Exemplo n.º 1
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    def test_simulation_theory(self):
        reset_brian2()

        t = 1000 * ms
        dt = 0.01 * ms
        defaultclock.dt = dt

        pop = MFLinearPopulation(
            100, {
                PP.GM: 25. * nS,
                PP.CM: 0.5 * nF,
                PP.VL: -70. * mV,
                PP.VTHR: -50. * mV,
                PP.VRES: -55. * mV,
                PP.TAU_RP: 2. * ms
            })
        pop.rate = 1 * Hz

        noise = MFStaticInput(1000, 1 * Hz, pop, {
            IP.GM: 2 * nS,
            IP.VREV: 0 * volt,
            IP.TAU: 2. * ms,
        })

        rec = MFLinearInput(pop, pop, {
            IP.GM: 0.973 / 100 * nS,
            IP.VREV: -70 * volt,
            IP.TAU: 10. * ms,
        })

        system = MFSystem(pop)

        solver = MFSolver.rates_voltages(system, solver='mse', maxiter=1)
        sol = solver.run()
        theory = sol.state[0]

        rate = PopulationRateMonitor(pop.brian2)

        net = system.collect_brian2_network(rate)
        net.run(t)

        #brian2_introspect(net, globals())

        stable_t = int(t / dt * 0.1)
        isolated = np.array(rate.rate)[stable_t:-stable_t]
        print(isolated.mean())

        if False:
            plt.plot(rate.t / ms, rate.smooth_rate(width=25 * ms) / Hz)
            plt.plot(np.ones(10000) * isolated.mean(), label='simulation mean')
            plt.plot(np.ones(10000) * theory, label='theory mean')
            plt.ylabel('Population rate (Hz) per 100')
            plt.xlabel('Simulation time (ms)')
            plt.title('Poisson noise 5 Hz per 1000')
            plt.legend()
            plt.show()
Exemplo n.º 2
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    def test_model_gen_with_one_source(self):
        pop = MFLinearPopulation(1, params_pop)
        pop.add_input(
            MFInput(None,
                    pop,
                    params_source,
                    connection=Connection.all_to_all(),
                    name='test'))

        assert_equations(
            pop.brian2_model, '''
            I_test = (0. * siemens) * (v - (0. * volt)) * s_test : amp
            I = I_test : amp
            dv/dt = (- (25. * nsiemens) * (v - (-70. * mvolt)) - I) / (0.5 * nfarad) : volt
            ds_test/dt = - s_test / (10. * msecond) : 1
            ''')
Exemplo n.º 3
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    def test_model_gen_without_source(self):
        pop = MFLinearPopulation(1, params_pop)

        assert_equations(
            pop.brian2_model, '''
            I = 0 : amp
            dv/dt = (- (25. * nsiemens) * (v - (-70. * mvolt)) - I) / (0.5 * nfarad) : volt
            ''')
Exemplo n.º 4
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    def test_model_gen(self):
        reset_brian2()
        pop = MFLinearPopulation(1, params_pop)
        source = MFInput(None, pop, params_source, name='test')

        assert_equations(
            source.brian2_model, '''
            I_test = (0. * siemens) * (v - (0. * volt)) * s_test : amp
            ds_test / dt = -s_test / (10. * msecond) : 1
            ''')
Exemplo n.º 5
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def with_rate(rate):
    reset_brian2()

    pop = MFLinearPopulation(n_pop, {
        PP.GM: 25. * nS,
        PP.CM: 0.5 * nF,
        PP.VL: -70. * mV,
        PP.VTHR: -50. * mV,
        PP.VRES: -55. * mV,
        PP.TAU_RP: 2. * ms
    })
    pop.rate = 10 * Hz

