def plot_max_dff_valence(res, start_days, end_days, figure_path):
res = copy.copy(res)
# list_of_days = list(zip(start_days, end_days))
list_of_days = end_days
start_end_day_res = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
start_end_day_res = filter.filter(start_end_day_res,
{'odor_valence': ['CS+', 'CS-']})
_max_dff(start_end_day_res)
start_end_day_res = reduce.new_filter_reduce(
start_end_day_res,
filter_keys=['odor_valence', 'mouse'],
reduce_key='max_dff')
add_naive_learned(start_end_day_res, start_days, end_days)
ax_args_copy = ax_args.copy()
# ax_args_copy.update({'xticks':[res['DAQ_O_ON_F'][-1], res['DAQ_W_ON_F'][-1]], 'xticklabels':['ON', 'US'],
# 'ylim':[0, .2]})
nMice = len(np.unique(res['mouse']))
# colors = ['Green'] * nMice + ['Red'] * nMice
# trace_args_copy = trace_args.copy()
# trace_args_copy.update({'linestyle':'--','alpha':.5, 'linewidth':.75})
plot.plot_results(start_end_day_res,
loop_keys='mouse',
x_key='odor_valence',
y_key='max_dff',
path=figure_path,
colors=['gray'] * 10,
legend=False,
fig_size=(2, 1.5))
def plot_overlap_water(res, start_days, end_days, figure_path):
ax_args_copy = overlap_ax_args.copy()
res = copy.copy(res)
mice = np.unique(res['mouse'])
res = filter.filter_days_per_mouse(res, days_per_mouse=end_days)
add_naive_learned(res, start_days, end_days)
ax_args_copy.update({'xlim': [-1, 2]})
y_keys = ['US/CS+', 'CS+/US']
summary_res = defaultdict(list)
for arg in y_keys:
_get_overlap_water(res, arg=arg)
new_res = reduce.new_filter_reduce(
res,
filter_keys=['mouse', 'day', 'odor_valence'],
reduce_key='Overlap')
new_res['Type'] = np.array([arg] * len(new_res['training_day']))
reduce.chain_defaultdicts(summary_res, new_res)
summary_res.pop('Overlap_sem')
summary_res.pop('Overlap_std')
summary_res = filter.filter(summary_res, {'odor_valence': 'CS+'})
mean_std_res = reduce.new_filter_reduce(summary_res,
filter_keys='Type',
reduce_key='Overlap')
types = np.unique(summary_res['Type'])
scatter_args_copy = scatter_args.copy()
scatter_args_copy.update({'s': 2, 'alpha': .6})
for i, type in enumerate(types):
reuse_arg = True
if i == 0:
reuse_arg = False
temp = filter.filter(summary_res, {'Type': type})
plot.plot_results(temp,
x_key='Type',
y_key='Overlap',
loop_keys='mouse',
colors=['Black'] * len(mice),
plot_function=plt.scatter,
path=figure_path,
plot_args=scatter_args_copy,
ax_args=ax_args_copy,
save=False,
reuse=reuse_arg,
fig_size=(1.5, 1.5),
rect=(.25, .25, .6, .6),
legend=False)
plot.plot_results(mean_std_res,
x_key='Type',
y_key='Overlap',
error_key='Overlap_sem',
path=figure_path,
plot_function=plt.errorbar,
plot_args=error_args,
ax_args=ax_args,
save=True,
reuse=True,
fig_size=(1.5, 1.5),
legend=False)
print(mean_std_res['Overlap'])
def plot_summary_water(res, start_days, end_days, figure_path):
ax_args_copy = ax_args.copy()
res = copy.copy(res)
get_responsive_cells(res)
list_of_days = list(zip(start_days, end_days))
mice = np.unique(res['mouse'])
start_end_day_res = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
add_naive_learned(start_end_day_res, start_days, end_days, 'a', 'b')
odor_list = ['US']
colors = ['Turquoise']
ax_args_copy.update({'xlim': [-1, 2]})
for i, odor in enumerate(odor_list):
plot.plot_results(start_end_day_res,
select_dict={'odor_standard': odor},
x_key='training_day',
y_key='Fraction Responsive',
loop_keys='mouse',
colors=[colors[i]] * len(mice),
path=figure_path,
plot_args=line_args,
ax_args=ax_args_copy,
fig_size=(1.6, 1.5),
legend=False)
before_csm = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'a',
'odor_standard': 'US'
})
after_csm = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'b',
'odor_standard': 'US'
})
from scipy.stats import ranksums, wilcoxon, kruskal
print('Before PT CS+: {}'.format(np.mean(
before_csm['Fraction Responsive'])))
print('After PT CS+: {}'.format(np.mean(after_csm['Fraction Responsive'])))
print('Wilcoxin:{}'.format(
wilcoxon(before_csm['Fraction Responsive'],
after_csm['Fraction Responsive'])))
def plot_overlap_odor(res,
start_days,
end_days,
delete_non_selective=False,
figure_path=None,
excitatory=True):
ax_args_copy = overlap_ax_args.copy()
res = copy.copy(res)
res = _get_overlap_odor(res, delete_non_selective)
list_of_days = list(zip(start_days, end_days))
mice = np.unique(res['mouse'])
