex is toggled for every $L_a$ transformation. This is the most straight
|
||||||
forward implementation, but often the $L_a$ transformation is performed several
|
forward implementation but often the $L_a$ transformation is performed several
|
||||||
times on the same vertex. The neighbourhood would have to be toggled either
|
times on the same vertex. The neighbourhood would have to be toggled either
|
||||||
once or not at all depending on whether the number of $L_a$ transformations is
|
once or not at all depending on whether the number of $L_a$ transformations is
|
||||||
odd or even.
|
odd or even.
|
||||||
|
|
|
@ -3,29 +3,29 @@
|
||||||
|
|
||||||
Quantum computing has been a rapidly growing field over the last years with
|
Quantum computing has been a rapidly growing field over the last years with
|
||||||
many companies and institutions working on building and using quantum computers
|
many companies and institutions working on building and using quantum computers
|
||||||
\cite{ibmq}\cite{intelqc}\cite{microsoftqc}\cite{dwavesys}.
|
\cite{ibmq}\cite{intelqc}\cite{microsoftqc}\cite{dwavesys}\cite{lrzqc}\cite{heise25_18}.
|
||||||
One important topic in this research is quantum error correction
|
One important topic in this research is quantum error correction
|
||||||
\cite{nielsen_chuang_2010}\cite{gottesman2009}\cite{gottesman1997}\cite{shor1995}
|
\cite{nielsen_chuang_2010}\cite{gottesman2009}\cite{gottesman1997}\cite{shor1995}
|
||||||
that will allow the execution of arbitrarily long quantum circuits \cite{nielsen_chuang_2010}.
|
that will allow the execution of arbitrarily long quantum circuits \cite{nielsen_chuang_2010}. One
|
||||||
A notable class of quantum error correction strategies are stabilizer codes
|
important class of quantum error correction strategies are stabilizer codes
|
||||||
\cite{gottesman2009}\cite{gottesman1997} that can be simulated exponentially
|
\cite{gottesman2009}\cite{gottesman1997} that can be simulated exponentially
|
||||||
faster than general quantum circuits
|
faster than general quantum circuits
|
||||||
\cite{gottesman_aaronson2008}\cite{CHP}\cite{andersbriegel2005}.
|
\cite{gottesman_aaronson2008}\cite{CHP}\cite{andersbriegel2005}.
|
||||||
|
|
||||||
Being able to simulate large stabilizer states is particularly interesting for
|
|
||||||
exploring quantum error correction strategies as fault tolerant quantum computing
|
|
||||||
requires several layers of encoding - so called concatenated codes \cite{nielsen_chuang_2010} -
|
|
||||||
that use many physical qbits organized in several layers to encode one logical qbit.
|
|
||||||
|
|
||||||
One particularly efficient way to simulate stabilizer states is the graphical
|
One particularly efficient way to simulate stabilizer states is the graphical
|
||||||
representation \cite{andersbriegel2005} that has been studied extensively in
|
representation \cite{andersbriegel2005} that has been studied extensively in
|
||||||
the context of both quantum error correction and quantum information theory
|
the context of both quantum error correction and quantum information theory
|
||||||
\cite{schlingenmann2001}\cite{dahlberg_ea2019}\cite{vandennest_ea2004}\cite{hein_eisert_briegel2008}.
|
\cite{schlingenmann2001}\cite{dahlberg_ea2019}\cite{vandennest_ea2004}\cite{hein_eisert_briegel2008}.
|
||||||
This paper describes the development of a quantum computing simulator
|
This paper describes the development of a quantum computing simulator
|
||||||
using both the usual dense state vector representation for a general state
|
using both the usual dense state vector representation for a general state
|
||||||
and a graphical representation for stabilizer states. After giving an introduction
|
and a graphical representation for stabilizer states. After giving some introduction
|
||||||
to quantum computing, some basic properties of stabilizer states and their
|
to quantum computing some basic properties of stabilizer states and their
|
||||||
dynamics are elucidated. Using this the graphical representation is introduced
|
dynamics are elucidated. Using this the graphical representation is introduced
|
||||||
and notable operations on the graphical states are explained. Following is
|
and some operations on the graphical states are explained. Following is
|
||||||
a chapter describing the implementation of these techniques and some performance
|
a chapter describing the implementation of these techniques and some performance
|
||||||
analysis.
|
analysis.
|
||||||
|
|
||||||
|
Being able to simulate large stabilizer states is particularly interesting for
|
||||||
|
exploring quantum error correction strategies as fault tolerant quantum computing
|
||||||
|
requires several layers of encoding - so called concatenated codes \cite{nielsen_chuang_2010} -
|
||||||
|
that require many physical qbits to encode one logical qbit.
|
||||||
|
|
|
@ -43,7 +43,7 @@ with
|
||||||
|
|
||||||
Note that $X = HZH$ and $Z = R_{\pi}$, so the set of $H, R_\phi$ is sufficient.
|
Note that $X = HZH$ and $Z = R_{\pi}$, so the set of $H, R_\phi$ is sufficient.
|
||||||
Further note that the basis vectors are chosen s.t. $Z\ket{0} = +\ket{0}$ and $Z\ket{1} = -\ket{1}$;
|
Further note that the basis vectors are chosen s.t. $Z\ket{0} = +\ket{0}$ and $Z\ket{1} = -\ket{1}$;
|
||||||
transforming to the other Pauli eigenstates is done using $H$ and $S$
|
transforming to the other Pauli eigenstates is done using $H$ and $SH$
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
S := R_{\frac{\pi}{2}} = \left(\begin{array}{cc} 1 & 0 \\ 0 & i\end{array}\right)
|
S := R_{\frac{\pi}{2}} = \left(\begin{array}{cc} 1 & 0 \\ 0 & i\end{array}\right)
|
||||||
|
@ -148,10 +148,10 @@ For a single-qbit gate $U$ and a qbit $j = 0, 1, ..., n - 1$
|
||||||
|
|
||||||
In particular for $X, Z$
|
In particular for $X, Z$
|
||||||
\begin{equation}\label{eq:CX_pr}
|
\begin{equation}\label{eq:CX_pr}
|
||||||
CX_{i, j} = \ket{0}\bra{0}_j\otimes I_i + \ket{1}\bra{1}_j \otimes X_i
|
CX(i, j) = \ket{0}\bra{0}_j\otimes I_i + \ket{1}\bra{1}_j \otimes X_i
|
||||||
\end{equation}
|
\end{equation}
|
||||||
\begin{equation}\label{eq:CZ_pr}
|
\begin{equation}\label{eq:CZ_pr}
|
||||||
CZ_{i, j} = \ket{0}\bra{0}_j\otimes I_i + \ket{1}\bra{1}_j \otimes Z_i .
|
CZ(i, j) = \ket{0}\bra{0}_j\otimes I_i + \ket{1}\bra{1}_j \otimes Z_i .
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
This follows the definition given in \cite{barenco_ea_1995}.
|
This follows the definition given in \cite{barenco_ea_1995}.
|
||||||
|
@ -214,8 +214,6 @@ As mentioned in \ref{ref:many_qbits} one can approximate an arbitrary $n$-qbit
|
||||||
gate $U$ as a product of some single-qbit gates and either $CX$ or $CZ$.
|
gate $U$ as a product of some single-qbit gates and either $CX$ or $CZ$.
|
||||||
Writing (possibly huge) products of matrices is quite unpractical and
|
Writing (possibly huge) products of matrices is quite unpractical and
|
||||||
unreadable. To address this problem quantum circuits have been introduced.
|
unreadable. To address this problem quantum circuits have been introduced.
|
||||||
The quantum circuits introduced here follow the conventions from
|
|
||||||
\cite{nielsen_chuang_2010}.
|
|
||||||
These represent the qbits as a horizontal line and a gate acting on a qbit is
|
These represent the qbits as a horizontal line and a gate acting on a qbit is
|
||||||
a box with a name on the respective line. Quantum circuits are read from
|
a box with a name on the respective line. Quantum circuits are read from
|
||||||
left to right. This means that a gate $U_i = Z_i X_i H_i$ has the
|
left to right. This means that a gate $U_i = Z_i X_i H_i$ has the
|
||||||
|
@ -246,15 +244,6 @@ Several qbits can be abbreviated by writing a slash on the qbit line:
|
||||||
}
|
}
|
||||||
\]
|
\]
|
||||||
|
|
||||||
Measurements are denoted using a special "gate", the classical result
|
|
||||||
is written as double lines:
|
|
||||||
|
|
||||||
\[
|
|
||||||
\Qcircuit @C=1em @R=.7em {
|
|
||||||
& \gate{H} & \gate{X} & \qw & \meter & \cw \\
|
|
||||||
}
|
|
||||||
\]
|
|
||||||
|
|
||||||
|
|
||||||
\section{Quantum Algorithms}
|
\section{Quantum Algorithms}
|
||||||
\label{ref:quantum_algorithms}
|
\label{ref:quantum_algorithms}
|
||||||
|
@ -283,8 +272,7 @@ Where $T\ket{\varphi} = \exp(2\pi i\varphi) \ket{\varphi}$ and the measurement
|
||||||
result $\tilde{\varphi} = \frac{x}{2^n}$ is an estimation for $\varphi$. If
|
result $\tilde{\varphi} = \frac{x}{2^n}$ is an estimation for $\varphi$. If
|
||||||
a success rate of $1-\epsilon$ and an accuracy of $| \varphi - \tilde{\varphi}
|
a success rate of $1-\epsilon$ and an accuracy of $| \varphi - \tilde{\varphi}
|
||||||
| < 2^{-m}$ is wanted, then $N = m + \log_2(2 + \frac{1}{2\epsilon})$ qbits are
|
| < 2^{-m}$ is wanted, then $N = m + \log_2(2 + \frac{1}{2\epsilon})$ qbits are
|
||||||
required \cite{nielsen_chuang_2010}.
|
required \cite{nielsen_chuang_2010}\cite{lehner2019}.
|
||||||
The gate $FT^\dagger$ is the inverse quantum fourier transform as described in \cite{nielsen_chuang_2010}.
|
|
||||||
|
|
||||||
%Another possible way to use quantum computers in physics is to simulate a system's
|
%Another possible way to use quantum computers in physics is to simulate a system's
|
||||||
%time evolution using the transfer matrix. By mapping an interesting system to
|
%time evolution using the transfer matrix. By mapping an interesting system to
|
||||||
|
|
|
@ -6,18 +6,16 @@ The stabilizer formalism was originally introduced by Gottesman
|
||||||
\cite{gottesman1997} for quantum error correction and is a useful tool to
|
\cite{gottesman1997} for quantum error correction and is a useful tool to
|
||||||
encode quantum information such that it is protected against noise. The
|
encode quantum information such that it is protected against noise. The
|
||||||
prominent Shor code \cite{shor1995} is an example of a stabilizer code
|
prominent Shor code \cite{shor1995} is an example of a stabilizer code
|
||||||
(although it was described before the stabilizer formalism was discovered), as
|
(although it was discovered before the stabilizer formalism was discovered), as
|
||||||
are the 3-qbit bit-flip and phase-flip codes.