    MFStaticInput(n_noise, rate * Hz, pop, {
        IP.GM: 2.08 * nS,
        IP.VREV: 0 * volt,
        IP.TAU: 1.5 * ms,
    })

    system = MFSystem(pop)

    rate = PopulationRateMonitor(pop.brian2)
    net = system.collect_brian2_network(rate)
    net.run(t)

    margin = round(0.5 * second / defaultclock.dt)
    stable = rate.smooth_rate(width=20 * ms)[margin:-margin]

    mean_simu = np.mean(stable)
    std_simu = np.reshape(stable, (samples, -1)).mean(axis=1).std() / np.sqrt(samples) * 1.96
    print(std_simu)

    solver = MFSolver.rates_voltages(system, solver='simplex', maxiter=1)
    sol = solver.run()
    mean_theo = sol.state[0]

    return [mean_theo, mean_simu, std_simu]
Exemplo n.º 6
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        def for_rate(rate):
            reset_brian2()

            pop = MFLinearPopulation(
                n_pop, {
                    PP.GM: 25. * nS,
                    PP.CM: 0.5 * nF,
                    PP.VL: -70. * mV,
                    PP.VTHR: -50. * mV,
                    PP.VRES: -55. * mV,
                    PP.TAU_RP: 2. * ms
                })
            pop.rate = 1 * Hz

            MFStaticInput(n_noise, rate * Hz, pop, {
                IP.GM: 2 * nS,
                IP.VREV: 0 * volt,
                IP.TAU: 2. * ms,
            })

            t = 500 * ms
            dt = 0.1 * ms

            system = MFSystem(pop)
            rate = PopulationRateMonitor(pop.brian2)
            net = system.collect_brian2_network(rate)
            net.run(t)
            stable_t = int(t / dt * 0.1)
            isolated = np.array(rate.rate)[stable_t:-stable_t]
            sim = np.mean(isolated)

            solver = MFSolver.rates_voltages(system,
                                             solver='simplex',
                                             maxiter=1)
            sol = solver.run()
            return [sol.state[0], sim]
Exemplo n.º 7
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        def for_rate(rate):
            pop = MFLinearPopulation(100, {
                PP.GM: 25. * nS,
                PP.CM: 0.5 * nF,
                PP.VL: -70. * mV,
                PP.VTHR: -50. * mV,
                PP.VRES: -55. * mV,
                PP.TAU_RP: 2. * ms
            })
            pop.rate = 10 * Hz

            noise = MFStaticInput(1000, rate * Hz, pop, {
                IP.GM: 2 * nS,
                IP.VREV: 0 * volt,
                IP.TAU: 2. * ms,
            })
            pop.add_noise(noise)

            system = MFSystem(pop)

            solver = MFSolver.rates_voltages(system, solver='mse', maxiter=1)
            print(solver.state)
            sol = solver.run()
            return sol.state[0]
Exemplo n.º 8
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    def test_simulation_theory(self):
        reset_brian2()

        t = 3000 * ms
        dt = 0.01 * ms
        n = 100

        poisson = MFPoissonPopulation(n, n * 10 * Hz)
        pop = MFLinearPopulation(
            n, {
                PP.GM: 10 * nsiemens,
                PP.VL: 0 * mV,
                PP.CM: 5 * nfarad,
                PP.VTHR: 0 * mV,
                PP.VRES: 0 * mV,
                PP.TAU_RP: 15 * ms
            })
        syn = MFLinearNMDAInput(
            poisson, pop, {
                IP.GM: 10 * nsiemens,
                IP.VREV: 0 * mV,
                IP.TAU: 20 * ms,
                IP.TAU_NMDA: 30 * ms,
                IP.BETA: 1,
                IP.GAMMA: 1,
            })

        system = MFSystem(pop, poisson)

        solver = MFSolver.rates_voltages(system, solver='mse')
        solver.run()
        theory = syn.g_dyn() / syn.origin.n

        m = StateMonitor(syn.brian2, syn.post_variable_name, record=range(100))
        defaultclock.dt = dt
        net = system.collect_brian2_network(m)
        net.run(t)

        stable_t = int(t / dt * 0.1)
        simulation = m.__getattr__(syn.post_variable_name)[:, stable_t:]
        simulation_mean = np.mean(simulation)
        print(simulation)

        assert np.isclose(theory, simulation_mean, rtol=0.5, atol=0.5)
Exemplo n.º 9
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    def test_simulation_theory(self):
        reset_brian2()

