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merge into: raab:chirp_bodylength
Branches Tags
raab:master raab:chirp_simulation raab:eventtriggeredchirps raab:chirp_bodylength raab:plot_event_timeline raab:behaviour
...
pull from: raab:eventtriggeredchirps
Branches Tags
raab:master raab:chirp_simulation raab:eventtriggeredchirps raab:chirp_bodylength raab:plot_event_timeline raab:behaviour

45 Commits
chirp_body ... eventtrigg

Author SHA1 Message Date
sprause
b48270f475 fix branches 2023-01-24 17:59:22 +01:00
sprause
d629948c52 adjusted kernel width slightly 2023-01-24 17:57:12 +01:00
sprause
1a0770f86f implemented individual recording plots 2023-01-24 17:57:12 +01:00
sprause
ad513f180e implemented plots for all recordings incl bootstrapping, std is over 9000 2023-01-24 17:57:12 +01:00
sprause
fda6821211 implemented recording loop 2023-01-24 17:57:12 +01:00
sprause
f68630974f corrected zorder in plots, q5 and physical problems okay 2023-01-24 17:57:12 +01:00
sprause
ced7f6f1ad something weird 2023-01-24 17:57:12 +01:00
sprause
a96a638c31 winner vs loser plot, winner physical strange 2023-01-24 17:57:12 +01:00
sprause
b1b9d9d3f1 implemented bootstrapping, q5 of physical still weird 2023-01-24 17:57:12 +01:00
sprause
5a0853a023 all event triggered chirps + chirprate with gaussian kernel 2023-01-24 17:57:12 +01:00
sprause
8b327fdcbf start implementing gammakernel 2023-01-24 17:57:12 +01:00
sprause
5d8c41c899 new plotfile for CTC and PTC 2023-01-24 17:57:12 +01:00
sprause
a8171814dd Fish loop needs debugging 2023-01-24 17:57:12 +01:00
sprause
7652663fb7 setup 2023-01-24 17:57:12 +01:00
weygoldt
a2960b87a4 Merge branch 'master' of https://whale.am28.uni-tuebingen.de/git/raab/GP2023_chirp_detection 2023-01-24 17:47:48 +01:00
weygoldt
23f5035a59 plot subset 2023-01-24 17:47:43 +01:00
wendtalexander
0aba24e6aa Merge branch 'master' of https://whale.am28.uni-tuebingen.de/git/raab/GP2023_chirp_detection 2023-01-24 17:38:42 +01:00
wendtalexander
39b46221bd plot_event_timepline 2023-01-24 17:38:39 +01:00
sprause
a264f96d1f adjusted kernel width slightly 2023-01-24 17:31:28 +01:00
weygoldt
dda0d645f3 Merge branch 'master' of https://whale.am28.uni-tuebingen.de/git/raab/GP2023_chirp_detection 2023-01-24 17:27:43 +01:00
weygoldt
70c4b012be new poster template 2023-01-24 17:27:37 +01:00
wendtalexander
ccc60a8354 adding chirp differences 2023-01-24 16:09:17 +01:00
sprause
babcf984e6 implemented individual recording plots 2023-01-24 15:49:17 +01:00
wendtalexander
01f74a471e adding size differences 2023-01-24 15:32:52 +01:00
sprause
d3e77d20cc implemented plots for all recordings incl bootstrapping, std is over 9000 2023-01-24 15:22:40 +01:00
wendtalexander
08fbb67163 Merge branch 'master' of https://whale.am28.uni-tuebingen.de/git/raab/GP2023_chirp_detection 2023-01-24 14:19:43 +01:00
wendtalexander
33fa9f92bc chirp body changes 2023-01-24 14:19:42 +01:00
weygoldt
fe41f8f59c Merge branch 'master' of https://whale.am28.uni-tuebingen.de/git/raab/GP2023_chirp_detection 2023-01-24 14:08:11 +01:00
weygoldt
632e0d5fd8 new poster template 2023-01-24 14:08:07 +01:00
wendtalexander
a371755b1c adding variable for scatter plot 2023-01-24 14:07:38 +01:00
wendtalexander
726301c593 adding plot to poster 2023-01-24 14:04:44 +01:00
wendtalexander
ea98a20a68 adding plotstyle boxplots 2023-01-24 13:56:41 +01:00
sprause
dc2074222c Merge branch 'master' into eventtriggeredchirps 
zsh:1: command not found: q
 2023-01-24 11:08:21 +01:00
sprause
b83d3518cc implemented recording loop 2023-01-24 11:07:52 +01:00
sprause
fc8b15901c corrected zorder in plots, q5 and physical problems okay 2023-01-24 09:15:36 +01:00
sprause
b44a346097 Merge branch 'master' into eventtriggeredchirps 2023-01-23 18:06:58 +01:00
sprause
782fb60e7a something weird 2023-01-23 18:03:01 +01:00
sprause
1bdb7e721a winner vs loser plot, winner physical strange 2023-01-23 17:49:07 +01:00
sprause
e7b9d239d2 implemented bootstrapping, q5 of physical still weird 2023-01-23 15:58:22 +01:00
sprause
7fd98743b0 all event triggered chirps + chirprate with gaussian kernel 2023-01-23 13:48:40 +01:00
sprause
b4bc49e366 start implementing gammakernel 2023-01-23 10:01:24 +01:00
sprause
e19ddcb391 merge master 2023-01-23 09:58:48 +01:00
sprause
c5b9d648e8 new plotfile for CTC and PTC 2023-01-23 09:49:19 +01:00
sprause
c6340e5a4d Fish loop needs debugging 2023-01-22 21:19:14 +01:00
sprause
b2a4d80d17 setup 2023-01-21 17:36:05 +01:00
27 changed files with 1682 additions and 228 deletions
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88
code/behavior.py
View File

@@ -1,4 +1,5 @@
import os
import os
import numpy as np
import matplotlib.pyplot as plt
@@ -6,6 +7,7 @@ import matplotlib.pyplot as plt
from IPython import embed
from pandas import read_csv
from modules.logger import makeLogger
from scipy.ndimage import gaussian_filter1d
logger = makeLogger(__name__)
@@ -106,7 +108,6 @@ def correct_chasing_events(
logger.info('Chasing events are equal')
return category, timestamps
# Correct the wrong chasing events; delete double events
wrong_ids = []
for i in range(len(longer_array)-(len_diff+1)):
@@ -123,6 +124,31 @@ def correct_chasing_events(
return category, timestamps
def event_triggered_chirps(
event: np.ndarray,
chirps:np.ndarray,
time_before_event: int,
time_after_event: int
)-> tuple[np.ndarray, np.ndarray]:
event_chirps = [] # chirps that are in specified window around event
centered_chirps = [] # timestamps of chirps around event centered on the event timepoint
for event_timestamp in event:
start = event_timestamp - time_before_event # timepoint of window start
stop = event_timestamp + time_after_event # timepoint of window ending
chirps_around_event = [c for c in chirps if (c >= start) & (c <= stop)] # get chirps that are in a -5 to +5 sec window around event
event_chirps.append(chirps_around_event)
if len(chirps_around_event) == 0:
continue
else:
centered_chirps.append(chirps_around_event - event_timestamp)
centered_chirps = np.concatenate(centered_chirps, axis=0) # convert list of arrays to one array for plotting
return event_chirps, centered_chirps
def main(datapath: str):
# behavior is pandas dataframe with all the data
@@ -144,11 +170,6 @@ def main(datapath: str):
chasing_offset = timestamps[category == 1]
physical_contact = timestamps[category == 2]
##### TODO Physical contact-triggered chirps (PTC) mit Rasterplot #####
# Wahrscheinlichkeit von Phys auf Ch und vice versa
# Chasing-triggered chirps (CTC) mit Rasterplot
# Wahrscheinlichkeit von Chase auf Ch und vice versa
# First overview plot
fig1, ax1 = plt.subplots()
ax1.scatter(chirps, np.ones_like(chirps), marker='*', color='royalblue', label='Chirps')
@@ -160,13 +181,50 @@ def main(datapath: str):
plt.close()
# Get fish ids
all_fish_ids = np.unique(chirps_fish_ids)
fish_ids = np.unique(chirps_fish_ids)
##### Chasing triggered chirps CTC #####
# Evaluate how many chirps were emitted in specific time window around the chasing onset events
# Iterate over chasing onsets (later over fish)
time_around_event = 5 # time window around the event in which chirps are counted, 5 = -5 to +5 sec around event
#### Loop crashes at concatenate in function ####
# for i in range(len(fish_ids)):
# fish = fish_ids[i]
# chirps = chirps[chirps_fish_ids == fish]
# print(fish)
chasing_chirps, centered_chasing_chirps = event_triggered_chirps(chasing_onset, chirps, time_around_event, time_around_event)
physical_chirps, centered_physical_chirps = event_triggered_chirps(physical_contact, chirps, time_around_event, time_around_event)
# Kernel density estimation ???
# centered_chasing_chirps_convolved = gaussian_filter1d(centered_chasing_chirps, 5)
# centered_chasing = chasing_onset[0] - chasing_onset[0] ## get the 0 timepoint for plotting; set one chasing event to 0
offsets = [0.5, 1]
fig4, ax4 = plt.subplots(figsize=(20 / 2.54, 12 / 2.54), constrained_layout=True)
ax4.eventplot(np.array([centered_chasing_chirps, centered_physical_chirps]), lineoffsets=offsets, linelengths=0.25, colors=['g', 'r'])
ax4.vlines(0, 0, 1.5, 'tab:grey', 'dashed', 'Timepoint of event')
# ax4.plot(centered_chasing_chirps_convolved)
ax4.set_yticks(offsets)
ax4.set_yticklabels(['Chasings', 'Physical \n contacts'])
ax4.set_xlabel('Time[s]')
ax4.set_ylabel('Type of event')
plt.show()
# Associate chirps to inidividual fish
fish1 = chirps[chirps_fish_ids == all_fish_ids[0]]
fish2 = chirps[chirps_fish_ids == all_fish_ids[1]]
fish1 = chirps[chirps_fish_ids == fish_ids[0]]
fish2 = chirps[chirps_fish_ids == fish_ids[1]]
fish = [len(fish1), len(fish2)]
### Plots:
# 1. All recordings, all fish, all chirps
# One CTC, one PTC
# 2. All recordings, only winners
# One CTC, one PTC
# 3. All recordings, all losers
# One CTC, one PTC
#### Chirp counts per fish general #####
fig2, ax2 = plt.subplots()
x = ['Fish1', 'Fish2']
@@ -196,22 +254,20 @@ def main(datapath: str):
fig3 , ax3 = plt.subplots()
ax3.bar(['Chirps in chasing events', 'Chasing events without Chirps'], [counts_chirps_chasings, chasings_without_chirps], width=width)
plt.ylabel('Count')
plt.show()
# plt.show()
plt.close()
# comparison between chasing events with and without chirps
# comparison between chasing events with and without chirps
embed()
exit()
if __name__ == '__main__':
# Path to the data
datapath = '../data/mount_data/2020-05-13-10_00/'
datapath = '../data/mount_data/2020-05-13-10_00/'
main(datapath)