|
are the 3-qbit bit-flip and phase-flip codes.
|
||||||
|
|
||||||
It was only later that Gottesman and Knill realized that stabilizer states can
|
It was only later that Gottesman and Knill discovered that stabilizer states
|
||||||
be simulated in polynomial time on a classical machine \cite{gottesman2008}.
|
can be simulated in polynomial time on a classical machine
|
||||||
This performance has since been improved to $n\log(n)$ time on average
|
\cite{gottesman2008}. This performance has since been improved to $n\log(n)$
|
||||||
\cite{andersbriegel2005}.
|
time on average \cite{andersbriegel2005}.
|
||||||
|
|
||||||
\section{Stabilizers and Stabilizer States}
|
\section{Stabilizers and Stabilizer States}
|
||||||
|
|
||||||
The discussion below follows the argumentation given in \cite{nielsen_chuang_2010}.
|
|
||||||
|
|
||||||
\subsection{Local Pauli Group and Multilocal Pauli Group}
|
\subsection{Local Pauli Group and Multilocal Pauli Group}
|
||||||
|
|
||||||
\begin{definition}
|
\begin{definition}
|
||||||
|
@ -41,13 +39,14 @@ either commute or anticommute.
|
||||||
is called the multilocal Pauli group on $n$ qbits \cite{andersbriegel2005}.
|
is called the multilocal Pauli group on $n$ qbits \cite{andersbriegel2005}.
|
||||||
\end{definition}
|
\end{definition}
|
||||||
|
|
||||||
The group property of $P_n$ and the (anti-)commutator relationships can be
|
The group property of $P_n$ and the (anti-)commutator relationships follow
|
||||||
deduced from its definition via the tensor product.
|
directly from its definition via the tensor product.
|
||||||
%Further are $p \in P_n$ hermitian and have the eigenvalues $\pm 1$ for
|
%Further are $p \in P_n$ hermitian and have the eigenvalues $\pm 1$ for
|
||||||
%$p \neq \pm I$, $+1$ for $p = I$ and $-1$ for $p = -I$.
|
%$p \neq \pm I$, $+1$ for $p = I$ and $-1$ for $p = -I$.
|
||||||
|
|
||||||
\subsection{Stabilizers}
|
\subsection{Stabilizers}
|
||||||
|
|
||||||
|
The discussion below follows the argumentation given in \cite{nielsen_chuang_2010}.
|
||||||
|
|
||||||
\begin{definition}
|
\begin{definition}
|
||||||
\label{def:stabilizer}
|
\label{def:stabilizer}
|
||||||
|
@ -60,19 +59,20 @@ deduced from its definition via the tensor product.
|
||||||
\end{definition}
|
\end{definition}
|
||||||
|
|
||||||
\begin{lemma}
|
\begin{lemma}
|
||||||
If $S$ is a set of stabilizers, these statements follow directly:
|
If $S$ is a set of stabilizers, the following statements follow
|
||||||
|
directly:
|
||||||
|
|
||||||
\begin{enumerate}
|
\begin{enumerate}
|
||||||
\item{$\pm iI \notin S$}
|
\item{$\pm iI \notin S$}
|
||||||
\item{$(S^{(i)})^2 = I$ $\forall i$}
|
\item{$(S^{(i)})^2 = I$ for all $i$}
|
||||||
\item{$S^{(i)}$ are hermitian $\forall i$ }
|
\item{$S^{(i)}$ are hermitian for all $i$ }
|
||||||
\end{enumerate}
|
\end{enumerate}
|
||||||
\end{lemma}
|
\end{lemma}
|
||||||
\begin{proof}
|
\begin{proof}
|
||||||
|
|
||||||
\begin{enumerate}
|
\begin{enumerate}
|
||||||
\item{$(iI)^2 = (-iI)^2 = -I$. Which contradicts the definition of $S$.}
|
\item{$(iI)^2 = (-iI)^2 = -I$. Which contradicts the definition of $S$.}
|
||||||
\item{From the definition of $S$ ($P_n$ respectively) one sees that any
|
\item{From the definition of $S$ ($P_n$ respectively) follows that any
|
||||||
$S^{(i)} \in S$ has the form $\pm i^l \left(\bigotimes\limits_{j=0}^{n-1} \tilde{p}_j\right)$ where
|
$S^{(i)} \in S$ has the form $\pm i^l \left(\bigotimes\limits_{j=0}^{n-1} \tilde{p}_j\right)$ where
|
||||||
$\tilde{p}_j \in \{X, Y, Z, I\}$ and $l \in \{0, 1\}$. As $\left(\bigotimes\limits_{j=0}^{n-1} \tilde{p}_j\right)$
|
$\tilde{p}_j \in \{X, Y, Z, I\}$ and $l \in \{0, 1\}$. As $\left(\bigotimes\limits_{j=0}^{n-1} \tilde{p}_j\right)$
|
||||||
is hermitian and unitary $(S^{(i)})^2$ is either $+I$ or $-I$. As $-I \notin S$ $(S^{(i)})^2 = I$ follows directly.
|
is hermitian and unitary $(S^{(i)})^2$ is either $+I$ or $-I$. As $-I \notin S$ $(S^{(i)})^2 = I$ follows directly.
|
||||||
|
@ -85,7 +85,7 @@ deduced from its definition via the tensor product.
|
||||||
|
|
||||||
Considering all the elements of a group can be impractical for some
|
Considering all the elements of a group can be impractical for some
|
||||||
calculations, the generators of a group are introduced. Often it is enough to
|
calculations, the generators of a group are introduced. Often it is enough to
|
||||||
discuss the generator's properties in order to understand those of the
|
discuss the generator's properties in order to understand the properties of the
|
||||||
group.
|
group.
|
||||||
|
|
||||||
\begin{definition}
|
\begin{definition}
|
||||||
|
@ -99,19 +99,20 @@ group.
|
||||||
$g_i$ and $m$ is the smallest integer for which these statements hold.
|
$g_i$ and $m$ is the smallest integer for which these statements hold.
|
||||||
\end{definition}
|
\end{definition}
|
||||||
|
|
||||||
From now on the generators $\langle S^{(i)} \rangle_{i}$ will be
|
In the following discussions $\langle S^{(i)} \rangle_{i=0, ..., n-1}$ will be
|
||||||
used as the required properties of a set of stabilizers that can be studied on
|
used as the required properties of a set of stabilizers that can be studied on
|
||||||
its generators.
|
its generators.
|
||||||
|
|
||||||
\subsection{Stabilizer States}
|
\subsection{Stabilizer States}
|
||||||
\label{ref:stab_states}
|
\label{ref:stab_states}
|
||||||
|
|
||||||
One important property of hermitian operators is that they have real
|
One important basic insight from quantum mechanics is that hermitian operators
|
||||||
eigenvalues and eigenspaces which are associated with these eigenvalues.
|
have real eigenvalues and eigenspaces which are associated with these
|
||||||
Finding these eigenvalues and eigenvectors is what one calls solving a quantum
|
eigenvalues. Finding these eigenvalues and eigenvectors is what one calls
|
||||||
mechanical system. It is fundamental for quantum mechanics that commuting
|
solving a quantum mechanical system. One of the most fundamental insights of
|
||||||
operators have a common set of eigenvectors, i.e. they can be diagonalized
|
quantum mechanics is that commuting operators have a common set of
|
||||||
simultaneously. This motivates and justifies the following definition.
|
eigenvectors, i.e. they can be diagonalized simultaneously. This motivates and
|
||||||
|
justifies the following definition.
|
||||||
|
|
||||||
\begin{definition}
|
\begin{definition}
|
||||||
For a set of stabilizers $S$ the vector space
|
For a set of stabilizers $S$ the vector space
|
||||||
|
@ -127,9 +128,9 @@ simultaneously. This motivates and justifies the following definition.
|
||||||
It is clear that to show the stabilization property of $S$ the proof for the
|
It is clear that to show the stabilization property of $S$ the proof for the
|
||||||
generators is sufficient, as all the generators forming an element in $S$ can
|
generators is sufficient, as all the generators forming an element in $S$ can
|
||||||
be absorbed into $\ket{\psi}$. The dimension of $V_S$ is not immediately
|
be absorbed into $\ket{\psi}$. The dimension of $V_S$ is not immediately
|
||||||
clear. One can show that for a set of stabilizers $\langle S^{(i)}
|
clear. One can however show that for a set of stabilizers $\langle S^{(i)}
|
||||||
\rangle_{i=1, ..., n-m}$ the dimension $\dim V_S = 2^m$ \cite[Chapter
|
\rangle_{i=1, ..., n-m}$ the dimension $\dim V_S = 2^m$ \cite[Chapter
|
||||||
10.5]{nielsen_chuang_2010}. This yields this important result:
|
10.5]{nielsen_chuang_2010}. This yields the following important result:
|
||||||
|
|
||||||
\begin{theorem} \label{thm:unique_s_state} For a $n$ qbit system and
|
\begin{theorem} \label{thm:unique_s_state} For a $n$ qbit system and
|
||||||
stabilizers $S = \langle S^{(i)} \rangle_{i=1, ..., n}$ the stabilizer
|
stabilizers $S = \langle S^{(i)} \rangle_{i=1, ..., n}$ the stabilizer
|
||||||
|
@ -145,14 +146,14 @@ In the following discussions for $n$ qbits a set $S = \langle S^{(i)}
|
||||||
\subsection{Dynamics of Stabilizer States}
|
\subsection{Dynamics of Stabilizer States}
|
||||||
\label{ref:dynamics_stabilizer}
|
\label{ref:dynamics_stabilizer}
|
||||||
|
|
||||||
Consider a $n$-qbit state $\ket{\psi}$ that is the $+1$ eigenstate of $S
|
Consider a $n$ qbit state $\ket{\psi}$ that is the $+1$ eigenstate of $S
|
||||||
= \langle S^{(i)} \rangle_{i=1,...,n}$ and a unitary transformation $U$ that
|
= \langle S^{(i)} \rangle_{i=1,...,n}$ and a unitary transformation $U$ that
|
||||||
describes the dynamics of the system, i.e.
|
describes the dynamics of the system, i.e.
