def test_simple_operators(): L = 4 g = nk.graph.Hypercube(L, 1) hi = nk.hilbert.Spin(g, 0.5) sx = [[0, 1], [1, 0]] sy = [[0, -1.0j], [1.0j, 0]] sz = [[1, 0], [0, -1]] sm = [[0, 0], [1, 0]] sp = [[0, 1], [0, 0]] print("Testing Sigma_x/y/z...") for i in range(L): sx_hat = nk.operator.LocalOperator(hi, sx, [i]) sy_hat = nk.operator.LocalOperator(hi, sy, [i]) sz_hat = nk.operator.LocalOperator(hi, sz, [i]) assert (sigmax(hi, i).to_dense() == sx_hat.to_dense()).all() assert (sigmay(hi, i).to_dense() == sy_hat.to_dense()).all() assert (sigmaz(hi, i).to_dense() == sz_hat.to_dense()).all() print("Testing Sigma_+/-...") for i in range(L): sm_hat = nk.operator.LocalOperator(hi, sm, [i]) sp_hat = nk.operator.LocalOperator(hi, sp, [i]) assert (sigmam(hi, i).to_dense() == sm_hat.to_dense()).all() assert (sigmap(hi, i).to_dense() == sp_hat.to_dense()).all() print("Testing Sigma_+/- composition...") hi = nk.hilbert.Spin(g, 0.5) for i in range(L): sx = sigmax(hi, i) sy = sigmay(hi, i) sigmam_hat = 0.5 * (sx + (-1j) * sy) sigmap_hat = 0.5 * (sx + (1j) * sy) assert (sigmam(hi, i).to_dense() == sigmam_hat.to_dense()).all() assert (sigmap(hi, i).to_dense() == sigmap_hat.to_dense()).all() print("Testing create/destroy composition...") hi = nk.hilbert.Boson(g, 3) for i in range(L): a = bdestroy(hi, i) ad = bcreate(hi, i) n = bnumber(hi, i) assert np.allclose(n.to_dense(), (ad * a).to_dense()) assert (ad.to_dense() == a.conjugate().transpose().to_dense()).all()
def test_pauli_algebra(S): hi = nk.hilbert.Spin(S)**N for i in range(N): sx = spin.sigmax(hi, i) sy = spin.sigmay(hi, i) sz = spin.sigmaz(hi, i) sm = spin.sigmam(hi, i) sp = spin.sigmap(hi, i) assert_almost_equal(0.5 * (sx - 1j * sy).to_dense(), sm.to_dense()) assert_almost_equal(0.5 * (sx + 1j * sy).to_dense(), sp.to_dense()) assert_almost_equal(0.5 * (sx.to_dense() - 1j * sy.to_dense()), sm.to_dense()) assert_almost_equal(0.5 * (sx.to_dense() + 1j * sy.to_dense()), sp.to_dense()) if S == 1 / 2: Imat = np.eye(hi.n_states) # check that -i sx sy sz = I assert_almost_equal((-1j * sx @ sy @ sz).to_dense(), Imat) assert_almost_equal( (-1j * sx.to_dense() @ sy.to_dense() @ sz.to_dense()), Imat)
def test_simple_operators(): L = 4 hi = nk.hilbert.Spin(0.5) ** L sx = [[0, 1], [1, 0]] sy = [[0, -1.0j], [1.0j, 0]] sz = [[1, 0], [0, -1]] sm = [[0, 0], [1, 0]] sp = [[0, 1], [0, 0]] print("Testing Sigma_x/y/z...") for i in range(L): sx_hat = nk.operator.LocalOperator(hi, sx, [i]) sy_hat = nk.operator.LocalOperator(hi, sy, [i]) sz_hat = nk.operator.LocalOperator(hi, sz, [i]) assert (sigmax(hi, i).to_dense() == sx_hat.to_dense()).all() assert (sigmay(hi, i).to_dense() == sy_hat.to_dense()).all() assert (sigmaz(hi, i).to_dense() == sz_hat.to_dense()).all() print("Testing Sigma_+/-...") for i in range(L): sm_hat = nk.operator.LocalOperator(hi, sm, [i]) sp_hat = nk.operator.LocalOperator(hi, sp, [i]) assert (sigmam(hi, i).to_dense() == sm_hat.to_dense()).all() assert (sigmap(hi, i).to_dense() == sp_hat.to_dense()).all() print("Testing Sigma_+/- composition...") hi = nk.hilbert.Spin(0.5, N=L) for i in range(L): sx = sigmax(hi, i) sy = sigmay(hi, i) sigmam_hat = 0.5 * (sx + (-1j) * sy) sigmap_hat = 0.5 * (sx + (1j) * sy) assert (sigmam(hi, i).to_dense() == sigmam_hat.to_dense()).all() assert (sigmap(hi, i).to_dense() == sigmap_hat.to_dense()).all() print("Testing create/destroy composition...") hi = nk.hilbert.Fock(3, N=L) for i in range(L): print("i=", i) a = bdestroy(hi, i) ad = bcreate(hi, i) n = bnumber(hi, i) assert np.allclose(n.to_dense(), (ad @ a).to_dense()) assert (ad.to_dense() == a.conjugate().transpose().to_dense()).all() print("Testing mixed spaces...") L = 3 his = nk.hilbert.Spin(0.5, N=L) hib = nk.hilbert.Fock(3, N=L - 1) hi = his * hib for i in range(hi.size): print("i=", i) sx = sigmax(hi, i) assert sx.operators[0].shape == (hi.shape[i], hi.shape[i]) assert np.allclose(n.to_dense(), (ad @ a).to_dense()) assert (ad.to_dense() == a.conjugate().transpose().to_dense()).all() for i in range(3): print("i=", i) a = bdestroy(hi, i) ad = bcreate(hi, i) n = bnumber(hi, i) for j in range(3, 5): print("j=", i) a = bdestroy(hi, j) ad = bcreate(hi, j) n = bnumber(hi, j) assert np.allclose(n.to_dense(), (ad @ a).to_dense()) assert (ad.to_dense() == a.conjugate().transpose().to_dense()).all()