def determine_sthresh_hc3(df): print('Computing straightrank of all passes') num_sess = df.shape[0] capassdf = {'CA1': [], 'CA3': []} for nsess in range(num_sess): if (nsess > 20): break print('\r%d/%d Session' % (nsess, num_sess), flush=True, end='') posdf = df.loc[nsess, 'posdf'] occ_dict = df.loc[nsess, 'occ_dict'] xx, yy = occ_dict['xx'], occ_dict['yy'] x_ax, y_ax = xx[0, :], yy[:, 0] tunner = IndataProcessor(posdf, vthresh=5, sthresh=0, minpasstime=0.6) trange = (tunner.t.max(), tunner.t.min()) dt = tunner.t[1] - tunner.t[0] interpolater_angle = interp1d(tunner.t, tunner.angle) interpolater_x = interp1d(tunner.t, tunner.x) interpolater_y = interp1d(tunner.t, tunner.y) for ca in ['CA1', 'CA3']: field_df, spdf = df.loc[nsess, ['%sfields' % (ca), '%s_spdf' % (ca)]] num_fields = field_df.shape[0] for nfield in range(num_fields): cellid, mask = field_df.loc[nfield, ['cellid', 'mask']] tsp, pf = spdf.loc[cellid, ['tsp', 'pf']] tok, idin = tunner.get_idin(mask.T, x_ax, y_ax) passdf = tunner.construct_singlefield_passdf( tok, tsp, interpolater_x, interpolater_y, interpolater_angle) duration = passdf['t'].apply(lambda x: x.max() - x.min()) nspks = passdf['tsp'].apply(lambda x: x.shape[0]) passdf = passdf[(duration > 0.4) & (nspks > 1)].reset_index(drop=True) capassdf[ca].append(passdf) passdf_ca1 = pd.concat(capassdf['CA1'], axis=0, ignore_index=True) passdf_ca3 = pd.concat(capassdf['CA3'], axis=0, ignore_index=True) print('\nCA1\n', passdf_ca1['straightrank'].describe()) print('0.1 quantile = %0.2f' % (np.quantile(passdf_ca1['straightrank'].to_numpy(), 0.1))) print('CA3\n', passdf_ca3['straightrank'].describe()) print('0.1 quantile = %0.2f' % (np.quantile(passdf_ca3['straightrank'].to_numpy(), 0.1))) return
def plot_pair_examples(df, vthresh=5, sthresh=3, plot_dir=None): def select_cases(ntrial, ca, npair): if (ntrial==0) and (ca== 'CA1') and (npair==9): return 'kld', 1 elif (ntrial==7) and (ca== 'CA1') and (npair==22): return 'kld', 0 elif (ntrial==123) and (ca== 'CA1') and (npair==0): # 628 return 'eg', 14 elif (ntrial==9) and (ca== 'CA1') and (npair==1): # 140 return 'eg', 4 elif (ntrial==56) and (ca== 'CA1') and (npair==1): # 334 return 'eg', 8 elif (ntrial==73) and (ca== 'CA1') and (npair==2): # 394 return 'eg', 12 elif (ntrial==17) and (ca== 'CA2') and (npair==4): # 256 return 'eg', 0 elif (ntrial==18) and (ca== 'CA2') and (npair==4): # 263 return 'eg', 6 elif (ntrial==26) and (ca== 'CA3') and (npair==1): # 299 return 'eg', 10 elif (ntrial==21) and (ca== 'CA3') and (npair==2): # 283 return 'eg', 2 else: return None, None all_ntrials = [0, 7, 123, 9, 56, 73, 17, 18, 26, 21] # Paired spikes figw_pairedsp = total_figw*0.8 figh_pairedsp = figw_pairedsp/5 # Pair eg figw_paireg = total_figw*0.8 figh_paireg = figw_paireg/4 * 1.1 fig_paireg = plt.figure(figsize=(figw_paireg, figh_paireg)) ax_paireg = np.array([ fig_paireg.add_subplot(2, 8, 1), fig_paireg.add_subplot(2, 8, 2, polar=True), fig_paireg.add_subplot(2, 8, 3), fig_paireg.add_subplot(2, 8, 4, polar=True), fig_paireg.add_subplot(2, 8, 5), fig_paireg.add_subplot(2, 8, 6, polar=True), fig_paireg.add_subplot(2, 8, 7), fig_paireg.add_subplot(2, 8, 8, polar=True), fig_paireg.add_subplot(2, 8, 9), fig_paireg.add_subplot(2, 8, 10, polar=True), fig_paireg.add_subplot(2, 8, 11), fig_paireg.add_subplot(2, 8, 12, polar=True), fig_paireg.add_subplot(2, 8, 13), fig_paireg.add_subplot(2, 8, 14, polar=True), fig_paireg.add_subplot(2, 8, 15), fig_paireg.add_subplot(2, 8, 16, polar=True), ]) # KLD figw_kld = total_figw*0.9/2 # leave 0.2 for colorbar in fig 5 figh_kld = total_figw*0.9/4 fig_kld, ax_kld = plt.subplots(2, 4, figsize=(figw_kld, figh_kld), subplot_kw={'polar':True}) num_trials = df.shape[0] aedges = np.linspace(-np.pi, np.pi, 36) aedm = midedges(aedges) abind = aedges[1] - aedges[0] sp_binwidth = 5 precess_filter = PrecessionFilter() for ntrial in range(num_trials): if ntrial not in all_ntrials: continue wave = df.loc[ntrial, 'wave'] precesser = PrecessionProcesser(sthresh=sthresh, vthresh=vthresh, wave=wave) for ca in ['CA%d' % (i + 1) for i in range(3)]: # Get data pair_df = df.loc[ntrial, ca + 'pairs'] field_df = df.loc[ntrial, ca + 'fields'] indata = df.loc[ntrial, ca + 'indata'] if (indata.shape[0] < 1) & (pair_df.shape[0] < 1) & (field_df.shape[0] < 1): continue tunner = IndataProcessor(indata, vthresh=vthresh, smooth=True) interpolater_angle = interp1d(tunner.t, tunner.angle) interpolater_x = interp1d(tunner.t, tunner.x) interpolater_y = interp1d(tunner.t, tunner.y) all_maxt, all_mint = tunner.t.max(), tunner.t.min() trange = (all_maxt, all_mint) dt = tunner.t[1] - tunner.t[0] precesser.set_trange(trange) ## Loop for pairs num_pairs = pair_df.shape[0] for npair in range(num_pairs): case, case_axid = select_cases(ntrial, ca, npair) if case is None: continue print('trial %d, %s, pair %d, case=%s' % (ntrial, ca, npair, case)) # find within-mask indexes field_ids = pair_df.loc[npair, 'fi'] - 1 # minus 1 to convert to python index mask1 = field_df.loc[field_ids[0], 'mask'] mask2 = field_df.loc[field_ids[1], 'mask'] # field's boundaries xyval1 = field_df.loc[field_ids[0], 'xyval'] xyval2 = field_df.loc[field_ids[1], 'xyval'] # Find overlap pf1 = field_df.loc[field_ids[0], 'pf'] pf2 = field_df.loc[field_ids[1], 'pf'] _, ks_dist, _ = dist_overlap(pf1['map'], pf2['map'], mask1, mask2) # Field's center coordinates maskedmap1, maskedmap2 = pf1['map'] * mask1, pf2['map'] * mask2 cooridx1 = np.unravel_index(maskedmap1.argmax(), maskedmap1.shape) cooridx2 = np.unravel_index(maskedmap2.argmax(), maskedmap2.shape) fcoor1 = np.array([pf1['X'][cooridx1[0], cooridx1[1]], pf1['Y'][cooridx1[0], cooridx1[1]]]) fcoor2 = np.array([pf2['X'][cooridx2[0], cooridx2[1]], pf2['Y'][cooridx2[0], cooridx2[1]]]) # get single fields' statistics passdf1 = field_df.loc[field_ids[0], 'passes'] passdf2 = field_df.loc[field_ids[1], 'passes'] (x1list, y1list, t1list, angle1list), tsp1list = append_info_from_passes(passdf1, vthresh, sthresh, trange) (x2list, y2list, t2list, angle2list), tsp2list = append_info_from_passes(passdf2, vthresh, sthresh, trange) if (len(t1list) < 1) or (len(t2list) < 1) or (len(tsp1list) < 1) or (len(tsp2list) < 1): continue x1, x2 = np.concatenate(x1list), np.concatenate(x2list) y1, y2 = np.concatenate(y1list), np.concatenate(y2list) hd1, hd2 = np.concatenate(angle1list), np.concatenate(angle2list) pos1, pos2 = np.stack([x1, y1]).T, np.stack([x2, y2]).T tsp1, tsp2 = np.concatenate(tsp1list), np.concatenate(tsp2list) xsp1, xsp2 = interpolater_x(tsp1), interpolater_x(tsp2) ysp1, ysp2 = interpolater_y(tsp1), interpolater_y(tsp2) possp1, possp2 = np.stack([xsp1, ysp1]).T, np.stack([xsp2, ysp2]).T hdsp1, hdsp2 = interpolater_angle(tsp1), interpolater_angle(tsp2) nspks1, nspks2 = tsp1.shape[0], tsp2.shape[0] # Directionality biner1 = DirectionerBining(aedges, hd1) fangle1, fR1, (spbins1, occbins1, normprob1) = biner1.get_directionality(hdsp1) mlmer1 = DirectionerMLM(pos1, hd1, dt=dt, sp_binwidth=sp_binwidth, a_binwidth=abind) fangle1_mlm, fR1_mlm, normprob1_mlm = mlmer1.get_directionality(possp1, hdsp1) normprob1_mlm[np.isnan(normprob1_mlm)] = 0 biner2 = DirectionerBining(aedges, hd2) fangle2, fR2, (spbins2, occbins2, normprob2) = biner2.get_directionality(hdsp2) mlmer2 = DirectionerMLM(pos2, hd2, dt=dt, sp_binwidth=sp_binwidth, a_binwidth=abind) fangle2_mlm, fR2_mlm, normprob2_mlm = mlmer2.get_directionality(possp2, hdsp2) normprob2_mlm[np.isnan(normprob2_mlm)] = 0 # Pass-based phaselag, extrinsic/intrinsic phase_finder = ThetaEstimator(0.005, 0.3, [5, 12]) AB_tsp1_list, BA_tsp1_list = [], [] AB_tsp2_list, BA_tsp2_list = [], [] nspikes_AB_list, nspikes_BA_list = [], [] duration_AB_list, duration_BA_list = [], [] t_all = [] passangles_all, x_all, y_all = [], [], [] paired_tsp_list = [] # Precession per pair neuro_keys_dict1 = dict(tsp='tsp1', spikev='spike1v', spikex='spike1x', spikey='spike1y', spikeangle='spike1angle') neuro_keys_dict2 = dict(tsp='tsp2', spikev='spike2v', spikex='spike2x', spikey='spike2y', spikeangle='spike2angle') pass_dict_keys = precesser._gen_precess_infokeys() pass_dict1 = precesser.gen_precess_dict(tag='1') pass_dict2 = precesser.gen_precess_dict(tag='2') pass_dictp = {**pass_dict1, **pass_dict2, **{'direction':[]}} pairedpasses = pair_df.loc[npair, 'pairedpasses'] num_passes = pairedpasses.shape[0] for npass in range(num_passes): # Get spikes tsp1, tsp2, vsp1, vsp2 = pairedpasses.loc[npass, ['tsp1', 'tsp2', 'spike1v', 'spike2v']] x, y, pass_angles, v = pairedpasses.loc[npass, ['x', 'y', 'angle', 'v']] # Straightness straightrank = compute_straightness(pass_angles) if straightrank < sthresh: continue # Find direction infield1, infield2, t = pairedpasses.loc[npass, ['infield1', 'infield2', 't']] loc, direction = ThetaEstimator.find_direction(infield1, infield2) duration = t.max() - t.min() # Speed threshold passmask = v > vthresh spmask1, spmask2 = vsp1 > vthresh, vsp2 > vthresh xinv, yinv, pass_angles_inv, tinv = x[passmask], y[passmask], pass_angles[passmask], t[passmask] tsp1_inv, tsp2_inv = tsp1[spmask1], tsp2[spmask2] # Find paired spikes