|
||||||
|
|
||||||
\begin{equation} \ket{\psi'} = U \ket{\psi} \end{equation}
|
\begin{equation} \ket{\psi'} = U \ket{\psi} \end{equation}
|
||||||
|
|
||||||
It is clear that in general $\ket{\psi'}$ will not be stabilized by $S$
|
It is clear that in general $\ket{\psi'}$ will not be stabilized by $S$
|
||||||
anymore. Under some constraints there are statements that can be made
|
anymore. There are however some statements that can be made
|
||||||
\cite{nielsen_chuang_2010}:
|
\cite{nielsen_chuang_2010}:
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
|
@ -177,7 +178,7 @@ a set of stabilizers.
|
||||||
C_n := \left\{U \in U(2^n) \middle| \forall p \in P_n: UpU^\dagger \in P_n \right\}
|
C_n := \left\{U \in U(2^n) \middle| \forall p \in P_n: UpU^\dagger \in P_n \right\}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
is called the Clifford group, $C_1 =: C_L$ the local Clifford
|
is called the Clifford group. $C_1 =: C_L$ is called the local Clifford
|
||||||
group \cite{andersbriegel2005}.
|
group \cite{andersbriegel2005}.
|
||||||
\end{definition}
|
\end{definition}
|
||||||
|
|
||||||
|
@ -189,8 +190,8 @@ a set of stabilizers.
|
||||||
and $\sqrt{-iX} = \frac{1}{\sqrt{2}} \left(\begin{array}{cc} 1 & -i
|
and $\sqrt{-iX} = \frac{1}{\sqrt{2}} \left(\begin{array}{cc} 1 & -i
|
||||||
\\ -i & 1 \end{array}\right)$.
|
\\ -i & 1 \end{array}\right)$.
|
||||||
|
|
||||||
When using $\sqrt{iZ}, \sqrt{-iX}$ the product has a length
|
Also $C_L$ is generated by a product of at most $5$ matrices
|
||||||
not greater than $5$. }
|
$\sqrt{iZ}$, $\sqrt{-iX}$. }
|
||||||
\item{$C_n$ can be generated using $C_L$ and $CZ$ or $CX$.}
|
\item{$C_n$ can be generated using $C_L$ and $CZ$ or $CX$.}
|
||||||
\end{enumerate}
|
\end{enumerate}
|
||||||
\end{theorem}
|
\end{theorem}
|
||||||
|
@ -210,17 +211,17 @@ a set of stabilizers.
|
||||||
\end{enumerate}
|
\end{enumerate}
|
||||||
\end{proof}
|
\end{proof}
|
||||||
|
|
||||||
This is an important result: As under a transformation $U \in C_n$ $S'
|
This is quite an important result: As under a transformation $U \in C_n$ $S'
|
||||||
= U S U^\dagger$ is a set of $n$ independent stabilizers and $\ket{\psi'}$ is
|
= U S U^\dagger$ is a set of $n$ independent stabilizers and $\ket{\psi'}$ is
|
||||||
stabilized by $S'$ one can consider the dynamics of the stabilizers instead of
|
stabilized by $S'$ one can consider the dynamics of the stabilizers instead of
|
||||||
the actual state. Updating the $n$ stabilizers is considerably more efficient
|
the actual state. This is considerably more efficient as only $n$ stabilizers
|
||||||
as each stabilizer the tensor product of $n$ Pauli matrices. This has led to
|
have to be modified, each being just the tensor product of $n$ Pauli matrices.
|
||||||
the simulation using stabilizer tableaux
|
This has led to the simulation using stabilizer tableaux
|
||||||
\cite{gottesman_aaronson2008}\cite{CHP}.
|
\cite{gottesman_aaronson2008}\cite{CHP}.
|
||||||
|
|
||||||
\subsection{Measurements on Stabilizer States} \label{ref:meas_stab}
|
\subsection{Measurements on Stabilizer States} \label{ref:meas_stab}
|
||||||
|
|
||||||
Also measurements are dynamics covered by the stabilizers
|
Interestingly also measurements are dynamics covered by the stabilizers
|
||||||
\cite{nielsen_chuang_2010}. When an observable $g_a \in \{\pm X_a, \pm Y_a,
|
\cite{nielsen_chuang_2010}. When an observable $g_a \in \{\pm X_a, \pm Y_a,
|
||||||
\pm Z_a\}$ acting on qbit $a$ is measured one has to consider the projector
|
\pm Z_a\}$ acting on qbit $a$ is measured one has to consider the projector
|
||||||
|
|
||||||
|
@ -228,9 +229,8 @@ Also measurements are dynamics covered by the stabilizers
|
||||||
P_{g_a,s} = \frac{I + (-1)^s g_a}{2}.
|
P_{g_a,s} = \frac{I + (-1)^s g_a}{2}.
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
If now $g_a$ commutes with all $S^{(i)}$ a result of $s=0,1$ (depending on
|
If now $g_a$ commutes with all $S^{(i)}$ a result of $s=0$ is measured with
|
||||||
whether $g_a \in S$ or $-g_a \in S$) is measured with probability $1$ and the
|
probability $1$ and the stabilizers are left unchanged:
|
||||||
stabilizers are left unchanged:
|
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
|
@ -244,14 +244,14 @@ stabilizers are left unchanged:
|
||||||
As the state that is stabilized by $S$ is unique $\ket{\psi'} = \ket{\psi}$
|
As the state that is stabilized by $S$ is unique $\ket{\psi'} = \ket{\psi}$
|
||||||
\cite{nielsen_chuang_2010}.
|
\cite{nielsen_chuang_2010}.
|
||||||
|
|
||||||
If $g_a$ does not commute with all stabilizers the Lemma \ref{lemma:stab_measurement} gives the
|
If $g_a$ does not commute with all stabilizers the following lemma gives the
|
||||||
result of the measurement.
|
result of the measurement.
|
||||||
|
|
||||||
\begin{lemma}
|
\begin{lemma}
|
||||||
\label{lemma:stab_measurement} Let $J := \left\{ S^{(i)} \middle| [g_a,
|
\label{lemma:stab_measurement} Let $J := \left\{ S^{(i)} \middle| [g_a,
|
||||||
S^{(i)}] \neq 0\right\} \neq \{\}$ and $J^c := \left\{S^{(i)} \middle|
|
S^{(i)}] \neq 0\right\} \neq \{\}$ and $J^c := \left\{S^{(i)} \middle|
|
||||||
S^{(i)} \notin J \right\}$. When measuring $\frac{I + (-1)^s g_a}{2} $ $s=1$
|
S^{(i)} \notin J \right\}$. When measuring $\frac{I + (-1)^s g_a}{2} $ $s=1$
|
||||||
and $s=0$ are obtained with probability $\frac{1}{2}$ and after choosing a $S^{(j)}
|
and $s=0$ are obtained with probability $\frac{1}{2}$ and after choosing a $j
|
||||||
\in J$ the new state $\ket{\psi'}$ is stabilized by \cite{nielsen_chuang_2010}
|
\in J$ the new state $\ket{\psi'}$ is stabilized by \cite{nielsen_chuang_2010}
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\langle \{(-1)^s g_a\} \cup \left\{S^{(i)} S^{(j)} \middle| S^{(i)} \in J \setminus \{S^{(j)}\} \right\} \cup J^c \rangle.
|
\langle \{(-1)^s g_a\} \cup \left\{S^{(i)} S^{(j)} \middle| S^{(i)} \in J \setminus \{S^{(j)}\} \right\} \cup J^c \rangle.
|
||||||
|
@ -259,7 +259,7 @@ and $s=0$ are obtained with probability $\frac{1}{2}$ and after choosing a $S^{(
|
||||||
\end{lemma}
|
\end{lemma}
|
||||||
|
|
||||||
\begin{proof}
|
\begin{proof}
|
||||||
As $g_a$ is a Pauli operator and $S^{(i)} \in J$ are multilocal Pauli
|
As $g_a$ is a Pauli operator and $S^{(i)} \in J$ are multi-local Pauli
|
||||||
operators, $S^{(i)}$ and $g_a$ anticommute. Choose a $S^{(j)} \in J$. Then
|
operators, $S^{(i)}$ and $g_a$ anticommute. Choose a $S^{(j)} \in J$. Then
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
|
@ -271,6 +271,7 @@ and $s=0$ are obtained with probability $\frac{1}{2}$ and after choosing a $S^{(
|
||||||
&= \left|\hbox{Tr}\left(\frac{I - g_a}{2}\ket{\psi}\bra{\psi}\right)\right|\\
|
&= \left|\hbox{Tr}\left(\frac{I - g_a}{2}\ket{\psi}\bra{\psi}\right)\right|\\
|
||||||
&= P(s=1)
|
&= P(s=1)
|
||||||
\end{aligned}
|
\end{aligned}
|
||||||
|
\notag
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
With $P(s=+1) + P(s=-1) = 1$ follows $P(s=+1) = \frac{1}{2} = P(s=-1)$.
|
With $P(s=+1) + P(s=-1) = 1$ follows $P(s=+1) = \frac{1}{2} = P(s=-1)$.
|
||||||
|
@ -283,18 +284,18 @@ and $s=0$ are obtained with probability $\frac{1}{2}$ and after choosing a $S^{(
|
||||||
&= S^{(j)}S^{(i)}\frac{I + (-1)^{s + 2}g_a}{2}\ket{\psi} \\
|
&= S^{(j)}S^{(i)}\frac{I + (-1)^{s + 2}g_a}{2}\ket{\psi} \\
|
||||||
&= S^{(j)}S^{(i)}\frac{I + (-1)^sg_a}{2}\ket{\psi}
|
&= S^{(j)}S^{(i)}\frac{I + (-1)^sg_a}{2}\ket{\psi}
|
||||||
\end{aligned}
|
\end{aligned}
|
||||||
|
\notag
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
The state after measurement is stabilized by $S^{(j)}S^{(i)}$ for $S^{(j)},S^{(i)} \in J$,
|
The state after measurement is stabilized by $S^{(j)}S^{(i)}$ $i,j \in J$,
|
||||||
and by $S^{(i)} \in J^c$. $(-1)^sg_a$ trivially stabilizes $\ket{\psi'}$
|
and by $S^{(i)} \in J^c$. $(-1)^sg_a$ trivially stabilizes $\ket{\psi'}$
|
||||||
\cite{nielsen_chuang_2010}.
|
\cite{nielsen_chuang_2010}.
|
||||||
\end{proof}
|
\end{proof}
|
||||||
|
|
||||||
\section{The VOP-free Graph States}
|
\section{The VOP-free Graph States}
|
||||||
This section will discuss the vertex operator (VOP)-free graph states. Why they
|
This section will discuss the vertex operator (VOP)-free graph states. Why they
|
||||||
are called vertex operator-free will be clear in \ref{ref:sec_g_states}.
