Filter out troughs based on distance between peaks

Important note: Because this answer was quite long already, I've decided to rewrite it completely, instead of updating it a 5th time. Go check out the version history if you're interested in the "historical context"


First, run some required imports:

import pandas as pd
import numpy as np

import matplotlib.pyplot as plt
from matplotlib import gridspec
import matplotlib as mpl
mpl.style.use('seaborn-paper') ## for nicer looking plots only

from lmfit import fit_report
from lmfit.models import GaussianModel, BreitWignerModel

Then clean up the data (as posted above, saved as .csv):

df=pd.read_csv('pdFilterDates.txt',delim_whitespace=True) ## data as given above
df['date'] = pd.to_datetime(df['date'],format = '%m/%d/%Y')

## initial cleanup
df=df.dropna() ## clean initial NA values, e.g. 3/10/2018

## there is a duplicate at datetime.date(2018, 6, 21):
# print(df['date'][df.date.duplicated()].dt.date.values) 
df=df.groupby('date').mean().reset_index() ## so we take a mean value here
# print(df['date'][df.date.duplicated()].dt.date.values) ## see, no more duplicates

df = df.set_index('date',drop=False) ## now we can set date as index

and re-index it on a daily frequency:

complete_date_range_idx = pd.date_range(df.index.min(), df.index.max(),freq='D') 
df_filled=df.reindex(complete_date_range_idx, fill_value=np.nan).reset_index()
## obtain index values, which can be understood as time delta in days from the start

idx=df_filled.index.values ## this will be used again, in the end

## now we obtain (x,y) on basis of idx
not_na=pd.notna(df_filled['Values'])
x=idx[not_na]     ## len: 176 
y=df_filled['Values'][not_na].values

### let's write over the original df
df=df_filled 
#####

And now for the interesting part: fitting the data with some asymmetric lineshape (Breit-Wigner-Fano) and remove the "outliers" that lie below a certain threshold. We do this first by manually declaring where this peak is supposed to be (our initial guess, we can remove 3 points), then we do it again by using the fit (fit 1) as input (removing 8 points) and finally obtain our final fit.

As requested, we can now interpolate the fit back on the daily index that we have created before (bwf_result_final.eval(x=idx)) and create additional columns in the dataframe: y_fine, which holds only the fit, y_final, which holds the final point cloud (i.e. after the outlier removal), and a joined dataset (which looks "jagged") y_joined. Finally, we can plot this on basis of the "fine" data range (df['index']).

Figure 1: iteratively removing outliers

Figure 2: cleaned up dataset

# choose an asymmetric line shape (Fano resonance)
bwf_model = BreitWignerModel()

# make initial guesses: 
params = bwf_model.make_params(center=75, amplitude=0.2, sigma=20, q=1/0.2)

# plot initial guess and fit result    
bwf_result = bwf_model.fit(y, params, x=x)

####------------------ create first figure----------
fig=plt.figure(figsize=(8,3),frameon=True,)
gs1 = gridspec.GridSpec(1,3,
    left=0.08,right=0.95,
    bottom=0.15,top=0.9,
    wspace=0.1
)

a1=plt.subplot(gs1[0])
a2=plt.subplot(gs1[1])
a3=plt.subplot(gs1[2])


#------------------ first subplot ------------------
a1.set_title('Outliers from 1st guess')
## show initial x,y
a1.scatter(x,y,facecolors='None',edgecolors='b',marker='o',linewidth=1,zorder=3)

# outliers=np.argwhere(np.abs(y-bwf_result.init_fit)>1.9) ## if you want to exclude points both above and below
outliers=np.argwhere(( bwf_result.init_fit -y ) >1.9)

# remove outliers from point cloud
x_new=np.delete(x,outliers)
y_new=np.delete(y,outliers)

#### run a fit on the "cleaned" dataset
bwf_result_mod = bwf_model.fit(y_new, params, x=x_new)

a1.plot(x, bwf_result.init_fit, 'r--',label='initial guess')
a1.fill_between(x, bwf_result.init_fit, bwf_result.init_fit-1.9, color='r', hatch='///',alpha=0.2,zorder=1,label=u'guess - 1.9')
a1.scatter(x[outliers],y[outliers],c='r',marker='x',s=10**2,linewidth=1,zorder=4,label='outliers') ## show outliers
a1.plot(x_new, bwf_result_mod.best_fit, color='g',label='fit 1')

pointsRemoved=len(y)-len(y_new)
a1.text(1.05,0.5,u'↓{0} points removed'.format(pointsRemoved),ha='center',va='center',rotation=90,transform=a1.transAxes)