pairidx1, pairidx2 = find_pair_times(tsp1_inv, tsp2_inv) paired_tsp1, paired_tsp2 = tsp1_inv[pairidx1], tsp2_inv[pairidx2] if (paired_tsp1.shape[0] < 1) and (paired_tsp2.shape[0] < 1): continue paired_tsp_eachpass = np.concatenate([paired_tsp1, paired_tsp2]) paired_tsp_list.append(paired_tsp_eachpass) # Get pass info passangles_all.append(pass_angles_inv) x_all.append(xinv) y_all.append(yinv) t_all.append(tinv) if direction == 'A->B': AB_tsp1_list.append(tsp1_inv) AB_tsp2_list.append(tsp2_inv) nspikes_AB_list.append(tsp1_inv.shape[0] + tsp2_inv.shape[0]) duration_AB_list.append(duration) elif direction == 'B->A': BA_tsp1_list.append(tsp1_inv) BA_tsp2_list.append(tsp2_inv) nspikes_BA_list.append(tsp1_inv.shape[0] + tsp2_inv.shape[0]) duration_BA_list.append(duration) if (direction == 'A->B') or (direction == 'B->A'): precess1 = precesser._get_precession(pairedpasses, npass, neuro_keys_dict1) precess2 = precesser._get_precession(pairedpasses, npass, neuro_keys_dict2) if (precess1 is None) or (precess2 is None): continue else: pass_dictp = precesser.append_pass_dict(pass_dictp, precess1, tag='1') pass_dictp = precesser.append_pass_dict(pass_dictp, precess2, tag='2') pass_dictp['direction'].append(direction) ############## Plot paired spikes examples ############## if (ntrial==26) and (ca=='CA3') and (npair==1) and (npass==10): if (tsp1_inv.shape[0] != 0) or (tsp2_inv.shape[0] != 0): mintsp_plt = np.min(np.concatenate([tsp1_inv, tsp2_inv])) tsp1_inv = tsp1_inv - mintsp_plt tsp2_inv = tsp2_inv - mintsp_plt tmp_idx1, tmp_idx2 = find_pair_times(tsp1_inv, tsp2_inv) pairedsp1, pairedsp2 = tsp1_inv[tmp_idx1], tsp2_inv[tmp_idx2] fig_pairsp, ax_pairsp = plt.subplots(figsize=(figw_pairedsp, figh_pairedsp)) ax_pairsp.eventplot(tsp1_inv, color='k', lineoffsets=0, linelengths=1, linewidths=0.75) ax_pairsp.eventplot(tsp2_inv, color='k', lineoffsets=1, linelengths=1, linewidths=0.75) ax_pairsp.eventplot(pairedsp1, color='darkorange', lineoffsets=0, linelengths=1, linewidths=0.75) ax_pairsp.eventplot(pairedsp2, color='darkorange', lineoffsets=1, linelengths=1, linewidths=0.75) ax_pairsp.set_yticks([0, 1]) ax_pairsp.set_yticklabels(['Field A', 'Field B']) ax_pairsp.set_ylim(-0.7, 1.7) ax_pairsp.tick_params(labelsize=ticksize) ax_pairsp.set_xlabel('t (s)', fontsize=fontsize) ax_pairsp.xaxis.set_label_coords(1, -0.075) ax_pairsp.spines['left'].set_visible(False) ax_pairsp.spines['right'].set_visible(False) ax_pairsp.spines['top'].set_visible(False) fig_pairsp.tight_layout() fig_pairsp.savefig(os.path.join(plot_dir, 'example_pairedspikes.%s' % (figext)), dpi=dpi) # fig_pairsp.savefig(os.path.join(plot_dir, 'examples_pairspikes', 'trial-%d_%s_pair-%d_pass-%d.%s' % (ntrial, ca, npair, npass, figext)), dpi=dpi) # Paired spikes if (len(paired_tsp_list) == 0) or (len(passangles_all) == 0): continue hd_pair = np.concatenate(passangles_all) x_pair, y_pair = np.concatenate(x_all), np.concatenate(y_all) pos_pair = np.stack([x_pair, y_pair]).T paired_tsp = np.concatenate(paired_tsp_list) paired_tsp = paired_tsp[(paired_tsp <= all_maxt) & (paired_tsp >= all_mint)] if paired_tsp.shape[0] < 1: continue num_spikes_pair = paired_tsp.shape[0] hdsp_pair = interpolater_angle(paired_tsp) xsp_pair = interpolater_x(paired_tsp) ysp_pair = interpolater_y(paired_tsp) possp_pair = np.stack([xsp_pair, ysp_pair]).T # Pair Directionality biner_pair = DirectionerBining(aedges, hd_pair) fanglep, fRp, (spbinsp, occbinsp, normprobp) = biner_pair.get_directionality(hdsp_pair) mlmer_pair = DirectionerMLM(pos_pair, hd_pair, dt, sp_binwidth, abind) fanglep_mlm, fRp_mlm, normprobp_mlm = mlmer_pair.get_directionality(possp_pair, hdsp_pair) normprobp_mlm[np.isnan(normprobp_mlm)] = 0 # KLD kld_mlm = calc_kld(normprob1_mlm, normprob2_mlm, normprobp_mlm) ############## Plot pair examples ############## if case == 'eg': ax_paireg[case_axid].plot(tunner.x, tunner.y, c='0.8', linewidth=0.75) ax_paireg[case_axid].plot(xyval1[:, 0], xyval1[:, 1], c='k', linewidth=1) ax_paireg[case_axid].plot(xyval2[:, 0], xyval2[:, 1], c='k', linewidth=1) ax_paireg[case_axid].axis('off') xp, yp = circular_density_1d(aedm, 20 * np.pi, 60, (-np.pi, np.pi), w=normprobp_mlm) ax_paireg[case_axid+1] = directionality_polar_plot(ax_paireg[case_axid+1], xp, yp, fanglep_mlm, linewidth=0.75) ax_paireg[case_axid].text(0.6, -0.05, '%0.2f' % (ks_dist), fontsize=legendsize, c='k', transform=ax_paireg[case_axid].transAxes) ax_paireg[case_axid+1].text(0.6, -0.05, '%0.2f' % (fRp_mlm), fontsize=legendsize, c='k', transform=ax_paireg[case_axid+1].transAxes) ############## Plot KLD examples ############## if case == 'kld': x1, y1 = circular_density_1d(aedm, 20 * np.pi, 60, (-np.pi, np.pi), w=normprob1_mlm) x2, y2 = circular_density_1d(aedm, 20 * np.pi, 60, (-np.pi, np.pi), w=normprob2_mlm) xp, yp = circular_density_1d(aedm, 20 * np.pi, 60, (-np.pi, np.pi), w=normprobp_mlm) indep_prob = normprob1_mlm * normprob2_mlm indep_prob = indep_prob / np.sum(indep_prob) indep_angle = circmean(aedm, w=indep_prob, d=abind) xindep, yindep = circular_density_1d(aedm, 20 * np.pi, 60, (-np.pi, np.pi), w=indep_prob) kld_linewidth = 0.75 ax_kld[case_axid, 0] = directionality_polar_plot(ax_kld[case_axid, 0], x1, y1, fangle1_mlm, linewidth=kld_linewidth) ax_kld[case_axid, 1] = directionality_polar_plot(ax_kld[case_axid, 1], x2, y2, fangle2_mlm, linewidth=kld_linewidth) ax_kld[case_axid, 2] = directionality_polar_plot(ax_kld[case_axid, 2], xindep, yindep, indep_angle, linewidth=kld_linewidth) ax_kld[case_axid, 3] = directionality_polar_plot(ax_kld[case_axid, 3], xp, yp, fanglep_mlm, linewidth=kld_linewidth) kldtext_x, kldtext_y = 0, -0.2 ax_kld[case_axid, 3].text(kldtext_x, kldtext_y, 'KLD=%0.2f' % (kld_mlm), fontsize=legendsize, transform=ax_kld[case_axid, 3].transAxes)
def pair_field_preprocess_exp(df, vthresh=5, sthresh=3, NShuffles=200, save_pth=None): pairdata_dict = dict(pair_id=[], ca=[], overlap=[], border1=[], border2=[], area1=[], area2=[], xyval1=[], xyval2=[], aver_rate1=[], aver_rate2=[], aver_rate_pair=[], peak_rate1=[], peak_rate2=[], minocc1=[], minocc2=[], fieldcoor1=[], fieldcoor2=[], com1=[], com2=[], rate_angle1=[], rate_angle2=[], rate_anglep=[], rate_R1=[], rate_R2=[], rate_Rp=[], num_spikes1=[], num_spikes2=[], num_spikes_pair=[], phaselag_AB=[], phaselag_BA=[], corr_info_AB=[], corr_info_BA=[], thetaT_AB=[], thetaT_BA=[], rate_AB=[], rate_BA=[], corate=[], pair_rate=[], kld=[], rate_R_pvalp=[], precess_df1=[], precess_angle1=[], precess_R1=[], precess_df2=[], precess_angle2=[], precess_R2=[], numpass_at_precess1=[], numpass_at_precess2=[], precess_dfp=[]) num_trials = df.shape[0] aedges = np.linspace(-np.pi, np.pi, 36) abind = aedges[1] - aedges[0] sp_binwidth = 5 aedges_precess = np.linspace(-np.pi, np.pi, 6) kappa_precess = 1 precess_filter = PrecessionFilter() pair_id = 0 for ntrial in range(num_trials): wave = df.loc[ntrial, 'wave'] precesser = PrecessionProcesser(wave=wave) for ca in ['CA%d' % (i + 1) for i in range(3)]: # Get data pair_df = df.loc[ntrial, ca + 'pairs'] field_df = df.loc[ntrial, ca + 'fields'] indata = df.loc[ntrial, ca + 'indata'] if (indata.shape[0] < 1) & (pair_df.shape[0] < 1) & (field_df.shape[0] < 1): continue tunner = IndataProcessor(indata, vthresh=vthresh, sthresh=sthresh, minpasstime=0.4) interpolater_angle = interp1d(tunner.t, tunner.angle) interpolater_x = interp1d(tunner.t, tunner.x) interpolater_y = interp1d(tunner.t, tunner.y) all_maxt, all_mint = tunner.t.max(), tunner.t.min() trange = (all_maxt, all_mint) dt = tunner.t[1] - tunner.t[0] precesser.set_trange(trange) ## Loop for pairs num_pairs = pair_df.shape[0] for npair in range(num_pairs): print('%d/%d trial, %s, %d/%d pair id=%d' % (ntrial, num_trials, ca, npair, num_pairs, pair_id)) # find within-mask indexes field_ids = pair_df.loc[npair, 'fi'] - 1 # minus 1 to convert to python index mask1, pf1, xyval1 = field_df.loc[field_ids[0], ['mask', 'pf', 'xyval']] mask2, pf2, xyval2 = field_df.loc[field_ids[1], ['mask', 'pf', 'xyval']] tsp1 = field_df.loc[field_ids[0], 'xytsp']['tsp'] tsp2 = field_df.loc[field_ids[1], 'xytsp']['tsp'] xaxis1, yaxis1 = pf1['X'][:, 0], pf1['Y'][0, :] xaxis2, yaxis2 = pf2['X'][:, 0], pf2['Y'][0, :] assert (np.all(xaxis1==xaxis2) and np.all(yaxis1==yaxis2)) area1 = mask1.sum() area2 = mask2.sum() field_d1 = np.sqrt(area1/np.pi)*2 field_d2 = np.sqrt(area2/np.pi)*2 # Find overlap _, ks_dist, _ = dist_overlap(pf1['map'], pf2['map'], mask1, mask2) # Field's center coordinates maskedmap1, maskedmap2 = pf1['map'] * mask1, pf2['map'] * mask2 cooridx1 = np.unravel_index(maskedmap1.argmax(), maskedmap1.shape) cooridx2 = np.unravel_index(maskedmap2.argmax(), maskedmap2.shape) fcoor1 = np.array([pf1['X'][cooridx1[0], cooridx1[1]], pf1['Y'][cooridx1[0], cooridx1[1]]]) fcoor2 = np.array([pf2['X'][cooridx2[0], cooridx2[1]], pf2['Y'][cooridx2[0], cooridx2[1]]]) XY1 = np.stack([pf1['X'].ravel(), pf1['Y'].ravel()]) XY2 = np.stack([pf2['X'].ravel(), pf2['Y'].ravel()]) com1 = np.sum(XY1 * (maskedmap1/np.sum(maskedmap1)).ravel().reshape(1, -1), axis=1) com2 = np.sum(XY2 * (maskedmap2/np.sum(maskedmap2)).ravel().reshape(1, -1), axis=1) # Border