start_end_day_res = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
start_end_day_res = reduce.new_filter_reduce(
start_end_day_res,
filter_keys=['mouse', 'day', 'condition'],
reduce_key='Overlap')
add_naive_learned(start_end_day_res, start_days, end_days)
filter.assign_composite(start_end_day_res,
loop_keys=['condition', 'training_day'])
odor_list = ['+:+', '-:-', '+:-']
colors = ['Green', 'Red', 'Gray']
name_str = '_E' if excitatory else '_I'
ax_args_copy.update({'xlim': [-1, 6]})
for i, odor in enumerate(odor_list):
save_arg = False
reuse_arg = True
if i == 0:
reuse_arg = False
if i == len(odor_list) - 1:
save_arg = True
temp = filter.filter(start_end_day_res, {'condition': odor})
name = ','.join([str(x) for x in start_days]) + '_' + ','.join(
[str(x) for x in end_days])
name += name_str
plot.plot_results(temp,
x_key='condition_training_day',
y_key='Overlap',
loop_keys='mouse',
colors=[colors[i]] * len(mice),
path=figure_path,
plot_args=line_args,
ax_args=ax_args_copy,
save=save_arg,
reuse=reuse_arg,
name_str=name,
fig_size=(2, 1.5),
legend=False)
b = filter.filter(temp, {'training_day': 'Learned'})
print(odor)
print(np.mean(b['Overlap']))
start_end_day_res = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
add_naive_learned(start_end_day_res,
start_days,
end_days,
str1='0',
str2='1')
start_end_day_res.pop('Overlap_sem', None)
summary_res = reduce.new_filter_reduce(start_end_day_res,
filter_keys='training_day',
reduce_key='Overlap')
ax_args_copy.update({
'xlim': [-1, 2],
'ylim': [0, .5],
'yticks': [0, .1, .2, .3, .4, .5]
})
plot.plot_results(summary_res,
x_key='training_day',
y_key='Overlap',
path=figure_path,
plot_args=bar_args,
ax_args=ax_args_copy,
plot_function=plt.bar,
fig_size=(2, 1.5),
legend=False,
reuse=False,
save=False)
plot.plot_results(summary_res,
x_key='training_day',
y_key='Overlap',
error_key='Overlap_sem',
path=figure_path,
plot_function=plt.errorbar,
plot_args=error_args,
ax_args=ax_args,
save=True,
reuse=True,
name_str=name_str)
before_odor = filter.filter(start_end_day_res,
filter_dict={
'training_day': '0',
'condition': '+:+'
})
after_odor = filter.filter(start_end_day_res,
filter_dict={
'training_day': '1',
'condition': '+:+'
})
before_csp = filter.filter(start_end_day_res,
filter_dict={
'training_day': '0',
'condition': '+:-'
})
after_csp = filter.filter(start_end_day_res,
filter_dict={
'training_day': '1',
'condition': '+:-'
})
before_csm = filter.filter(start_end_day_res,
filter_dict={
'training_day': '0',
'condition': '-:-'
})
after_csm = filter.filter(start_end_day_res,
filter_dict={
'training_day': '1',
'condition': '-:-'
})
from scipy.stats import ranksums, wilcoxon, kruskal
print('Before ++: {}'.format(np.mean(before_odor['Overlap'])))
print('After ++: {}'.format(np.mean(after_odor['Overlap'])))
print('Wilcoxin:{}'.format(
wilcoxon(before_odor['Overlap'], after_odor['Overlap'])))
print('Before +-: {}'.format(np.mean(before_csp['Overlap'])))
print('After +-: {}'.format(np.mean(after_csp['Overlap'])))
print('Wilcoxin:{}'.format(
wilcoxon(before_csp['Overlap'], after_csp['Overlap'])))
print('Before --: {}'.format(np.mean(before_csm['Overlap'])))
print('After --: {}'.format(np.mean(after_csm['Overlap'])))
print('Wilcoxin:{}'.format(
wilcoxon(before_csm['Overlap'], after_csm['Overlap'])))
def plot_summary_odor_pretraining(res,
start_days,
end_days,
arg_naive,
figure_path,
save,
excitatory=True):
ax_args_copy = ax_args.copy()
res = copy.copy(res)
list_of_days = list(zip(start_days, end_days))
mice = np.unique(res['mouse'])
start_end_day_res = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
get_responsive_cells(start_end_day_res)
if arg_naive:
day_start = filter.filter(start_end_day_res,
{'odor_standard': 'PT Naive'})
day_start['odor_standard'] = np.array(['PT CS+'] *
len(day_start['odor_standard']))
day_end = filter.filter_days_per_mouse(start_end_day_res,
days_per_mouse=end_days)
day_end = filter.filter(day_end, {'odor_standard': 'PT CS+'})
reduce.chain_defaultdicts(day_start, day_end)
start_end_day_res = day_start
else:
start_end_day_res = filter.exclude(start_end_day_res,
{'odor_standard': 'PT Naive'})
add_naive_learned(start_end_day_res, start_days, end_days, 'a', 'b')
filter.assign_composite(start_end_day_res,
