Exemple #1
0
def observe(total, cmdargs):
    if total < 3:
        print(" ".join(str(x) for x in cmdargs))
        raise ValueError('Missing arguments')
    inputname = cmdargs[1]
    observname = cmdargs[2]
    outputname = "dataObserve.hdf5"
    if total == 4:
        outputname = cmdargs[3]
    # ---------------------------------------------------------------

    para = Parameter(inputname)
    Lat = Lattice(para)
    ob = Observ(Lat)
    print(Lat.Model)
    dof = Dofs("SpinHalf")  # default spin-1/2
    if Lat.Model == "AKLT":
        dof = Dofs("SpinOne")

    # ------- Read dataSpec file -------
    rfile = h5py.File('dataSpec.hdf5', 'r')
    evalset = rfile["3.Eigen"]["Eigen Values"]
    evecset = rfile["3.Eigen"]["Wavefunctions"]

    # extract eigen value and eigen vector from HDF5 rfile
    print(dof.hilbsize ** Lat.Nsite)
    evals = np.zeros(para.Nstates, dtype=float)
    evecs = np.zeros((dof.hilbsize ** Lat.Nsite, para.Nstates), dtype=complex)
    evalset.read_direct(evals)
    evecset.read_direct(evecs)

    rfile.close()

    # ------- Calculate spin response S(\omega) & write to HDF5---------
    if observname == "spin_response":
        print("Calculating S(omega)...")
        tic = time.perf_counter()
        SpinRes = ob.SpRe(evals, evecs, dof.type)
        toc = time.perf_counter()
        print(f"time = {toc-tic:0.4f} sec")

        wfile = h5py.File(outputname, 'a')
        if "Spin Response" in list(wfile.keys()):
            wfile.__delitem__("Spin Response")  # over write if existed
        wfile.create_dataset("Spin Response", data=SpinRes)
        wfile["Spin Response"].attrs["time"] = toc - tic

        wfile.close()
    # ------- Calculate spin conductivity & write to HDF5---------
    elif observname == "spin_cond":
        pass
    # ------- Calculate energy conductivity & write to HDF5---------
    elif observname == "energy_cond":
        pass
    # ------- Calculate Single-Magnon DOS & write to HDF5---------
    elif observname == "singlemagnon":
        print("Calculating Single-Magnon DOS...")
        tic = time.perf_counter()
        SMag = ob.SingleMagnon(evals, evecs, dof.type)
        toc = time.perf_counter()
        print(f"time = {toc-tic:0.4f} sec")

        wfile = h5py.File(outputname, 'a')
        if "Single-Magnon DOS" in list(wfile.keys()):
            wfile.__delitem__("Single-Magnon DOS")  # over write if existed
        wfile.create_dataset("Single-Magnon DOS", data=SMag)
        wfile["Single-Magnon DOS"].attrs["time"] = toc - tic

        wfile.close()

    # ------- Calculate SzSz DOS & write to HDF5---------
    elif observname == "szsz":
        print("Calculating SzSz spectrum...")
        tic = time.perf_counter()
        SZSZ = ob.SzSz(evals, evecs, dof.type)
        toc = time.perf_counter()
        print(f"time = {toc-tic:0.4f} sec")

        wfile = h5py.File(outputname, 'a')
        if "SzSz" in list(wfile.keys()):
            wfile.__delitem__("SzSz")  # over write if existed
        wfile.create_dataset("SzSz", data=SZSZ)
        wfile["SzSz"].attrs["time"] = toc - tic

        wfile.close()

        # ------- Calculate SpSm DOS & write to HDF5---------
    elif observname == "spsm":
        print("Calculating SpSm spectrum...")
        tic = time.perf_counter()
        SPSM = ob.SpSm(evals, evecs, dof.type)
        toc = time.perf_counter()
        print(f"time = {toc - tic:0.4f} sec")

        wfile = h5py.File(outputname, 'a')
        if "SpSm" in list(wfile.keys()):
            wfile.__delitem__("SpSm")  # over write if existed
        wfile.create_dataset("SpSm", data=SPSM)
        wfile["SpSm"].attrs["time"] = toc - tic

        wfile.close()
        # ------- Calculate energy current of TFIM & write to HDF5---------
    elif observname == "ecurrent1":
        site = 2
        if para.Model != "TFIM":
            raise ValueError("ecurrent1 is designed for TFIM exclusively")
        print("Calculating energy current of TFIM...")
        tic = time.perf_counter()
        mEcurr = ob.ecurrent1(evals, evecs, site)
        toc = time.perf_counter()
        print(f"time = {toc - tic:0.4f} sec")
        print("Current at site=", site, "is ", mEcurr)

    else:
        raise ValueError("Observable not supported yet")
Exemple #2
0
        2000: (2.5312e3, 0.284779, None),
        2300: (2.5312e3, 0.284779, None),
        2600: (2.5312e3, 0.284779, None),
    }

    param.z3 = MultiFreqImpType()
    param.z3.rlc_s = {
        1700: (0.1, 4.2e-3, None),
        2000: (0.1, 4.2e-3, None),
        2300: (0.1, 4.2e-3, None),
        2600: (0.1, 4.2e-3, None),
    }

    param.zc = MultiFreqImpType()
    param.zc.rlc_s = {
        1700: (None, None, 2.35e-3),
        2000: (None, None, 2.35e-3),
        2300: (None, None, 2.35e-3),
        2600: (None, None, 2.35e-3),
    }

    param.n = {
        1700: 13.5,
        2000: 13.5,
        2300: 12,
        2600: 12,
    }