border1 = check_border(mask1, margin=2) border2 = check_border(mask2, margin=2) # Construct passes (segment & chunk) for field 1 and 2 tok1, idin1 = tunner.get_idin(mask1, xaxis1, yaxis1) tok2, idin2 = tunner.get_idin(mask2, xaxis2, yaxis2) passdf1 = tunner.construct_singlefield_passdf(tok1, tsp1, interpolater_x, interpolater_y, interpolater_angle) passdf2 = tunner.construct_singlefield_passdf(tok2, tsp2, interpolater_x, interpolater_y, interpolater_angle) allchunk_df1 = passdf1[(~passdf1['rejected']) & (passdf1['chunked']<2)].reset_index(drop=True) allchunk_df2 = passdf2[(~passdf2['rejected']) & (passdf2['chunked']<2)].reset_index(drop=True) # allchunk_df1 = passdf1[(~passdf1['rejected']) ].reset_index(drop=True) # allchunk_df2 = passdf2[(~passdf2['rejected']) ].reset_index(drop=True) if (allchunk_df1.shape[0] < 1) or (allchunk_df2.shape[0] < 1): continue x1list, y1list, angle1list = allchunk_df1['x'].to_list(), allchunk_df1['y'].to_list(), allchunk_df1['angle'].to_list() t1list, tsp1list = allchunk_df1['t'].to_list(), allchunk_df1['tsp'].to_list() x2list, y2list, angle2list = allchunk_df2['x'].to_list(), allchunk_df2['y'].to_list(), allchunk_df2['angle'].to_list() t2list, tsp2list = allchunk_df2['t'].to_list(), allchunk_df2['tsp'].to_list() if (len(t1list) < 1) or (len(t2list) < 1) or (len(tsp1list) < 1) or (len(tsp2list) < 1): continue x1, x2 = np.concatenate(x1list), np.concatenate(x2list) y1, y2 = np.concatenate(y1list), np.concatenate(y2list) hd1, hd2 = np.concatenate(angle1list), np.concatenate(angle2list) pos1, pos2 = np.stack([x1, y1]).T, np.stack([x2, y2]).T tsp1, tsp2 = np.concatenate(tsp1list), np.concatenate(tsp2list) xsp1, xsp2 = np.concatenate(allchunk_df1['spikex'].to_list()), np.concatenate(allchunk_df2['spikex'].to_list()) ysp1, ysp2 = np.concatenate(allchunk_df1['spikey'].to_list()), np.concatenate(allchunk_df2['spikey'].to_list()) possp1, possp2 = np.stack([xsp1, ysp1]).T, np.stack([xsp2, ysp2]).T hdsp1 = np.concatenate(allchunk_df1['spikeangle'].to_list()) hdsp2 = np.concatenate(allchunk_df2['spikeangle'].to_list()) nspks1, nspks2 = tsp1.shape[0], tsp2.shape[0] # Rates aver_rate1 = nspks1 / (x1.shape[0]*dt) peak_rate1 = np.max(pf1['map'] * mask1) aver_rate2 = nspks2 / (x2.shape[0] * dt) peak_rate2 = np.max(pf2['map'] * mask2) # Directionality occbins1, _ = np.histogram(hd1, bins=aedges) spbins1, _ = np.histogram(hdsp1, bins=aedges) mlmer1 = DirectionerMLM(pos1, hd1, dt=dt, sp_binwidth=sp_binwidth, a_binwidth=abind) rate_angle1, rate_R1, normprob1_mlm = mlmer1.get_directionality(possp1, hdsp1) normprob1_mlm[np.isnan(normprob1_mlm)] = 0 occbins2, _ = np.histogram(hd2, bins=aedges) spbins2, _ = np.histogram(hdsp2, bins=aedges) mlmer2 = DirectionerMLM(pos2, hd2, dt=dt, sp_binwidth=sp_binwidth, a_binwidth=abind) rate_angle2, rate_R2, normprob2_mlm = mlmer2.get_directionality(possp2, hdsp2) normprob2_mlm[np.isnan(normprob2_mlm)] = 0 minocc1, minocc2 = occbins1.min(), occbins2.min() neuro_keys_dict = dict(tsp='tsp', spikev='spikev', spikex='spikex', spikey='spikey', spikeangle='spikeangle') # Precession1 & Post-hoc exclusion for 1st field accept_mask1 = (~passdf1['rejected']) & (passdf1['chunked'] < 2) passdf1['excluded_for_precess'] = ~accept_mask1 precessdf1, precessangle1, precessR1, _ = get_single_precessdf(passdf1, precesser, precess_filter, neuro_keys_dict, field_d=field_d1, kappa=kappa_precess, bins=None) fitted_precessdf1 = precessdf1[precessdf1['fitted']].reset_index(drop=True) if (precessangle1 is not None) and (fitted_precessdf1.shape[0] > 0): # Post-hoc precession exclusion _, _, postdoc_dens1 = compute_precessangle(pass_angles=fitted_precessdf1['mean_anglesp'].to_numpy(), pass_nspikes=fitted_precessdf1['pass_nspikes'].to_numpy(), precess_mask=fitted_precessdf1['precess_exist'].to_numpy(), kappa=None, bins=aedges_precess) (_, passbins_p1, passbins_np1, _) = postdoc_dens1 all_passbins1 = passbins_p1 + passbins_np1 numpass_at_precess1 = get_numpass_at_angle(target_angle=precessangle1, aedge=aedges_precess, all_passbins=all_passbins1) else: numpass_at_precess1 = None # Precession2 & Post-hoc exclusion for 2nd field accept_mask2 = (~passdf2['rejected']) & (passdf2['chunked'] < 2) passdf2['excluded_for_precess'] = ~accept_mask2 precessdf2, precessangle2, precessR2, _ = get_single_precessdf(passdf2, precesser, precess_filter, neuro_keys_dict, field_d=field_d2, kappa=kappa_precess, bins=None) fitted_precessdf2 = precessdf2[precessdf2['fitted']].reset_index(drop=True) if (precessangle2 is not None) and (fitted_precessdf2.shape[0] > 0): # Post-hoc precession exclusion _, _, postdoc_dens2 = compute_precessangle(pass_angles=fitted_precessdf2['mean_anglesp'].to_numpy(), pass_nspikes=fitted_precessdf2['pass_nspikes'].to_numpy(), precess_mask=fitted_precessdf2['precess_exist'].to_numpy(), kappa=None, bins=aedges_precess) (_, passbins_p2, passbins_np2, _) = postdoc_dens2 all_passbins2 = passbins_p2 + passbins_np2 numpass_at_precess2 = get_numpass_at_angle(target_angle=precessangle2, aedge=aedges_precess, all_passbins=all_passbins2) else: numpass_at_precess2 = None # # Paired field processing # Construct pairedpasses mask_union = mask1 | mask2 field_d_union = np.sqrt(mask_union.sum()/np.pi)*2 tok_pair, _ = tunner.get_idin(mask_union, xaxis1, yaxis1) pairedpasses = tunner.construct_pairfield_passdf(tok_pair, tok1, tok2, tsp1, tsp2, interpolater_x, interpolater_y, interpolater_angle) # Phase lags phase_finder = ThetaEstimator(0.005, 0.3, [5, 12]) AB_tsp1_list, BA_tsp1_list = [], [] AB_tsp2_list, BA_tsp2_list = [], [] nspikes_AB_list, nspikes_BA_list = [], [] duration_AB_list, duration_BA_list = [], [] t_all = [] passangles_all, x_all, y_all = [], [], [] paired_tsp_list = [] accepted_df = pairedpasses[(~pairedpasses['rejected']) & (pairedpasses['chunked']<2)].reset_index(drop=True) # accepted_df = pairedpasses[(~pairedpasses['rejected'])].reset_index(drop=True) for npass in range(accepted_df.shape[0]): # Get data t, tsp1, tsp2 = accepted_df.loc[npass, ['t', 'tsp1', 'tsp2']] x, y, pass_angles, v, direction = accepted_df.loc[npass, ['x', 'y', 'angle', 'v', 'direction']] duration = t.max() - t.min() # Find paired spikes pairidx1, pairidx2 = find_pair_times(tsp1, tsp2) paired_tsp1, paired_tsp2 = tsp1[pairidx1], tsp2[pairidx2] if (paired_tsp1.shape[0] < 1) and (paired_tsp2.shape[0] < 1): continue paired_tsp_eachpass = np.concatenate([paired_tsp1, paired_tsp2]) paired_tsp_list.append(paired_tsp_eachpass) passangles_all.append(pass_angles) x_all.append(x) y_all.append(y) t_all.append(t) if direction == 'A->B': AB_tsp1_list.append(tsp1) AB_tsp2_list.append(tsp2) nspikes_AB_list.append(tsp1.shape[0] + tsp2.shape[0]) duration_AB_list.append(duration) elif direction == 'B->A': BA_tsp1_list.append(tsp1) BA_tsp2_list.append(tsp2) nspikes_BA_list.append(tsp1.shape[0] + tsp2.shape[0]) duration_BA_list.append(duration) # Phase lags thetaT_AB, phaselag_AB, corr_info_AB = phase_finder.find_theta_isi_hilbert(AB_tsp1_list, AB_tsp2_list) thetaT_BA, phaselag_BA, corr_info_BA = phase_finder.find_theta_isi_hilbert(BA_tsp1_list, BA_tsp2_list) # Pair precession neuro_keys_dict1 = dict(tsp='tsp1', spikev='spike1v', spikex='spike1x', spikey='spike1y', spikeangle='spike1angle') neuro_keys_dict2 = dict(tsp='tsp2', spikev='spike2v', spikex='spike2x', spikey='spike2y', spikeangle='spike2angle') accept_mask = (~pairedpasses['rejected']) & (pairedpasses['chunked']<2) & ((pairedpasses['direction']=='A->B')| (pairedpasses['direction']=='B->A')) pairedpasses['excluded_for_precess'] = ~accept_mask precess_dfp = precesser.get_single_precession(pairedpasses, neuro_keys_dict1, field_d_union, tag='1') precess_dfp = precesser.get_single_precession(precess_dfp, neuro_keys_dict2, field_d_union, tag='2') precess_dfp = precess_filter.filter_pair(precess_dfp) fitted_precess_dfp = precess_dfp[precess_dfp['fitted1'] & precess_dfp['fitted2']].reset_index(drop=True) # Paired spikes if (len(paired_tsp_list) == 0) or (len(passangles_all) == 0): continue hd_pair = np.concatenate(passangles_all) x_pair, y_pair = np.concatenate(x_all), np.concatenate(y_all) pos_pair = np.stack([x_pair, y_pair]).T paired_tsp = np.concatenate(paired_tsp_list) paired_tsp = paired_tsp[(paired_tsp <= all_maxt) & (paired_tsp >= all_mint)] if paired_tsp.shape[0] < 1: continue num_spikes_pair = paired_tsp.shape[0] hdsp_pair = interpolater_angle(paired_tsp) xsp_pair = interpolater_x(paired_tsp) ysp_pair = interpolater_y(paired_tsp) possp_pair = np.stack([xsp_pair, ysp_pair]).T aver_rate_pair = num_spikes_pair / (x_pair.shape[0] * dt) # Pair Directionality occbinsp, _ = np.histogram(hd_pair, bins=aedges) spbinsp, _ = np.histogram(hdsp_pair, bins=aedges) mlmer_pair = DirectionerMLM(pos_pair, hd_pair, dt, sp_binwidth, abind) rate_anglep, rate_Rp, normprobp_mlm = mlmer_pair.get_directionality(possp_pair, hdsp_pair) normprobp_mlm[np.isnan(normprobp_mlm)] = 0 # Time shift shuffling if np.isnan(rate_Rp): rate_R_pvalp = np.nan else: rate_R_pvalp = timeshift_shuffle_exp_wrapper(paired_tsp_list, t_all, rate_Rp, NShuffles, mlmer_pair, interpolater_x, interpolater_y, interpolater_angle, trange) # Rates