102
code/chirpdetection.py
View File

@@ -102,7 +102,7 @@ class ChirpPlotBuffer:
self.t0 = 0
fig = plt.figure(
figsize=(14 / 2.54, 20 / 2.54)
figsize=(14 * ps.cm, 18 * ps.cm)
)
gs0 = gr.GridSpec(
@@ -133,8 +133,10 @@ class ChirpPlotBuffer:
data_oi,
self.data.raw_rate,
self.t0 - 5,
[np.min(self.frequency) - 100, np.max(self.frequency) + 200]
[np.min(self.frequency) - 300, np.max(self.frequency) + 300]
)
ax0.set_ylim(np.min(self.frequency) - 100,
np.max(self.frequency) + 200)
for track_id in self.data.ids:
@@ -157,27 +159,35 @@ class ChirpPlotBuffer:
zorder=10, color=ps.gblue1)
else:
ax0.plot(t-self.t0_old, f, lw=lw,
zorder=10, color=ps.gray, alpha=0.5)
zorder=10, color=ps.black)
ax0.fill_between(
np.arange(self.t0, self.t0 + self.dt, 1 / self.data.raw_rate),
q50 - self.config.minimal_bandwidth / 2,
q50 + self.config.minimal_bandwidth / 2,
color=ps.gblue1,
lw=1,
ls="dashed",
alpha=0.5,
)
# ax0.fill_between(
# np.arange(self.t0, self.t0 + self.dt, 1 / self.data.raw_rate),
# q50 - self.config.minimal_bandwidth / 2,
# q50 + self.config.minimal_bandwidth / 2,
# color=ps.gblue1,
# lw=1,
# ls="dashed",
# alpha=0.5,
# )
# ax0.fill_between(
# np.arange(self.t0, self.t0 + self.dt, 1 / self.data.raw_rate),
# search_lower,
# search_upper,
# color=ps.gblue2,
# lw=1,
# ls="dashed",
# alpha=0.5,
# )
ax0.axhline(q50 - self.config.minimal_bandwidth / 2,
color=ps.gblue1, lw=1, ls="dashed")
ax0.axhline(q50 + self.config.minimal_bandwidth / 2,
color=ps.gblue1, lw=1, ls="dashed")
ax0.axhline(search_lower, color=ps.gblue2, lw=1, ls="dashed")
ax0.axhline(search_upper, color=ps.gblue2, lw=1, ls="dashed")
ax0.fill_between(
np.arange(self.t0, self.t0 + self.dt, 1 / self.data.raw_rate),
search_lower,
search_upper,
color=ps.gblue2,
lw=1,
ls="dashed",
alpha=0.5,
)
# ax0.axhline(q50, spec_times[0], spec_times[-1],
# color=ps.gblue1, lw=2, ls="dashed")
# ax0.axhline(q50 + self.search_frequency,
@@ -187,7 +197,11 @@ class ChirpPlotBuffer:
if len(chirps) > 0:
for chirp in chirps:
ax0.scatter(
chirp, np.median(self.frequency) + 150, c=ps.black, marker="v"
chirp, np.median(self.frequency), c=ps.red, marker=".",
edgecolors=ps.red,
facecolors=ps.red,
zorder=10,
s=70,
)
# plot waveform of filtered signal
@@ -207,25 +221,31 @@ class ChirpPlotBuffer:
c=ps.gblue3, lw=lw, label="baseline inst. freq.")
# plot filtered and rectified envelope
ax4.plot(self.time, self.baseline_envelope, c=ps.gblue1, lw=lw)
ax4.plot(self.time, self.baseline_envelope *
waveform_scaler, c=ps.gblue1, lw=lw)
ax4.scatter(
(self.time)[self.baseline_peaks],
self.baseline_envelope[self.baseline_peaks],
(self.baseline_envelope*waveform_scaler)[self.baseline_peaks],
edgecolors=ps.red,
facecolors=ps.red,
zorder=10,
marker="o",
facecolors="none",
marker=".",
s=70,
# facecolors="none",
)
# plot envelope of search signal
ax5.plot(self.time, self.search_envelope, c=ps.gblue2, lw=lw)
ax5.plot(self.time, self.search_envelope *
waveform_scaler, c=ps.gblue2, lw=lw)
ax5.scatter(
(self.time)[self.search_peaks],
self.search_envelope[self.search_peaks],
(self.search_envelope*waveform_scaler)[self.search_peaks],
edgecolors=ps.red,
facecolors=ps.red,
zorder=10,
marker="o",
facecolors="none",
marker=".",
s=70,
# facecolors="none",
)
# plot filtered instantaneous frequency
@@ -235,16 +255,20 @@ class ChirpPlotBuffer:
self.frequency_time[self.frequency_peaks],
self.frequency_filtered[self.frequency_peaks],
edgecolors=ps.red,
facecolors=ps.red,
zorder=10,
marker="o",
facecolors="none",
marker=".",
s=70,
# facecolors="none",
)
ax0.set_ylabel("frequency [Hz]")
ax1.set_ylabel("a.u.")
ax2.set_ylabel("a.u.")
ax1.set_ylabel(r"$\mu$V")
ax2.set_ylabel(r"$\mu$V")
ax3.set_ylabel("Hz")
ax5.set_ylabel("a.u.")
ax4.set_ylabel(r"$\mu$V")
ax5.set_ylabel(r"$\mu$V")
ax6.set_ylabel("Hz")
ax6.set_xlabel("time [s]")
plt.setp(ax0.get_xticklabels(), visible=False)
@@ -323,7 +347,7 @@ def plot_spectrogram(
aspect="auto",
origin="lower",
interpolation="gaussian",
alpha=0.6,
# alpha=0.6,
)
# axis.use_sticky_edges = False
return spec_times
@@ -628,7 +652,7 @@ def chirpdetection(datapath: str, plot: str, debug: str = 'false') -> None:
raw_time = np.arange(data.raw.shape[0]) / data.raw_rate
# good chirp times for data: 2022-06-02-10_00
# window_start_index = (3 * 60 * 60 + 6 * 60 + 43.5 + 5) * data.raw_rate
# window_start_index = (3 * 60 * 60 + 6 * 60 + 43.5) * data.raw_rate
# window_duration_index = 60 * data.raw_rate
# t0 = 0
@@ -651,7 +675,7 @@ def chirpdetection(datapath: str, plot: str, debug: str = 'false') -> None:
multiwindow_chirps = []
multiwindow_ids = []
for st, window_start_index in enumerate(window_start_indices):
for st, window_start_index in enumerate(window_start_indices[3175:]):
logger.info(f"Processing window {st+1} of {len(window_start_indices)}")
@@ -1097,4 +1121,4 @@ if __name__ == "__main__":
datapath = "../data/2022-06-02-10_00/"
# datapath = "/home/weygoldt/Data/uni/efishdata/2016-colombia/fishgrid/2016-04-09-22_25/"
# datapath = "/home/weygoldt/Data/uni/chirpdetection/GP2023_chirp_detection/data/mount_data/2020-03-13-10_00/"
chirpdetection(datapath, plot="show", debug="false")
chirpdetection(datapath, plot="save", debug="false")

