cjayb · June 14, 2021 04:06 · jasmainak · Jun 14, 2021
diff --git a/demo_evoked_lfp.py b/demo_evoked_lfp.py
 """
 ===================================
 08. Record extracellular potentials
 ===================================

 The main output of HNN simulations is the 'dipole' waveform, i.e., the net
 intracellular current flowing in pyramidal cell apical dendrites. At the large
 distances between cells and M/EEG sensors, this 'primary' current is the main
 contributor to the measured fields. Close to the cells, the local field
 potential (LFP) is the result of intracellular current leaking into the
 extracellular medium through active and passive membrane channels. Under some
 simplifying assumptions, we may approximate the LFP at virtual electrodes
 placed in and around the HNN network model.
 """

 # Authors: Nick Tolley <[email protected]>
 #          Mainak Jas <[email protected]>
 #          Christopher Bailey <[email protected]>

 # sphinx_gallery_thumbnail_number = 3

 import os.path as op
 import matplotlib.pyplot as plt

 ###############################################################################
 # We will use the default network with three evoked drives; see
 # :ref:`evoked example <sphx_glr_auto_examples_plot_simulate_evoked.py>` for
 # details. We'll go ahead and use the drive features defined in the parameter
 # file.

 import hnn_core
 from hnn_core import read_params, default_network, simulate_dipole

 hnn_core_root = op.dirname(hnn_core.__file__)
 params_fname = op.join(hnn_core_root, 'param', 'default.json')
 params = read_params(params_fname)
 net = default_network(params, add_drives_from_params=True)

 ###############################################################################
 # Extracellular recordings require specifying the electrode postions. It can be
 # useful to visualize the cells of the network to decide on the placement of
 # each electrode.
 net.plot_cells()

 ###############################################################################
 # The default network consists of an L5 and an L2 layer, within which the cell
 # somas are arranged in a regular grid, and apical dendrites are aligned along
 # the z-axis. We can simulate a linear array multielectrode with 100 um
 # intercontact spacing [1]_ by specifying a list of (x, y, z) coordinate
 # triplets. The L5 pyramidal cell somas are at z=0 um, with apical dendrites
 # extending up to approximately z=2000 um. L2 pyramidal cell somas reside at
 # z=1300 um, and have apical dendrites extending to z=2300 um. We'll place the
 # recording array in the center of the network. By default, a value of
 # 0.3 S/m is used for the constant extracellular conductivity. We'll use the
 # point source approximation method for calculations.

 depths = list(range(-525, 2750, 100))
 electrode_pos = [(4.5, 4.5, dep) for dep in depths]
 sigma, method, min_distance = 0.3, 'psa', 0.5
 net.add_electrode_array('shank1', electrode_pos, sigma=sigma,
                        method=method)

 ###############################################################################
 # The electrode arrays are stored under ``Network.rec_array`` as a dictionary
 # of :class:`~hnn_core.extracellular.ElectrodeArray` objects that are now
 # attached to the network and will be recorded during the simulation. Note that
 # calculating the extracellular potentials requires additional computational
 # resources and will thus slightly slow down the simulation.
 # :ref:`Using MPI <sphx_glr_auto_examples_plot_simulate_mpi_backend.py>` will
 # speed up computation considerably. Note that we will perform smoothing of the
 # dipole time series during plotting (``postproc=False``)
 print(net.rec_array)
 net.plot_cells()

 dpl = simulate_dipole(net, postproc=False)

 ###############################################################################
 # For plotting both agregate dipole moment and LFP traces, we'll use a 10 ms
 # smoothing window, after which both data can be decimated by a factor of 20
 # from 40 to 2 kHz sampling rates. Note that decimation is applied in two
 # steps.
 trial_idx = 0
 window_len = 10  # ms
 decimate = [5, 4]  # from 40k to 8k to 2k
 fig, axs = plt.subplots(3, 1, sharex=True, figsize=(8, 10),
                        gridspec_kw={'height_ratios': [1, 3, 1]})

 # First plot the external drive statistics driving the network
 net.cell_response.plot_spikes_hist(ax=axs[0], show=False)
 axs[0].set_title('External drive spike event histograms')

 # Then plot the aggregate dipole time series on its own axis
 dpl_ax = axs[1].twinx()
 dpl_color = (0.6, 0., 0.6)

 dpl[trial_idx].copy().smooth(
    window_len=window_len).plot(ax=dpl_ax, decim=decimate,
                                color=dpl_color, show=False)
 dpl_ax.yaxis.label.set_color(dpl_color)
 dpl_ax.set_title('Aggregate dipole moment overlaid on laminar LFP traces')

 voltage_offset = 300  # the spacing between individual traces
 voltage_scalebar = 500  # can be different from offset
 # we can assign each electrode a unique color using a linear colormap
 colors = plt.get_cmap('cividis', len(electrode_pos))
 net.rec_array['shank1'][trial_idx].plot(ax=axs[1],
                                        voltage_offset=voltage_offset,
                                        voltage_scalebar=voltage_scalebar,
                                        contact_labels=depths,
                                        color=colors,
                                        window_len=window_len,
                                        decim=decimate, show=False)
 axs[1].grid(True, which='major', axis='x')
 axs[1].set_xlabel('')
 # Finally, add the spike raster to the bottom subplot
 net.cell_response.plot_spikes_raster(ax=axs[2], show=False)
 axs[2].set_title('Network spiking responses')
 plt.show()

 ###############################################################################
 # The strong fluctuations seen in the dipole waveform appear to correlate with
 # similarly large amplitude LFP signals close to the L5 pyramidal soma layer.
 #
 # References
 # ----------
 # .. [1] Kajikawa, Y. & Schroeder, C. E. How local is the local field
 #        potential? Neuron 72, 847–858 (2011).
	"""
	===================================
	08. Record extracellular potentials
	===================================