|
are called vertex operator-free will be clear in the following section about
|
||||||
Most of the discussion here is adapted from \cite{hein_eisert_briegel2008}
|
graph states.
|
||||||
whith some parts from \cite{andersbriegel2005}.
|
|
||||||
|
|
||||||
\subsection{VOP-free Graph States}
|
\subsection{VOP-free Graph States}
|
||||||
|
|
||||||
|
@ -310,7 +311,7 @@ called the neighbourhood of $i$ \cite{hein_eisert_briegel2008}.
|
||||||
This definition of a graph is way less general than the definition of a graph
|
This definition of a graph is way less general than the definition of a graph
|
||||||
in graph theory. Using this definition will however allow to avoid an
|
in graph theory. Using this definition will however allow to avoid an
|
||||||
extensive list of constraints on the graph from graph theory that are implied
|
extensive list of constraints on the graph from graph theory that are implied
|
||||||
here.
|
in this definition.
|
||||||
|
|
||||||
\begin{definition}
|
\begin{definition}
|
||||||
For a graph $G = (V = \{0, ..., n-1\}, E)$ the associated stabilizers are
|
For a graph $G = (V = \{0, ..., n-1\}, E)$ the associated stabilizers are
|
||||||
|
@ -323,35 +324,34 @@ here.
|
||||||
\end{definition}
|
\end{definition}
|
||||||
|
|
||||||
It is clear that the $K_G^{(i)}$ are multilocal Pauli operators. That they
|
It is clear that the $K_G^{(i)}$ are multilocal Pauli operators. That they
|
||||||
commute is trivial for $\{a,b\} \notin E$. If $\{a, b\} \in E$
|
commute is clear if $\{a,b\} \notin E$. If $\{a, b\} \in E$
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
K_G^{(a)} K_G^{(b)} &= X_a \left(\prod\limits_{i \in n_a} Z_i\right)
|
K_G^{(a)} K_G^{(b)} &= X_a \left(\prod\limits_{i \in n_a} Z_i\right)
|
||||||
X_b \left(\prod\limits_{j\in n_b} Z_j\right)\\
|
X_b \left(\prod\limits_{j\in n_b} Z_j\right)\\
|
||||||
&= X_a \left(\prod\limits_{i \in n_a\setminus \{b\}} Z_i\right) Z_b
|
&= X_a \left(\prod\limits_{i \in \setminus \{b\}} Z_i\right) Z_b
|
||||||
X_b \left(\prod\limits_{j\in n_b\setminus \{a\}} Z_j\right) Z_a\\
|
X_b \left(\prod\limits_{j\in n_b\setminus \{b\}} Z_j\right) Z_a\\
|
||||||
&= X_a Z_b X_b Z_a
|
&= X_a Z_b X_b Z_a
|
||||||
\left(\prod\limits_{j\in n_b\setminus \{a\}} Z_j\right)
|
\left(\prod\limits_{j\in n_b\setminus \{b\}} Z_j\right)
|
||||||
\left(\prod\limits_{i \in n_a\setminus \{b\}} Z_i\right)\\
|
\left(\prod\limits_{i \in \setminus \{b\}} Z_i\right)\\
|
||||||
&= -X_b Z_b X_a Z_a
|
&= -X_b Z_b X_a Z_a
|
||||||
\left(\prod\limits_{j\in n_b\setminus \{a\}} Z_j\right)
|
\left(\prod\limits_{j\in n_b\setminus \{b\}} Z_j\right)
|
||||||
\left(\prod\limits_{i \in n_a\setminus \{b\}} Z_i\right)\\
|
\left(\prod\limits_{i \in \setminus \{b\}} Z_i\right)\\
|
||||||
&= X_b Z_a X_a Z_b
|
&= X_b Z_a X_a Z_b
|
||||||
\left(\prod\limits_{j\in n_b\setminus \{a\}} Z_j\right)
|
\left(\prod\limits_{j\in n_b\setminus \{b\}} Z_j\right)
|
||||||
\left(\prod\limits_{i \in n_a \setminus \{b\}} Z_i\right)\\
|
\left(\prod\limits_{i \in \setminus \{b\}} Z_i\right)\\
|
||||||
&= K_G^{(b)} K_G^{(a)}.\\
|
&= K_G^{(b)} K_G^{(a)}.\\
|
||||||
\end{aligned}
|
\end{aligned}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
|
|
||||||
This definition of a graph state might not seem too helpful but recalling
|
This definition of a graph state might not seem to be straight forward but
|
||||||
Theorem \ref{thm:unique_s_state} it is clear that $\ket{\bar{G}}$ is unique.
|
recalling Theorem \ref{thm:unique_s_state} it is clear that $\ket{\bar{G}}$ is
|
||||||
Lemma \ref{lemma:g_bar} will provide a way to construct this state from the
|
unique. The following lemma will provide a way to construct this state from the
|
||||||
graph.
|
graph.
|
||||||
|
|
||||||
\begin{lemma}
|
\begin{lemma}
|
||||||
\label{lemma:g_bar}
|
|
||||||
For a graph $G = (V, E)$ the associated state $\ket{\bar{G}}$ is
|
For a graph $G = (V, E)$ the associated state $\ket{\bar{G}}$ is
|
||||||
constructed using \cite{hein_eisert_briegel2008}
|
constructed using \cite{hein_eisert_briegel2008}
|
||||||
|
|
||||||
|
@ -472,18 +472,18 @@ Another transformation on the VOP-free graph states for a vertex $a \in V$ is
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
This transformation toggles the neighbourhood of $a$ which is an operation
|
This transformation toggles the neighbourhood of $a$ which is an operation
|
||||||
that will be used later \cite{andersbriegel2005}.
|
that will be used later\cite{andersbriegel2005}.
|
||||||
|
|
||||||
\begin{lemma}
|
\begin{lemma}
|
||||||
\label{lemma:M_a}
|
\label{lemma:M_a}
|
||||||
When applying $M_a$ to a state $\ket{\bar{G}}$ the new state
|
When applying $M_a$ to a state $\ket{\bar{G}}$ the new state
|
||||||
$\ket{\bar{G}'}$ is again a VOP-free graph state and the
|
$\ket{\bar{G}'}$ is again a VOP-free graph state and the
|
||||||
graph is updated according to \cite{andersbriegel2005}:
|
graph is updated according to\cite{andersbriegel2005}:
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
n_a' &= n_a \\
|
n_a' &= n_a \\
|
||||||
n_j' &= n_j, \hbox{ if } j \notin n_a\\
|
n_j' &= n_j, \hbox{ if } j \notin n_a\\
|
||||||
n_j' &= n_j \Delta n_a \setminus \{j\}, \hbox{ if } j \in n_a
|
n_j' &= n_j \Delta n_a, \hbox{ if } j \in n_a
|
||||||
\end{aligned}
|
\end{aligned}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
\end{lemma}
|
\end{lemma}
|
||||||
|
@ -509,7 +509,7 @@ that will be used later \cite{andersbriegel2005}.
|
||||||
&= \sqrt{iZ_j} X_j\sqrt{iZ_j}^\dagger\left(\prod\limits_{m \in n_j \setminus \{a\}} Z_m\right)
|
&= \sqrt{iZ_j} X_j\sqrt{iZ_j}^\dagger\left(\prod\limits_{m \in n_j \setminus \{a\}} Z_m\right)
|
||||||
\sqrt{-iX_a} Z_a \sqrt{-iX_a}^\dagger \\
|
\sqrt{-iX_a} Z_a \sqrt{-iX_a}^\dagger \\
|
||||||
&= (-1)^2 Y_j Y_a \left(\prod\limits_{m \in n_j \setminus \{a\}} Z_m\right)\\
|
&= (-1)^2 Y_j Y_a \left(\prod\limits_{m \in n_j \setminus \{a\}} Z_m\right)\\
|
||||||
&= (-1)i^2 Z_j X_a X_j Z_a \left(\prod\limits_{m \in n_j \setminus \{a\}} Z_m\right).
|
&= (-1)i^2 Z_j X_a X_j Z_a \left(\prod\limits_{m \in n_j \setminus \{a\}} Z_m\right)
|
||||||
\end{aligned}
|
\end{aligned}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
|
@ -517,8 +517,8 @@ that will be used later \cite{andersbriegel2005}.
|
||||||
\ket{\bar{G}}$ is the $+1$ eigenstate of the new $K_{G'}^{(i)}$. Because
|
\ket{\bar{G}}$ is the $+1$ eigenstate of the new $K_{G'}^{(i)}$. Because
|
||||||
$\forall i\in V\setminus n_a$ $[K_G^{(i)}, M_a] = 0$ it is clear that
|
$\forall i\in V\setminus n_a$ $[K_G^{(i)}, M_a] = 0$ it is clear that
|
||||||
$\forall j \notin n_a$ $K_{G'}^{(j)} = K_G^{(j)}$. To construct the
|
$\forall j \notin n_a$ $K_{G'}^{(j)} = K_G^{(j)}$. To construct the
|
||||||
$K_{G'}^{(i)}$ choose a $j \in n_a$ and partition the neighbourhoods $n_a
|
$K_{G'}^{(i)}$ let for some $j \in n_a$ $n_a =: \{j\} \cup F$ and $n_j =:
|
||||||
=: \{j\} \cup F$ and $n_j =: \{a\} \cup D$. Then follows:
|
\{a\} \cup D$. Then follows:
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
|
@ -526,7 +526,7 @@ that will be used later \cite{andersbriegel2005}.
|
||||||
&= Z_j X_a X_j Z_a \left(\prod\limits_{l \in D} Z_l\right)
|
&= Z_j X_a X_j Z_a \left(\prod\limits_{l \in D} Z_l\right)
|
||||||
\left(\prod\limits_{l \in F}Z_l\right)
|
\left(\prod\limits_{l \in F}Z_l\right)
|
||||||
\left(\prod\limits_{l \in F}Z_l\right) \\
|
\left(\prod\limits_{l \in F}Z_l\right) \\
|
||||||
&= Z_j X_a X_j Z_a \left(\prod\limits_{l \in ((F\cup D) \setminus (F\cap D))} Z_l\right)
|
&= Z_j X_a X_j Z_a \left(\prod\limits_{l \in ((F\cup D) \setminus (F\cap D))} Z_L\right)
|
||||||
\left(\prod\limits_{l \in F}Z_l\right) \\
|
\left(\prod\limits_{l \in F}Z_l\right) \\
|
||||||
&= K_{G'}^{(a)} K_{G'}^{(j)} \\
|
&= K_{G'}^{(a)} K_{G'}^{(j)} \\
|
||||||
&= K_{G}^{(a)} K_{G'}^{(j)}
|
&= K_{G}^{(a)} K_{G'}^{(j)}
|
||||||
|
@ -543,7 +543,7 @@ that will be used later \cite{andersbriegel2005}.