loop_keys=['odor_standard', 'training_day'])
odor_list = ['PT CS+']
colors = ['Orange']
ax_args_copy = ax_args_copy.copy()
ax_args_copy.update({
'xlim': [-1, 10],
'ylim': [0, .4],
'yticks': [0, .1, .2, .3, .4]
})
for i, odor in enumerate(odor_list):
save_arg = False
reuse_arg = True
if i == 0:
reuse_arg = False
if save and i == len(odor_list) - 1:
save_arg = True
plot.plot_results(start_end_day_res,
select_dict={'odor_standard': odor},
x_key='odor_standard_training_day',
y_key='Fraction Responsive',
loop_keys='mouse',
colors=[colors[i]] * len(mice),
path=figure_path,
plot_args=line_args,
ax_args=ax_args_copy,
save=save_arg,
reuse=reuse_arg,
fig_size=(2.5, 1.5),
legend=False,
name_str='_E' if excitatory else '_I')
before_csm = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'a',
'odor_standard': 'PT CS+'
})
after_csm = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'b',
'odor_standard': 'PT CS+'
})
from scipy.stats import ranksums, wilcoxon, kruskal
print('Before PT CS+: {}'.format(np.mean(
before_csm['Fraction Responsive'])))
print('After PT CS+: {}'.format(np.mean(after_csm['Fraction Responsive'])))
from scipy.stats import sem
print('After PT CS+ STD: {}'.format(sem(after_csm['Fraction Responsive'])))
print('Wilcoxin:{}'.format(
wilcoxon(before_csm['Fraction Responsive'],
after_csm['Fraction Responsive'])))
def plot_summary_odor(res,
start_days,
end_days,
use_colors=True,
figure_path=None,
reuse=False,
excitatory=True):
ax_args_copy = ax_args.copy()
res = copy.copy(res)
get_responsive_cells(res)
list_of_days = list(zip(start_days, end_days))
mice = np.unique(res['mouse'])
start_end_day_res = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
add_naive_learned(start_end_day_res, start_days, end_days, 'a', 'b')
filter.assign_composite(start_end_day_res,
loop_keys=['odor_valence', 'training_day'])
start_end_day_res = reduce.new_filter_reduce(
start_end_day_res,
filter_keys=['training_day', 'mouse', 'odor_valence'],
reduce_key='Fraction Responsive')
odor_list = ['CS+', 'CS-']
if use_colors:
colors = ['Green', 'Red']
else:
colors = ['Black'] * 2
ax_args_copy = ax_args_copy.copy()
ax_args_copy.update({
'xlim': [-1, 8],
'ylim': [0, .4],
'yticks': [0, .1, .2, .3, .4]
})
name_str = '_E' if excitatory else '_I'
for i, odor in enumerate(odor_list):
save_arg = False
reuse_arg = True
if i == 0 and not reuse:
reuse_arg = False
if i == len(odor_list) - 1:
save_arg = True
plot.plot_results(start_end_day_res,
select_dict={'odor_valence': odor},
x_key='odor_valence_training_day',
y_key='Fraction Responsive',
loop_keys='mouse',
colors=[colors[i]] * len(mice),
path=figure_path,
plot_args=line_args,
ax_args=ax_args_copy,
save=save_arg,
reuse=reuse_arg,
fig_size=(2.5, 1.5),
legend=False,
name_str=','.join([str(x)
for x in start_days]) + name_str)
start_end_day_res = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
add_naive_learned(start_end_day_res, start_days, end_days, 'a', 'b')
filter.assign_composite(start_end_day_res,
loop_keys=['odor_valence', 'training_day'])
start_end_day_res = reduce.new_filter_reduce(
start_end_day_res,
filter_keys=['training_day', 'mouse', 'odor_standard'],
reduce_key='Fraction Responsive')
before_csp = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'a',
'odor_valence': 'CS+'
})
after_csp = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'b',
'odor_valence': 'CS+'
})
before_csm = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'a',
'odor_valence': 'CS-'
})
after_csm = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'b',
'odor_valence': 'CS-'
})
try:
from scipy.stats import ranksums, wilcoxon, kruskal
print('Before CS+: {}'.format(
np.mean(before_csp['Fraction Responsive'])))
print('After CS+: {}'.format(np.mean(
after_csp['Fraction Responsive'])))
print('Wilcoxin:{}'.format(
wilcoxon(before_csp['Fraction Responsive'],
after_csp['Fraction Responsive'])))
print('Before CS-: {}'.format(
np.mean(before_csm['Fraction Responsive'])))
print('After CS-: {}'.format(np.mean(
after_csm['Fraction Responsive'])))
print('Wilcoxin:{}'.format(
wilcoxon(before_csm['Fraction Responsive'],
after_csm['Fraction Responsive'])))
except:
print('stats didnt work')
def plot_responsive_difference_odor_and_water(res,
odor_start_days,
water_start_days,
end_days,
use_colors=True,
figure_path=None,
