Python BirthDeathChain Examples

Programming Language: Python

Namespace/Package Name: pyemma.msm.tests.birth_death_chain

Class/Type: BirthDeathChain

Examples at hotexamples.com: 3

Python BirthDeathChain - 3 examples found. These are the top rated real world Python examples of pyemma.msm.tests.birth_death_chain.BirthDeathChain extracted from open source projects. You can rate examples to help us improve the quality of examples.

Frequently Used Methods

Show Hide

BirthDeathChain(3)

transition_matrix(3)

Example #1

Show file

    def setUp(self):
        """Store state of the rng"""
        self.state = np.random.mtrand.get_state()
        """Reseed the rng to enforce 'deterministic' behavior"""
        np.random.mtrand.seed(0xDEADBEEF)
        """Meta-stable birth-death chain"""
        b = 2
        q = np.zeros(7)
        p = np.zeros(7)
        q[1:] = 0.5
        p[0:-1] = 0.5
        q[2] = 1.0 - 10**(-b)
        q[4] = 10**(-b)
        p[2] = 10**(-b)
        p[4] = 1.0 - 10**(-b)

        bdc = BirthDeathChain(q, p)
        P = bdc.transition_matrix()
        self.dtraj = generate_traj(P, 10000, start=0)
        self.tau = 1

        self.k = 3
        """ Predictions and experimental data """
        self.E = np.vstack((np.linspace(-0.1, 1.,
                                        7), np.linspace(1.5, -0.1, 7))).T
        self.m = np.array([0.0, 0.0])
        self.w = np.array([2.0, 2.5])
        self.sigmas = 1. / np.sqrt(2) / np.sqrt(self.w)
        """ Feature trajectory """
        self.ftraj = self.E[self.dtraj, :]

        self.AMM = AugmentedMarkovModel(E=self.E, m=self.m, w=self.w)
        self.AMM.estimate([self.dtraj])

Example #2

Show file

File: test_msm.py Project: mejk/PyEMMA

    def setUp(self):
        """Store state of the rng"""
        self.state = np.random.mtrand.get_state()
        """Reseed the rng to enforce 'deterministic' behavior"""
        np.random.mtrand.seed(42)
        """Meta-stable birth-death chain"""
        b = 2
        q = np.zeros(7)
        p = np.zeros(7)
        q[1:] = 0.5
        p[0:-1] = 0.5
        q[2] = 1.0 - 10**(-b)
        q[4] = 10**(-b)
        p[2] = 10**(-b)
        p[4] = 1.0 - 10**(-b)

        bdc = BirthDeathChain(q, p)
        P = bdc.transition_matrix()
        self.dtraj = generate_traj(P, 10000, start=0)
        self.tau = 1
        """Estimate MSM"""
        self.C_MSM = count_matrix(self.dtraj, self.tau, sliding=True)
        self.lcc_MSM = largest_connected_set(self.C_MSM)
        self.Ccc_MSM = largest_connected_submatrix(self.C_MSM,
                                                   lcc=self.lcc_MSM)
        self.P_MSM = transition_matrix(self.Ccc_MSM, reversible=True)
        self.mu_MSM = stationary_distribution(self.P_MSM)
        self.k = 3
        self.ts = timescales(self.P_MSM, k=self.k, tau=self.tau)

Example #3

Show file

File: test_cktest.py Project: sowmya-debug/PyEMMA

    def setUp(self):
        """Store state of the rng"""
        self.state = np.random.mtrand.get_state()

        """Reseed the rng to enforce 'deterministic' behavior"""
        np.random.mtrand.seed(42)

        """Meta-stable birth-death chain"""
        b = 2
        q = np.zeros(7)
        p = np.zeros(7)
        q[1:] = 0.5
        p[0:-1] = 0.5
        q[2] = 1.0 - 10 ** (-b)
        q[4] = 10 ** (-b)
        p[2] = 10 ** (-b)
        p[4] = 1.0 - 10 ** (-b)

        bdc = BirthDeathChain(q, p)
        P = bdc.transition_matrix()
        dtraj = generate_traj(P, 10000, start=0)
        tau = 1

        """Estimate MSM"""
        MSM = estimate_markov_model(dtraj, tau)
        C_MSM = MSM.count_matrix_full
        lcc_MSM = MSM.largest_connected_set
        Ccc_MSM = MSM.count_matrix_active
        P_MSM = MSM.transition_matrix
        mu_MSM = MSM.stationary_distribution

        """Meta-stable sets"""
        A = [0, 1, 2]
        B = [4, 5, 6]

        w_MSM = np.zeros((2, mu_MSM.shape[0]))
        w_MSM[0, A] = mu_MSM[A] / mu_MSM[A].sum()
        w_MSM[1, B] = mu_MSM[B] / mu_MSM[B].sum()

        K = 10
        P_MSM_dense = P_MSM

        p_MSM = np.zeros((K, 2))
        w_MSM_k = 1.0 * w_MSM
        for k in range(1, K):
            w_MSM_k = np.dot(w_MSM_k, P_MSM_dense)
            p_MSM[k, 0] = w_MSM_k[0, A].sum()
            p_MSM[k, 1] = w_MSM_k[1, B].sum()

        """Assume that sets are equal, A(\tau)=A(k \tau) for all k"""
        w_MD = 1.0 * w_MSM
        p_MD = np.zeros((K, 2))
        eps_MD = np.zeros((K, 2))
        p_MSM[0, :] = 1.0
        p_MD[0, :] = 1.0
        eps_MD[0, :] = 0.0
        for k in range(1, K):
            """Build MSM at lagtime k*tau"""
            C_MD = count_matrix(dtraj, k * tau, sliding=True) / (k * tau)
            lcc_MD = largest_connected_set(C_MD)
            Ccc_MD = largest_connected_submatrix(C_MD, lcc=lcc_MD)
            c_MD = Ccc_MD.sum(axis=1)
            P_MD = transition_matrix(Ccc_MD).toarray()
            w_MD_k = np.dot(w_MD, P_MD)

            """Set A"""
            prob_MD = w_MD_k[0, A].sum()
            c = c_MD[A].sum()
            p_MD[k, 0] = prob_MD
            eps_MD[k, 0] = np.sqrt(k * (prob_MD - prob_MD ** 2) / c)

            """Set B"""
            prob_MD = w_MD_k[1, B].sum()
            c = c_MD[B].sum()
            p_MD[k, 1] = prob_MD
            eps_MD[k, 1] = np.sqrt(k * (prob_MD - prob_MD ** 2) / c)

        """Input"""
        self.MSM = MSM
        self.K = K
        self.A = A
        self.B = B

        """Expected results"""
        self.p_MSM = p_MSM
        self.p_MD = p_MD
        self.eps_MD = eps_MD