|
||||||
Because $\left\{K_G^{(i)} \middle| i \notin n_a\right\} \cup \left\{S^{(i)}
|
Because $\left\{K_G^{(i)} \middle| i \notin n_a\right\} \cup \left\{S^{(i)}
|
||||||
\middle| i\in n_a\right\}$ and $\left\{K_G^{(i)} \middle| i \notin
|
\middle| i\in n_a\right\}$ and $\left\{K_G^{(i)} \middle| i \notin
|
||||||
n_a\right\} \cup \left\{K_{G'}^{(i)} \middle| i\in n_a \right\}$ are both $n$
|
n_a\right\} \cup \left\{K_{G'}^{(i)} \middle| i\in n_a \right\}$ are both $n$
|
||||||
commuting multilocal Pauli operators where the $S^{(i)}$ can be generated from
|
commuting multi-local Pauli operators where the $S^{(i)}$ can be generated from
|
||||||
the $K_{G'}^{(i)}$ and $\ket{\bar{G}'}$ is a $+1$ eigenstate of $K_{G'}^{(j)}$
|
the $K_{G'}^{(i)}$ and $\ket{\bar{G}'}$ is a $+1$ eigenstate of $K_{G'}^{(j)}$
|
||||||
$\langle\left\{K_G^{(i)} \middle| i \notin n_a\right\} \cup \left\{K_{G'}^{(i)}
|
$\langle\left\{K_G^{(i)} \middle| i \notin n_a\right\} \cup \left\{K_{G'}^{(i)}
|
||||||
\middle| i\in n_a \right\}\rangle$ are the stabilizers of $\ket{\bar{G}'}$.
|
\middle| i\in n_a \right\}\rangle$ are the stabilizers of $\ket{\bar{G}'}$.
|
||||||
|
@ -551,17 +551,16 @@ Therefore the associated graph is changed as given in the third equation.
|
||||||
\end{proof}
|
\end{proof}
|
||||||
|
|
||||||
\section{Graph States}
|
\section{Graph States}
|
||||||
\label{ref:sec_g_states}
|
|
||||||
|
|
||||||
The definition of a VOP-free graph state above raises an obvious question: Can
|
The definition of a VOP-free graph state above raises an obvious question: Can
|
||||||
any stabilizer state be described using just a graph? The answer is no. The
|
any stabilizer state be described using just a graph? The answer is straight
|
||||||
most simple cases are the single qbit states $\ket{0},\ket{1}$ and $\ket{+_Y},
|
forward: No. The most simple cases are the single qbit states $\ket{0},\ket{1}$
|
||||||
\ket{-_Y}$. But there is an extension to the VOP-free graph states that allows
|
and $\ket{+_Y}, \ket{-_Y}$. But there is an extension to the VOP-free graph
|
||||||
the representation of an arbitrary stabilizer state. The proof that any
|
states that allows the representation of an arbitrary stabilizer state. The
|
||||||
state can be represented is purely constructive. As seen in Theorem
|
proof that indeed any state can be represented is purely constructive. As seen
|
||||||
\ref{thm:clifford_group_approx} any $c \in C_n$ can be constructed from $CZ$
|
in Theorem \ref{thm:clifford_group_approx} any $c \in C_n$ can be constructed
|
||||||
and $C_L$. In the following discussion it will become clear that both $C_L$ and
|
from $CZ$ and $C_L$. In the following discussion it will become clear that both
|
||||||
$CZ$ can be applied to a general graph state
|
$C_L$ and $CZ$ can be applied to a general graph state
|
||||||
\footnote{
|
\footnote{
|
||||||
One can show that any stabilizer state is local Clifford equivalent to
|
One can show that any stabilizer state is local Clifford equivalent to
|
||||||
a VOP-free graph state, i.e. only tensor products of $C_L$ matrices are
|
a VOP-free graph state, i.e. only tensor products of $C_L$ matrices are
|
||||||
|
@ -588,9 +587,9 @@ $CZ$ can be applied to a general graph state
|
||||||
The notation in \cite{andersbriegel2005} is different. Instead of using $(V, E, O)$
|
The notation in \cite{andersbriegel2005} is different. Instead of using $(V, E, O)$
|
||||||
to represent any stabilizer $(V, E)$ is used to represent what is called a VOP-free
|
to represent any stabilizer $(V, E)$ is used to represent what is called a VOP-free
|
||||||
graph state in this paper. Then the state $\ket{\bar{G}}$ is extended with local Clifford
|
graph state in this paper. Then the state $\ket{\bar{G}}$ is extended with local Clifford
|
||||||
gates $c_1, ..., c_n$ to an arbitrary stabilizer state. The full state is denoted as
|
gates $c_1, ..., c_n$ to an arbitrary stabilizer state. The state is then denoted as
|
||||||
$\ket{\bar{G}; (c_1, ..., c_n)} \equiv \ket{\bar{G}; \vec{c}}$. This paper prefers
|
$\ket{\bar{G}; (c_1, ..., c_n)} \equiv \ket{\bar{G}; \vec{c}}$. This paper prefers
|
||||||
the notation $(V, E, O)$ as it both emphasizes the use of stabilizers and is closer
|
the notation using $(V, E, O)$ as it both emphasizes the use of stabilizers and is closer
|
||||||
to the representation used in the simulator.
|
to the representation used in the simulator.
|
||||||
}.
|
}.
|
||||||
\end{definition}
|
\end{definition}
|
||||||
|
@ -604,33 +603,30 @@ immediately:
|
||||||
|
|
||||||
The great advantage of this representation of a stabilizer state is its space
|
The great advantage of this representation of a stabilizer state is its space
|
||||||
requirement: Instead of storing $n^2$ Pauli matrices only some vertices (which
|
requirement: Instead of storing $n^2$ Pauli matrices only some vertices (which
|
||||||
are implicit when choosing $V=\{0, ..., n-1\}$), the edges and some vertex
|
often are implicit), the edges and some vertex operators ($n$ matrices) have to
|
||||||
operators ($n$ matrices) have to be stored. Theorem \ref{thm:cl24} will improve
|
be stored. The following theorem will improve this even further: instead of $n$
|
||||||
this even further: Instead of $n$ matrices it is sufficient to store $n$
|
matrices it is sufficient to store $n$ integers representing the vertex
|
||||||
integers representing the vertex operators.
|
operators:
|
||||||
|
|
||||||
\begin{theorem}
|
\begin{theorem}
|
||||||
\label{thm:cl24}
|
|
||||||
$C_L$ has $24$ degrees of freedom disregarding a global phase \cite{andersbriegel2005}.
|
$C_L$ has $24$ degrees of freedom disregarding a global phase \cite{andersbriegel2005}.
|
||||||
\end{theorem}
|
\end{theorem}
|
||||||
\begin{proof} It is clear that any $a \in C_L$ is a group isomorphism $P
|
\begin{proof} It is clear that $\forall a \in C_L$ a is a group isomorphism $P
|
||||||
\rightarrow P$: $apa^\dagger a p' a^\dagger = a pp'a^\dagger$. Therefore
|
\rightarrow P$: $apa^\dagger a p' a^\dagger = a pp'a^\dagger$. Therefore
|
||||||
$a$ will preserve the (anti-)commutator relations of $P$. Further note
|
$a$ will preserve the (anti-)commutator relations of $P$. Further note
|
||||||
that $Y = iXZ$, so one has to consider the (anti-)commutator relations of
|
that $Y = iXZ$, so one has to consider the anti-commutator relations of
|
||||||
$X,Z$ only.
|
$X,Z$ only.
|
||||||
|
|
||||||
As the transformations are unitary they preserve eigenvalues, so $X$ can be
|
As the transformations are unitary they preserve eigenvalues, so $X$ can be
|
||||||
mapped to $\pm X, \pm Y, \pm Z$ which gives $6$ degrees of freedom.
|
mapped to $\pm X, \pm Y, \pm Z$ which gives $6$ degrees of freedom.
|
||||||
Furthermore the image of $Z$ has to anti-commute with the image of $X$ therefore
|
Furthermore the image of $Z$ has to anti-commute with the image of $X$ so
|
||||||
$Z$ has four possible images under the transformation. This gives another
|
$Z$ has four possible images under the transformation. This gives another
|
||||||
$4$ degrees of freedom and a total of $24$.
|
$4$ degrees of freedom and a total of $24$. \end{proof}
|
||||||
\end{proof}
|
|
||||||
|
|
||||||
From now on $C_L = \langle H, S \rangle$ (disregarding a global phase) will be
|
From now on $C_L = \langle H, S \rangle$ (disregarding a global phase) will be
|
||||||
used. One can show (by construction) that $H, S$ generate a possible choice of
|
used. One can show (by construction) that $H, S$ generate a possible choice of
|
||||||
$C_L$, as do $\sqrt{-iX}, \sqrt{-iZ}$ which is required in one specific
|
$C_L$, as do $\sqrt{-iX}, \sqrt{-iZ}$ which is required in one specific
|
||||||
operation on graph states \cite{andersbriegel2005}. All elements of $C_L$ can
|
operation on graph states \cite{andersbriegel2005}.
|
||||||
be found in \ref{ref:impl_g_states}.
|
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
S = \left(\begin{array}{cc} 1 & 0 \\ 0 & i \end{array}\right)
|
S = \left(\begin{array}{cc} 1 & 0 \\ 0 & i \end{array}\right)
|
||||||
|
@ -648,12 +644,12 @@ be found in \ref{ref:impl_g_states}.