        t = 3000 * ms
        dt = 0.01 * ms
        n = 100

        alpha = 0.5

        poisson = MFPoissonPopulation(n, n * 10 * Hz)
        pop = MFLinearPopulation(
            n, {
                PP.GM: 10 * nsiemens,
                PP.VL: 0 * mV,
                PP.CM: 5 * nfarad,
                PP.VTHR: 0 * mV,
                PP.VRES: 0 * mV,
                PP.TAU_RP: 15 * ms
            })
        syn = MFLinear3TSInput(
            poisson, pop, {
                IP.GM: 10 * nsiemens,
                IP.VREV: 0 * mvolt,
                IP.TAU: 0 * ms,
                IP.TAU_RISE: 2 * ms,
                IP.TAU_D1: 20 * ms,
                IP.TAU_D2: 30 * ms,
                IP.ALPHA: alpha
            })

        system = MFSystem(pop, poisson)

        solver = MFSolver.rates_voltages(system, solver='mse')
        solver.run()
        theory = syn.g_dyn() / syn.origin.n

        print(syn.brian2)

        m1 = StateMonitor(syn.brian2,
                          syn.post_variable_name[0],
                          record=range(100))
        m2 = StateMonitor(syn.brian2,
                          syn.post_variable_name[1],
                          record=range(100))
        m3 = StateMonitor(syn.brian2,
                          syn.post_variable_name[2],
                          record=range(100))
        m4 = StateMonitor(syn.brian2,
                          syn.post_variable_name[3],
                          record=range(100))
        defaultclock.dt = dt

        net = system.collect_brian2_network(m1, m2, m3, m4)
        net.run(t)

        stable_t = int(t / dt * 0.1)
        simulation_1 = m1.__getattr__(syn.post_variable_name[0])[:, stable_t:]
        simulation_mean_1 = np.mean(simulation_1)
        simulation_2 = m2.__getattr__(syn.post_variable_name[1])[:, stable_t:]
        simulation_mean_2 = np.mean(simulation_2)
        simulation_3 = m3.__getattr__(syn.post_variable_name[2])[:, stable_t:]
        simulation_mean_3 = np.mean(simulation_3)
        simulation_4 = m4.__getattr__(syn.post_variable_name[3])[:, stable_t:]
        simulation_mean_4 = np.mean(simulation_4)

        simulation_mean = alpha * simulation_mean_1 + (
            1 - alpha) * simulation_mean_2 + -alpha * simulation_mean_3 - (
                1 - alpha) * simulation_mean_4

        assert np.isclose(theory, simulation_mean, rtol=0.5, atol=0.5)
Exemplo n.º 10
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N_sub = int(N_E * f)
N_non = int(N_E * (1. - f * p))
w_plus = 2.1
w_minus = 1. - f * (w_plus - 1.) / (1. - f)

# modeling
E_params = {
    PP.GM: g_m_E,
    PP.CM: C_m_E,
    PP.VL: V_L,
    PP.VTHR: V_thr,
    PP.VRES: V_reset,
    PP.TAU_RP: tau_rp_E
}

pop_e = MFLinearPopulation(N_non, E_params, name="E")
pop_e_sel = modelling.multiple_populations(p,
                                           MFLinearPopulation,
                                           N_sub,
                                           E_params,
                                           name="E sel")

#pop_e_el = MFLinearPopulation(N_sub, E_params, name="E sel")

I_params = {
    PP.GM: g_m_I,
    PP.CM: C_m_I,
    PP.VL: V_L,
    PP.VTHR: V_thr,
    PP.VRES: V_reset,
    PP.TAU_RP: tau_rp_I,
Exemplo n.º 11
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def one_subpopulation():