522
code/eventchirpsplots.py Normal file
View File

@@ -0,0 +1,522 @@
import os
import numpy as np
import pandas as pd
import matplotlib.pyplot as plt
from tqdm import tqdm
from IPython import embed
from pandas import read_csv
from modules.logger import makeLogger
from modules.plotstyle import PlotStyle
from modules.datahandling import causal_kde1d, acausal_kde1d
logger = makeLogger(__name__)
ps = PlotStyle()
class Behavior:
"""Load behavior data from csv file as class attributes
Attributes
----------
behavior: 0: chasing onset, 1: chasing offset, 2: physical contact
behavior_type:
behavioral_category:
comment_start:
comment_stop:
dataframe: pandas dataframe with all the data
duration_s:
media_file:
observation_date:
observation_id:
start_s: start time of the event in seconds
stop_s: stop time of the event in seconds
total_length:
"""
def __init__(self, folder_path: str) -> None:
print(f'{folder_path}')
LED_on_time_BORIS = np.load(os.path.join(folder_path, 'LED_on_time.npy'), allow_pickle=True)
self.time = np.load(os.path.join(folder_path, "times.npy"), allow_pickle=True)
csv_filename = [f for f in os.listdir(folder_path) if f.endswith('.csv')][0] # check if there are more than one csv file
self.dataframe = read_csv(os.path.join(folder_path, csv_filename))
self.chirps = np.load(os.path.join(folder_path, 'chirps.npy'), allow_pickle=True)
self.chirps_ids = np.load(os.path.join(folder_path, 'chirp_ids.npy'), allow_pickle=True)
for k, key in enumerate(self.dataframe.keys()):
key = key.lower()
if ' ' in key:
key = key.replace(' ', '_')
if '(' in key:
key = key.replace('(', '')
key = key.replace(')', '')
setattr(self, key, np.array(self.dataframe[self.dataframe.keys()[k]]))
last_LED_t_BORIS = LED_on_time_BORIS[-1]
real_time_range = self.time[-1] - self.time[0]
factor = 1.034141
shift = last_LED_t_BORIS - real_time_range * factor
self.start_s = (self.start_s - shift) / factor
self.stop_s = (self.stop_s - shift) / factor
"""
1 - chasing onset
2 - chasing offset
3 - physical contact event
temporal encpding needs to be corrected ... not exactly 25FPS.
### correspinding python code ###
factor = 1.034141
LED_on_time_BORIS = np.load(os.path.join(folder_path, 'LED_on_time.npy'), allow_pickle=True)
last_LED_t_BORIS = LED_on_time_BORIS[-1]
real_time_range = times[-1] - times[0]
shift = last_LED_t_BORIS - real_time_range * factor
data = pd.read_csv(os.path.join(folder_path, file[1:-7] + '.csv'))
boris_times = data['Start (s)']
data_times = []
for Cevent_t in boris_times:
Cevent_boris_times = (Cevent_t - shift) / factor
data_times.append(Cevent_boris_times)
data_times = np.array(data_times)
behavior = data['Behavior']
"""
def correct_chasing_events(
category: np.ndarray,
timestamps: np.ndarray
) -> tuple[np.ndarray, np.ndarray]:
onset_ids = np.arange(
len(category))[category == 0]
offset_ids = np.arange(
len(category))[category == 1]
wrong_bh = np.arange(len(category))[category!=2][:-1][np.diff(category[category!=2])==0]
if onset_ids[0] > offset_ids[0]:
offset_ids = np.delete(offset_ids, 0)
help_index = offset_ids[0]
wrong_bh = np.append(wrong_bh[help_index])
category = np.delete(category, wrong_bh)
timestamps = np.delete(timestamps, wrong_bh)
# Check whether on- or offset is longer and calculate length difference
if len(onset_ids) > len(offset_ids):
len_diff = len(onset_ids) - len(offset_ids)
logger.info(f'Onsets are greater than offsets by {len_diff}')
elif len(onset_ids) < len(offset_ids):
len_diff = len(offset_ids) - len(onset_ids)
logger.info(f'Offsets are greater than onsets by {len_diff}')
elif len(onset_ids) == len(offset_ids):
logger.info('Chasing events are equal')
return category, timestamps
def event_triggered_chirps(
event: np.ndarray,
chirps:np.ndarray,
time_before_event: int,
time_after_event: int,
dt: float,
width: float,
)-> tuple[np.ndarray, np.ndarray, np.ndarray]:
event_chirps = [] # chirps that are in specified window around event
centered_chirps = [] # timestamps of chirps around event centered on the event timepoint
for event_timestamp in event:
start = event_timestamp - time_before_event
stop = event_timestamp + time_after_event
chirps_around_event = [c for c in chirps if (c >= start) & (c <= stop)]
event_chirps.append(chirps_around_event)
if len(chirps_around_event) == 0:
continue
else:
centered_chirps.append(chirps_around_event - event_timestamp)
time = np.arange(-time_before_event, time_after_event, dt)
# Kernel density estimation with some if's
if len(centered_chirps) == 0:
centered_chirps = np.array([])
centered_chirps_convolved = np.zeros(len(time))
else:
centered_chirps = np.concatenate(centered_chirps, axis=0) # convert list of arrays to one array for plotting
centered_chirps_convolved = (acausal_kde1d(centered_chirps, time, width)) / len(event)
return event_chirps, centered_chirps, centered_chirps_convolved
def main(datapath: str):
foldernames = [datapath + x + '/' for x in os.listdir(datapath) if os.path.isdir(datapath + x)]
nrecording_chirps = []
nrecording_chirps_fish_ids = []
nrecording_chasing_onsets = []
nrecording_chasing_offsets = []
nrecording_physicals = []
# Iterate over all recordings and save chirp- and event-timestamps
for folder in foldernames:
# exclude folder with empty LED_on_time.npy
if folder == '../data/mount_data/2020-05-12-10_00/':
continue
bh = Behavior(folder)
# Chirps are already sorted
category = bh.behavior
timestamps = bh.start_s
chirps = bh.chirps
nrecording_chirps.append(chirps)
chirps_fish_ids = bh.chirps_ids
nrecording_chirps_fish_ids.append(chirps_fish_ids)
fish_ids = np.unique(chirps_fish_ids)
# Correct for doubles in chasing on- and offsets to get the right on-/offset pairs
# Get rid of tracking faults (two onsets or two offsets after another)
category, timestamps = correct_chasing_events(category, timestamps)
# Split categories
chasing_onsets = timestamps[category == 0]
nrecording_chasing_onsets.append(chasing_onsets)
chasing_offsets = timestamps[category == 1]
nrecording_chasing_offsets.append(chasing_offsets)
physical_contacts = timestamps[category == 2]
nrecording_physicals.append(physical_contacts)
# Define time window for chirps around event analysis
time_before_event = 30
time_after_event = 60
dt = 0.01
width = 1.5 # width of kernel for all recordings, currently gaussian kernel
recording_width = 2 # width of kernel for each recording
time = np.arange(-time_before_event, time_after_event, dt)
##### Chirps around events, all fish, all recordings #####
# Centered chirps per event type
nrecording_centered_onset_chirps = []
nrecording_centered_offset_chirps = []
nrecording_centered_physical_chirps = []
# Bootstrapped chirps per recording and per event: 27[1000[n]] 27 recs, 1000 shuffles, n chirps
nrecording_shuffled_convolved_onset_chirps = []
nrecording_shuffled_convolved_offset_chirps = []
nrecording_shuffled_convolved_physical_chirps = []
nbootstrapping = 10
for i in range(len(nrecording_chirps)):
chirps = nrecording_chirps[i]
chasing_onsets = nrecording_chasing_onsets[i]
chasing_offsets = nrecording_chasing_offsets[i]
physical_contacts = nrecording_physicals[i]
# Chirps around chasing onsets
_, centered_chasing_onset_chirps, cc_chasing_onset_chirps = event_triggered_chirps(chasing_onsets, chirps, time_before_event, time_after_event, dt, recording_width)
# Chirps around chasing offsets
_, centered_chasing_offset_chirps, cc_chasing_offset_chirps = event_triggered_chirps(chasing_offsets, chirps, time_before_event, time_after_event, dt, recording_width)
# Chirps around physical contacts
_, centered_physical_chirps, cc_physical_chirps = event_triggered_chirps(physical_contacts, chirps, time_before_event, time_after_event, dt, recording_width)
nrecording_centered_onset_chirps.append(centered_chasing_onset_chirps)
nrecording_centered_offset_chirps.append(centered_chasing_offset_chirps)
nrecording_centered_physical_chirps.append(centered_physical_chirps)
## Shuffled chirps ##
nshuffled_onset_chirps = []
nshuffled_offset_chirps = []
nshuffled_physical_chirps = []
for j in tqdm(range(nbootstrapping)):
# Calculate interchirp intervals; add first chirp timestamp in beginning to get equal lengths
interchirp_intervals = np.append(np.array([chirps[0]]), np.diff(chirps))
np.random.shuffle(interchirp_intervals)
shuffled_chirps = np.cumsum(interchirp_intervals)
# Shuffled chasing onset chirps
_, _, cc_shuffled_onset_chirps = event_triggered_chirps(chasing_onsets, shuffled_chirps, time_before_event, time_after_event, dt, recording_width)
nshuffled_onset_chirps.append(cc_shuffled_onset_chirps)
# Shuffled chasing offset chirps
_, _, cc_shuffled_offset_chirps = event_triggered_chirps(chasing_offsets, shuffled_chirps, time_before_event, time_after_event, dt, recording_width)
nshuffled_offset_chirps.append(cc_shuffled_offset_chirps)
# Shuffled physical contact chirps
_, _, cc_shuffled_physical_chirps = event_triggered_chirps(physical_contacts, shuffled_chirps, time_before_event, time_after_event, dt, recording_width)
nshuffled_physical_chirps.append(cc_shuffled_physical_chirps)
rec_shuffled_q5_onset, rec_shuffled_median_onset, rec_shuffled_q95_onset = np.percentile(
nshuffled_onset_chirps, (5, 50, 95), axis=0)
rec_shuffled_q5_offset, rec_shuffled_median_offset, rec_shuffled_q95_offset = np.percentile(
nshuffled_offset_chirps, (5, 50, 95), axis=0)
rec_shuffled_q5_physical, rec_shuffled_median_physical, rec_shuffled_q95_physical = np.percentile(
nshuffled_physical_chirps, (5, 50, 95), axis=0)
#### Recording plots ####
fig, ax = plt.subplots(1, 3, figsize=(28*ps.cm, 16*ps.cm, ), constrained_layout=True, sharey='all')
ax[0].set_xlabel('Time[s]')
# Plot chasing onsets
ax[0].set_ylabel('Chirp rate [Hz]')
ax[0].plot(time, cc_chasing_onset_chirps, color=ps.yellow, zorder=2)
ax0 = ax[0].twinx()
ax0.eventplot(centered_chasing_onset_chirps, linelengths=0.2, colors=ps.gray, alpha=0.25, zorder=1)
ax0.vlines(0, 0, 1.5, ps.white, 'dashed')
ax[0].set_zorder(ax0.get_zorder()+1)
ax[0].patch.set_visible(False)
ax0.set_yticklabels([])
ax0.set_yticks([])
ax[0].fill_between(time, rec_shuffled_q5_onset, rec_shuffled_q95_onset, color=ps.gray, alpha=0.5)
ax[0].plot(time, rec_shuffled_median_onset, color=ps.black)
# Plot chasing offets
ax[1].set_xlabel('Time[s]')
ax[1].plot(time, cc_chasing_offset_chirps, color=ps.orange, zorder=2)
ax1 = ax[1].twinx()
ax1.eventplot(centered_chasing_offset_chirps, linelengths=0.2, colors=ps.gray, alpha=0.25, zorder=1)
ax1.vlines(0, 0, 1.5, ps.white, 'dashed')
ax[1].set_zorder(ax1.get_zorder()+1)
ax[1].patch.set_visible(False)
ax1.set_yticklabels([])