|
||||||
|
|
||||||
So far the graphical representation of stabilizer states is just another way to
|
So far the graphical representation of stabilizer states is just another way to
|
||||||
store basically a stabilizer tableaux that might require less memory than the
|
store basically a stabilizer tableaux that might require less memory than the
|
||||||
tableaux used in CHP \cite{CHP}. The power of this formalism can be seen by
|
tableaux used in CHP\cite{CHP}. The true power of this formalism is seen when
|
||||||
studying its dynamics. The simplest case is a local Clifford operator $c_j$
|
studying its dynamics. The simplest case is a local Clifford operator $c_j$
|
||||||
acting on a qbit $j$ changing the stabilizers to $\langle c_j S^{(i)}
|
acting on a qbit $j$: The stabilizers are changed to $\langle c_j S^{(i)}
|
||||||
c_j^\dagger\rangle_i$. Using the definition of the graphical representation one
|
c_j^\dagger\rangle_i$. Using the definition of the graphical representation one
|
||||||
sees that just the vertex operators are changed and the new vertex operators
|
sees that just the vertex operators are changed and the new vertex operators
|
||||||
are given by \cite{andersbriegel2005}
|
are given by
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
|
@ -663,9 +659,9 @@ are given by \cite{andersbriegel2005}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
The action of a $CZ$ gate on the state $(V, E, O)$ is in most cases less
|
The action of a $CZ$ gate on the state $(V, E, O)$ is in most cases less
|
||||||
trivial. Let $a \neq b$ be two qbits. Consider the action of $CZ_{a,b}$ on
|
trivial. Let $a \neq b$ be two qbits, now consider the action of $CZ_{a,b}$ on
|
||||||
$(V, E, O)$. The cases given here follow the implementation of a $CZ$
|
$(V, E, O)$. The cases given here follow the implementation of a $CZ$
|
||||||
application in \cite{pyqcs}. The respective paragraphs from
|
application in \cite{pyqcs}, the respective paragraphs from
|
||||||
\cite{andersbriegel2005} are given in italic. Most of the discussion follows
|
\cite{andersbriegel2005} are given in italic. Most of the discussion follows
|
||||||
the one given in \cite{andersbriegel2005} closely.
|
the one given in \cite{andersbriegel2005} closely.
|
||||||
|
|
||||||
|
@ -686,7 +682,7 @@ options with and without an edge between the qbits and $24$ Clifford operators
|
||||||
on each vertex.
|
on each vertex.
|
||||||
|
|
||||||
All those states and the resulting state after a $CZ$ application can be
|
All those states and the resulting state after a $CZ$ application can be
|
||||||
computed which leads to another interesting insight that will be useful later:
|
computed which leads to another interesting result that will be useful later:
|
||||||
If one vertex has the vertex operator $I$ the resulting state can be chosen
|
If one vertex has the vertex operator $I$ the resulting state can be chosen
|
||||||
such that at least one of the vertex operators is $I$ again and in particular
|
such that at least one of the vertex operators is $I$ again and in particular
|
||||||
the identity on the vertex can be preserved under the application of a $CZ$.
|
the identity on the vertex can be preserved under the application of a $CZ$.
|
||||||
|
@ -697,7 +693,7 @@ has non-operand (i.e. neighbours that are neither $a$ nor $b$) neighbours. In
|
||||||
this case one can try to clear the vertex operators which will succeed for at
|
this case one can try to clear the vertex operators which will succeed for at
|
||||||
least one qbit.
|
least one qbit.
|
||||||
|
|
||||||
The transformation given in Lemma \ref{lemma:M_a} is used to clear the vertex
|
The transformation given in Lemma \ref{lemma:M_a} is used to "clear" the vertex
|
||||||
operators. Recalling that the transformation $M_j$ toggles the neighbourhood of
|
operators. Recalling that the transformation $M_j$ toggles the neighbourhood of
|
||||||
vertex $j$ gives substance to the following theorem:
|
vertex $j$ gives substance to the following theorem:
|
||||||
|
|
||||||
|
@ -734,7 +730,7 @@ steps:
|
||||||
}
|
}
|
||||||
\end{enumerate}
|
\end{enumerate}
|
||||||
|
|
||||||
This algorithm has the important properties that if it succeeds $o_a
|
This algorithm has the important properties that if the algorithm succeeds $o_a
|
||||||
= I$ and $o_b$ has picked up powers of $\sqrt{iZ}^\dagger$. If $b$ has
|
= I$ and $o_b$ has picked up powers of $\sqrt{iZ}^\dagger$. If $b$ has
|
||||||
non-operand neighbours after clearing the vertex operators on $a$, then the
|
non-operand neighbours after clearing the vertex operators on $a$, then the
|
||||||
vertex operators on $b$ can be cleared using the same algorithm which gives
|
vertex operators on $b$ can be cleared using the same algorithm which gives
|
||||||
|
@ -755,29 +751,28 @@ non-operand neighbours and $b$ does not. Now the state $\ket{G}$ has the form
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
\ket{G} &= \left(\prod\limits_{o_i \in O} o_i\right) \left(\prod\limits_{\{i,j\} \in E} CZ_{i,j}\right) \ket{+}_n \\
|
\ket{G} &= \left(\prod\limits_{o_i \in O} o_i\right) \left(\prod\limits_{\{i,j\} \in E} CZ_{i,j}\right) \ket{+}_n \\
|
||||||
&= \left(\prod\limits_{o_i \in O \setminus \{o_b\}} o_i \right) \left(\prod\limits_{\{i,j\} \in E \setminus \{a,b\}} CZ_{i,j}\right) o_b (CZ_{a,b})^s \ket{+}_n \\
|
&= \left(\prod\limits_{o_i \in O \setminus \{o_b\}} o_i \right) \left(\prod\limits_{\{i,j\} \in E \setminus \{a,b\}} CZ_{i,j}\right) o_b (CZ_{a,b})^s \ket{+}_n \\
|
||||||
&= \left(\prod\limits_{o_i \in O \setminus \{o_b\}} o_i \right) \left(\prod\limits_{\{i,j\} \in E \setminus \{a,b\}} CZ_{i,j}\right) \ket{+}_{n-2} \otimes \left(o_b (CZ_{a,b})^s \ket{+}_2\right).\\
|
&= \left(\prod\limits_{o_i \in O \setminus \{o_b\}} o_i \right) \left(\prod\limits_{\{i,j\} \in E \setminus \{a,b\}} CZ_{i,j}\right) \ket{+}_{n-2} \otimes \left(o_b (CZ_{a,b})^s \ket{+}_2\right) .\\
|
||||||
\end{aligned}
|
\end{aligned}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
As $o_b$ commutes with all operators but $CZ_{a,b}$ and $s \in \{0, 1\}$
|
As $o_b$ commutes with all operators but $CZ_{a,b}$ and $s \in \{0, 1\}$
|
||||||
indicates whether there is an edge between $a$ and $b$. Applying the $CZ$
|
indicates whether there is an edge between $a$ and $b$.
|
||||||
gives
|
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
CZ_{a,b}\ket{G} &= CZ_{a,b}\left(\prod\limits_{o_i \in O \setminus \{o_b\}} o_i \right) \left(\prod\limits_{\{i,j\} \in E \setminus \{a,b\}} CZ_{i,j}\right) o_b (CZ_{a,b})^s \ket{+} \\
|
CZ_{a,b}\ket{G} &= CZ_{a,b}\left(\prod\limits_{o_i \in O \setminus \{o_b\}} o_i \right) \left(\prod\limits_{\{i,j\} \in E \setminus \{a,b\}} CZ_{i,j}\right) o_b (CZ_{a,b})^s \ket{+} \\
|
||||||
&= \left(\prod\limits_{o_i \in O \setminus \{o_b\}} o_i \right) \left(\prod\limits_{\{i,j\} \in E \setminus \{a,b\}} CZ_{i,j}\right) \ket{+}_{n-2} \otimes \left(CZ_{a,b} o_b (CZ_{a,b})^s \ket{+}_2\right). \\
|
&= \left(\prod\limits_{o_i \in O \setminus \{o_b\}} o_i \right) \left(\prod\limits_{\{i,j\} \in E \setminus \{a,b\}} CZ_{i,j}\right) \ket{+}_{n-2} \otimes \left(CZ_{a,b} o_b (CZ_{a,b})^s \ket{+}_2\right) \\
|
||||||
\end{aligned}
|
\end{aligned}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
This allows to reuse the method in Case 2 to apply the $CZ$ while keeping the
|
This allows to re-use the method in Case 2 to apply the $CZ$ while keeping the
|
||||||
$o_a = I$.
|
$o_a = I$.
|
||||||
|
|
||||||
As it has been shown how both $CZ$ and $C_L$ act on a graph state $\ket{G}$
|
As it has been shown how both $CZ$ and $C_L$ act on a graph state $\ket{G}$
|
||||||
and the resulting state is a graph state as well this proofs constructively
|
and the resulting state is a graph state as well this proofs constructively
|
||||||
that the graphical representation of a stabilizer state is able to represent
|
that the graphical representation of a stabilizer state is indeed able to
|
||||||
any stabilizer state. If one wants to do computations using this formalism it
|
represent any stabilizer state. If one wants to do computations using this
|
||||||
is also necessary to perform measurements.
|
formalism it is however also necessary to perform measurements.
|
||||||
|
|
||||||
\subsection{Measurements on Graph States}
|
\subsection{Measurements on Graph States}
|
||||||
\label{ref:meas_graph}
|
\label{ref:meas_graph}
|
||||||
|
@ -787,13 +782,13 @@ the graph after a measurement is described in \cite{hein_eisert_briegel2008}.
|
||||||
|
|
||||||
Recalling \ref{ref:meas_stab} it is clear that one has to compute the
|
Recalling \ref{ref:meas_stab} it is clear that one has to compute the
|
||||||
commutator of the observable $g_a = Z_a$ with the stabilizers to get the
|
commutator of the observable $g_a = Z_a$ with the stabilizers to get the
|
||||||
probability amplitudes which is an expensive computation in theory. It is
|
probability amplitudes which is a quite expensive computation in theory. It is
|
||||||
possible to simplify the problem by pulling the observable behind the vertex
|
possible to simplify the problem by pulling the observable behind the vertex
|
||||||
operators. For this consider the projector $P_{a,s} = \frac{I + (-1)^sZ_a}{2}$
|
operators. For this consider the projector $P_{a,s} = \frac{I + (-1)^sZ_a}{2}$
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
P_{a,s} \ket{G} &= P_{a,s} \left(\prod\limits_{o_i \in O} o_i \right) \ket{\bar{G}} \\
|
P_{a,s} \ket{\psi} &= P_{a,s} \left(\prod\limits_{o_i \in O} o_i \right) \ket{\bar{G}} \\
|
||||||
&= \left(\prod\limits_{o_i \in O \setminus \{o_a\}}o_i \right)P_a o_a \ket{\bar{G}} \\
|
&= \left(\prod\limits_{o_i \in O \setminus \{o_a\}}o_i \right)P_a o_a \ket{\bar{G}} \\
|
||||||
&= \left(\prod\limits_{o_i \in O \setminus \{o_a\}}o_i \right) o_a o_a^\dagger P_a o_a \ket{\bar{G}} \\
|
&= \left(\prod\limits_{o_i \in O \setminus \{o_a\}}o_i \right) o_a o_a^\dagger P_a o_a \ket{\bar{G}} \\
|
||||||
&= \left(\prod\limits_{o_i \in O} o_i \right) o_a^\dagger P_a o_a \ket{\bar{G}} \\
|
&= \left(\prod\limits_{o_i \in O} o_i \right) o_a^\dagger P_a o_a \ket{\bar{G}} \\
|
||||||
|
@ -813,11 +808,11 @@ projector as $o_a$ is a Clifford operator
|
||||||
\end{aligned}
|
\end{aligned}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
Where $\tilde{g}_a \in \{\pm X_a, \pm Y_a, \pm Z_a\}$. Therefore, it is enough
|
Where $\tilde{g}_a \in \{\pm X_a, \pm Y_a, \pm Z_a\}$. Therefore, it is
|
||||||
to study the measurements of any Pauli operator on the VOP-free graph states.