    # populations
    N = 250
    N_E = int(N * 0.8)  # pyramidal neurons
    N_I = int(N * 0.2)  # interneurons

    # voltage
    V_L = -70. * mV
    V_thr = -50. * mV
    V_reset = -55. * mV
    V_E = 0. * mV
    V_I = -70. * mV

    # membrane capacitance
    C_m_E = 0.5 * nF
    C_m_I = 0.2 * nF

    # membrane leak
    g_m_E = 25. * nS
    g_m_I = 20. * nS

    # refractory period
    tau_rp_E = 2. * ms
    tau_rp_I = 1. * ms

    # external stimuli
    rate = 3 * Hz
    C_ext = 800

    # AMPA (excitatory)
    g_AMPA_ext_E = 2.08 * nS
    g_AMPA_rec_E = 0.104 * nS * 800. / N_E
    g_AMPA_ext_I = 1.62 * nS
    g_AMPA_rec_I = 0.081 * nS * 800. / N_E
    tau_AMPA = 2. * ms

    # NMDA (excitatory)
    g_NMDA_E = 0.327 * nS * 800. / N_E
    g_NMDA_I = 0.258 * nS * 800. / N_E
    tau_NMDA_rise = 2. * ms
    tau_NMDA_decay = 100. * ms
    alpha = 0.5 / ms
    beta = 0.062
    gamma = 1. / 3.57
    Mg2 = 1.

    # GABAergic (inhibitory)
    g_GABA_E = 1.25 * nS * 200. / N_I
    g_GABA_I = 0.973 * nS * 200. / N_I
    tau_GABA = 10. * ms

    # subpopulations
    f = 0.1
    p = 1
    N_sub = int(N_E * f)
    N_non = int(N_E * (1. - f * p))
    w_plus = 2.1
    w_minus = 1. - f * (w_plus - 1.) / (1. - f)

    # modeling
    E_params = {
        PP.GM: g_m_E,
        PP.CM: C_m_E,
        PP.VL: V_L,
        PP.VTHR: V_thr,
        PP.VRES: V_reset,
        PP.TAU_RP: tau_rp_E
    }

    I_params = {
        PP.GM: g_m_I,
        PP.CM: C_m_I,
        PP.VL: V_L,
        PP.VTHR: V_thr,
        PP.VRES: V_reset,
        PP.TAU_RP: tau_rp_I,
    }

    pop_e1 = MFLinearPopulation(N_non, E_params, name="E")
    pop_e2 = MFLinearPopulation(N_sub, E_params, name="Edown")
    pop_i = MFLinearPopulation(N_I, I_params, name="I")

    # noise pops
    MFStaticInput(C_ext,
                  rate,
                  pop_e1, {
                      IP.GM: g_AMPA_ext_E,
                      IP.VREV: V_E,
                      IP.TAU: tau_AMPA,
                  },
                  name="E_noise1")

    MFStaticInput(C_ext,
                  rate,
                  pop_e2, {
                      IP.GM: g_AMPA_ext_E,
                      IP.VREV: V_E,
                      IP.TAU: tau_AMPA,
                  },
                  name="E_noise2")

    MFStaticInput(C_ext,
                  rate,
                  pop_i, {
                      IP.GM: g_AMPA_ext_I,
                      IP.VREV: V_E,
                      IP.TAU: tau_AMPA,
                  },
                  name="I_noise")

    # E->E NMDA
    ee_nmda = MFParameters({
        IP.GM: g_NMDA_E,
        IP.VREV: V_E,
        IP.TAU: tau_NMDA_decay,
        IP.TAU_NMDA_RISE: tau_NMDA_rise,
        IP.ALPHA: alpha,
        IP.BETA: beta,
        IP.GAMMA: gamma,
        IP.MG: Mg2,
    })

    MFNonLinearNMDAInput(pop_e1,
                         pop_e1,
                         ee_nmda + {IP.W: 1},
                         name='EE NMDA 1',
                         connection=Connection.all_to_others())

    MFNonLinearNMDAInput(pop_e1,
                         pop_e2,
                         ee_nmda + {IP.W: w_minus},
                         name='EE NMDA 2')

    MFNonLinearNMDAInput(pop_e2,
                         pop_e2,
                         ee_nmda + {IP.W: w_plus},
                         name='EE NMDA 3',
                         connection=Connection.all_to_others())

    MFNonLinearNMDAInput(pop_e2, pop_e1, ee_nmda + {IP.W: 1}, name='EE NMDA 4')