ax1.set_yticks([])
ax[1].fill_between(time, rec_shuffled_q5_offset, rec_shuffled_q95_offset, color=ps.gray, alpha=0.5)
ax[1].plot(time, rec_shuffled_median_offset, color=ps.black)
# Plot physical contacts
ax[2].set_xlabel('Time[s]')
ax[2].plot(time, cc_physical_chirps, color=ps.maroon, zorder=2)
ax2 = ax[2].twinx()
ax2.eventplot(centered_physical_chirps, linelengths=0.2, colors=ps.gray, alpha=0.25, zorder=1)
ax2.vlines(0, 0, 1.5, ps.white, 'dashed')
ax[2].set_zorder(ax2.get_zorder()+1)
ax[2].patch.set_visible(False)
ax2.set_yticklabels([])
ax2.set_yticks([])
ax[2].fill_between(time, rec_shuffled_q5_physical, rec_shuffled_q95_physical, color=ps.gray, alpha=0.5)
ax[2].plot(time, rec_shuffled_median_physical, ps.black)
fig.suptitle(f'Recording: {i}')
plt.show()
# plt.close()
nrecording_shuffled_convolved_onset_chirps.append(nshuffled_onset_chirps)
nrecording_shuffled_convolved_offset_chirps.append(nshuffled_offset_chirps)
nrecording_shuffled_convolved_physical_chirps.append(nshuffled_physical_chirps)
# vstack um 1. Dim zu cutten
nrecording_shuffled_convolved_onset_chirps = np.vstack(nrecording_shuffled_convolved_onset_chirps)
nrecording_shuffled_convolved_offset_chirps = np.vstack(nrecording_shuffled_convolved_offset_chirps)
nrecording_shuffled_convolved_physical_chirps = np.vstack(nrecording_shuffled_convolved_physical_chirps)
shuffled_q5_onset, shuffled_median_onset, shuffled_q95_onset = np.percentile(
nrecording_shuffled_convolved_onset_chirps, (5, 50, 95), axis=0)
shuffled_q5_offset, shuffled_median_offset, shuffled_q95_offset = np.percentile(
nrecording_shuffled_convolved_offset_chirps, (5, 50, 95), axis=0)
shuffled_q5_physical, shuffled_median_physical, shuffled_q95_physical = np.percentile(
nrecording_shuffled_convolved_physical_chirps, (5, 50, 95), axis=0)
# Flatten all chirps
all_chirps = np.concatenate(nrecording_chirps).ravel() # not centered
# Flatten event timestamps
all_onsets = np.concatenate(nrecording_chasing_onsets).ravel() # not centered
all_offsets = np.concatenate(nrecording_chasing_offsets).ravel() # not centered
all_physicals = np.concatenate(nrecording_physicals).ravel() # not centered
# Flatten all chirps around events
all_onset_chirps = np.concatenate(nrecording_centered_onset_chirps).ravel() # centered
all_offset_chirps = np.concatenate(nrecording_centered_offset_chirps).ravel() # centered
all_physical_chirps = np.concatenate(nrecording_centered_physical_chirps).ravel() # centered
# Convolute all chirps
# Divide by total number of each event over all recordings
all_onset_chirps_convolved = (acausal_kde1d(all_onset_chirps, time, width)) / len(all_onsets)
all_offset_chirps_convolved = (acausal_kde1d(all_offset_chirps, time, width)) / len(all_offsets)
all_physical_chirps_convolved = (acausal_kde1d(all_physical_chirps, time, width)) / len(all_physicals)
# Plot all events with all shuffled
fig, ax = plt.subplots(1, 3, figsize=(28*ps.cm, 16*ps.cm, ), constrained_layout=True, sharey='all')
# offsets = np.arange(1,28,1)
ax[0].set_xlabel('Time[s]')
# Plot chasing onsets
ax[0].set_ylabel('Chirp rate [Hz]')
ax[0].plot(time, all_onset_chirps_convolved, color=ps.yellow, zorder=2)
ax0 = ax[0].twinx()
nrecording_centered_onset_chirps = np.asarray(nrecording_centered_onset_chirps, dtype=object)
ax0.eventplot(np.array(nrecording_centered_onset_chirps), linelengths=0.5, colors=ps.gray, alpha=0.25, zorder=1)
ax0.vlines(0, 0, 1.5, ps.white, 'dashed')
ax[0].set_zorder(ax0.get_zorder()+1)
ax[0].patch.set_visible(False)
ax0.set_yticklabels([])
ax0.set_yticks([])
ax[0].fill_between(time, shuffled_q5_onset, shuffled_q95_onset, color=ps.gray, alpha=0.5)
ax[0].plot(time, shuffled_median_onset, color=ps.black)
# Plot chasing offets
ax[1].set_xlabel('Time[s]')
ax[1].plot(time, all_offset_chirps_convolved, color=ps.orange, zorder=2)
ax1 = ax[1].twinx()
nrecording_centered_offset_chirps = np.asarray(nrecording_centered_offset_chirps, dtype=object)
ax1.eventplot(np.array(nrecording_centered_offset_chirps), linelengths=0.5, colors=ps.gray, alpha=0.25, zorder=1)
ax1.vlines(0, 0, 1.5, ps.white, 'dashed')
ax[1].set_zorder(ax1.get_zorder()+1)
ax[1].patch.set_visible(False)
ax1.set_yticklabels([])
ax1.set_yticks([])
ax[1].fill_between(time, shuffled_q5_offset, shuffled_q95_offset, color=ps.gray, alpha=0.5)
ax[1].plot(time, shuffled_median_offset, color=ps.black)
# Plot physical contacts
ax[2].set_xlabel('Time[s]')
ax[2].plot(time, all_physical_chirps_convolved, color=ps.maroon, zorder=2)
ax2 = ax[2].twinx()
nrecording_centered_physical_chirps = np.asarray(nrecording_centered_physical_chirps, dtype=object)
ax2.eventplot(np.array(nrecording_centered_physical_chirps), linelengths=0.5, colors=ps.gray, alpha=0.25, zorder=1)
ax2.vlines(0, 0, 1.5, ps.white, 'dashed')
ax[2].set_zorder(ax2.get_zorder()+1)
ax[2].patch.set_visible(False)
ax2.set_yticklabels([])
ax2.set_yticks([])
ax[2].fill_between(time, shuffled_q5_physical, shuffled_q95_physical, color=ps.gray, alpha=0.5)
ax[2].plot(time, shuffled_median_physical, ps.black)
fig.suptitle('All recordings')
plt.show()
# plt.close()
embed()
# chasing_durations = []
# # Calculate chasing duration to evaluate a nice time window for kernel density estimation
# for onset, offset in zip(chasing_onsets, chasing_offsets):
# duration = offset - onset
# chasing_durations.append(duration)
# fig, ax = plt.subplots()
# ax.boxplot(chasing_durations)
# plt.show()
# plt.close()
# # Associate chirps to individual fish
# fish1 = chirps[chirps_fish_ids == fish_ids[0]]
# fish2 = chirps[chirps_fish_ids == fish_ids[1]]
# fish = [len(fish1), len(fish2)]
# Convolution over all recordings
# Rasterplot for each recording
# #### Chirps around events, winner VS loser, one recording ####
# # Load file with fish ids and winner/loser info
# meta = pd.read_csv('../data/mount_data/order_meta.csv')
# current_recording = meta[meta.index == 43]
# fish1 = current_recording['rec_id1'].values
# fish2 = current_recording['rec_id2'].values
# # Implement check if fish_ids from meta and chirp detection are the same???
# winner = current_recording['winner'].values
# if winner == fish1:
# loser = fish2
# elif winner == fish2:
# loser = fish1
# winner_chirps = chirps[chirps_fish_ids == winner]
# loser_chirps = chirps[chirps_fish_ids == loser]
# # Event triggered winner chirps
# _, winner_centered_onset, winner_cc_onset = event_triggered_chirps(chasing_onsets, winner_chirps, time_before_event, time_after_event, dt, width)
# _, winner_centered_offset, winner_cc_offset = event_triggered_chirps(chasing_offsets, winner_chirps, time_before_event, time_after_event, dt, width)
# _, winner_centered_physical, winner_cc_physical = event_triggered_chirps(physical_contacts, winner_chirps, time_before_event, time_after_event, dt, width)
# # Event triggered loser chirps
# _, loser_centered_onset, loser_cc_onset = event_triggered_chirps(chasing_onsets, loser_chirps, time_before_event, time_after_event, dt, width)
# _, loser_centered_offset, loser_cc_offset = event_triggered_chirps(chasing_offsets, loser_chirps, time_before_event, time_after_event, dt, width)
# _, loser_centered_physical, loser_cc_physical = event_triggered_chirps(physical_contacts, loser_chirps, time_before_event, time_after_event, dt, width)
# ########## Winner VS Loser plot ##########
# fig, ax = plt.subplots(2, 3, figsize=(50 / 2.54, 15 / 2.54), constrained_layout=True, sharey='row')
# offset = [1.35]
# ax[1][0].set_xlabel('Time[s]')
# ax[1][1].set_xlabel('Time[s]')
# ax[1][2].set_xlabel('Time[s]')
# # Plot winner chasing onsets
# ax[0][0].set_ylabel('Chirp rate [Hz]')
# ax[0][0].plot(time, winner_cc_onset, color='tab:blue', zorder=100)
# ax0 = ax[0][0].twinx()
# ax0.eventplot(np.array([winner_centered_onset]), lineoffsets=offset, linelengths=0.1, colors=['tab:green'], alpha=0.25, zorder=-100)
# ax0.set_ylabel('Event')
# ax0.vlines(0, 0, 1.5, 'tab:grey', 'dashed')
# ax[0][0].set_zorder(ax0.get_zorder()+1)
# ax[0][0].patch.set_visible(False)
# ax0.set_yticklabels([])
# ax0.set_yticks([])
# # Plot winner chasing offets
# ax[0][1].plot(time, winner_cc_offset, color='tab:blue', zorder=100)
# ax1 = ax[0][1].twinx()
# ax1.eventplot(np.array([winner_centered_offset]), lineoffsets=offset, linelengths=0.1, colors=['tab:purple'], alpha=0.25, zorder=-100)
# ax1.vlines(0, 0, 1.5, 'tab:grey', 'dashed')
# ax[0][1].set_zorder(ax1.get_zorder()+1)
# ax[0][1].patch.set_visible(False)
# ax1.set_yticklabels([])
# ax1.set_yticks([])
# # Plot winner physical contacts
# ax[0][2].plot(time, winner_cc_physical, color='tab:blue', zorder=100)
# ax2 = ax[0][2].twinx()
# ax2.eventplot(np.array([winner_centered_physical]), lineoffsets=offset, linelengths=0.1, colors=['tab:red'], alpha=0.25, zorder=-100)
# ax2.vlines(0, 0, 1.5, 'tab:grey', 'dashed')
# ax[0][2].set_zorder(ax2.get_zorder()+1)
# ax[0][2].patch.set_visible(False)
# ax2.set_yticklabels([])
# ax2.set_yticks([])
# # Plot loser chasing onsets
# ax[1][0].set_ylabel('Chirp rate [Hz]')
# ax[1][0].plot(time, loser_cc_onset, color='tab:blue', zorder=100)
# ax3 = ax[1][0].twinx()
# ax3.eventplot(np.array([loser_centered_onset]), lineoffsets=offset, linelengths=0.1, colors=['tab:green'], alpha=0.25, zorder=-100)
# ax3.vlines(0, 0, 1.5, 'tab:grey', 'dashed')
# ax[1][0].set_zorder(ax3.get_zorder()+1)
# ax[1][0].patch.set_visible(False)
# ax3.set_yticklabels([])
# ax3.set_yticks([])
# # Plot loser chasing offsets
# ax[1][1].plot(time, loser_cc_offset, color='tab:blue', zorder=100)
# ax4 = ax[1][1].twinx()
# ax4.eventplot(np.array([loser_centered_offset]), lineoffsets=offset, linelengths=0.1, colors=['tab:purple'], alpha=0.25, zorder=-100)
# ax4.vlines(0, 0, 1.5, 'tab:grey', 'dashed')
# ax[1][1].set_zorder(ax4.get_zorder()+1)
# ax[1][1].patch.set_visible(False)
# ax4.set_yticklabels([])
# ax4.set_yticks([])
# # Plot loser physical contacts
# ax[1][2].plot(time, loser_cc_physical, color='tab:blue', zorder=100)
# ax5 = ax[1][2].twinx()
# ax5.eventplot(np.array([loser_centered_physical]), lineoffsets=offset, linelengths=0.1, colors=['tab:red'], alpha=0.25, zorder=-100)
# ax5.vlines(0, 0, 1.5, 'tab:grey', 'dashed')
# ax[1][2].set_zorder(ax5.get_zorder()+1)
# ax[1][2].patch.set_visible(False)
# ax5.set_yticklabels([])
# ax5.set_yticks([])
# plt.show()
# plt.close()
# for i in range(len(fish_ids)):
# fish = fish_ids[i]
# chirps_temp = chirps[chirps_fish_ids == fish]
# print(fish)
#### Chirps around events, only losers, one recording ####
if __name__ == '__main__':
# Path to the data
datapath = '../data/mount_data/'
main(datapath)