with np.errstate(divide='ignore', invalid='ignore'): # None means no sample rate_AB = np.sum(nspikes_AB_list) / np.sum(duration_AB_list) rate_BA = np.sum(nspikes_BA_list) / np.sum(duration_BA_list) corate = np.sum(nspikes_AB_list + nspikes_BA_list) / np.sum(duration_AB_list + duration_BA_list) pair_rate = num_spikes_pair / np.sum(duration_AB_list + duration_BA_list) # KLD kld = calc_kld(normprob1_mlm, normprob2_mlm, normprobp_mlm) pairdata_dict['pair_id'].append(pair_id) pairdata_dict['ca'].append(ca) pairdata_dict['overlap'].append(ks_dist) pairdata_dict['border1'].append(border1) pairdata_dict['border2'].append(border2) pairdata_dict['area1'].append(area1) pairdata_dict['area2'].append(area2) pairdata_dict['xyval1'].append(xyval1) pairdata_dict['xyval2'].append(xyval2) pairdata_dict['aver_rate1'].append(aver_rate1) pairdata_dict['aver_rate2'].append(aver_rate2) pairdata_dict['aver_rate_pair'].append(aver_rate_pair) pairdata_dict['peak_rate1'].append(peak_rate1) pairdata_dict['peak_rate2'].append(peak_rate2) pairdata_dict['minocc1'].append(minocc1) pairdata_dict['minocc2'].append(minocc2) pairdata_dict['fieldcoor1'].append(fcoor1) pairdata_dict['fieldcoor2'].append(fcoor2) pairdata_dict['com1'].append(com1) pairdata_dict['com2'].append(com2) pairdata_dict['rate_angle1'].append(rate_angle1) pairdata_dict['rate_angle2'].append(rate_angle2) pairdata_dict['rate_anglep'].append(rate_anglep) pairdata_dict['rate_R1'].append(rate_R1) pairdata_dict['rate_R2'].append(rate_R2) pairdata_dict['rate_Rp'].append(rate_Rp) pairdata_dict['num_spikes1'].append(nspks1) pairdata_dict['num_spikes2'].append(nspks2) pairdata_dict['num_spikes_pair'].append(num_spikes_pair) pairdata_dict['phaselag_AB'].append(phaselag_AB) pairdata_dict['phaselag_BA'].append(phaselag_BA) pairdata_dict['corr_info_AB'].append(corr_info_AB) pairdata_dict['corr_info_BA'].append(corr_info_BA) pairdata_dict['thetaT_AB'].append(thetaT_AB) pairdata_dict['thetaT_BA'].append(thetaT_BA) pairdata_dict['rate_AB'].append(rate_AB) pairdata_dict['rate_BA'].append(rate_BA) pairdata_dict['corate'].append(corate) pairdata_dict['pair_rate'].append(pair_rate) pairdata_dict['kld'].append(kld) pairdata_dict['rate_R_pvalp'].append(rate_R_pvalp) pairdata_dict['precess_df1'].append(fitted_precessdf1) pairdata_dict['precess_angle1'].append(precessangle1) pairdata_dict['precess_R1'].append(precessR1) pairdata_dict['numpass_at_precess1'].append(numpass_at_precess1) pairdata_dict['precess_df2'].append(fitted_precessdf2) pairdata_dict['precess_angle2'].append(precessangle2) pairdata_dict['precess_R2'].append(precessR2) pairdata_dict['numpass_at_precess2'].append(numpass_at_precess2) pairdata_dict['precess_dfp'].append(fitted_precess_dfp) pair_id += 1 pairdata = pd.DataFrame(pairdata_dict) pairdata = append_extrinsicity(pairdata) pairdata.to_pickle(save_pth) return pairdata
def plot_placefield_examples(rawdf, save_dir=None): example_dir = join(save_dir, 'example_fields2') os.makedirs(example_dir) field_figl = total_figw / 8 field_linew = 0.75 field_ms = 1 warnings.filterwarnings("ignore") # Parameters vthresh = 5 sthresh = 3 num_trials = rawdf.shape[0] aedges = np.linspace(-np.pi, np.pi, 36) aedm = midedges(aedges) abind = aedges[1] - aedges[0] sp_binwidth = 5 precess_filter = PrecessionFilter() # Plot color wheel fig_ch, ax_ch = color_wheel('hsv', (field_figl, field_figl)) fig_ch.savefig(os.path.join(save_dir, 'colorwheel.%s' % (figext)), transparent=True, dpi=dpi) # Selected Examples example_list = [ 'CA1-field16', 'CA2-field11', 'CA3-field378', # Precession 'CA1-field151', 'CA1-field222', 'CA1-field389', 'CA1-field400', 'CA1-field409', 'CA2-field28', 'CA2-field47', 'CA3-field75' ] fieldid = dict(CA1=0, CA2=0, CA3=0) fieldid_skip = dict(CA1=0, CA2=0, CA3=0) for ntrial in range(num_trials): wave = rawdf.loc[ntrial, 'wave'] precesser = PrecessionProcesser(wave=wave) for ca in ['CA%d' % i for i in range(1, 4)]: # Get data field_df = rawdf.loc[ntrial, ca + 'fields'] indata = rawdf.loc[ntrial, ca + 'indata'] if indata.shape[0] < 1: continue trajx, trajy = indata['x'].to_numpy(), indata['y'].to_numpy() num_fields = field_df.shape[0] tunner = IndataProcessor(indata, vthresh=5, sthresh=3, minpasstime=0.4, smooth=None) interpolater_angle = interp1d(tunner.t, tunner.angle) interpolater_x = interp1d(tunner.t, tunner.x) interpolater_y = interp1d(tunner.t, tunner.y) all_maxt, all_mint = tunner.t.max(), tunner.t.min() trange = (all_maxt, all_mint) dt = tunner.t[1] - tunner.t[0] precesser.set_trange(trange) for nfield in range(num_fields): if ('%s-field%d' % (ca, fieldid[ca])) not in example_list: fieldid[ca] += 1 continue print('Plotting fields: Trial %d/%d %s field %d/%d' % (ntrial, num_trials, ca, nfield, num_fields)) # Get field spikes xytsp, xyval = field_df.loc[nfield, ['xytsp', 'xyval']] tsp, xsp, ysp = xytsp['tsp'], xytsp['xsp'], xytsp['ysp'] pf = field_df.loc[nfield, 'pf'] # Get spike angles insession = np.where((tsp < all_maxt) & (tsp > all_mint))[0] tspins, xspins, yspins = tsp[insession], xsp[insession], ysp[ insession] anglespins = interpolater_angle(tspins) # Directionality passdf = field_df.loc[nfield, 'passes'] (xl, yl, tl, hdl), tspl = append_info_from_passes(passdf, vthresh, sthresh, trange) if (len(tspl) < 1) or (len(tl) < 1): # fieldid[ca] += 1 fieldid_skip[ca] += 1 continue x = np.concatenate(xl) y = np.concatenate(yl) pos = np.stack([x, y]).T hd = np.concatenate(hdl) tsp = np.concatenate(tspl) xsp, ysp = interpolater_x(tsp), interpolater_y(tsp) possp = np.stack([xsp, ysp]).T hdsp = interpolater_angle(tsp) # Directionality biner = DirectionerBining(aedges, hd) fieldangle, fieldR, (spike_bins, occ_bins, _) = biner.get_directionality(hdsp) mlmer = DirectionerMLM(pos, hd, dt, sp_binwidth, abind) fieldangle, fieldR, norm_prob = mlmer.get_directionality( possp, hdsp) norm_prob[np.isnan(norm_prob)] = 0 # # (Plot) Place field Example fig2 = plt.figure(figsize=(field_figl * 2, field_figl)) peak_rate = pf['map'].max() ax_field2 = fig2.add_subplot(1, 2, 1) ax_field2.plot(trajx, trajy, c='0.8', linewidth=0.25) ax_field2.plot(xyval[:, 0], xyval[:, 1], c='k', zorder=3, linewidth=field_linew) ax_field2.scatter(xspins, yspins, c=anglespins, marker='.', cmap='hsv', s=field_ms, zorder=2.5) ax_field2.axis('off') x_new, y_new = circular_density_1d(aedm, 30 * np.pi, 100, (-np.pi, np.pi), w=norm_prob) l = y_new.max() ax_polar = fig2.add_axes([0.33, 0.3, 0.6, 0.6], polar=True) ax_polar.plot(x_new, y_new, c='0.3', linewidth=field_linew, zorder=2.1) ax_polar.plot([x_new[-1], x_new[0]], [y_new[-1], y_new[0]], c='0.3', linewidth=field_linew, zorder=2.1) # ax_polar.plot([fieldangle, fieldangle], [0, l], c='k', linewidth=field_linew) ax_polar.annotate("", xy=(fieldangle, l), xytext=(0, 0), color='k', zorder=3, arrowprops=dict(arrowstyle="->")) ax_polar.annotate(r'$\theta_{rate}$', xy=(fieldangle, l), fontsize=legendsize) ax_polar.spines['polar'].set_visible(False) ax_polar.set_xticks([0, np.pi / 2, np.pi, 3 * np.pi / 2]) ax_polar.set_yticks([]) ax_polar.set_yticklabels([]) ax_polar.set_xticklabels([]) basey = -0.3 ax_polar.annotate('%0.2f' % (peak_rate), xy=(0.75, 0.05), color='k', zorder=3, fontsize=legendsize, xycoords='figure fraction') ax_polar.annotate('%0.2f' % (fieldR), xy=(0.75, 0.175), color='k', zorder=3, fontsize=legendsize, xycoords='figure fraction') # ax_polar.text(0.5, basey, '%0.2f' % (peak_rate), fontsize=legendsize, transform=ax_polar.transAxes) # ax_polar.text(0.5, basey + 0.25, '%0.2f' % (fieldR), fontsize=legendsize, transform=ax_polar.transAxes) fig2.tight_layout() fig2.savefig(os.path.join(example_dir, '%s-field%d.png' % (ca, fieldid[ca])), dpi=dpi) fig2.savefig(os.path.join(example_dir, '%s-field%d.eps' % (ca, fieldid[ca])), dpi=dpi) plt.close() fieldid[ca] += 1