#------------------ second plot ------------------
a2.set_title('Outliers from 1st fit')
## show initial x,y
a2.scatter(x,y,facecolors='None',edgecolors='grey',marker='o',linewidth=.5,zorder=0,label='original data')

a2.scatter(x_new,y_new,facecolors='None',edgecolors='b',marker='o',linewidth=1,zorder=3)
a2.plot(x_new, bwf_result_mod.best_fit, color='g',label='fit 1')

# new_outliers=np.argwhere(np.abs(bwf_result_mod.residual)>0.8) ## if you want to exclude points both above and below
new_outliers=np.argwhere( bwf_result_mod.residual >0.8)

x_new_2=np.delete(x_new,new_outliers)
y_new_2=np.delete(y_new,new_outliers)

a2.scatter(x_new[new_outliers],y_new[new_outliers],c='r',marker='x',s=10**2,linewidth=1,zorder=4,label='new outliers')
a2.fill_between(x_new, bwf_result_mod.best_fit, bwf_result_mod.best_fit-0.8, color='r', hatch='///',alpha=0.2,zorder=1,label=u'fit - 0.8')

pointsRemoved=len(y_new)-len(y_new_2)
a2.text(1.05,0.5,u'↓{0} points removed'.format(pointsRemoved),ha='center',va='center',rotation=90,transform=a2.transAxes)

#------------------ third plot ------------------
_orig=len(y)
_remo=(len(y)-len(y_new_2))
_pct=_remo/(_orig/100.)
a3.set_title(u'Result ({0} of {1} removed, ~{2:.0f}%)'.format(_orig,_remo,_pct ))

x_final=np.delete(x_new,new_outliers)
y_final=np.delete(y_new,new_outliers)

## store final point cloud in the df
df.loc[x_final,'y_final']=y_final

a3.scatter(x_final,y_final,facecolors='None',edgecolors='b',marker='o',linewidth=1,zorder=3)

## make final fit:
bwf_result_final = bwf_model.fit(y_final, params, x=x_final)
a3.scatter(x,y,facecolors='None',edgecolors='grey',marker='o',linewidth=.5,zorder=0,label='original data')

a3.plot(x_final, bwf_result_final.best_fit, color='g',label='fit 2')

## now that we are "happy" with bwf_result_final, let's apply it on the df's "fine" (i.e. daily) index!
y_fine=bwf_result_final.eval(x=idx)
## 
df['y_fine']=y_fine # store fit function
df['y_joined']=df['y_final'] # store final point cloud
df['y_joined'][df['y_final'].isnull()]=df['y_fine'] # join fit function points with final point cloud

####------------------ create second figure----------

fig2=plt.figure(figsize=(8,3),frameon=True,)
gs2 = gridspec.GridSpec(1,1,
    left=0.08,right=0.95,
    bottom=0.15,top=0.9,
    wspace=0.1
)
ax2=plt.subplot(gs2[0])


ax2.scatter(df['date'],df['Values'],facecolors='None',edgecolors='grey',marker='o',linewidth=1,zorder=0,label='original data')
ax2.plot(df['index'],df['y_fine'],c="g",zorder=3,label="final fit applied to all dates")
ax2.plot(df['index'],df['y_joined'],color="r",marker=".",markersize=6,zorder=2,label="(points-outliers) +fit ")

# print(df.head(30))

for a in [a1,a2,a3,ax2]:
    a.set_ylim(-.5,7)
    a.legend()

a1.set_ylabel('Value')
ax2.set_ylabel('Value')

for a in [a2,a3]:
    plt.setp(a.get_yticklabels(),visible=False)
for a in [a1,a2,a3,ax2]:
    a.set_xlabel('Days from start')

fig.savefig('outlier_removal.pdf')
fig2.savefig('final_data.pdf')
plt.show()