include_water=True,
normalize=False,
pt_start=None,
pt_learned=None,
average=True,
ylim=.22,
reuse_arg=False,
save_arg=True):
key = 'Change in Fraction Responsive'
if normalize:
key = 'Norm. Fraction Responsive'
def _helper(start_end_day_res):
combs, list_of_ixs = filter.retrieve_unique_entries(
start_end_day_res, ['mouse', 'odor_standard'])
for i, comb in enumerate(combs):
ixs = list_of_ixs[i]
assert len(ixs) == 2
if start_end_day_res['training_day'][0] == 'Naive':
ref = ixs[0]
test = ixs[1]
elif start_end_day_res['training_day'][0] == 'Learned':
ref = ixs[1]
test = ixs[0]
else:
raise ValueError('cannot find ref day')
if normalize:
start_end_day_res[key][test] = start_end_day_res['Fraction Responsive'][test] / \
start_end_day_res['Fraction Responsive'][ref]
start_end_day_res[key][ref] = 1
else:
start_end_day_res[key][test] = start_end_day_res['Fraction Responsive'][test] - \
start_end_day_res['Fraction Responsive'][ref]
start_end_day_res[key][ref] = 0
ax_args_copy = ax_args.copy()
res = copy.copy(res)
get_responsive_cells(res)
list_of_days = list(zip(odor_start_days, end_days))
mice = np.unique(res['mouse'])
res[key] = np.zeros_like(res['Fraction Responsive'])
start_end_day_res = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
start_end_day_res = filter.filter(
start_end_day_res, {'odor_valence': ['CS+', 'CS-', 'Naive']})
add_naive_learned(start_end_day_res, odor_start_days, end_days)
odors = ['CS+', 'CS-', 'Naive']
if 'PT CS+' in np.unique(res['odor_valence']):
odors = ['PT CS+'] + odors
list_of_days = list(zip(pt_start, pt_learned))
start_end_day_res_pt = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
start_end_day_res_pt = filter.filter(start_end_day_res_pt,
{'odor_valence': 'PT CS+'})
add_naive_learned(start_end_day_res_pt, pt_start, pt_learned)
reduce.chain_defaultdicts(start_end_day_res, start_end_day_res_pt)
if include_water:
odors += ['US']
list_of_days = list(zip(water_start_days, end_days))
start_end_day_res_water = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
start_end_day_res_water = filter.filter(start_end_day_res_water,
{'odor_valence': 'US'})
add_naive_learned(start_end_day_res_water, water_start_days, end_days)
reduce.chain_defaultdicts(start_end_day_res, start_end_day_res_water)
filter.assign_composite(start_end_day_res,
loop_keys=['odor_standard', 'training_day'])
if average:
start_end_day_res = reduce.new_filter_reduce(
start_end_day_res,
filter_keys=['odor_valence', 'mouse', 'training_day'],
reduce_key=key)
start_end_day_res.pop(key + '_sem')
_helper(start_end_day_res)
start_end_day_res = filter.filter(start_end_day_res,
{'training_day': 'Learned'})
summary_res = reduce.new_filter_reduce(start_end_day_res,
filter_keys='odor_valence',
reduce_key=key)
dict = {
'CS+': 'Green',
'CS-': 'Red',
'US': 'Turquoise',
'PT CS+': 'Orange',
'Naive': 'Gray'
}
if use_colors:
colors = [
dict[key] for key in np.unique(start_end_day_res['odor_valence'])
]
else:
colors = ['Black'] * 6
ax_args_copy = ax_args_copy.copy()
n_valence = len(np.unique(summary_res['odor_valence']))
ax_args_copy.update({
'xlim': [-.5, 3.5],
'ylim': [-ylim, ylim],
'yticks': [-.3, -.2, -.1, 0, .1, .2, .3]
})
if normalize:
ax_args_copy.update({
'xlim': [-.5, 3.5],
'ylim': [-.1, 1.5],
'yticks': [0, .5, 1, 1.5]
})
error_args_ = {
'fmt': '.',
'capsize': 2,
'elinewidth': 1,
'markersize': 2,
'alpha': .75
}
scatter_args_copy = scatter_args.copy()
scatter_args_copy.update({'s': 3})
for i, odor in enumerate(odors):
reuse = True
if i == 0:
reuse = reuse_arg
plot.plot_results(start_end_day_res,
loop_keys='odor_valence',
select_dict={'odor_valence': odor},
x_key='odor_valence',
y_key=key,
colors=[dict[odor]] * len(mice),
path=figure_path,
plot_args=scatter_args_copy,
plot_function=plt.scatter,
ax_args=ax_args_copy,
save=False,
reuse=reuse,
fig_size=(2, 1.5),
rect=(.25, .2, .6, .6),
legend=False,
name_str=','.join([str(x) for x in odor_start_days]))
if not normalize:
plt.plot(plt.xlim(), [0, 0], '--', color='gray', linewidth=1, alpha=.5)
plot.plot_results(summary_res,
x_key='odor_valence',
y_key=key,
error_key=key + '_sem',
colors='black',
path=figure_path,
plot_args=error_args_,
plot_function=plt.errorbar,
ax_args=ax_args_copy,
save=save_arg,
reuse=True,
fig_size=(2, 1.5),
legend=False)