    # E->E AMPA
    ee_ampa = MFParameters({
        IP.GM: g_AMPA_rec_E,
        IP.VREV: V_E,
        IP.TAU: tau_AMPA,
    })

    MFLinearInput(pop_e1, pop_e1, ee_ampa + {IP.W: 1}, name='EE AMPA 1')

    MFLinearInput(pop_e1,
                  pop_e2,
                  ee_ampa + {IP.W: w_minus},
                  name='EE AMPA 2',
                  connection=Connection.all_to_others())

    MFLinearInput(pop_e2, pop_e1, ee_ampa + {IP.W: w_plus}, name='EE AMPA 3')

    MFLinearInput(pop_e2,
                  pop_e2,
                  ee_ampa + {IP.W: 1},
                  name='EE AMPA 4',
                  connection=Connection.all_to_others())

    # E->I NMDA
    ei_nmda = {
        IP.GM: g_NMDA_I,
        IP.VREV: V_E,
        IP.W: 1,
        IP.TAU: tau_NMDA_decay,
        IP.TAU_NMDA_RISE: tau_NMDA_rise,
        IP.ALPHA: alpha,
        IP.BETA: beta,
        IP.GAMMA: gamma,
        IP.MG: Mg2,
    }

    MFNonLinearNMDAInput(pop_e1, pop_i, ei_nmda, name='EI NMDA')

    MFNonLinearNMDAInput(pop_e2, pop_i, ei_nmda, name='EI NMDA 2')

    # E->I AMPA
    ei_ampa = {
        IP.GM: g_AMPA_rec_E,
        IP.VREV: V_E,
        IP.TAU: tau_AMPA,
    }

    MFLinearInput(pop_e1, pop_i, ei_ampa, name='EI AMPA')

    MFLinearInput(pop_e2, pop_i, ei_ampa, name='EI AMPA 2')

    # I->I GABA
    MFLinearInput(pop_i,
                  pop_i, {
                      IP.GM: g_GABA_I,
                      IP.VREV: V_I,
                      IP.TAU: tau_GABA,
                  },
                  name='II GABA',
                  connection=Connection.all_to_others())

    # I->E GABA
    ie_gaba = {
        IP.GM: g_GABA_E,
        IP.VREV: V_I,
        IP.TAU: tau_GABA,
    }

    MFLinearInput(pop_i, pop_e1, ie_gaba, name='IE GABA 1')

    MFLinearInput(pop_i, pop_e2, ie_gaba, name='IE GABA 2')

    return MFSystem(pop_e1, pop_e2, pop_i, name="Brunel Wang 2001")
Exemplo n.º 12
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def no_subpopulation():

    # brunel 1999 system, one up state pop
    initials = {'nu_e': 3 * Hz, 'nu_i': 9 * Hz}

    pop_e = MFLinearPopulation(800, {
        PP.GM: params_standard['E']['g_L'],
        PP.VL: params_standard['E']['V_L'],
        PP.CM: params_standard['E']['C_m'],
        PP.VTHR: params_standard['E']['V_th'],
        PP.VRES: params_standard['E']['V_reset'],
        PP.TAU_RP: params_standard['E']['t_ref']
    }, name='E')

    pop_i = MFLinearPopulation(200, {
        PP.GM: params_standard['I']['g_L'],
        PP.VL: params_standard['I']['V_L'],
        PP.CM: params_standard['I']['C_m'],
        PP.VTHR: params_standard['I']['V_th'],
        PP.VRES: params_standard['I']['V_reset'],
        PP.TAU_RP: params_standard['I']['t_ref']
    }, name='I')

    pop_e.rate = initials['nu_e']
    pop_e.v_mean = -51. * mV
    pop_i.rate = initials['nu_i']
    pop_i.v_mean = -55. * mV

    system = MFSystem(pop_e, pop_i, name='EI')