	The main output of HNN simulations is the 'dipole' waveform, i.e., the net
	intracellular current flowing in pyramidal cell apical dendrites. At the large
	distances between cells and M/EEG sensors, this 'primary' current is the main
	contributor to the measured fields. Close to the cells, the local field
	potential (LFP) is the result of intracellular current leaking into the
	extracellular medium through active and passive membrane channels. Under some
	simplifying assumptions, we may approximate the LFP at virtual electrodes
	placed in and around the HNN network model.
	"""

	# Authors: Nick Tolley <[email protected]>
	# Mainak Jas <[email protected]>
	# Christopher Bailey <[email protected]>

	# sphinx_gallery_thumbnail_number = 3

	import os.path as op
	import matplotlib.pyplot as plt

	###############################################################################
	# We will use the default network with three evoked drives; see
	# :ref:`evoked example <sphx_glr_auto_examples_plot_simulate_evoked.py>` for
	# details. We'll go ahead and use the drive features defined in the parameter
	# file.

	import hnn_core
	from hnn_core import read_params, default_network, simulate_dipole

	hnn_core_root = op.dirname(hnn_core.__file__)
	params_fname = op.join(hnn_core_root, 'param', 'default.json')
	params = read_params(params_fname)
	net = default_network(params, add_drives_from_params=True)

	###############################################################################
	# Extracellular recordings require specifying the electrode postions. It can be
	# useful to visualize the cells of the network to decide on the placement of
	# each electrode.
	net.plot_cells()

	###############################################################################
	# The default network consists of an L5 and an L2 layer, within which the cell
	# somas are arranged in a regular grid, and apical dendrites are aligned along
	# the z-axis. We can simulate a linear array multielectrode with 100 um
	# intercontact spacing [1]_ by specifying a list of (x, y, z) coordinate
	# triplets. The L5 pyramidal cell somas are at z=0 um, with apical dendrites
	# extending up to approximately z=2000 um. L2 pyramidal cell somas reside at
	# z=1300 um, and have apical dendrites extending to z=2300 um. We'll place the
	# recording array in the center of the network. By default, a value of
	# 0.3 S/m is used for the constant extracellular conductivity. We'll use the
	# point source approximation method for calculations.

	depths = list(range(-525, 2750, 100))
	electrode_pos = [(4.5, 4.5, dep) for dep in depths]
	sigma, method, min_distance = 0.3, 'psa', 0.5
	net.add_electrode_array('shank1', electrode_pos, sigma=sigma,
	method=method)

	###############################################################################
	# The electrode arrays are stored under ``Network.rec_array`` as a dictionary
	# of :class:`~hnn_core.extracellular.ElectrodeArray` objects that are now
	# attached to the network and will be recorded during the simulation. Note that
	# calculating the extracellular potentials requires additional computational
	# resources and will thus slightly slow down the simulation.
	# :ref:`Using MPI <sphx_glr_auto_examples_plot_simulate_mpi_backend.py>` will
	# speed up computation considerably. Note that we will perform smoothing of the
	# dipole time series during plotting (``postproc=False``)
	print(net.rec_array)
	net.plot_cells()

	dpl = simulate_dipole(net, postproc=False)

	###############################################################################
	# For plotting both agregate dipole moment and LFP traces, we'll use a 10 ms
	# smoothing window, after which both data can be decimated by a factor of 20
	# from 40 to 2 kHz sampling rates. Note that decimation is applied in two
	# steps.
	trial_idx = 0
	window_len = 10 # ms
	decimate = [5, 4] # from 40k to 8k to 2k
	fig, axs = plt.subplots(3, 1, sharex=True, figsize=(8, 10),
	gridspec_kw={'height_ratios': [1, 3, 1]})

	# First plot the external drive statistics driving the network
	net.cell_response.plot_spikes_hist(ax=axs[0], show=False)
	axs[0].set_title('External drive spike event histograms')

	# Then plot the aggregate dipole time series on its own axis
	dpl_ax = axs[1].twinx()
	dpl_color = (0.6, 0., 0.6)

	dpl[trial_idx].copy().smooth(
	window_len=window_len).plot(ax=dpl_ax, decim=decimate,
	color=dpl_color, show=False)
	dpl_ax.yaxis.label.set_color(dpl_color)
	dpl_ax.set_title('Aggregate dipole moment overlaid on laminar LFP traces')

	voltage_offset = 300 # the spacing between individual traces
	voltage_scalebar = 500 # can be different from offset
	# we can assign each electrode a unique color using a linear colormap
	colors = plt.get_cmap('cividis', len(electrode_pos))
	net.rec_array['shank1'][trial_idx].plot(ax=axs[1],
	voltage_offset=voltage_offset,
	voltage_scalebar=voltage_scalebar,
	contact_labels=depths,
	color=colors,
	window_len=window_len,
	decim=decimate, show=False)
	axs[1].grid(True, which='major', axis='x')
	axs[1].set_xlabel('')
	# Finally, add the spike raster to the bottom subplot
	net.cell_response.plot_spikes_raster(ax=axs[2], show=False)
	axs[2].set_title('Network spiking responses')
	plt.show()

	###############################################################################
	# The strong fluctuations seen in the dipole waveform appear to correlate with
	# similarly large amplitude LFP signals close to the L5 pyramidal soma layer.
	#
	# References
	# ----------
	# .. [1] Kajikawa, Y. & Schroeder, C. E. How local is the local field
	# potential? Neuron 72, 847–858 (2011).