def plot_summary_odor_and_water(res,
odor_start_days,
water_start_days,
end_days,
use_colors=True,
excitatory=True,
arg='odor_valence',
figure_path=None):
include_water = True
ax_args_copy = ax_args.copy()
res = copy.copy(res)
get_responsive_cells(res)
mice = np.unique(res['mouse'])
list_of_days = list(zip(odor_start_days, end_days))
start_end_day_res = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
start_end_day_res = filter.exclude(start_end_day_res,
{'odor_valence': 'US'})
add_naive_learned(start_end_day_res, odor_start_days, end_days, 'a', 'b')
if include_water:
list_of_days = list(zip(water_start_days, end_days))
start_end_day_res_water = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
start_end_day_res_water = filter.filter(start_end_day_res_water,
{'odor_valence': 'US'})
add_naive_learned(start_end_day_res_water, water_start_days, end_days,
'a', 'b')
reduce.chain_defaultdicts(start_end_day_res, start_end_day_res_water)
ax_args_copy = ax_args_copy.copy()
if arg == 'odor_valence':
start_end_day_res = reduce.new_filter_reduce(
start_end_day_res,
filter_keys=['training_day', 'mouse', 'odor_valence'],
reduce_key='Fraction Responsive')
odor_list = ['CS+', 'CS-']
ax_args_copy.update({
'xlim': [-1, 6],
'ylim': [0, .6],
'yticks': [0, .1, .2, .3, .4, .5]
})
colors = ['Green', 'Red']
elif arg == 'naive':
arg = 'odor_valence'
start_end_day_res = reduce.new_filter_reduce(
start_end_day_res,
filter_keys=['training_day', 'mouse', 'odor_valence'],
reduce_key='Fraction Responsive')
odor_list = ['CS+']
ax_args_copy.update({
'xlim': [-1, 4],
'ylim': [0, .6],
'yticks': [0, .1, .2, .3, .4, .5]
})
colors = ['GoldenRod']
else:
odor_list = ['CS+1', 'CS+2', 'CS-1', 'CS-2']
colors = ['Green', 'Green', 'Red', 'Red']
ax_args_copy.update({
'xlim': [-1, 10],
'ylim': [0, .6],
'yticks': [0, .1, .2, .3, .4, .5]
})
filter.assign_composite(start_end_day_res, loop_keys=[arg, 'training_day'])
if not use_colors:
colors = ['Black'] * 4
name_str = '_E' if excitatory else '_I'
for i, odor in enumerate(odor_list):
reuse_arg = True
if i == 0:
reuse_arg = False
plot.plot_results(start_end_day_res,
select_dict={arg: odor},
x_key=arg + '_training_day',
y_key='Fraction Responsive',
loop_keys='mouse',
colors=[colors[i]] * len(mice),
path=figure_path,
plot_args=line_args,
ax_args=ax_args_copy,
save=False,
reuse=reuse_arg,
fig_size=(2.5, 1.5),
legend=False,
name_str=','.join([str(x) for x in odor_start_days]))
plot.plot_results(start_end_day_res,
select_dict={'odor_standard': 'US'},
x_key='training_day',
y_key='Fraction Responsive',
loop_keys='mouse',
colors=['Turquoise'] * len(mice),
path=figure_path,
plot_args=line_args,
ax_args=ax_args_copy,
fig_size=(1.6, 1.5),
legend=False,
reuse=True,
save=True,
name_str=name_str)
before_odor = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'a',
'odor_valence': ['CS+', 'CS-']
})
after_odor = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'b',
'odor_valence': ['CS+', 'CS-']
})
before_csp = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'a',
'odor_valence': 'CS+'
})
after_csp = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'b',
'odor_valence': 'CS+'
})
before_csm = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'a',
'odor_valence': 'CS-'
})
after_csm = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'b',
'odor_valence': 'CS-'
})
before_water = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'a',
'odor_valence': 'US'
})
after_water = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'b',
'odor_valence': 'US'
})
try:
from scipy.stats import ranksums, wilcoxon, kruskal
print('Before Odor: {}'.format(
np.mean(before_odor['Fraction Responsive'])))
print('After Odor: {}'.format(
np.mean(after_odor['Fraction Responsive'])))
print('Wilcoxin:{}'.format(
wilcoxon(before_odor['Fraction Responsive'],
after_odor['Fraction Responsive'])))
print('Before CS+: {}'.format(
np.mean(before_csp['Fraction Responsive'])))
print('After CS+: {}'.format(np.mean(
after_csp['Fraction Responsive'])))
print('Wilcoxin:{}'.format(
wilcoxon(before_csp['Fraction Responsive'],
after_csp['Fraction Responsive'])))
print('Before CS-: {}'.format(
np.mean(before_csm['Fraction Responsive'])))
print('After CS-: {}'.format(np.mean(
after_csm['Fraction Responsive'])))
print('Wilcoxin:{}'.format(