def single_field_preprocess_networks(simdata, radius=10, vthresh=2, sthresh=80, NShuffles=200, subsample_fraction=1, save_pth=None): """ Parameters ---------- Indata SpikeData NeuronPos radius vthresh : float Default = 5. Same as Emily's data. sthresh : float Default = 80. Determined by the same percentile (10%) of passes excluded in Emily's data (sthresh = 3 there). subsample_fraction : float The fraction that the spikes would be subsampled. =1 if no subsampling is needed Returns ------- """ datadict = dict(num_spikes=[], border=[], aver_rate=[], peak_rate=[], fieldangle_mlm=[], fieldR_mlm=[], spike_bins=[], occ_bins=[], shift_pval_mlm=[], precess_df=[], precess_angle=[], precess_angle_low=[], precess_R=[]) Indata, SpikeData, NeuronPos = simdata['Indata'], simdata[ 'SpikeData'], simdata['NeuronPos'] aedges = np.linspace(-np.pi, np.pi, 36) abind = aedges[1] - aedges[0] sp_binwidth = 5 tunner = IndataProcessor(Indata, vthresh, True) wave = dict(tax=Indata['t'].to_numpy(), phase=Indata['phase'].to_numpy(), theta=np.ones(Indata.shape[0])) interpolater_angle = interp1d(tunner.t, tunner.angle) interpolater_x = interp1d(tunner.t, tunner.x) interpolater_y = interp1d(tunner.t, tunner.y) trange = (tunner.t.max(), tunner.t.min()) dt = tunner.t[1] - tunner.t[0] precesser = PrecessionProcesser(sthresh=sthresh, vthresh=vthresh, wave=wave) precesser.set_trange(trange) precess_filter = PrecessionFilter() nspikes_stats = (13, 40) pass_nspikes = [] num_neurons = NeuronPos.shape[0] for nidx in range(num_neurons): print('%d/%d Neuron' % (nidx, num_neurons)) # Get spike indexes + subsample spdf = SpikeData[SpikeData['neuronidx'] == nidx].reset_index(drop=True) tidxsp = spdf['tidxsp'].to_numpy().astype(int) if subsample_fraction < 1: np.random.seed(nidx) sampled_tidxsp = np.random.choice(tidxsp.shape[0] - 1, int(tidxsp.shape[0] * subsample_fraction), replace=False) sampled_tidxsp.sort() tidxsp = tidxsp[sampled_tidxsp] # Get tok neuronx, neurony = NeuronPos.loc[nidx, ['neuronx', 'neurony']] dist = np.sqrt((neuronx - tunner.x)**2 + (neurony - tunner.y)**2) tok = dist < radius # Check border border = check_border_sim(neuronx, neurony, radius, (-40, 40)) # Get info from passes all_passidx = segment_passes(tok) passdf = construct_passdf_sim(tunner, all_passidx, tidxsp) beh_info, all_tsp_list = append_info_from_passes( passdf, vthresh, sthresh, trange) (all_x_list, all_y_list, all_t_list, all_passangles_list) = beh_info if (len(all_tsp_list) < 1) or (len(all_x_list) < 1): continue all_x = np.concatenate(all_x_list) all_y = np.concatenate(all_y_list) all_passangles = np.concatenate(all_passangles_list) all_tsp = np.concatenate(all_tsp_list) all_anglesp = interpolater_angle(all_tsp) xsp, ysp = interpolater_x(all_tsp), interpolater_y(all_tsp) pos = np.stack([all_x, all_y]).T possp = np.stack([xsp, ysp]).T # Average firing rate aver_rate = all_tsp.shape[0] / (all_x.shape[0] * dt) # Field's directionality num_spikes = all_tsp.shape[0] occ_bins, _ = np.histogram(all_passangles, bins=aedges) spike_bins, _ = np.histogram(all_anglesp, bins=aedges) mlmer = DirectionerMLM(pos, all_passangles, dt, sp_binwidth=sp_binwidth, a_binwidth=abind) fieldangle_mlm, fieldR_mlm, norm_prob_mlm = mlmer.get_directionality( possp, all_anglesp) # Precession per pass neuro_keys_dict = dict(tsp='tsp', spikev='spikev', spikex='spikex', spikey='spikey', spikeangle='spikeangle') precessdf, precess_angle, precess_R, _ = get_single_precessdf( passdf, precesser, precess_filter, neuro_keys_dict) filtered_precessdf = precessdf[precessdf['precess_exist']].reset_index( drop=True) pass_nspikes = pass_nspikes + list(filtered_precessdf['pass_nspikes']) # Precession - pass with low/high spike number if precessdf.shape[0] > 0: ldf = precessdf[precessdf['pass_nspikes'] < nspikes_stats[0]] # 25% quantile if (ldf.shape[0] > 0) and (ldf['precess_exist'].sum() > 0): passangle_l, pass_nspikes_l = ldf['spike_angle'].to_numpy( ), ldf['pass_nspikes'].to_numpy() precess_mask_l = ldf['precess_exist'].to_numpy() precess_angle_low, _, _ = compute_precessangle( passangle_l, pass_nspikes_l, precess_mask_l) else: precess_angle_low = None else: precess_angle_low = None # Time shift shuffling shi_pval_mlm = timeshift_shuffle_exp_wrapper( all_tsp_list, all_t_list, fieldR_mlm, NShuffles, mlmer, interpolater_x, interpolater_y, interpolater_angle, trange) datadict['border'].append(border) datadict['num_spikes'].append(num_spikes) datadict['aver_rate'].append(aver_rate) datadict['peak_rate'].append(None) datadict['fieldangle_mlm'].append(fieldangle_mlm) datadict['fieldR_mlm'].append(fieldR_mlm) datadict['spike_bins'].append(spike_bins) datadict['occ_bins'].append(occ_bins) datadict['shift_pval_mlm'].append(shi_pval_mlm) datadict['precess_df'].append(precessdf) datadict['precess_angle'].append(precess_angle) datadict['precess_angle_low'].append(precess_angle_low) datadict['precess_R'].append(precess_R) print('Num spikes:\n') print( pd.DataFrame({'pass_nspikes': pass_nspikes})['pass_nspikes'].describe()) datadf = pd.DataFrame(datadict) datadf.to_pickle(save_pth)
def single_field_preprocess_exp(df, vthresh=5, sthresh=3, NShuffles=200, save_pth=None): fielddf_dict = dict(ca=[], num_spikes=[], border=[], aver_rate=[], peak_rate=[], rate_angle=[], rate_R=[], rate_R_pval=[], minocc=[], field_area=[], field_bound=[], precess_df=[], precess_angle=[], precess_angle_low=[], precess_R=[], precess_R_pval=[], numpass_at_precess=[], numpass_at_precess_low=[]) num_trials = df.shape[0] aedges = np.linspace(-np.pi, np.pi, 36) abind = aedges[1] - aedges[0] sp_binwidth = 5 aedges_precess = np.linspace(-np.pi, np.pi, 6) kappa_precess = 1 precess_filter = PrecessionFilter() nspikes_stats = { 'CA1': 6, 'CA2': 6, 'CA3': 7 } # 25% quantile of precessing passes for ntrial in range(num_trials): wave = df.loc[ntrial, 'wave'] precesser = PrecessionProcesser(wave=wave) for ca in ['CA%d' % (i + 1) for i in range(3)]: # Get data field_df = df.loc[ntrial, ca + 'fields'] indata = df.loc[ntrial, ca + 'indata'] num_fields = field_df.shape[0] if indata.shape[0] < 1: continue tunner = IndataProcessor(indata, vthresh=vthresh, sthresh=sthresh, minpasstime=0.4) interpolater_angle = interp1d(tunner.t, tunner.angle) interpolater_x = interp1d(tunner.t, tunner.x) interpolater_y = interp1d(tunner.t, tunner.y) trange = (tunner.t.max(), tunner.t.min()) dt = tunner.t[1] - tunner.t[0] precesser.set_trange(trange) for nf in range(num_fields): print('%d/%d trial, %s, %d/%d field' % (ntrial, num_trials, ca, nf, num_fields)) # Get field info mask, pf, xyval = field_df.loc[nf, ['mask', 'pf', 'xyval']] tsp = field_df.loc[nf, 'xytsp']['tsp'] xaxis, yaxis = pf['X'][:, 0], pf['Y'][0, :] field_area = np.sum(mask) field_d = np.sqrt(field_area / np.pi) * 2 border = check_border(mask, margin=2) # Construct passes (segment & chunk) tok, idin = tunner.get_idin(mask, xaxis, yaxis) passdf = tunner.construct_singlefield_passdf( tok, tsp, interpolater_x, interpolater_y, interpolater_angle) allchunk_df = passdf[(~passdf['rejected']) & (passdf['chunked'] < 2)].reset_index( drop=True) # allchunk_df = passdf[(~passdf['rejected'])].reset_index(drop=True) # Get info from passdf and interpolate if allchunk_df.shape[0] < 1: continue all_x_list, all_y_list = allchunk_df['x'].to_list( ), allchunk_df['y'].to_list() all_t_list, all_passangles_list = allchunk_df['t'].to_list( ), allchunk_df['angle'].to_list() all_tsp_list, all_chunked_list = allchunk_df['tsp'].to_list( ), allchunk_df['chunked'].to_list() all_x = np.concatenate(all_x_list) all_y = np.concatenate(all_y_list) all_passangles = np.concatenate(all_passangles_list) all_tsp = np.concatenate(all_tsp_list) all_anglesp = np.concatenate( allchunk_df['spikeangle'].to_list()) xsp, ysp = np.concatenate( allchunk_df['spikex'].to_list()), np.concatenate( allchunk_df['spikey'].to_list()) pos = np.stack([all_x, all_y]).T possp = np.stack([xsp, ysp]).T # Average firing rate aver_rate = all_tsp.shape[0] / (all_x.shape[0] * dt) peak_rate = np.max(field_df.loc[nf, 'pf']['map'] * mask) # Field's directionality - need angle, anglesp, pos num_spikes = all_tsp.shape[0] occ_bins, _ = np.histogram(all_passangles, bins=aedges) minocc = occ_bins.min() mlmer = DirectionerMLM(pos, all_passangles, dt, sp_binwidth=sp_binwidth, a_binwidth=abind) rate_angle, rate_R, norm_prob_mlm = mlmer.get_directionality( possp, all_anglesp) # Time shift shuffling for rate directionality if np.isnan(rate_R): rate_R_pval = np.nan else: rate_R_pval = timeshift_shuffle_exp_wrapper( all_tsp_list, all_t_list, rate_R, NShuffles, mlmer, interpolater_x, interpolater_y, interpolater_angle, trange) # Precession per pass neuro_keys_dict = dict(tsp='tsp', spikev='spikev', spikex='spikex', spikey='spikey', spikeangle='spikeangle') accept_mask = (~passdf['rejected']) & (passdf['chunked'] < 2) passdf['excluded_for_precess'] = ~accept_mask precessdf, precess_angle, precess_R, _ = get_single_precessdf( passdf, precesser, precess_filter, neuro_keys_dict, field_d=field_d, kappa=kappa_precess, bins=None) fitted_precessdf = precessdf[precessdf['fitted']].reset_index( drop=True) # Proceed only if precession exists if (precess_angle is not None) and ( fitted_precessdf['precess_exist'].sum() > 0): # Post-hoc precession exclusion _, binR, postdoc_dens = compute_precessangle( pass_angles=fitted_precessdf['mean_anglesp'].to_numpy( ), pass_nspikes=fitted_precessdf['pass_nspikes'].to_numpy( ), precess_mask=fitted_precessdf['precess_exist']. to_numpy(), kappa=None, bins=aedges_precess) (_, passbins_p, passbins_np, _) = postdoc_dens all_passbins = passbins_p + passbins_np numpass_at_precess = get_numpass_at_angle( target_angle=precess_angle, aedge=aedges_precess, all_passbins=all_passbins) # Precession - low-spike passes ldf = fitted_precessdf[fitted_precessdf['pass_nspikes'] < nspikes_stats[ca]] # 25% quantile if (ldf.shape[0] > 0) and (ldf['precess_exist'].sum() > 0): precess_angle_low, _, _ = compute_precessangle( pass_angles=ldf['mean_anglesp'].to_numpy(), pass_nspikes=ldf['pass_nspikes'].to_numpy(), precess_mask=ldf['precess_exist'].to_numpy(), kappa=kappa_precess, bins=None) _, _, postdoc_dens_low = compute_precessangle( pass_angles=ldf['mean_anglesp'].to_numpy(), pass_nspikes=ldf['pass_nspikes'].to_numpy(), precess_mask=ldf['precess_exist'].to_numpy(), kappa=None, bins=aedges_precess) (_, passbins_p_low, passbins_np_low, _) = postdoc_dens_low all_passbins_low = passbins_p_low + passbins_np_low numpass_at_precess_low = get_numpass_at_angle( target_angle=precess_angle_low, aedge=aedges_precess, all_passbins=all_passbins_low) else: precess_angle_low = None numpass_at_precess_low = None # # Precession - time shift shuffle # psr = PassShuffler(all_t_list, all_tsp_list) # all_shuffled_R = np.zeros(NShuffles) # shufi = 0 # fail_times = 0 # repeated_times = 0 # tmpt = time.time() # while (shufi < NShuffles) & (fail_times < NShuffles): # # # Re-construct passdf # shifted_tsp_boxes = psr.timeshift_shuffle(seed=shufi+fail_times, return_concat=False) # # # shifted_spikex_boxes, shifted_spikey_boxes = [], [] # shifted_spikeangle_boxes, shifted_rejected_boxes = [], [] # # for boxidx, shuffled_tsp_box in enumerate(shifted_tsp_boxes): # shuffled_tsp_box = shuffled_tsp_box[(shuffled_tsp_box < trange[0]) & (shuffled_tsp_box > trange[1])] # shifted_spikex_boxes.append(interpolater_x(shuffled_tsp_box)) # shifted_spikey_boxes.append(interpolater_y(shuffled_tsp_box)) # shifted_spikeangle_boxes.append(interpolater_angle(shuffled_tsp_box)) # rejected, _ = tunner.rejection_singlefield(shuffled_tsp_box, all_t_list[boxidx], all_passangles_list[boxidx]) # shifted_rejected_boxes.append(rejected) # shuffled_passdf = pd.DataFrame({'x':all_x_list, 'y':all_y_list, 't':all_t_list, 'angle':all_passangles_list, # 'chunked':all_chunked_list, 'rejected':shifted_rejected_boxes, # neuro_keys_dict['tsp']:shifted_tsp_boxes, neuro_keys_dict['spikex']:shifted_spikex_boxes, # neuro_keys_dict['spikey']:shifted_spikey_boxes, neuro_keys_dict['spikeangle']:shifted_spikeangle_boxes}) # shuffled_accept_mask = (~shuffled_passdf['rejected']) & (shuffled_passdf['chunked'] < 2) # shuffled_passdf['excluded_for_precess'] = ~shuffled_accept_mask # shuf_precessdf, shuf_precessangle, shuf_precessR, _ = get_single_precessdf(shuffled_passdf, precesser, precess_filter, neuro_keys_dict, occ_bins.min(), # field_d=field_d, kappa=kappa_precess, bins=None) # # if (shuf_precessdf.shape[0] > 0) and (shuf_precessR is not None): # all_shuffled_R[shufi] = shuf_precessR # shufi += 1 # else: # fail_times += 1 # precess_R_pval = 1 - np.nanmean(precess_R > all_shuffled_R) # precess_shuffletime = time.time()-tmpt # print('Shuf %0.4f - %0.4f - %0.4f, Target %0.4f'%(np.quantile(all_shuffled_R, 0.25), np.quantile(all_shuffled_R, 0.5), np.quantile(all_shuffled_R, 0.75), precess_R)) # print('Best precess=%0.2f, pval=%0.5f, time=%0.2f, failed=%d, repeated=%d'%(precess_angle, precess_R_pval, precess_shuffletime, fail_times, repeated_times)) precess_R_pval = 1 else: numpass_at_precess = None precess_angle_low = None numpass_at_precess_low = None precess_R_pval = None fielddf_dict['ca'].append(ca) fielddf_dict['num_spikes'].append(num_spikes) fielddf_dict['field_area'].append(field_area) fielddf_dict['field_bound'].append(xyval) fielddf_dict['border'].append(border) fielddf_dict['aver_rate'].append(aver_rate) fielddf_dict['peak_rate'].append(peak_rate) fielddf_dict['rate_angle'].append(rate_angle) fielddf_dict['rate_R'].append(rate_R) fielddf_dict['rate_R_pval'].append(rate_R_pval) fielddf_dict['minocc'].append(minocc) fielddf_dict['precess_df'].append(fitted_precessdf) fielddf_dict['precess_angle'].append(precess_angle) fielddf_dict['precess_angle_low'].append(precess_angle_low) fielddf_dict['precess_R'].append(precess_R) fielddf_dict['precess_R_pval'].append(precess_R_pval) fielddf_dict['numpass_at_precess'].append(numpass_at_precess) fielddf_dict['numpass_at_precess_low'].append( numpass_at_precess_low) # tmpdf = pd.DataFrame(dict(ca=fielddf_dict['ca'], pval=fielddf_dict['precess_R_pval'])) # for catmp, cadftmp in tmpdf.groupby('ca'): # nonnan_count = cadftmp[~cadftmp['pval'].isna()].shape[0] # if nonnan_count ==0: # nonnan_count = 1 # sig_count = cadftmp[cadftmp['pval'] < 0.05].shape[0] # print('%s: ALL %d/%d=%0.2f, Among Precess %d/%d=%0.2f'%(catmp, sig_count, cadftmp.shape[0], # sig_count/cadftmp.shape[0], sig_count, # nonnan_count, sig_count/nonnan_count)) fielddf_raw = pd.DataFrame(fielddf_dict) # Assign field ids within ca fielddf_raw['fieldid_ca'] = 0 for ca, cadf in fielddf_raw.groupby('ca'): fieldidca = np.arange(cadf.shape[0]) + 1 index_ca = cadf.index fielddf_raw.loc[index_ca, 'fieldid_ca'] = fieldidca fielddf_raw.to_pickle(save_pth) return fielddf_raw
from scipy.interpolate import interp1d from common.utils import load_pickle from common.comput_utils import IndataProcessor rawdf_pth = 'data/emankindata_processed_withwave.pickle' df = load_pickle(rawdf_pth) numspikes_dict = dict(CA1=[], CA2=[], CA3=[]) num_trials = df.shape[0] for ntrial in range(num_trials): for ca in ['CA%d' % (i + 1) for i in range(3)]: field_df = df.loc[ntrial, ca + 'fields'] indata = df.loc[ntrial, ca + 'indata'] num_fields = field_df.shape[0] if indata.shape[0] < 1: continue tunner = IndataProcessor(indata, vthresh=0, sthresh=-5, minpasstime=0) interpolater_angle = interp1d(tunner.t, tunner.angle) interpolater_x = interp1d(tunner.t, tunner.x) interpolater_y = interp1d(tunner.t, tunner.y) for nf in range(num_fields): print('\r%d/%d trial, %s, %d/%d field' % (ntrial, num_trials, ca, nf, num_fields), flush=True, end='') mask, pf, xyval = field_df.loc[nf, ['mask', 'pf', 'xyval']] tsp = field_df.loc[nf, 'xytsp']['tsp'] xaxis, yaxis = pf['X'][:, 0], pf['Y'][0, :] # Construct passes (segment & chunk) tok, idin = tunner.get_idin(mask, xaxis, yaxis) passdf = tunner.construct_singlefield_passdf( tok, tsp, interpolater_x, interpolater_y, interpolater_angle)
def pair_field_preprocess_Romani(simdata, save_pth, radius=2, vthresh=2, sthresh=80, NShuffles=200): pairdata_dict = dict( neuron1id=[], neuron2id=[], neuron1pos=[], neuron2pos=[], neurondist=[], # overlap is calculated afterward border1=[], border2=[], aver_rate1=[], aver_rate2=[], aver_rate_pair=[], com1=[], com2=[], rate_angle1=[], rate_angle2=[], rate_anglep=[], rate_R1=[], rate_R2=[], rate_Rp=[], num_spikes1=[], num_spikes2=[], num_spikes_pair=[], phaselag_AB=[], phaselag_BA=[], corr_info_AB=[], corr_info_BA=[], rate_AB=[], rate_BA=[], corate=[], pair_rate=[], kld=[], rate_R_pvalp=[], precess_df1=[], precess_angle1=[], precess_R1=[], precess_df2=[], precess_angle2=[], precess_R2=[], numpass_at_precess1=[], numpass_at_precess2=[], precess_dfp=[]) Indata, SpikeData, NeuronPos = simdata['Indata'], simdata[ 'SpikeData'], simdata['NeuronPos'] wave = dict(tax=Indata['t'].to_numpy(), phase=Indata['phase'].to_numpy(), theta=np.ones(Indata.shape[0])) subsample_fraction = 0.25 # setting minpasstime = 0.4 minspiketresh = 14 default_T = 1 / 10 aedges = np.linspace(-np.pi, np.pi, 36) abind = aedges[1] - aedges[0] sp_binwidth = 2 * np.pi / 16 precesser = PrecessionProcesser(wave=wave) precess_filter = PrecessionFilter() kappa_precess = 1 aedges_precess = np.linspace(-np.pi, np.pi, 6) field_d = radius * 2 # Precomputation tunner = IndataProcessor(Indata, vthresh=vthresh, sthresh=sthresh, minpasstime=minpasstime) interpolater_angle = interp1d(tunner.t, tunner.angle) interpolater_x = interp1d(tunner.t, tunner.x) interpolater_y = interp1d(tunner.t, tunner.y) all_maxt, all_mint = tunner.t.max(), tunner.t.min() trange = (all_maxt, all_mint) dt = tunner.t[1] - tunner.t[0] precesser.set_trange(trange) # Combination of pairs np.random.seed(0) sampled_idx_all = np.random.choice(NeuronPos.shape[0], 200, replace=False).astype(int) samples1 = sampled_idx_all[0:80] samples2 = sampled_idx_all[80:160] total_num = samples1.shape[0] * samples2.shape[0] progress = 0 for i in samples1: for j in samples2: print( '%d/%d (%d,%d): sample %d' % (progress, total_num, i, j, len(pairdata_dict['neuron1pos']))) # Distance neu1x, neu1y = NeuronPos.iloc[i] neu2x, neu2y = NeuronPos.iloc[j] neurondist = np.sqrt((neu1x - neu2x)**2 + (neu1y - neu2y)**2) # Get tok tok1 = np.sqrt((tunner.x - neu1x)**2 + (tunner.y - neu1y)**2) < radius tok2 = np.sqrt((tunner.x - neu2x)**2 + (tunner.y - neu2y)**2) < radius tok_union = tok1 | tok2 tok_intersect = tok1 & tok2 if np.sum(tok_intersect) < 10: # anything larger than 0 will do progress += 1 continue # Get spike indexes + subsample spdf1 = SpikeData[SpikeData['neuronidx'] == i].reset_index( drop=True) spdf2 = SpikeData[SpikeData['neuronidx'] == j].reset_index( drop=True) tidxsp1, tidxsp2 = spdf1['tidxsp'].to_numpy().astype( int), spdf2['tidxsp'].to_numpy().astype(int) np.random.seed(i * j) sampled_tidxsp1 = np.random.choice(tidxsp1.shape[0] - 1, int(tidxsp1.shape[0] * subsample_fraction), replace=False) sampled_tidxsp1.sort() tidxsp1 = tidxsp1[sampled_tidxsp1] np.random.seed(i * j + 1) sampled_tidxsp2 = np.random.choice(tidxsp2.shape[0] - 1, int(tidxsp2.shape[0] * subsample_fraction), replace=False) sampled_tidxsp2.sort() tidxsp2 = tidxsp2[sampled_tidxsp2] tsp1 = tunner.t[tidxsp1] tsp2 = tunner.t[tidxsp2] # Condition: Paired spikes exist tsp_diff = pair_diff(tsp1, tsp2) spok = np.sum(np.abs(tsp_diff) < default_T) if spok < minspiketresh: progress = progress + 1 continue # Check border border1 = check_border_sim(neu1x, neu1y, radius, (0, 2 * np.pi)) border2 = check_border_sim(neu2x, neu2y, radius, (0, 2 * np.pi)) # Construct passes (segment & chunk) for field 1 and 2 passdf1 = tunner.construct_singlefield_passdf( tok1, tsp1, interpolater_x, interpolater_y, interpolater_angle) passdf2 = tunner.construct_singlefield_passdf( tok2, tsp2, interpolater_x, interpolater_y, interpolater_angle) # allchunk_df1 = passdf1[(~passdf1['rejected']) & (passdf1['chunked']<2)].reset_index(drop=True) # allchunk_df2 = passdf2[(~passdf2['rejected']) & (passdf2['chunked']<2)].reset_index(drop=True) allchunk_df1 = passdf1[(~passdf1['rejected'])].reset_index( drop=True) allchunk_df2 = passdf2[(~passdf2['rejected'])].reset_index( drop=True) if (allchunk_df1.shape[0] < 1) or (allchunk_df2.shape[0] < 1): continue x1list, y1list, angle1list = allchunk_df1['x'].to_list( ), allchunk_df1['y'].to_list(), allchunk_df1['angle'].to_list() t1list, tsp1list = allchunk_df1['t'].to_list( ), allchunk_df1['tsp'].to_list() x2list, y2list, angle2list = allchunk_df2['x'].to_list( ), allchunk_df2['y'].to_list(), allchunk_df2['angle'].to_list() t2list, tsp2list = allchunk_df2['t'].to_list( ), allchunk_df2['tsp'].to_list() if (len(t1list) < 1) or (len(t2list) < 1) or ( len(tsp1list) < 1) or (len(tsp2list) < 1): continue x1, x2 = np.concatenate(x1list), np.concatenate(x2list) y1, y2 = np.concatenate(y1list), np.concatenate(y2list) hd1, hd2 = np.concatenate(angle1list), np.concatenate(angle2list) pos1, pos2 = np.stack([x1, y1]).T, np.stack([x2, y2]).T tsp1, tsp2 = np.concatenate(tsp1list), np.concatenate(tsp2list) xsp1, xsp2 = np.concatenate( allchunk_df1['spikex'].to_list()), np.concatenate( allchunk_df2['spikex'].to_list()) ysp1, ysp2 = np.concatenate( allchunk_df1['spikey'].to_list()), np.concatenate( allchunk_df2['spikey'].to_list()) possp1, possp2 = np.stack([xsp1, ysp1]).T, np.stack([xsp2, ysp2]).T hdsp1 = np.concatenate(allchunk_df1['spikeangle'].to_list()) hdsp2 = np.concatenate(allchunk_df2['spikeangle'].to_list()) nspks1, nspks2 = tsp1.shape[0], tsp2.shape[0] # Rates aver_rate1 = nspks1 / (x1.shape[0] * dt) peak_rate1 = None aver_rate2 = nspks2 / (x2.shape[0] * dt) peak_rate2 = None # Directionality occbins1, _ = np.histogram(hd1, bins=aedges) spbins1, _ = np.histogram(hdsp1, bins=aedges) mlmer1 = DirectionerMLM(pos1, hd1, dt=dt, sp_binwidth=sp_binwidth, a_binwidth=abind) rate_angle1, rate_R1, normprob1_mlm = mlmer1.get_directionality( possp1, hdsp1) normprob1_mlm[np.isnan(normprob1_mlm)] = 0 occbins2, _ = np.histogram(hd2, bins=aedges) spbins2, _ = np.histogram(hdsp2, bins=aedges) mlmer2 = DirectionerMLM(pos2, hd2, dt=dt, sp_binwidth=sp_binwidth, a_binwidth=abind) rate_angle2, rate_R2, normprob2_mlm = mlmer2.get_directionality( possp2, hdsp2) normprob2_mlm[np.isnan(normprob2_mlm)] = 0 neuro_keys_dict = dict(tsp='tsp', spikev='spikev', spikex='spikex', spikey='spikey', spikeangle='spikeangle') # Precession1 & Post-hoc exclusion for 1st field accept_mask1 = (~passdf1['rejected']) & (passdf1['chunked'] < 2) passdf1['excluded_for_precess'] = ~accept_mask1 precessdf1, precessangle1, precessR1, _ = get_single_precessdf( passdf1, precesser, precess_filter, neuro_keys_dict, field_d=field_d, kappa=kappa_precess, bins=None) fitted_precessdf1 = precessdf1[precessdf1['fitted']].reset_index( drop=True) if (precessangle1 is not None) and (fitted_precessdf1.shape[0] > 0): # Post-hoc precession exclusion _, _, postdoc_dens1 = compute_precessangle( pass_angles=fitted_precessdf1['mean_anglesp'].to_numpy(), pass_nspikes=fitted_precessdf1['pass_nspikes'].to_numpy(), precess_mask=fitted_precessdf1['precess_exist'].to_numpy(), kappa=None, bins=aedges_precess) (_, passbins_p1, passbins_np1, _) = postdoc_dens1 all_passbins1 = passbins_p1 + passbins_np1 numpass_at_precess1 = get_numpass_at_angle( target_angle=precessangle1, aedge=aedges_precess, all_passbins=all_passbins1) else: numpass_at_precess1 = None # Precession2 & Post-hoc exclusion for 2nd field accept_mask2 = (~passdf2['rejected']) & (passdf2['chunked'] < 2) passdf2['excluded_for_precess'] = ~accept_mask2 precessdf2, precessangle2, precessR2, _ = get_single_precessdf( passdf2, precesser, precess_filter, neuro_keys_dict, field_d=field_d, kappa=kappa_precess, bins=None) fitted_precessdf2 = precessdf2[precessdf2['fitted']].reset_index( drop=True) if (precessangle2 is not None) and (fitted_precessdf2.shape[0] > 0): # Post-hoc precession exclusion _, _, postdoc_dens2 = compute_precessangle( pass_angles=fitted_precessdf2['mean_anglesp'].to_numpy(), pass_nspikes=fitted_precessdf2['pass_nspikes'].to_numpy(), precess_mask=fitted_precessdf2['precess_exist'].to_numpy(), kappa=None, bins=aedges_precess) (_, passbins_p2, passbins_np2, _) = postdoc_dens2 all_passbins2 = passbins_p2 + passbins_np2 numpass_at_precess2 = get_numpass_at_angle( target_angle=precessangle2, aedge=aedges_precess, all_passbins=all_passbins2) else: numpass_at_precess2 = None # # Paired field processing field_d_union = radius * 2 pairedpasses = tunner.construct_pairfield_passdf( tok_union, tok1, tok2, tsp1, tsp2, interpolater_x, interpolater_y, interpolater_angle) phase_finder = ThetaEstimator(0.005, 0.3, [5, 12]) AB_tsp1_list, BA_tsp1_list = [], [] AB_tsp2_list, BA_tsp2_list = [], [] nspikes_AB_list, nspikes_BA_list = [], [] duration_AB_list, duration_BA_list = [], [] t_all = [] passangles_all, x_all, y_all = [], [], [] paired_tsp_list = [] # accepted_df = pairedpasses[(~pairedpasses['rejected']) & (pairedpasses['chunked']<2)].reset_index(drop=True) accepted_df = pairedpasses[( ~pairedpasses['rejected'])].reset_index(drop=True) for npass in range(accepted_df.shape[0]): # Get data t, tsp1, tsp2 = accepted_df.loc[npass, ['t', 'tsp1', 'tsp2']] x, y, pass_angles, v, direction = accepted_df.loc[ npass, ['x', 'y', 'angle', 'v', 'direction']] duration = t.max() - t.min() # Find paired spikes pairidx1, pairidx2 = find_pair_times(tsp1, tsp2) paired_tsp1, paired_tsp2 = tsp1[pairidx1], tsp2[pairidx2] if (paired_tsp1.shape[0] < 1) and (paired_tsp2.shape[0] < 1): continue paired_tsp_eachpass = np.concatenate( [paired_tsp1, paired_tsp2]) paired_tsp_list.append(paired_tsp_eachpass) passangles_all.append(pass_angles) x_all.append(x) y_all.append(y) t_all.append(t) if direction == 'A->B': AB_tsp1_list.append(tsp1) AB_tsp2_list.append(tsp2) nspikes_AB_list.append(tsp1.shape[0] + tsp2.shape[0]) duration_AB_list.append(duration) elif direction == 'B->A': BA_tsp1_list.append(tsp1) BA_tsp2_list.append(tsp2) nspikes_BA_list.append(tsp1.shape[0] + tsp2.shape[0]) duration_BA_list.append(duration) # Phase lags thetaT_AB, phaselag_AB, corr_info_AB = phase_finder.find_theta_isi_hilbert( AB_tsp1_list, AB_tsp2_list) thetaT_BA, phaselag_BA, corr_info_BA = phase_finder.find_theta_isi_hilbert( BA_tsp1_list, BA_tsp2_list) # Pair precession neuro_keys_dict1 = dict(tsp='tsp1', spikev='spike1v', spikex='spike1x', spikey='spike1y', spikeangle='spike1angle') neuro_keys_dict2 = dict(tsp='tsp2', spikev='spike2v', spikex='spike2x', spikey='spike2y', spikeangle='spike2angle') accept_mask = (~pairedpasses['rejected']) & ( pairedpasses['chunked'] < 2) & ( (pairedpasses['direction'] == 'A->B') | (pairedpasses['direction'] == 'B->A')) pairedpasses['excluded_for_precess'] = ~accept_mask precess_dfp = precesser.get_single_precession(pairedpasses, neuro_keys_dict1, field_d_union, tag='1') precess_dfp = precesser.get_single_precession(precess_dfp, neuro_keys_dict2, field_d_union, tag='2') precess_dfp = precess_filter.filter_pair(precess_dfp) fitted_precess_dfp = precess_dfp[ precess_dfp['fitted1'] & precess_dfp['fitted2']].reset_index(drop=True) # Paired spikes if (len(paired_tsp_list) == 0) or (len(passangles_all) == 0): continue hd_pair = np.concatenate(passangles_all) x_pair, y_pair = np.concatenate(x_all), np.concatenate(y_all) pos_pair = np.stack([x_pair, y_pair]).T paired_tsp = np.concatenate(paired_tsp_list) paired_tsp = paired_tsp[(paired_tsp <= all_maxt) & (paired_tsp >= all_mint)] if paired_tsp.shape[0] < 1: continue num_spikes_pair = paired_tsp.shape[0] hdsp_pair = interpolater_angle(paired_tsp) xsp_pair = interpolater_x(paired_tsp) ysp_pair = interpolater_y(paired_tsp) possp_pair = np.stack([xsp_pair, ysp_pair]).T aver_rate_pair = num_spikes_pair / (x_pair.shape[0] * dt) # Pair Directionality occbinsp, _ = np.histogram(hd_pair, bins=aedges) spbinsp, _ = np.histogram(hdsp_pair, bins=aedges) mlmer_pair = DirectionerMLM(pos_pair, hd_pair, dt, sp_binwidth, abind) rate_anglep, rate_Rp, normprobp_mlm = mlmer_pair.get_directionality( possp_pair, hdsp_pair) normprobp_mlm[np.isnan(normprobp_mlm)] = 0 # Time shift shuffling rate_R_pvalp = timeshift_shuffle_exp_wrapper( paired_tsp_list, t_all, rate_Rp, NShuffles, mlmer_pair, interpolater_x, interpolater_y, interpolater_angle, trange) # Rates with np.errstate(divide='ignore', invalid='ignore'): # None means no sample rate_AB = np.sum(nspikes_AB_list) / np.sum(duration_AB_list) rate_BA = np.sum(nspikes_BA_list) / np.sum(duration_BA_list) corate = np.sum(nspikes_AB_list + nspikes_BA_list) / np.sum(duration_AB_list + duration_BA_list) pair_rate = num_spikes_pair / np.sum(duration_AB_list + duration_BA_list) # KLD kld = calc_kld(normprob1_mlm, normprob2_mlm, normprobp_mlm) pairdata_dict['neuron1id'].append(i) pairdata_dict['neuron2id'].append(j) pairdata_dict['neuron1pos'].append(NeuronPos.iloc[i].to_numpy()) pairdata_dict['neuron2pos'].append(NeuronPos.iloc[j].to_numpy()) pairdata_dict['neurondist'].append(neurondist) pairdata_dict['border1'].append(border1) pairdata_dict['border2'].append(border2) pairdata_dict['aver_rate1'].append(aver_rate1) pairdata_dict['aver_rate2'].append(aver_rate2) pairdata_dict['aver_rate_pair'].append(aver_rate_pair) pairdata_dict['com1'].append(NeuronPos.iloc[i].to_numpy()) pairdata_dict['com2'].append(NeuronPos.iloc[j].to_numpy()) pairdata_dict['rate_angle1'].append(rate_angle1) pairdata_dict['rate_angle2'].append(rate_angle2) pairdata_dict['rate_anglep'].append(rate_anglep) pairdata_dict['rate_R1'].append(rate_R1) pairdata_dict['rate_R2'].append(rate_R2) pairdata_dict['rate_Rp'].append(rate_Rp) pairdata_dict['num_spikes1'].append(nspks1) pairdata_dict['num_spikes2'].append(nspks2) pairdata_dict['num_spikes_pair'].append(num_spikes_pair) pairdata_dict['phaselag_AB'].append(phaselag_AB) pairdata_dict['phaselag_BA'].append(phaselag_BA) pairdata_dict['corr_info_AB'].append(corr_info_AB) pairdata_dict['corr_info_BA'].append(corr_info_BA) pairdata_dict['rate_AB'].append(rate_AB) pairdata_dict['rate_BA'].append(rate_BA) pairdata_dict['corate'].append(corate) pairdata_dict['pair_rate'].append(pair_rate) pairdata_dict['kld'].append(kld) pairdata_dict['rate_R_pvalp'].append(rate_R_pvalp) pairdata_dict['precess_df1'].append(fitted_precessdf1) pairdata_dict['precess_angle1'].append(precessangle1) pairdata_dict['precess_R1'].append(precessR1) pairdata_dict['precess_df2'].append(fitted_precessdf2) pairdata_dict['precess_angle2'].append(precessangle2) pairdata_dict['precess_R2'].append(precessR2) pairdata_dict['numpass_at_precess1'].append(numpass_at_precess1) pairdata_dict['numpass_at_precess2'].append(numpass_at_precess2) pairdata_dict['precess_dfp'].append(fitted_precess_dfp) progress = progress + 1 pairdata = pd.DataFrame(pairdata_dict) # Convert distance to overlap dist_range = pairdata['neurondist'].max() - pairdata['neurondist'].min() pairdata['overlap'] = (pairdata['neurondist'].max() - pairdata['neurondist']) / dist_range pairdata.to_pickle(save_pth) pairdata = append_extrinsicity(pairdata) pairdata.to_pickle(save_pth) return pairdata
def single_field_preprocess_Romani(simdata, radius=2, vthresh=2, sthresh=80, NShuffles=200, save_pth=None): """ Parameters ---------- Indata SpikeData NeuronPos radius vthresh : float Default = 2. Determined by the ratio between avergae speed in Emily's data and the target vthresh 5 there. sthresh : float Default = 80. Determined by the same percentile (10%) of passes excluded in Emily's data (sthresh = 3 there). It is different since straightrank depends on sampling frequency. It is 1ms in sumulation. subsample_fraction : float The fraction that the spikes would be subsampled. Returns ------- """ subsample_fraction = 0.4 datadict = dict(num_spikes=[], border=[], aver_rate=[], rate_angle=[], rate_R=[], rate_R_pval=[], minocc=[], precess_df=[], precess_angle=[], precess_angle_low=[], precess_R=[], numpass_at_precess=[], numpass_at_precess_low=[]) Indata, SpikeData, NeuronPos = simdata['Indata'], simdata[ 'SpikeData'], simdata['NeuronPos'] aedges = np.linspace(-np.pi, np.pi, 36) abind = aedges[1] - aedges[0] sp_binwidth = 2 * np.pi / 16 tunner = IndataProcessor(Indata, vthresh=vthresh, sthresh=sthresh, minpasstime=0.4) wave = dict(tax=Indata['t'].to_numpy(), phase=Indata['phase'].to_numpy(), theta=np.ones(Indata.shape[0])) interpolater_angle = interp1d(tunner.t, tunner.angle) interpolater_x = interp1d(tunner.t, tunner.x) interpolater_y = interp1d(tunner.t, tunner.y) trange = (tunner.t.max(), tunner.t.min()) dt = tunner.t[1] - tunner.t[0] precesser = PrecessionProcesser(wave=wave) precesser.set_trange(trange) precess_filter = PrecessionFilter() lowspike_num = 13 kappa_precess = 1 aedges_precess = np.linspace(-np.pi, np.pi, 6) num_neurons = NeuronPos.shape[0] for nidx in range(num_neurons): print('%d/%d Neuron' % (nidx, num_neurons)) # Get spike indexes + subsample spdf = SpikeData[SpikeData['neuronidx'] == nidx].reset_index(drop=True) tidxsp = spdf['tidxsp'].to_numpy().astype(int) np.random.seed(nidx) sampled_tidxsp = np.random.choice(tidxsp.shape[0] - 1, int(tidxsp.shape[0] * subsample_fraction), replace=False) sampled_tidxsp.sort() tidxsp = tidxsp[sampled_tidxsp] tsp = Indata.loc[tidxsp, 't'].to_numpy() neuron_pos = NeuronPos.iloc[nidx].to_numpy() # Check border border = check_border_sim(neuron_pos[0], neuron_pos[1], radius, (0, 2 * np.pi)) # Construct passdf dist = np.sqrt((neuron_pos[0] - tunner.x)**2 + (neuron_pos[1] - tunner.y)**2) tok = dist < radius passdf = tunner.construct_singlefield_passdf(tok, tsp, interpolater_x, interpolater_y, interpolater_angle) # allchunk_df = passdf[(~passdf['rejected']) & (passdf['chunked']<2)].reset_index(drop=True) allchunk_df = passdf[(~passdf['rejected'])].reset_index(drop=True) # Get info from passdf and interpolate if allchunk_df.shape[0] < 1: continue all_x_list, all_y_list = allchunk_df['x'].to_list( ), allchunk_df['y'].to_list() all_t_list, all_passangles_list = allchunk_df['t'].to_list( ), allchunk_df['angle'].to_list() all_tsp_list, all_chunked_list = allchunk_df['tsp'].to_list( ), allchunk_df['chunked'].to_list() all_x = np.concatenate(all_x_list) all_y = np.concatenate(all_y_list) all_passangles = np.concatenate(all_passangles_list) all_tsp = np.concatenate(all_tsp_list) all_anglesp = np.concatenate(allchunk_df['spikeangle'].to_list()) xsp, ysp = np.concatenate( allchunk_df['spikex'].to_list()), np.concatenate( allchunk_df['spikey'].to_list()) pos = np.stack([all_x, all_y]).T possp = np.stack([xsp, ysp]).T # Average firing rate aver_rate = all_tsp.shape[0] / (all_x.shape[0] * dt) # Field's directionality num_spikes = all_tsp.shape[0] occ_bins, _ = np.histogram(all_passangles, bins=aedges) minocc = occ_bins.min() mlmer = DirectionerMLM(pos, all_passangles, dt, sp_binwidth=sp_binwidth, a_binwidth=abind) rate_angle, rate_R, norm_prob_mlm = mlmer.get_directionality( possp, all_anglesp) # Time shift shuffling for rate directionality rate_R_pval = timeshift_shuffle_exp_wrapper(all_tsp_list, all_t_list, rate_R, NShuffles, mlmer, interpolater_x, interpolater_y, interpolater_angle, trange) # Precession per pass neuro_keys_dict = dict(tsp='tsp', spikev='spikev', spikex='spikex', spikey='spikey', spikeangle='spikeangle') accept_mask = (~passdf['rejected']) & (passdf['chunked'] < 2) passdf['excluded_for_precess'] = ~accept_mask precessdf, precess_angle, precess_R, _ = get_single_precessdf( passdf, precesser, precess_filter, neuro_keys_dict, field_d=radius * 2, kappa=kappa_precess, bins=None) fitted_precessdf = precessdf[precessdf['fitted']].reset_index( drop=True) # Proceed only if precession exists if (precess_angle is not None) and (fitted_precessdf['precess_exist'].sum() > 0): # Post-hoc precession exclusion _, binR, postdoc_dens = compute_precessangle( pass_angles=fitted_precessdf['mean_anglesp'].to_numpy(), pass_nspikes=fitted_precessdf['pass_nspikes'].to_numpy(), precess_mask=fitted_precessdf['precess_exist'].to_numpy(), kappa=None, bins=aedges_precess) (_, passbins_p, passbins_np, _) = postdoc_dens all_passbins = passbins_p + passbins_np numpass_at_precess = get_numpass_at_angle( target_angle=precess_angle, aedge=aedges_precess, all_passbins=all_passbins) # Precession - low-spike passes ldf = fitted_precessdf[fitted_precessdf['pass_nspikes'] < lowspike_num] # 25% quantile if (ldf.shape[0] > 0) and (ldf['precess_exist'].sum() > 0): precess_angle_low, _, _ = compute_precessangle( pass_angles=ldf['mean_anglesp'].to_numpy(), pass_nspikes=ldf['pass_nspikes'].to_numpy(), precess_mask=ldf['precess_exist'].to_numpy(), kappa=kappa_precess, bins=None) _, _, postdoc_dens_low = compute_precessangle( pass_angles=ldf['mean_anglesp'].to_numpy(), pass_nspikes=ldf['pass_nspikes'].to_numpy(), precess_mask=ldf['precess_exist'].to_numpy(), kappa=None, bins=aedges_precess) (_, passbins_p_low, passbins_np_low, _) = postdoc_dens_low all_passbins_low = passbins_p_low + passbins_np_low numpass_at_precess_low = get_numpass_at_angle( target_angle=precess_angle_low, aedge=aedges_precess, all_passbins=all_passbins_low) else: precess_angle_low = None numpass_at_precess_low = None else: numpass_at_precess = None precess_angle_low = None numpass_at_precess_low = None datadict['num_spikes'].append(num_spikes) datadict['border'].append(border) datadict['aver_rate'].append(aver_rate) # datadict['rate_angle'].append(rate_angle) datadict['rate_R'].append(rate_R) datadict['rate_R_pval'].append(rate_R_pval) datadict['minocc'].append(minocc) datadict['precess_df'].append(precessdf) datadict['precess_angle'].append(precess_angle) datadict['precess_angle_low'].append(precess_angle_low) datadict['precess_R'].append(precess_R) datadict['numpass_at_precess'].append(numpass_at_precess) datadict['numpass_at_precess_low'].append(numpass_at_precess_low) datadf = pd.DataFrame(datadict) datadf.to_pickle(save_pth)