3
code/extract_chirps.py
View File

@@ -4,6 +4,8 @@ import numpy as np
from chirpdetection import chirpdetection
from IPython import embed
# check rec ../data/mount_data/2020-03-25-10_00/ starting at 3175
def main(datapaths):
@@ -43,6 +45,7 @@ if __name__ == '__main__':
recs = pd.DataFrame(columns=['recording'], data=valid_datasets)
recs.to_csv('../recs.csv', index=False)
datapaths = ['../data/mount_data/2020-03-25-10_00/']
main(datapaths)
# window 1524 + 244 in dataset index 4 is nice example

1
code/modules/filehandling.py
View File

@@ -3,6 +3,7 @@ import os
import yaml
import numpy as np
from thunderfish.dataloader import DataLoader
import matplotlib.pyplot as plt
class ConfLoader:

126
code/modules/plotstyle.py
View File

@@ -23,16 +23,16 @@ def PlotStyle() -> None:
sky = "#89dceb"
teal = "#94e2d5"
green = "#a6e3a1"
yellow = "#f9e2af"
orange = "#fab387"
maroon = "#eba0ac"
red = "#f38ba8"
purple = "#cba6f7"
pink = "#f5c2e7"
yellow = "#f9d67f"
orange = "#faa472"
maroon = "#eb8486"
red = "#f37588"
purple = "#d89bf7"
pink = "#f59edb"
lavender = "#b4befe"
gblue1 = "#8cb8ff"
gblue2 = "#7cdcdc"
gblue3 = "#82e896"
gblue1 = "#89b4fa"
gblue2 = "#89dceb"
gblue3 = "#a6e3a1"
@classmethod
def lims(cls, track1, track2):
@@ -229,7 +229,7 @@ def PlotStyle() -> None:
plt.rc("legend", fontsize=SMALL_SIZE) # legend fontsize
plt.rc("figure", titlesize=BIGGER_SIZE) # fontsize of the figure title
plt.rcParams["image.cmap"] = 'cmo.haline'
plt.rcParams["image.cmap"] = "cmo.haline"
plt.rcParams["axes.xmargin"] = 0.05
plt.rcParams["axes.ymargin"] = 0.1
plt.rcParams["axes.titlelocation"] = "left"
@@ -261,31 +261,33 @@ def PlotStyle() -> None:
# plt.rcParams["axes.grid"] = True # display grid or not
# plt.rcParams["axes.grid.axis"] = "y" # which axis the grid is applied to
plt.rcParams["axes.labelcolor"] = white
plt.rcParams["axes.axisbelow"] = True # draw axis gridlines and ticks:
plt.rcParams["axes.axisbelow"] = True # draw axis gridlines and ticks:
plt.rcParams["axes.spines.left"] = True # display axis spines
plt.rcParams["axes.spines.bottom"] = True
plt.rcParams["axes.spines.top"] = False
plt.rcParams["axes.spines.right"] = False
plt.rcParams["axes.prop_cycle"] = cycler(
'color', [
'#b4befe',
'#89b4fa',
'#74c7ec',
'#89dceb',
'#94e2d5',
'#a6e3a1',
'#f9e2af',
'#fab387',
'#eba0ac',
'#f38ba8',
'#cba6f7',
'#f5c2e7',
])
"color",
[
"#b4befe",
"#89b4fa",
"#74c7ec",
"#89dceb",
"#94e2d5",
"#a6e3a1",
"#f9e2af",
"#fab387",
"#eba0ac",
"#f38ba8",
"#cba6f7",
"#f5c2e7",
],
)
plt.rcParams["xtick.color"] = gray # color of the ticks
plt.rcParams["ytick.color"] = gray # color of the ticks
plt.rcParams["grid.color"] = dark_gray # grid color
plt.rcParams["figure.facecolor"] = black # figure face color
plt.rcParams["figure.edgecolor"] = black # figure edge color
plt.rcParams["figure.facecolor"] = black # figure face color
plt.rcParams["figure.edgecolor"] = black # figure edge color
plt.rcParams["savefig.facecolor"] = black # figure face color when saving
return style
@@ -295,12 +297,11 @@ if __name__ == "__main__":
s = PlotStyle()
import matplotlib.pyplot as plt
import matplotlib.cbook as cbook
import matplotlib.cm as cm
import matplotlib.pyplot as plt
import matplotlib.cbook as cbook
from matplotlib.path import Path
from matplotlib.patches import PathPatch
from matplotlib.path import Path
# Fixing random state for reproducibility
np.random.seed(19680801)
@@ -308,14 +309,20 @@ if __name__ == "__main__":
delta = 0.025
x = y = np.arange(-3.0, 3.0, delta)
X, Y = np.meshgrid(x, y)
Z1 = np.exp(-X**2 - Y**2)
Z2 = np.exp(-(X - 1)**2 - (Y - 1)**2)
Z1 = np.exp(-(X**2) - Y**2)
Z2 = np.exp(-((X - 1) ** 2) - (Y - 1) ** 2)
Z = (Z1 - Z2) * 2
fig1, ax = plt.subplots()
im = ax.imshow(Z, interpolation='bilinear', cmap=cm.RdYlGn,
origin='lower', extent=[-3, 3, -3, 3],
vmax=abs(Z).max(), vmin=-abs(Z).max())
im = ax.imshow(
Z,
interpolation="bilinear",
cmap=cm.RdYlGn,
origin="lower",
extent=[-3, 3, -3, 3],
vmax=abs(Z).max(),
vmin=-abs(Z).max(),
)
plt.show()
@@ -328,22 +335,21 @@ if __name__ == "__main__":
all_data = [np.random.normal(0, std, 100) for std in range(6, 10)]
# plot violin plot
axs[0].violinplot(all_data,
showmeans=False,
showmedians=True)
axs[0].set_title('Violin plot')
axs[0].violinplot(all_data, showmeans=False, showmedians=True)
axs[0].set_title("Violin plot")
# plot box plot
axs[1].boxplot(all_data)
axs[1].set_title('Box plot')
axs[1].set_title("Box plot")
# adding horizontal grid lines
for ax in axs:
ax.yaxis.grid(True)
ax.set_xticks([y + 1 for y in range(len(all_data))],
labels=['x1', 'x2', 'x3', 'x4'])
ax.set_xlabel('Four separate samples')
ax.set_ylabel('Observed values')
ax.set_xticks(
[y + 1 for y in range(len(all_data))], labels=["x1", "x2", "x3", "x4"]
)
ax.set_xlabel("Four separate samples")
ax.set_ylabel("Observed values")
plt.show()
@@ -355,24 +361,42 @@ if __name__ == "__main__":
theta = np.linspace(0.0, 2 * np.pi, N, endpoint=False)
radii = 10 * np.random.rand(N)
width = np.pi / 4 * np.random.rand(N)
colors = cmo.cm.haline(radii / 10.)
colors = cmo.cm.haline(radii / 10.0)
ax = plt.subplot(projection='polar')
ax = plt.subplot(projection="polar")
ax.bar(theta, radii, width=width, bottom=0.0, color=colors, alpha=0.5)
plt.show()
methods = [None, 'none', 'nearest', 'bilinear', 'bicubic', 'spline16',
'spline36', 'hanning', 'hamming', 'hermite', 'kaiser', 'quadric',
'catrom', 'gaussian', 'bessel', 'mitchell', 'sinc', 'lanczos']
methods = [
None,
"none",
"nearest",
"bilinear",
"bicubic",
"spline16",
"spline36",
"hanning",
"hamming",
"hermite",
"kaiser",
"quadric",
"catrom",
"gaussian",
"bessel",
"mitchell",
"sinc",
"lanczos",
]
# Fixing random state for reproducibility
np.random.seed(19680801)
grid = np.random.rand(4, 4)
fig, axs = plt.subplots(nrows=3, ncols=6, figsize=(9, 6),
subplot_kw={'xticks': [], 'yticks': []})
fig, axs = plt.subplots(
nrows=3, ncols=6, figsize=(9, 6), subplot_kw={"xticks": [], "yticks": []}
)
for ax, interp_method in zip(axs.flat, methods):
ax.imshow(grid, interpolation=interp_method)