    # noise pops
    source_e_noise = MFStaticInput(params_standard['E']['Cext'], params_standard['E']['nu_ext'], pop_e, {
        IP.GM: params_standard['E']['gAMPA'],
        IP.VREV: params_standard['E']['VE'],
        IP.TAU: params_standard['E']['tau_AMPA'],
    }, name='E_noise')

    source_i_noise = MFStaticInput(params_standard['I']['Cext'], params_standard['I']['nu_ext'], pop_i, {
        IP.GM: params_standard['I']['gAMPA'],
        IP.VREV: params_standard['I']['VE'],
        IP.TAU: params_standard['I']['tau_AMPA'],
    }, name='I_noise')

    # E->E NMDA
    source_ee_nmda = MFLinearSTPNMDAInput(pop_e, pop_e, {
        IP.BETA: params_standard['E']['beta'],
        IP.GAMMA: params_standard['E']['gamma'],
        IP.GM: params_standard['E']['gNMDA'],
        IP.VREV: params_standard['E']['VE'],
        IP.TAU: params_standard['E']['tau_NMDA'],
        IP.W: 1,
        IP.TAU_F: 1000 * ms,
        IP.TAU_D: 150 * ms,
        IP.U: 1,
    }, name='EE Nmda')

    # E->I NMDA
    source_ie_nmda = MFLinearSTPNMDAInput(pop_e, pop_i, {
        IP.BETA: params_standard['I']['beta'],
        IP.GAMMA: params_standard['I']['gamma'],
        IP.GM: params_standard['I']['gNMDA'],
        IP.VREV: params_standard['I']['VE'],
        IP.TAU: params_standard['I']['tau_NMDA'],
        IP.W: 1,
        IP.TAU_F: 1000 * ms,
        IP.TAU_D: 150 * ms,
        IP.U: 1,
    }, name='IE Nmda')

    # I->I GABA

    source_ii_gaba = MFLinearInput(pop_i, pop_i, {
        IP.GM: params_standard['I']['gGABA'],
        IP.VREV:params_standard['I']['VI'],
        IP.TAU: params_standard['I']['tau_GABA'],
    }, name='II Gaba')

    # I->E GABA
    source_ei_gaba = MFLinearInput(pop_i, pop_e, {
        IP.GM: params_standard['E']['gGABA'],
        IP.VREV: params_standard['E']['VI'],
        IP.TAU: params_standard['E']['tau_GABA'],
    }, name='EI Gaba')

    return system
Exemplo n.º 13
0
def one_subpopulation(w_plus_val=2.5):

    # brunel 1999 system, one up state pop
    ff = .1
    w_plus = w_plus_val
    w_min = 1. - ff * (w_plus - 1.) / (1. - ff)
    initials = {'nu_plus': 25 * Hz, 'nu_min': 1.5 * Hz, 'nu_i': 9 * Hz}

    pop_e1 = MFLinearPopulation(800 * ff, {
        PP.GM: params_standard['E']['g_L'],
        PP.VL: params_standard['E']['V_L'],
        PP.CM: params_standard['E']['C_m'],
        PP.VTHR: params_standard['E']['V_th'],
        PP.VRES: params_standard['E']['V_reset'],
        PP.TAU_RP: params_standard['E']['t_ref']
    }, name='Eup')

    pop_e2 = MFLinearPopulation(800 * (1. - ff), {
        PP.GM: params_standard['E']['g_L'],
        PP.VL: params_standard['E']['V_L'],
        PP.CM: params_standard['E']['C_m'],
        PP.VTHR: params_standard['E']['V_th'],
        PP.VRES: params_standard['E']['V_reset'],
        PP.TAU_RP: params_standard['E']['t_ref']
    }, name='Edown')

    pop_i = MFLinearPopulation(200, {
        PP.GM: params_standard['I']['g_L'],
        PP.VL: params_standard['I']['V_L'],
        PP.CM: params_standard['I']['C_m'],
        PP.VTHR: params_standard['I']['V_th'],
        PP.VRES: params_standard['I']['V_reset'],
        PP.TAU_RP: params_standard['I']['t_ref']
    }, name='I')

    pop_e1.rate = initials['nu_plus']
    pop_e1.v_mean = -51. * mV
    pop_e2.rate = initials['nu_min']
    pop_e2.v_mean = -55. * mV
    pop_i.rate = initials['nu_i']
    pop_i.v_mean = -55. * mV

    system = MFSystem(pop_e1, pop_e2, pop_i, name='Brunel')