    Parameter.param_dict_to_pkl(param_dict)
    pass
Exemple #3
0
def main(total, cmdargs):
    if total != 2:
        print(" ".join(str(x) for x in cmdargs))
        raise ValueError('Missing arguments')
    inputname = cmdargs[1]
    sys.stdout = Logger()  # for exporting the logfile

    # ----------------------- Build and Diagonalize ---------------------------------
    para = Parameter(inputname)  # import parameters from input.inp
    Lat = Lattice(para)  # Build lattice
    ob = Observ(Lat)  # initialize observables
    tic = time.perf_counter()
    Hamil = Hamiltonian(Lat)  # Build Hamiltonian
    ham = Hamil.Ham  # Hamiltonian as sparse matrix
    toc = time.perf_counter()
    print(f"Hamiltonian construction time = {toc - tic:0.4f} sec")

    tic = time.perf_counter()
    evals, evecs = primme.eigsh(ham, para.Nstates, tol=1e-12, which='SA')
    evals, evecs = sort(evals, evecs)
    toc = time.perf_counter()

    evals = np.round(evals, 10)
    print("\n-----------Beg of Eigen Values-----------\n", *evals, sep='\n')
    print("\n-----------End of Eigen Values-----------")
    print(f"Diagonalization time = {toc - tic:0.4f} sec \n\n")

    # -------------- Entanglement properties of GS -----------
    if para.Option is not None:
        if "EE" in para.Option:
            EntS, Entvec = ob.EntSpec(
                evecs[:, 0])  # Entanglement spectrum and vector
            EntS = np.round(EntS, decimals=10)
            EntS_log = np.zeros(len(EntS))
            for i in range(len(EntS)):
                if EntS[i] <= 0:
                    EntS_log[i] = 0
                else:
                    EntS_log[i] = math.log(EntS[i])
            EE = -np.around(np.dot(EntS, EntS_log), decimals=8)
            print("Entanglement Spectrum=\n", EntS)
            print("Entanglement Entropy=", EE)

        # ------------------------ Ascii Ostream for EE--------
        file = open("entspec.dat", "w")
        # For a U-scan of Bose-Hubbard model
        if para.Model == "Bose_Hubbard":
            for i in range(EntS.size):
                file.write(str(abs(para.U)) + " " + str(EntS[i]))
                file.write("\n")
        else:
            for i in range(EntS.size):
                file.write(str(abs(para.Hx)) + " " + str(EntS[i]))
                file.write("\n")

    # ------------------------ Hdf5 Ostream (Big Data Storage) ------------------------------
    # ------------------------ Hdf5 Ostream (Big Data Storage) ------------------------------
    # ------------------------ Hdf5 Ostream (Big Data Storage) ------------------------------
    tic = time.perf_counter()
    file = h5py.File('dataSpec.hdf5', 'w')
    file.attrs["LLX"] = para.LLX
    file.attrs["LLY"] = para.LLY
    file.attrs["IsPeriodicX"] = para.IsPeriodicX
    file.attrs["IsPeriodicY"] = para.IsPeriodicY
    file.attrs["Kx"] = para.Kxx
    file.attrs["Ky"] = para.Kyy
    file.attrs["Kz"] = para.Kzz
    file.attrs["Hx"] = para.Hz
    file.attrs["Hy"] = para.Hy
    file.attrs["Hz"] = para.Hz
    file.attrs["#States2Keep"] = para.Nstates
    file.attrs["Model"] = para.Model
    file.attrs["Nsites"] = Lat.Nsite

    LatGrp = file.create_group("1.Lattice")
    LatGrp.create_dataset("Mesh", data=Lat.mesh_)
    LatGrp.create_dataset("Nearest Neighbors", data=Lat.nn_)

    ConnGrp = file.create_group("2.Connectors")
    if para.Model == "Heisenberg_Square" or para.Model == "Kitaev":
        ConnGrp.create_dataset("KxxGraph", data=Hamil.KxxGraph_)
        ConnGrp.create_dataset("KyyGraph", data=Hamil.KyyGraph_)
        ConnGrp.create_dataset("KzzGraph", data=Hamil.KzzGraph_)

    elif para.Model == "AKLT":
        ConnGrp.create_dataset("Kxx1Graph", data=Hamil.Kxx1Graph_)
        ConnGrp.create_dataset("Kyy1Graph", data=Hamil.Kyy1Graph_)
        ConnGrp.create_dataset("Kzz1Graph", data=Hamil.Kzz1Graph_)
        ConnGrp.create_dataset("Kxx2Graph", data=Hamil.Kxx2Graph_)
        ConnGrp.create_dataset("Kyy2Graph", data=Hamil.Kyy2Graph_)
        ConnGrp.create_dataset("Kzz2Graph", data=Hamil.Kzz2Graph_)
    elif para.Model == "Bose_Hubbard":
        ConnGrp.create_dataset("tGraph", data=Hamil.tGraph_)

    EigGrp = file.create_group("3.Eigen")
    EigGrp.create_dataset("Eigen Values", data=evals)
    EigGrp.create_dataset("Wavefunctions", data=evecs)

    if para.Option is not None:
        if "EE" in para.Option:
            EigGrp = file.create_group("4.Entanglment")
            EigGrp.create_dataset("ES", data=EntS)
            EigGrp.create_dataset("ESlog", data=EntS_log)
            EigGrp.create_dataset("EE", data=EE)

    file.close()
    toc = time.perf_counter()
    print(f"\nHDF5 time = {toc - tic:0.4f} sec")