109
code/plot_chirp_bodylegth.py
View File

@@ -1,9 +1,9 @@
import numpy as np
import os
import os
import numpy as np
import matplotlib.pyplot as plt
import matplotlib.pyplot as plt
from thunderfish.powerspectrum import decibel
from IPython import embed
@@ -19,13 +19,22 @@ logger = makeLogger(__name__)
def main(datapath: str):
foldernames = [datapath + x + '/' for x in os.listdir(datapath) if os.path.isdir(datapath+x)]
path_to_csv = ('/').join(foldernames[0].split('/')[:-2]) + '/order_meta.csv'
meta_id = read_csv(path_to_csv)
meta_id['recording'] = meta_id['recording'].str[1:-1]
foldernames = [
datapath + x + '/' for x in os.listdir(datapath) if os.path.isdir(datapath+x)]
path_order_meta = (
'/').join(foldernames[0].split('/')[:-2]) + '/order_meta.csv'
order_meta_df = read_csv(path_order_meta)
order_meta_df['recording'] = order_meta_df['recording'].str[1:-1]
path_id_meta = (
'/').join(foldernames[0].split('/')[:-2]) + '/id_meta.csv'
id_meta_df = read_csv(path_id_meta)
chirps_winner = []
size_diff = []
chirps_diff = []
chirps_loser = []
freq_diff = []
for foldername in foldernames:
# behabvior is pandas dataframe with all the data
@@ -41,47 +50,111 @@ def main(datapath: str):
category, timestamps = correct_chasing_events(category, timestamps)
folder_name = foldername.split('/')[-2]
winner_row = meta_id[meta_id['recording'] == folder_name]
winner_row = order_meta_df[order_meta_df['recording'] == folder_name]
winner = winner_row['winner'].values[0].astype(int)
winner_fish1 = winner_row['fish1'].values[0].astype(int)
winner_fish2 = winner_row['fish2'].values[0].astype(int)
groub = winner_row['group'].values[0].astype(int)
size_rows = id_meta_df[id_meta_df['group'] == groub]
if winner == winner_fish1:
winner_fish_id = winner_row['rec_id1'].values[0]
loser_fish_id = winner_row['rec_id2'].values[0]
size_winners = []
for l in ['l1', 'l2', 'l3']:
size_winner = size_rows[size_rows['fish']== winner_fish1][l].values[0]
size_winners.append(size_winner)
mean_size_winner = np.nanmean(size_winners)
size_losers = []
for l in ['l1', 'l2', 'l3']:
size_loser = size_rows[size_rows['fish']== winner_fish2][l].values[0]
size_losers.append(size_loser)
mean_size_loser = np.nanmean(size_losers)
size_diff.append(mean_size_winner - mean_size_loser)
elif winner == winner_fish2:
winner_fish_id = winner_row['rec_id2'].values[0]
loser_fish_id = winner_row['rec_id1'].values[0]
size_winners = []
for l in ['l1', 'l2', 'l3']:
size_winner = size_rows[size_rows['fish']== winner_fish2][l].values[0]
size_winners.append(size_winner)
mean_size_winner = np.nanmean(size_winners)
size_losers = []
for l in ['l1', 'l2', 'l3']:
size_loser = size_rows[size_rows['fish']== winner_fish1][l].values[0]
size_losers.append(size_loser)
mean_size_loser = np.nanmean(size_losers)
size_diff.append(mean_size_winner - mean_size_loser)
else:
continue
print(foldername)
all_fish_ids = np.unique(bh.chirps_ids)
chirp_loser = len(bh.chirps[bh.chirps_ids == loser_fish_id])
chirp_winner = len(bh.chirps[bh.chirps_ids == winner_fish_id])
chirp_loser = len(bh.chirps[bh.chirps_ids == loser_fish_id])
freq_winner = np.nanmedian(bh.freq[bh.ident==winner_fish_id])
freq_loser = np.nanmedian(bh.freq[bh.ident==loser_fish_id])
chirps_winner.append(chirp_winner)
chirps_loser.append(chirp_loser)
chirps_diff.append(chirp_winner - chirp_loser)
freq_diff.append(freq_winner - freq_loser)
fish1_id = all_fish_ids[0]
fish2_id = all_fish_ids[1]
print(winner_fish_id)
print(all_fish_ids)
fig, (ax1, ax2, ax3) = plt.subplots(1,3, figsize=(10,5))
scatterwinner = 1.15
scatterloser = 1.85
bplot1 = ax1.boxplot(chirps_winner, positions=[
1], showfliers=False, patch_artist=True)
bplot2 = ax1.boxplot(chirps_loser, positions=[
2], showfliers=False, patch_artist=True)
ax1.scatter(np.ones(len(chirps_winner))*scatterwinner, chirps_winner, color='r')
ax1.scatter(np.ones(len(chirps_loser))*scatterloser, chirps_loser, color='r')
ax1.set_xticklabels(['winner', 'loser'])
ax1.text(0.9, 0.9, f'n = {len(chirps_winner)}', transform=ax1.transAxes, color= ps.white)
fig, ax = plt.subplots()
ax.boxplot([chirps_winner, chirps_loser], showfliers=False)
ax.scatter(np.ones(len(chirps_winner)), chirps_winner, color='r')
ax.scatter(np.ones(len(chirps_loser))*2, chirps_loser, color='r')
ax.set_xticklabels(['winner', 'loser'])
for w, l in zip(chirps_winner, chirps_loser):
ax.plot([1,2], [w,l], color='r', alpha=0.5, linewidth=0.5)
ax1.plot([scatterwinner, scatterloser], [w, l], color='r', alpha=0.5, linewidth=0.5)
ax.set_ylabel('Chirpscounts [n]')
colors1 = ps.red
ps.set_boxplot_color(bplot1, colors1)
colors1 = ps.orange
ps.set_boxplot_color(bplot2, colors1)
ax1.set_ylabel('Chirpscounts [n]')
ax2.scatter(size_diff, chirps_diff, color='r')
ax2.set_xlabel('Size difference [mm]')
ax2.set_ylabel('Chirps difference [n]')
ax3.scatter(freq_diff, chirps_diff, color='r')
ax3.set_xlabel('Frequency difference [Hz]')
ax3.set_yticklabels([])
ax3.set
plt.savefig('../poster/figs/chirps_winner_loser.pdf')
plt.show()
if __name__ == '__main__':
# Path to the data
datapath = '../data/mount_data/'
main(datapath)
main(datapath)