    # noise pops

    source_e_noise1 = MFStaticInput(params_standard['E']['Cext'], params_standard['E']['nu_ext'], pop_e1, {
        IP.GM: params_standard['E']['gAMPA'],
        IP.VREV: params_standard['E']['VE'],
        IP.TAU: params_standard['E']['tau_AMPA'],
    }, name='E_noise1')

    source_e_noise2 = MFStaticInput(params_standard['E']['Cext'], params_standard['E']['nu_ext'], pop_e2, {
        IP.GM: params_standard['E']['gAMPA'],
        IP.VREV: params_standard['E']['VE'],
        IP.TAU: params_standard['E']['tau_AMPA'],
    }, name='E_noise2')

    source_i_noise = MFStaticInput(params_standard['I']['Cext'], params_standard['I']['nu_ext'], pop_i, {
        IP.GM: params_standard['I']['gAMPA'],
        IP.VREV: params_standard['I']['VE'],
        IP.TAU: params_standard['I']['tau_AMPA'],
    }, name='I_noise')

    # E->E NMDA
    ee_nmda = MFParameters({
        IP.BETA: params_standard['E']['beta'],
        IP.GAMMA: params_standard['E']['gamma'],
        IP.GM: params_standard['E']['gNMDA'],
        IP.VREV: params_standard['E']['VE'],
        IP.TAU: params_standard['E']['tau_NMDA'],

        IP.TAU_F: 1000 * ms,
        IP.TAU_D: 150 * ms,
        IP.U: 1,
    })

    source_ee_nmda1 = MFLinearSTPNMDAInput(pop_e1, pop_e1, ee_nmda + {
        IP.W: w_plus
    }, name='EE Nmda1')

    source_ee_nmda12 = MFLinearSTPNMDAInput(pop_e2, pop_e1, ee_nmda + {
        IP.W: w_min
    }, name='EE Nmda12')

    source_ee_nmda2 = MFLinearSTPNMDAInput(pop_e1, pop_e2, ee_nmda + {
        IP.W: w_min
    }, name='EE Nmda2')

    source_ee_nmda22 = MFLinearSTPNMDAInput(pop_e2, pop_e2, ee_nmda + {
        IP.W: (w_plus * ff + (1. - 2. * ff) * w_min) / (1 - ff)
    }, name='EE Nmda22')

    # E->I NMDA
    ei_nmda = {
        IP.BETA: params_standard['I']['beta'],
        IP.GAMMA: params_standard['I']['gamma'],
        IP.GM: params_standard['I']['gNMDA'],
        IP.VREV: params_standard['I']['VE'],
        IP.TAU: params_standard['I']['tau_NMDA'],
        IP.W: 1,
        IP.TAU_F: 1000 * ms,
        IP.TAU_D: 150 * ms,
        IP.U: 1,
    }

    source_ie_nmda = MFLinearSTPNMDAInput(pop_e1, pop_i, ei_nmda, name='IE Nmda')

    source_ie_nmda2 = MFLinearSTPNMDAInput(pop_e2, pop_i, ei_nmda, name='IE Nmda2')

    # I->I GABA

    source_ii_gaba = MFLinearInput(pop_i, pop_i, {
        IP.GM: params_standard['I']['gGABA'],
        IP.VREV: params_standard['I']['VI'],
        IP.TAU: params_standard['I']['tau_GABA'],
    }, name='II Gaba')

    # I->E GABA

    source_ei_gaba1 = MFLinearInput(pop_i, pop_e1, {
        IP.GM: params_standard['E']['gGABA'],
        IP.VREV: params_standard['E']['VI'],
        IP.TAU: params_standard['E']['tau_GABA'],
    }, name='EI Gaba')

    source_ei_gaba2 = MFLinearInput(pop_i, pop_e2, {
        IP.GM: params_standard['E']['gGABA'],
        IP.VREV: params_standard['E']['VI'],
        IP.TAU: params_standard['E']['tau_GABA'],
    }, name='EI Gaba2')

    return system