|
enough to study the measurements of any Pauli operator on the vertex operator
|
||||||
The commutators of the observable with the $K_G^{(i)}$ are easy to compute.
|
free graph states. The commutators of the observable with the $K_G^{(i)}$ are
|
||||||
Note that Pauli matrices either commute or anticommute and it is simpler to
|
quite easy to compute. Note that Pauli matrices either commute or anticommute
|
||||||
list the operators that anticommute:
|
and it is easier to list the operators that anticommute:
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
|
@ -832,26 +827,25 @@ $\tilde{g}_a = X_a (-X_a)$ is measured the result $s=0(1)$ is obtained with
|
||||||
probability $1$ and $(V, E, O)$ is unchanged. In any other case the results
|
probability $1$ and $(V, E, O)$ is unchanged. In any other case the results
|
||||||
$s=1$ and $s=0$ have probability $\frac{1}{2}$ and both graph and vertex
|
$s=1$ and $s=0$ have probability $\frac{1}{2}$ and both graph and vertex
|
||||||
operators have to be updated. Further it is clear that measurements of
|
operators have to be updated. Further it is clear that measurements of
|
||||||
$-\tilde{g}_a$ and $\tilde{g}_a$ are related by inverting the result $s$.
|
$-\tilde{g}_a$ and $\tilde{g}_a$ are related by just inverting the result $s$.
|
||||||
|
|
||||||
The calculations to obtain the transformation on graph and vertex operators are
|
The calculations to obtain the transformation on graph and vertex operators are
|
||||||
lengthy and follow the scheme of Lemma \ref{lemma:M_a}. \cite[Section
|
lengthy and follow the scheme of Lemma \ref{lemma:M_a}. \cite[Section
|
||||||
IV]{hein_eisert_briegel2008} also contains the steps required to obtain the
|
IV]{hein_eisert_briegel2008} also contains the steps required to obtain the
|
||||||
following results:
|
following results
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
U_{Z,s} &= \left(\prod\limits_{b \in n_a} Z_b^s\right) X_a^s H_a \\
|
U_{Z,s} &= \left(\prod\limits_{b \in n_a} Z_b^s\right) X_a^s H_a \\
|
||||||
U_{Y,s} &= \prod\limits_{b \in n_a} \sqrt{(-1)^{1-s} iZ_b} \sqrt{(-1)^{1-s} iZ_a}\\
|
U_{Y,s} &= \prod\limits_{b \in n_a} \sqrt{(-1)^{1-s} iZ_b} \sqrt{(-1)^{1-s} iZ_a}.\\
|
||||||
\end{aligned}
|
\end{aligned}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
These transformations split it in two parts: the first is a result of Lemma
|
These transformations split it two parts: the first is a result of Lemma
|
||||||
\ref{lemma:stab_measurement}. The second part makes sure that the qbit $a$ is
|
\ref{lemma:stab_measurement}. The second part makes sure that the qbit $a$ is
|
||||||
diagonal in the measured observable and has the correct eigenvalue. When comparing
|
diagonal in measured observable and has the correct eigenvalue. When comparing
|
||||||
with Lemma \ref{lemma:stab_measurement} in both cases $Y$ and $Z$ the anticommuting
|
with Lemma \ref{lemma:stab_measurement} in both cases $Y,Z$ the anticommuting
|
||||||
stabilizer $K_G^{(a)}$ is chosen. The graph is changed according to
|
stabilizer $K_G^{(a)}$ is chosen. The graph is changed according to
|
||||||
\footnote{$n_a \otimes n_a$ should be read as $\{\{i,j\} | i,j \in n_a, i \neq j\}$.}
|
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
|
@ -861,7 +855,7 @@ stabilizer $K_G^{(a)}$ is chosen. The graph is changed according to
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
|
|
||||||
For $g_a = X_a$ one has to choose a neighbour $b \in n_a$ and the transformations are
|
For $g_a = X_a$ one has to choose a $b \in n_a$ and the transformations are
|
||||||
|
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\begin{aligned}
|
\begin{aligned}
|
||||||
|
|
BIN
thesis/cover.png
Before Width: | Height: | Size: 133 KiB After Width: | Height: | Size: 183 KiB |
|
@ -21,7 +21,7 @@
|
||||||
CHP,
|
CHP,
|
||||||
url={https://www.scottaaronson.com/chp/},
|
url={https://www.scottaaronson.com/chp/},
|
||||||
urldate={09.03.2020},
|
urldate={09.03.2020},
|
||||||
author={Scott Aaronson and Daniel Gottesman},
|
author={Scott Aaronson, Daniel Gottesman},
|
||||||
title={CHP: CNOT-Hadamard-Phase},
|
title={CHP: CNOT-Hadamard-Phase},
|
||||||
year=2005,
|
year=2005,
|
||||||
note={https://www.scottaaronson.com/chp/}
|
note={https://www.scottaaronson.com/chp/}
|
||||||
|
@ -39,7 +39,6 @@
|
||||||
andersbriegel2005,
|
andersbriegel2005,
|
||||||
title={Fast simulation of stabilizer circuits using a graph state representation},
|
title={Fast simulation of stabilizer circuits using a graph state representation},
|
||||||
author={Simon Anders and Hans J. Briegel},
|
author={Simon Anders and Hans J. Briegel},
|
||||||
note={http://arxiv.org/abs/quant-ph/0504117v2},
|
|
||||||
year=2005
|
year=2005
|
||||||
}
|
}
|
||||||
@book{
|
@book{
|
||||||
|
@ -52,7 +51,7 @@
|
||||||
@book{
|
@book{
|
||||||
kaye_ea2007,
|
kaye_ea2007,
|
||||||
title={An Introduction to Quantum Computing},
|
title={An Introduction to Quantum Computing},
|
||||||
author={Phillip Kaye and Raymond Laflamme and Michelle Mosca},
|
author={Phillip Kaye, Raymond Laflamme and Michelle Mosca},
|
||||||
year=2007,
|
year=2007,
|
||||||
publisher={Oxford University Press}
|
publisher={Oxford University Press}
|
||||||
}
|
}
|
||||||
|
@ -76,7 +75,7 @@
|
||||||
gottesman_aaronson2008,
|
gottesman_aaronson2008,
|
||||||
title={Improved Simulation of Stabilizer Circuits},
|
title={Improved Simulation of Stabilizer Circuits},
|
||||||
year=2008,
|
year=2008,
|
||||||
author={Daniel Gottesman and Scott Aaronson},
|
author={Daniel Gottesman, Scott Aaronson},
|
||||||
note={https://arxiv.org/abs/quant-ph/0406196v5}
|
note={https://arxiv.org/abs/quant-ph/0406196v5}
|
||||||
}
|
}
|
||||||
|
|
||||||
|
@ -107,7 +106,7 @@
|
||||||
nielsen_chuang_2010,
|
nielsen_chuang_2010,
|
||||||
title={Quantum Computation and Quantum Information},
|
title={Quantum Computation and Quantum Information},
|
||||||
year=2010,
|
year=2010,
|
||||||
author={Michael A. Nielsen and Isaac L. Chuang},
|
author={Michael A. Nielsen, Isaac L. Chuang},
|
||||||
publisher={CAMBRIDGE UNIVERSITY PRESS},
|
publisher={CAMBRIDGE UNIVERSITY PRESS},
|
||||||
note={www.cambridge.org/9781107002173}
|
note={www.cambridge.org/9781107002173}
|
||||||
}
|
}
|
||||||
|
@ -124,7 +123,7 @@
|
||||||
marquezino_ea_2019,
|
marquezino_ea_2019,
|
||||||
title={A Primer on Quantum Computing},
|
title={A Primer on Quantum Computing},
|
||||||
year=2019,
|
year=2019,
|
||||||
author={Franklin de Lima Marquezino and Renato Portugal and Carlile Lavor},
|
author={Franklin de Lima Marquezino, Renato Portugal, Carlile Lavor},
|
||||||
publisher={Springer}
|
publisher={Springer}
|
||||||
}
|
}
|
||||||
@article{
|
@article{
|
||||||
|
@ -156,7 +155,7 @@
|
||||||
hein_eisert_briegel2008,
|
hein_eisert_briegel2008,
|
||||||
title={Multi-party entanglement in graph states},
|
title={Multi-party entanglement in graph states},
|
||||||
year=2008,
|
year=2008,
|
||||||
author={M. Hein and J. Eisert and H.J. Briegel},
|
author={M. Hein, J. Eisert, H.J. Briegel},
|
||||||
note={https://arxiv.org/abs/quant-ph/0307130v7}
|
note={https://arxiv.org/abs/quant-ph/0307130v7}
|
||||||
}
|
}
|
||||||
@article{
|
@article{
|
||||||
|
@ -191,13 +190,11 @@
|
||||||
urldate={19.09.2019},
|
urldate={19.09.2019},
|
||||||
title={IBM Q - What is quantum computing?},
|
title={IBM Q - What is quantum computing?},
|
||||||
author={IBM},
|
author={IBM},
|
||||||
note={https://www.ibm.com/quantum-computing/learn/what-is-quantum-computing/},
|
|
||||||
year=2019
|
year=2019
|
||||||
}
|
}
|
||||||
@online{
|
@online{
|
||||||
intelqc,
|
intelqc,
|
||||||
url={https://newsroom.intel.com/press-kits/quantum-computing/\#gs.2s0dux},
|
url={https://newsroom.intel.com/press-kits/quantum-computing/\#gs.2s0dux},
|
||||||
note={https://newsroom.intel.com/press-kits/quantum-computing/\#gs.2s0dux},
|
|
||||||
urldate={19.09.2019},
|
urldate={19.09.2019},
|
||||||
title={Intel Press Kit: Quantum Computing},
|
title={Intel Press Kit: Quantum Computing},
|
||||||
author={Intel},
|
author={Intel},
|
||||||
|
@ -206,7 +203,6 @@
|
||||||
@online{
|
@online{
|
||||||
microsoftqc,
|
microsoftqc,