6
code/plot_event_timeline.py
View File

@@ -87,7 +87,7 @@ def main(datapath: str):
ax[3].axvspan(0, 3, 0, 5, facecolor='grey', alpha=0.5)
ax[3].axvspan(3, 6, 0, 5, facecolor='grey', alpha=0.5)
ax[3].set_xticks(np.arange(0, 6.1, 0.5))
labelpad = 40
@@ -98,9 +98,9 @@ def main(datapath: str):
ax[3].set_xlabel('Time [h]')
ax[0].set_title(foldername.split('/')[-2])
# 2020-03-31-9_59
plt.show()
embed()
embed()
# plot chirps

4
code/plot_introduction_specs.py
View File

@@ -41,9 +41,9 @@ def main():
freqtime2, freq2 = instantaneous_frequency(
filtered2, data.raw_rate, smoothing_window=3)
ax1.plot(freqtime1*timescaler, freq1, color=ps.gblue1,
ax1.plot(freqtime1*timescaler, freq1, color=ps.red,
lw=2, label=f"fish 1, {np.median(freq1):.0f} Hz")
ax1.plot(freqtime2*timescaler, freq2, color=ps.gblue3,
ax1.plot(freqtime2*timescaler, freq2, color=ps.orange,
lw=2, label=f"fish 2, {np.median(freq2):.0f} Hz")
ax1.legend(bbox_to_anchor=(0, 1.02, 1, 0.2), loc="lower center",
mode="normal", borderaxespad=0, ncol=2)

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141
poster/main.tex
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@@ -1,4 +1,4 @@
\documentclass[25pt, a0paper, landscape, margin=0mm, innermargin=20mm,
\documentclass[25pt, a0paper, portrait, margin=0mm, innermargin=20mm,
blockverticalspace=2mm, colspace=20mm, subcolspace=0mm]{tikzposter} %Default values for poster format options.
\input{packages}
@@ -7,113 +7,84 @@ blockverticalspace=2mm, colspace=20mm, subcolspace=0mm]{tikzposter} %Default val
\begin{document}
\renewcommand{\baselinestretch}{1}
\title{\parbox{1900pt}{Pushing the limits of time-frequency uncertainty in the
detection of transient communication signals in weakly electric fish}}
\author{Sina Prause, Alexander Wendt, Patrick Weygoldt}
\institute{Supervised by Till Raab \& Jan Benda, Neurothology Group,
University of Tübingen}
\title{\parbox{1500pt}{Detection of transient communication signals in weakly electric fish}}
\author{Sina Prause, Alexander Wendt, and Patrick Weygoldt}
\institute{Supervised by Till Raab \& Jan Benda, Neuroethology Lab, University of Tuebingen}
\usetitlestyle[]{sampletitle}
\maketitle
\renewcommand{\baselinestretch}{1.4}
\begin{columns}
\column{0.5}
\column{0.4}
\myblock[TranspBlock]{Introduction}{
\begin{minipage}[t]{0.55\linewidth}
The time-frequency tradeoff makes reliable signal detecion and simultaneous
sender identification of freely interacting individuals impossible.
This profoundly limits our current understanding of chirps to experiments
with single - or physically separated - individuals.
\end{minipage} \hfill
\begin{minipage}[t]{0.40\linewidth}
\vspace{-1.5cm}
The time-frequency tradeoff makes reliable signal detecion and simultaneous
sender identification of freely interacting individuals impossible.
This profoundly limits our current understanding of chirps to experiments
with single - or physically separated - individuals.
% \begin{tikzfigure}[]
% \label{griddrawing}
% \includegraphics[width=1\linewidth]{figs/introplot}
% \end{tikzfigure}
}
\myblock[TranspBlock]{Chirp detection}{
\begin{tikzfigure}[]
\label{tradeoff}
\includegraphics[width=\linewidth]{figs/introplot}
\label{fig:example_a}
\includegraphics[width=1\linewidth]{figs/algorithm}
\end{tikzfigure}
\end{minipage}
\vspace{0cm}
}
\myblock[TranspBlock]{A chirp detection algorithm}{
\begin{tikzfigure}[]
\label{modulations}
\includegraphics[width=\linewidth]{figs/algorithm}
\end{tikzfigure}
\column{0.6}
\myblock[TranspBlock]{Chirps during competition}{
\begin{tikzfigure}[]
\label{fig:example_b}
\includegraphics[width=0.5\linewidth]{example-image-b}
\end{tikzfigure}
\noindent
}
\column{0.5}
\myblock[TranspBlock]{Chirps and diadic competitions}{
\begin{minipage}[t]{0.7\linewidth}
\myblock[TranspBlock]{Interactions at modulations}{
\vspace{-1.2cm}
\begin{tikzfigure}[]
\label{modulations}
\includegraphics[width=\linewidth]{figs/placeholder1}
\label{fig:example_c}
\includegraphics[width=0.5\linewidth]{example-image-c}
\end{tikzfigure}
\end{minipage} \hfill
\begin{minipage}[t]{0.25\linewidth}
\lipsum[3][1-3]
\end{minipage}
\begin{minipage}[t]{0.7\linewidth}
\begin{tikzfigure}[]
\label{modulations}
\includegraphics[width=\linewidth]{figs/placeholder1}
\end{tikzfigure}
\end{minipage} \hfill
\begin{minipage}[t]{0.25\linewidth}
\lipsum[3][1-3]
\end{minipage}
\begin{minipage}[t]{0.7\linewidth}
\begin{tikzfigure}[]
\label{modulations}
\includegraphics[width=\linewidth]{figs/placeholder1}
\end{tikzfigure}
\end{minipage} \hfill
\begin{minipage}[t]{0.25\linewidth}
\lipsum[3][1-3]
\end{minipage}
\begin{multicols}{2}
\begin{itemize}
\setlength\itemsep{0.5em}
\item $\Delta$EOD$f$ does not appear to decrease during synchronous modulations ().
\item Individuals that rise their EOD$f$ first appear to rise their frequency higher compared to reactors (\textbf{B}).
\vfill
\null
\columnbreak
\item Synchronized fish keep distances below 1 m (\textbf{C}) but distances over 3 m also occur (see \textbf{movie}).
\item Spatial interactions increase \textbf{after} the start of a synchronous modulation (\textbf{D}).
\end{itemize}
\end{multicols}
\vspace{-1cm}
}
\myblock[TranspBlock]{Conclusion}{
\lipsum[3][1-9]
}
\myblock[GrayBlock]{Conclusion}{
\begin{itemize}
\setlength\itemsep{0.5em}
\item Our analysis is the first to indicate that \textit{A. leptorhynchus} uses long, diffuse and synchronized EOD$f$ signals to communicate in addition to chirps and rises.
\item The recorded fish do not exhibit jamming avoidance behavior while close during synchronous modulations.
\item Synchronous signals \textbf{initiate} spatio-temporal interactions.
\end{itemize}
\vspace{0.2cm}
}
\end{columns}
% \column{0.3}
% \myblock[TranspBlock]{More Results}{
% \begin{tikzfigure}[]
% \label{results}
% \includegraphics[width=\linewidth]{example-image-a}
% \end{tikzfigure}
% \begin{multicols}{2}
% \lipsum[5][1-8]
% \end{multicols}
% \vspace{-1cm}
% }
% \myblock[TranspBlock]{Conclusion}{
% \begin{itemize}
% \setlength\itemsep{0.5em}
% \item \lipsum[1][1]
% \item \lipsum[1][1]
% \item \lipsum[1][1]
% \end{itemize}
% \vspace{0.2cm}
% }
\end{columns}
\node[
above right,
\node [above right,
text=white,
outer sep=45pt,
minimum width=\paperwidth,
align=center,
draw,
fill=boxes,
color=boxes,
] at (-0.51\paperwidth,-43.5) {
\textcolor{text}{\normalsize Contact: \{name\}.\{surname\}@student.uni-tuebingen.de}};
color=boxes] at (-43.6,-61) {
\textcolor{white}{
\normalsize Contact: \{name\}.\{surname\}@student.uni-tuebingen.de}};
\end{document}

5
poster/packages.tex
View File

@@ -1,11 +1,10 @@
\usepackage[utf8]{inputenc}
\usepackage[scaled]{helvet}
\renewcommand\familydefault{\sfdefault}
\renewcommand\familydefault{\sfdefault}
\usepackage[T1]{fontenc}
\usepackage{wrapfig}
\usepackage{setspace}
\usepackage{multicol}
\setlength{\columnsep}{1.5cm}
\usepackage{xspace}
\usepackage{tikz}
\usepackage{lipsum}
\usepackage{tikz}