wilcoxon(before_csm['Fraction Responsive'],
after_csm['Fraction Responsive'])))
print('Before US: {}'.format(
np.mean(before_water['Fraction Responsive'])))
print('After US: {}'.format(np.mean(
after_water['Fraction Responsive'])))
print('Wilcoxin:{}'.format(
wilcoxon(before_water['Fraction Responsive'],
after_water['Fraction Responsive'])))
except:
print('stats didnt work')
def plot_responsive_difference_odor_and_water(res,
odor_start_days,
end_days,
use_colors=True,
figure_path=None,
normalize=False,
ylim=.6):
key = 'Change in Fraction'
if normalize:
key = 'Norm. Fraction'
def _helper(start_end_day_res):
combs, list_of_ixs = filter.retrieve_unique_entries(
start_end_day_res, ['mouse', 'odor_valence'])
for i, comb in enumerate(combs):
ixs = list_of_ixs[i]
assert len(ixs) == 2
if start_end_day_res['training_day'][0] == 'Naive':
ref = ixs[0]
test = ixs[1]
elif start_end_day_res['training_day'][0] == 'Learned':
ref = ixs[1]
test = ixs[0]
else:
raise ValueError('cannot find ref day')
if normalize:
start_end_day_res[key][test] = start_end_day_res['Fraction'][test] / \
start_end_day_res['Fraction'][ref]
start_end_day_res[key][ref] = 1
else:
start_end_day_res[key][test] = start_end_day_res['Fraction'][test] - \
start_end_day_res['Fraction'][ref]
start_end_day_res[key][ref] = 0
ax_args_copy = ax_args.copy()
res = get_compare_responsive_sig(res)
list_of_days = list(zip(odor_start_days, end_days))
mice = np.unique(res['mouse'])
res[key] = np.zeros_like(res['Fraction'])
start_end_day_res = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
start_end_day_res = filter.filter(start_end_day_res,
{'odor_valence': ['CS+', 'CS-']})
add_naive_learned(start_end_day_res, odor_start_days, end_days)
_helper(start_end_day_res)
start_end_day_res = filter.filter(start_end_day_res,
{'training_day': 'Learned'})
summary_res = reduce.new_filter_reduce(start_end_day_res,
filter_keys='odor_valence',
reduce_key=key)
dict = {'CS+': 'Green', 'CS-': 'Red'}
if use_colors:
colors = [
dict[key] for key in np.unique(start_end_day_res['odor_valence'])
]
else:
colors = ['Black'] * 6
ax_args_copy = ax_args_copy.copy()
n_valence = len(np.unique(summary_res['odor_valence']))
ax_args_copy.update({
'xlim': [-1, n_valence],
'ylim': [-ylim, ylim],
'yticks': np.arange(-1, 1, .2)
})
if normalize:
ax_args_copy.update({
'xlim': [-1, n_valence],
'ylim': [-.1, 1.5],
'yticks': [0, .5, 1, 1.5]
})
scatter_args_copy = scatter_args.copy()
scatter_args_copy.update({'s': 8})
odors = ['CS+', 'CS-']
for i, odor in enumerate(odors):
reuse = True
if i == 0:
reuse = False
plot.plot_results(start_end_day_res,
loop_keys='odor_valence',
select_dict={'odor_valence': odor},
x_key='odor_valence',
y_key=key,
colors=[dict[odor]] * len(mice),
path=figure_path,
plot_args=scatter_args_copy,
plot_function=plt.scatter,
ax_args=ax_args_copy,
save=False,
reuse=reuse,
fig_size=(2, 1.5),
legend=False,
name_str=','.join([str(x) for x in odor_start_days]))
if not normalize:
plt.plot(plt.xlim(), [0, 0], '--', color='gray', linewidth=1, alpha=.5)
plot.plot_results(summary_res,
x_key='odor_valence',
y_key=key,
error_key=key + '_sem',
colors='black',
path=figure_path,
plot_args=error_args,
plot_function=plt.errorbar,
ax_args=ax_args_copy,
save=True,
reuse=True,
fig_size=(2, 1.5),
legend=False)
def plot_consistency_within_day(res, start, end, shuffle, pretraining,
figure_path):
d = list(zip(start, end))
res_temp = filter.filter_days_per_mouse(res, d)
if pretraining:
res_temp = filter.filter(res_temp, {'odor_valence': ['PT CS+']})
else:
res_temp = filter.filter(res_temp, {'odor_valence': ['CS+', 'CS-']})
corr_res = _correlation(res_temp)
corr_res.pop('data')
analysis.add_naive_learned(corr_res, start, end, '0', '1')
res_ = reduce.new_filter_reduce(
corr_res,
filter_keys=['mouse', 'odor_standard', 'training_day'],
reduce_key='consistency_corrcoef')
res_.pop('consistency_corrcoef_sem')
filter.assign_composite(res_, loop_keys=['training_day', 'odor_valence'])
if shuffle:
s = '_shuffled'
else:
s = ''
ax_args_copy = ax_args.copy()
ax_args_copy.update({
'xlim': [-.5, 2.5],
'ylim': [0, .55],
'yticks': np.arange(0, 1.1, .1)
})
swarm_args_copy = swarm_args.copy()
if pretraining:
swarm_args_copy.update({'palette': ['gray', 'orange', 'green', 'red']})
else:
swarm_args_copy.update({'palette': ['gray', 'gray', 'green', 'red']})
ix = res_['training_day_odor_valence'] == '1_PT CS+'
res_['training_day_odor_valence'][ix] = '1_APT CS+'
plot.plot_results(res_,
x_key='training_day_odor_valence',
y_key='consistency_corrcoef',
path=figure_path,
plot_args=swarm_args_copy,
plot_function=sns.stripplot,
ax_args=ax_args_copy,
reuse=False,
save=False,
sort=True,
name_str=s)
summary = reduce.new_filter_reduce(res_,
filter_keys='training_day_odor_valence',
reduce_key='consistency_corrcoef')
plot.plot_results(summary,
x_key='training_day_odor_valence',
y_key='consistency_corrcoef',
error_key='consistency_corrcoef_sem',
colors='black',
path=figure_path,
plot_args=error_args,
plot_function=plt.errorbar,
save=True,
reuse=True,
legend=False,
name_str=s)
print(summary['consistency_corrcoef'])
ix_a = res_['training_day_odor_valence'] == '0_CS+'
ix_b = res_['training_day_odor_valence'] == '0_CS-'
ix_c = res_['training_day_odor_valence'] == '1_CS+'
ix_d = res_['training_day_odor_valence'] == '1_CS-'
a = res_['consistency_corrcoef'][ix_a]
b = res_['consistency_corrcoef'][ix_b]
c = res_['consistency_corrcoef'][ix_c]
d = res_['consistency_corrcoef'][ix_d]
from scipy.stats import ranksums, wilcoxon, kruskal
import scikit_posthocs
print(kruskal(a, b, c))
x = scikit_posthocs.posthoc_dunn(a=[a, b, c, d], p_adjust=None)
print(x)
def plot_power(res,
start_days,
end_days,
figure_path,
excitatory=True,
odor_valence=('CS+'),
naive=False,
colors_before={
'CS+': 'Green',
'CS-': 'Red'
},
colors_after={
'CS+': 'Green',
'CS-': 'Red'
},
ylim=[0, .1],
align=True,
pad=True):
res = copy.copy(res)
_power(res, excitatory)
if pad:
right_on = np.median(res['DAQ_O_ON_F'])
for i, odor_on in enumerate(res['DAQ_O_ON_F']):
if np.abs(odor_on - right_on) > 2:
diff = (right_on - odor_on).astype(int)
if diff > 0:
p = res['Power'][i]
newp = np.zeros_like(p)
newp[:diff] = p[0]
newp[diff:] = p[:-diff]
res['Power'][i] = newp
print('early odor time. mouse: {}, day: {}'.format(
res['mouse'][i], res['day'][i]))
else:
p = res['Power'][i]
newp = np.zeros_like(p)
newp[:diff] = p[-diff:]
newp[diff:] = p[-1]
res['Power'][i] = newp
print('late odor time. mouse: {}, day: {}'.format(
res['mouse'][i], res['day'][i]))
if align:
nF = [len(x) for x in res['Power']]
max_frame = np.max(nF)
for i, p in enumerate(res['Power']):
if len(p) < max_frame:
newp = np.zeros(max_frame)
newp[:len(p)] = p
newp[len(p):] = p[-1]
res['Power'][i] = newp
res['Time'][i] = np.arange(0, max_frame)
print('pad frames. mouse: {}, day: {}'.format(
res['mouse'][i], res['day'][i]))
list_of_days = list(zip(start_days, end_days))
start_end_day_res = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
add_naive_learned(start_end_day_res, start_days, end_days)
if naive:
start_end_day_res = filter.exclude(start_end_day_res, {
'odor_standard': 'PT CS+',
'training_day': 'Naive'
})
ix = start_end_day_res['odor_valence'] == 'PT Naive'
start_end_day_res['odor_valence'][ix] = 'PT CS+'
start_end_day_sum_res = reduce.new_filter_reduce(
start_end_day_res,
filter_keys=['training_day', 'odor_valence'],
reduce_key='Power')
ax_args_copy = trace_ax_args.copy()
if excitatory:
yticks = np.arange(0, .2, .05)
else:
yticks = -1 * np.arange(0, .2, .025)
ax_args_copy.update({
'xticks': [res['DAQ_O_ON_F'][-1], res['DAQ_W_ON_F'][-1]],
'xticklabels': ['ON', 'US'],
'ylim':
ylim,
'yticks':
yticks
})
colors_b = [colors_before[x] for x in odor_valence]
colors = [colors_after[x] for x in odor_valence]
strr = ','.join([str(x) for x in start_days]) + '_' + ','.join(
[str(x) for x in end_days])
if excitatory:
strr += '_E'
else:
strr += '_I'
plot.plot_results(start_end_day_sum_res,
select_dict={
'odor_valence': odor_valence,
'training_day': 'Naive'
},
x_key='Time',
y_key='Power',
loop_keys='odor_valence',
error_key='Power_sem',
path=figure_path,
plot_function=plt.fill_between,
plot_args=fill_args,
ax_args=ax_args_copy,
colors=colors_b,
fig_size=(2, 1.5),
rect=(.3, .2, .6, .6),
save=False)
plot.plot_results(start_end_day_sum_res,
select_dict={
'odor_valence': odor_valence,
'training_day': 'Naive'
},
x_key='Time',
y_key='Power',
loop_keys='odor_valence',
path=figure_path,
plot_args=trace_args,
ax_args=ax_args_copy,
colors=colors_b,
fig_size=(2, 1.5),
reuse=True,
save=False)
plot.plot_results(start_end_day_sum_res,