|
||||||
url={https://www.microsoft.com/en-us/quantum/default.aspx},
|
url={https://www.microsoft.com/en-us/quantum/default.aspx},
|
||||||
note={https://www.microsoft.com/en-us/quantum/default.aspx},
|
|
||||||
urldate={19.09.2019},
|
urldate={19.09.2019},
|
||||||
title={Quantum Computing | Microsoft},
|
title={Quantum Computing | Microsoft},
|
||||||
author={Microsoft},
|
author={Microsoft},
|
||||||
|
@ -215,7 +211,6 @@
|
||||||
@online{
|
@online{
|
||||||
dwavesys,
|
dwavesys,
|
||||||
url={https://www.dwavesys.com/quantum-computing},
|
url={https://www.dwavesys.com/quantum-computing},
|
||||||
note={https://www.dwavesys.com/quantum-computing},
|
|
||||||
urldate={19.09.2019},
|
urldate={19.09.2019},
|
||||||
title={Quantum Computing | D-Wave Systems},
|
title={Quantum Computing | D-Wave Systems},
|
||||||
author={D-Wave Systems Inc}
|
author={D-Wave Systems Inc}
|
||||||
|
@ -223,7 +218,6 @@
|
||||||
@online{
|
@online{
|
||||||
lrzqc,
|
lrzqc,
|
||||||
url={https://www.lrz.de/wir/newsletter/2019-08/\#LRZ_bereit_fuer_bayerische_Quantechnologie},
|
url={https://www.lrz.de/wir/newsletter/2019-08/\#LRZ_bereit_fuer_bayerische_Quantechnologie},
|
||||||
note={https://www.lrz.de/wir/newsletter/2019-08/\#LRZ_bereit_fuer_bayerische_Quantechnologie},
|
|
||||||
urldate={19.09.2019},
|
urldate={19.09.2019},
|
||||||
title={LRZ-Newsletter Nr. 08/2019 vom 01.08.2019},
|
title={LRZ-Newsletter Nr. 08/2019 vom 01.08.2019},
|
||||||
author={S. Vieser},
|
author={S. Vieser},
|
||||||
|
@ -232,7 +226,6 @@
|
||||||
@online{
|
@online{
|
||||||
heise25_18,
|
heise25_18,
|
||||||
url={https://www.heise.de/select/ct/2018/25/1544250249368810},
|
url={https://www.heise.de/select/ct/2018/25/1544250249368810},
|
||||||
note={https://www.heise.de/select/ct/2018/25/1544250249368810},
|
|
||||||
urldate={19.09.2019},
|
urldate={19.09.2019},
|
||||||
title={Europa entfesselt Quanten-Power},
|
title={Europa entfesselt Quanten-Power},
|
||||||
author={Arne Grävemeyer},
|
author={Arne Grävemeyer},
|
||||||
|
@ -241,14 +234,14 @@
|
||||||
@article{
|
@article{
|
||||||
li_chen_fisher2019,
|
li_chen_fisher2019,
|
||||||
year=2019,
|
year=2019,
|
||||||
author={Yaodong Li and Xiao Chen and Matthew P. A. Fisher},
|
author={Yaodong Li, Xiao Chen, Matthew P. A. Fisher},
|
||||||
title={Measurement-driven entanglement transition in hybrid quantum circuits},
|
title={Measurement-driven entanglement transition in hybrid quantum circuits},
|
||||||
note={https://arxiv.org/abs/1901.08092}
|
note={https://arxiv.org/abs/1901.08092}
|
||||||
}
|
}
|
||||||
@article{
|
@article{
|
||||||
bermejovega_lin_vdnest2015,
|
bermejovega_lin_vdnest2015,
|
||||||
year=2015,
|
year=2015,
|
||||||
author={Juan Bermejo-Vega and Cedric Yen-Yu Lin and Maarten Van den Nest},
|
author={Juan Bermejo-Vega, Cedric Yen-Yu Lin, Maarten Van den Nest},
|
||||||
title={Normalizer circuits and a Gottesman-Knill theoremfor infinite-dimensional systems},
|
title={Normalizer circuits and a Gottesman-Knill theoremfor infinite-dimensional systems},
|
||||||
note={https://arxiv.org/pdf/1409.3208.pdf}
|
note={https://arxiv.org/pdf/1409.3208.pdf}
|
||||||
}
|
}
|
||||||
|
@ -269,7 +262,7 @@
|
||||||
@article{
|
@article{
|
||||||
bermejovega_vdnest2018,
|
bermejovega_vdnest2018,
|
||||||
year=2018,
|
year=2018,
|
||||||
author={Juan Bermejo-Vega and Maarten Van den Nest},
|
author={Juan Bermejo-Vega, Maarten Van den Nest},
|
||||||
title={Classical simulations of Abelian-group normalizer circuits with intermediate measurements},
|
title={Classical simulations of Abelian-group normalizer circuits with intermediate measurements},
|
||||||
note={https://arxiv.org/abs/1210.3637v2}
|
note={https://arxiv.org/abs/1210.3637v2}
|
||||||
}
|
}
|
||||||
|
@ -294,10 +287,3 @@
|
||||||
title={The Computer Language Benchmarks Game},
|
title={The Computer Language Benchmarks Game},
|
||||||
note={https://benchmarksgame-team.pages.debian.net/benchmarksgame/}
|
note={https://benchmarksgame-team.pages.debian.net/benchmarksgame/}
|
||||||
}
|
}
|
||||||
@article{
|
|
||||||
bouchet1991,
|
|
||||||
author={Andrk Bouchet},
|
|
||||||
title={Recognizing locally equivalent graphs},
|
|
||||||
year=1991,
|
|
||||||
note={https://pdf.sciencedirectassets.com/271536/1-s2.0-S0012365X00X02166/1-s2.0-0012365X9390357Y/main.pdf}
|
|
||||||
}
|
|
||||||
|
|
|
@ -1,4 +1,4 @@
|
||||||
\documentclass[a4paper,12pt,numbers=noenddot,egregdoesnotlikesansseriftitles]{scrreprt}
|
\documentclass[a4paper,12pt,numbers=noenddot]{scrreprt}
|
||||||
\usepackage[utf8]{inputenc}
|
\usepackage[utf8]{inputenc}
|
||||||
\usepackage{graphicx}
|
\usepackage{graphicx}
|
||||||
\usepackage{amssymb, amsthm}
|
\usepackage{amssymb, amsthm}
|
||||||
|
@ -52,18 +52,18 @@ Supervised by Prof. Dr. Christoph Lehner}
|
||||||
|
|
||||||
{\LARGE University of Regensburg\par}
|
{\LARGE University of Regensburg\par}
|
||||||
{\Large Institute I - Theoretical Physics\par}
|
{\Large Institute I - Theoretical Physics\par}
|
||||||
\vspace{0.7cm}
|
\vspace{1cm}
|
||||||
{\Large Bachelor Thesis\par}
|
{\Large Bachelor Thesis\par}
|
||||||
\vspace{0.7cm}
|
\vspace{1cm}
|
||||||
{\huge\bfseries An Efficient Quantum Computing Simulator using a Graphical Description for Many-Qbit Systems \par}
|
{\huge\bfseries An Efficient Quantum Computing Simulator using a Graphical Description for Many-Qbit Systems \par}
|
||||||
\vspace{0.7cm}
|
\vspace{1cm}
|
||||||
{\Large\itshape Daniel Knüttel\par}
|
{\Large\itshape Daniel Knüttel\par}
|
||||||
|
|
||||||
\includegraphics[width=\textwidth]{cover.png}
|
\includegraphics[width=\textwidth]{cover.png}
|
||||||
|
|
||||||
\vfill
|
\vfill
|
||||||
{\Large\itshape Supervised by \par
|
{\Large\itshape Supervised by \par
|
||||||
Prof. Dr. Christoph Lehner}
|
Dr. Christoph Lehner}
|
||||||
\vfill
|
\vfill
|
||||||
{\large 10.04.2020}
|
{\large 10.04.2020}
|
||||||
\end{titlepage}
|
\end{titlepage}
|
||||||
|
@ -82,34 +82,16 @@ Supervised by Prof. Dr. Christoph Lehner}
|
||||||
\include{chapters/appendix}
|
\include{chapters/appendix}
|
||||||
\end{appendices}
|
\end{appendices}
|
||||||
|
|
||||||
\newpage
|
|
||||||
\listoffigures
|
|
||||||
|
|
||||||
\bibliographystyle{unsrt}
|
\bibliographystyle{unsrt}
|
||||||
\bibliography{main}{}
|
\bibliography{main}{}
|
||||||
|
|
||||||
\newpage
|
|
||||||
{\Large\textbf{Acknowledgements}}
|
|
||||||
\\
|
|
||||||
\\
|
|
||||||
I want to thank Prof. Dr. Christoph Lehner for offering me the possibility to
|
|
||||||
write this thesis in his workgroup. He also found the time to answer my
|
|
||||||
questions and help me when I got stuck while keeping an inspiring atmosphere.\\
|
|
||||||
Further I own a big thank you to Simon Feyrer for proof-reading my thesis. \\
|
|
||||||
Also I want to thank Andreas Hackl for proof-reading my thesis and helping out
|
|
||||||
with several technical problems.\\
|
|
||||||
Thanks to Shirley Galbaw for helping to fix some of my terrible ingris grammar.
|
|
||||||
|
|
||||||
|
|
||||||
|
|
||||||
\newpage
|
\newpage
|
||||||
\textbf{Erklärung zur Anfertigung:}\\
|
\textbf{Erklärung zur Anfertigung:}\\
|
||||||
Ich habe die Arbeit selbständig verfasst, keine anderen als die angegebenen
|
Ich habe die Arbeit selbständig verfasst, keine anderen als die angegebenen Quellen und Hilfsmittel be-
|
||||||
Quellen und Hilfsmittel benutzt und bisher keiner anderen Prüfungsbehörde
|
nutzt und bisher keiner anderen Prüfungsbehörde vorgelegt. Außerdem bestätige ich hiermit, dass die
|
||||||
vorgelegt. Außerdem bestätige ich hiermit, dass die vorgelegten Druckexemplare
|
vorgelegten Druckexemplare und die vorgelegte elektronische Version der Arbeit identisch sind, dass ich
|
||||||
und die vorgelegte elektronische Version der Arbeit identisch sind, dass ich
|
über wissenschaftlich korrektes Arbeiten und Zitieren aufgeklärt wurde und dass ich von den in § 24 Abs.
|
||||||
über wissenschaftlich korrektes Arbeiten und Zitieren aufgeklärt wurde und dass
|
5 vorgesehenen Rechtsfolgen Kenntnis habe.
|
||||||
ich von den in § 24 Abs. 5 vorgesehenen Rechtsfolgen Kenntnis habe.
|
|
||||||
\\
|
\\
|
||||||
\\
|
\\
|
||||||
Unterschrift:
|
Unterschrift:
|
||||||
|
|