25
poster/style.tex
View File

@@ -16,10 +16,11 @@
\colorlet{notefgcolor}{background}
\colorlet{notebgcolor}{background}
% Title setup
\settitle{
% Rearrange the order of the minipages to e.g. center the title between the logos
\begin{minipage}[c]{0.6\paperwidth}
\begin{minipage}[c]{0.8\paperwidth}
% \centering
\vspace{2.5cm}\hspace{1.5cm}
\color{text}{\Huge{\textbf{\@title}} \par}
@@ -30,26 +31,28 @@
\vspace{2.5cm}
\end{minipage}
\begin{minipage}[c]{0.2\paperwidth}
% \centering
\vspace{1cm}\hspace{1cm}
\includegraphics[scale=1]{example-image-a}
\end{minipage}
\begin{minipage}[c]{0.2\paperwidth}
% \vspace{1cm}\hspace{1cm}
\centering
\includegraphics[scale=1]{example-image-a}
% \vspace{1cm}
\hspace{-10cm}
\includegraphics[width=\linewidth]{example-image-a}
\end{minipage}}
% \begin{minipage}[c]{0.2\paperwidth}
% \vspace{1cm}\hspace{1cm}
% \centering
% \includegraphics[width=\linewidth]{example-image-a}
% \end{minipage}}
% definie title style with background box
% define title style with background box (currently white)
\definetitlestyle{sampletitle}{
width=1189mm,
width=841mm,
roundedcorners=0,
linewidth=0pt,
innersep=15pt,
titletotopverticalspace=0mm,
titletoblockverticalspace=5pt
}{
\begin{scope}[line width=\titlelinewidth, rounded corners=\titleroundedcorners]
\begin{scope}[line width=\titlelinewidth,
rounded corners=\titleroundedcorners]
\draw[fill=text, color=boxes]
(\titleposleft,\titleposbottom)
rectangle

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poster_old/main.tex Normal file
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@@ -0,0 +1,119 @@
\documentclass[25pt, a0paper, landscape, margin=0mm, innermargin=20mm,
blockverticalspace=2mm, colspace=20mm, subcolspace=0mm]{tikzposter} %Default values for poster format options.
\input{packages}
\input{style}
\begin{document}
\renewcommand{\baselinestretch}{1}
\title{\parbox{1900pt}{Pushing the limits of time-frequency uncertainty in the
detection of transient communication signals in weakly electric fish}}
\author{Sina Prause, Alexander Wendt, Patrick Weygoldt}
\institute{Supervised by Till Raab \& Jan Benda, Neurothology Group,
University of Tübingen}
\usetitlestyle[]{sampletitle}
\maketitle
\renewcommand{\baselinestretch}{1.4}
\begin{columns}
\column{0.5}
\myblock[TranspBlock]{Introduction}{
\begin{minipage}[t]{0.55\linewidth}
The time-frequency tradeoff makes reliable signal detecion and simultaneous
sender identification of freely interacting individuals impossible.
This profoundly limits our current understanding of chirps to experiments
with single - or physically separated - individuals.
\end{minipage} \hfill
\begin{minipage}[t]{0.40\linewidth}
\vspace{-1.5cm}
\begin{tikzfigure}[]
\label{tradeoff}
\includegraphics[width=\linewidth]{figs/introplot}
\end{tikzfigure}
\end{minipage}
}
\myblock[TranspBlock]{A chirp detection algorithm}{
\begin{tikzfigure}[]
\label{modulations}
\includegraphics[width=\linewidth]{figs/algorithm}
\end{tikzfigure}
}
\column{0.5}
\myblock[TranspBlock]{Chirps and diadic competitions}{
\begin{minipage}[t]{0.7\linewidth}
\begin{tikzfigure}[]
\label{modulations}
\includegraphics[width=\linewidth]{figs/placeholder1}
\end{tikzfigure}
\end{minipage} \hfill
\begin{minipage}[t]{0.25\linewidth}
\lipsum[3][1-3]
\end{minipage}
\begin{minipage}[t]{0.7\linewidth}
\begin{tikzfigure}[]
\label{modulations}
\includegraphics[width=\linewidth]{figs/placeholder1}
\end{tikzfigure}
\end{minipage} \hfill
\begin{minipage}[t]{0.25\linewidth}
\lipsum[3][1-3]
\end{minipage}
\begin{minipage}[t]{0.7\linewidth}
\begin{tikzfigure}[]
\label{modulations}
\includegraphics[width=\linewidth]{figs/placeholder1}
\end{tikzfigure}
\end{minipage} \hfill
\begin{minipage}[t]{0.25\linewidth}
\lipsum[3][1-3]
\end{minipage}
}
\myblock[TranspBlock]{Conclusion}{
\lipsum[3][1-9]
}
% \column{0.3}
% \myblock[TranspBlock]{More Results}{
% \begin{tikzfigure}[]
% \label{results}
% \includegraphics[width=\linewidth]{example-image-a}
% \end{tikzfigure}
% \begin{multicols}{2}
% \lipsum[5][1-8]
% \end{multicols}
% \vspace{-1cm}
% }
% \myblock[TranspBlock]{Conclusion}{
% \begin{itemize}
% \setlength\itemsep{0.5em}
% \item \lipsum[1][1]
% \item \lipsum[1][1]
% \item \lipsum[1][1]
% \end{itemize}
% \vspace{0.2cm}
% }
\end{columns}
\node[
above right,
text=white,
outer sep=45pt,
minimum width=\paperwidth,
align=center,
draw,
fill=boxes,
color=boxes,
] at (-0.51\paperwidth,-43.5) {
\textcolor{text}{\normalsize Contact: \{name\}.\{surname\}@student.uni-tuebingen.de}};
\end{document}

11
poster_old/packages.tex Normal file
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\usepackage[utf8]{inputenc}
\usepackage[scaled]{helvet}
\renewcommand\familydefault{\sfdefault}
\usepackage[T1]{fontenc}
\usepackage{wrapfig}
\usepackage{setspace}
\usepackage{multicol}
\setlength{\columnsep}{1.5cm}
\usepackage{xspace}
\usepackage{tikz}
\usepackage{lipsum}

119
poster_old/style.tex Normal file
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\tikzposterlatexaffectionproofoff
\usetheme{Default}
\definecolor{text}{HTML}{e0e4f7}
\definecolor{background}{HTML}{111116}
\definecolor{boxes}{HTML}{2a2a32}
\definecolor{unired}{HTML}{a51e37}
\colorlet{blocktitlefgcolor}{text}
\colorlet{backgroundcolor}{background}
\colorlet{blocktitlebgcolor}{background}
\colorlet{blockbodyfgcolor}{text}
\colorlet{innerblocktitlebgcolor}{background}
\colorlet{innerblocktitlefgcolor}{text}
\colorlet{notefrcolor}{text}
\colorlet{notefgcolor}{background}
\colorlet{notebgcolor}{background}
% Title setup
\settitle{
% Rearrange the order of the minipages to e.g. center the title between the logos
\begin{minipage}[c]{0.6\paperwidth}
% \centering
\vspace{2.5cm}\hspace{1.5cm}
\color{text}{\Huge{\textbf{\@title}} \par}
\vspace*{2em}\hspace{1.5cm}
\color{text}{\LARGE \@author \par}
\vspace*{2em}\hspace{1.5cm}
\color{text}{\Large \@institute}
\vspace{2.5cm}
\end{minipage}
\begin{minipage}[c]{0.2\paperwidth}
% \centering
\vspace{1cm}\hspace{1cm}
\includegraphics[scale=1]{example-image-a}
\end{minipage}
\begin{minipage}[c]{0.2\paperwidth}
% \vspace{1cm}\hspace{1cm}
\centering
\includegraphics[scale=1]{example-image-a}
\end{minipage}}
% definie title style with background box
\definetitlestyle{sampletitle}{
width=1189mm,
roundedcorners=0,
linewidth=0pt,
innersep=15pt,
titletotopverticalspace=0mm,
titletoblockverticalspace=5pt
}{
\begin{scope}[line width=\titlelinewidth, rounded corners=\titleroundedcorners]
\draw[fill=text, color=boxes]
(\titleposleft,\titleposbottom)
rectangle
(\titleposright,\titlepostop);
\end{scope}
}
% define coustom block style for visible blocks
\defineblockstyle{GrayBlock}{
titlewidthscale=1,
bodywidthscale=1,
% titlecenter,
titleleft,
titleoffsetx=0pt,
titleoffsety=-30pt,
bodyoffsetx=0pt,
bodyoffsety=-40pt,
bodyverticalshift=0mm,
roundedcorners=25,
linewidth=1pt,
titleinnersep=20pt,
bodyinnersep=38pt
}{
\draw[rounded corners=\blockroundedcorners, inner sep=\blockbodyinnersep,
line width=\blocklinewidth, color=background,
top color=boxes, bottom color=boxes,
]
(blockbody.south west) rectangle (blockbody.north east); %
\ifBlockHasTitle%
\draw[rounded corners=\blockroundedcorners, inner sep=\blocktitleinnersep,
top color=background, bottom color=background,
line width=2, color=background, %fill=blocktitlebgcolor
]
(blocktitle.south west) rectangle (blocktitle.north east); %
\fi%
}
\newcommand\myblock[3][GrayBlock]{\useblockstyle{#1}\block{#2}{#3}\useblockstyle{Default}}
% Define blockstyle for tranparent block
\defineblockstyle{TranspBlock}{
titlewidthscale=0.99,
bodywidthscale=0.99,
titleleft,
titleoffsetx=15pt,
titleoffsety=-40pt,
bodyoffsetx=0pt,
bodyoffsety=-40pt,
bodyverticalshift=0mm,
roundedcorners=25,
linewidth=1pt,
titleinnersep=20pt,
bodyinnersep=38pt
}{
\draw[rounded corners=\blockroundedcorners, inner sep=\blockbodyinnersep,
line width=\blocklinewidth, color=background,
top color=background, bottom color=background,
]
(blockbody.south west) rectangle (blockbody.north east); %
\ifBlockHasTitle%
\draw[rounded corners=\blockroundedcorners, inner sep=\blocktitleinnersep,
top color=background, bottom color=background,
line width=2, color=background, %fill=blocktitlebgcolor
]
(blocktitle.south west) rectangle (blocktitle.north east); %
\fi%
}
\renewcommand\myblock[3][TranspBlock]{\useblockstyle{#1}\block{#2}{#3}\useblockstyle{Default}}