select_dict={
'odor_valence': odor_valence,
'training_day': 'Learned'
},
x_key='Time',
y_key='Power',
loop_keys='odor_valence',
error_key='Power_sem',
path=figure_path,
plot_function=plt.fill_between,
plot_args=fill_args,
ax_args=ax_args_copy,
colors=colors,
fig_size=(2, 1.5),
reuse=True,
save=False)
plot.plot_results(start_end_day_sum_res,
select_dict={
'odor_valence': odor_valence,
'training_day': 'Learned'
},
x_key='Time',
y_key='Power',
loop_keys='odor_valence',
path=figure_path,
plot_args=trace_args,
ax_args=ax_args_copy,
colors=colors,
fig_size=(2, 1.5),
reuse=True,
name_str=strr)
for i, x in enumerate(start_end_day_res['Power']):
on, off = [
start_end_day_res['DAQ_O_ON_F'][i],
start_end_day_res['DAQ_W_ON_F'][i]
]
y = np.max(x[on:off]) - np.min(x)
start_end_day_res['stat'].append(y)
start_end_day_res['stat'] = np.array(start_end_day_res['stat'])
for valence in odor_valence:
before_odor = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'Naive',
'odor_valence': valence
})
after_odor = filter.filter(start_end_day_res,
filter_dict={
'training_day': 'Learned',
'odor_valence': valence
})
try:
from scipy.stats import ranksums, wilcoxon, kruskal
print(before_odor['odor_valence'])
# print('Before: {}'.format(before_odor['stat']))
print('Before: {}'.format(np.mean(before_odor['stat'])))
# print('After: {}'.format(after_odor['stat']))
print('After: {}'.format(np.mean(after_odor['stat'])))
print('Wilcoxin:{}'.format(
wilcoxon(before_odor['stat'], after_odor['stat'])))
except:
print('stats didnt work')
return before_odor['stat'], after_odor['stat']
}
summary_res.pop('PCA Distance_std')
summary_res.pop('PCA Distance_sem')
summary_res = filter.filter(summary_res, filter_dict={'shuffle': 0})
if plot_cs:
select_dict = {'odor_valence': 'CS+'}
else:
select_dict = None
if condition.name == 'OFC_LONGTERM':
dt_learned_day, dt_last_day = get_days_per_mouse(
data_path, condition)
dt_learned_day = [3, 2, 2, 3]
filtered_res = filter.filter_days_per_mouse(
summary_res, list(zip(dt_learned_day, dt_last_day)))
analysis.add_naive_learned(filtered_res, dt_learned_day,
dt_last_day, 'Learned', 'Over-trained')
mean_std_res = reduce.new_filter_reduce(
filtered_res,
reduce_key='PCA Distance',
filter_keys=['training_day', 'odor_valence'])
plot.plot_results(filtered_res,
x_key='training_day',
y_key='PCA Distance',
loop_keys=['odor_valence', 'mouse'],
select_dict=select_dict,
colors=['Green'] * mice.size +
['Red'] * mice.size,
ax_args=summary_ax_args,
plot_function=plt.plot,
plot_args=summary_line_args,
path=figure_path,
def magnitude_histogram(res,
learned_days,
end_days,
use_colors=True,
figure_path=None,
reuse=False):
def _helper(res):
list_odor_on = res['DAQ_O_ON_F']
list_water_on = res['DAQ_W_ON_F']
list_of_dff = res['dff']
for i, dff in enumerate(list_of_dff):
s = list_odor_on[i]
e = list_water_on[i]
max = np.max(dff[:, s:e], axis=1)
res['max_dff'].append(max)
res['max_dff'] = np.array(res['max_dff'])
def _helper1(res):
for data in res['amplitude']:
res['max_dff'].append(data[data > 0])
res['max_dff'] = np.array(res['max_dff'])
res = copy.copy(res)
# list_of_days = list(zip(learned_days, end_days))
list_of_days = end_days
start_end_day_res = filter.filter_days_per_mouse(
res, days_per_mouse=list_of_days)
_helper(start_end_day_res)
add_naive_learned(start_end_day_res, learned_days, end_days)
filter.assign_composite(start_end_day_res,
loop_keys=['odor_standard', 'training_day'])
csp = filter.filter(start_end_day_res, filter_dict={'odor_valence': 'CS+'})
csm = filter.filter(start_end_day_res, filter_dict={'odor_valence': 'CS-'})
csp_data = np.hstack(csp['max_dff'].flat)
csm_data = np.hstack(csm['max_dff'].flat)
fig = plt.figure(figsize=(3, 2))
ax = fig.add_axes([.2, .2, .7, .7])
x_upper = 1.01
y_upper = .5
bins = 20
xrange = [0, x_upper]
yrange = [0, y_upper]
xticks = np.arange(0, x_upper, .2)
yticks = np.arange(0, y_upper, 3)
legends = ['CS+', 'CS-']
colors = ['green', 'red']
for i, data in enumerate([csp_data, csm_data]):
plt.hist(data,
bins=bins,
range=xrange,
density=True,
color=colors[i],
alpha=.5)
plt.legend(legends, loc=1, bbox_to_anchor=(1.05, .4), fontsize=5)
ax.set_xlabel('DF/F')
ax.set_ylabel('Fraction')
ax.set_xticks(xticks)
# ax.set_yticks(yticks)
plt.xlim(xrange)
# plt.ylim(yrange)
plt.show()
