def join_with_pois(data: DataFrame,
df_pois: DataFrame,
label_id: Optional[Text] = TRAJ_ID,
label_poi_name: Optional[Text] = NAME_POI,
reset_index: Optional[Text] = True):
"""
Performs the integration between trajectories and points
of interest, generating two new columns referring to the
name and the distance from the point of interest closest
to each point of the trajectory.
Parameters
----------
data : DataFrame
The input trajectory data.
df_pois : DataFrame
The input point of interest data.
label_id : str, optional
Label of df_pois referring to the Point of Interest id, by default TRAJ_ID
label_poi_name : str, optional
Label of df_pois referring to the Point of Interest name, by default NAME_POI
reset_index : bool, optional
Flag for reset index of the df_pois and data dataframes before the join,
by default True
"""
print('Integration with POIs...')
values = _reset_and_creates_id_and_lat_lon(data, df_pois, True,
reset_index)
current_distances, ids_POIs, tag_POIs, lat_user, lon_user = values
for idx, row in progress_bar(data.iterrows(), total=len(data)):
# create a vector to each lat
lat_user.fill(row[LATITUDE])
lon_user.fill(row[LONGITUDE])
# computing distances to idx
distances = np.float64(
haversine(
lat_user,
lon_user,
df_pois[LATITUDE].values,
df_pois[LONGITUDE].values,
))
# get index to arg_min and min distance
index_min = np.argmin(distances)
current_distances[idx] = np.min(distances)
# setting data for a single object movement
ids_POIs[idx] = df_pois.at[index_min, label_id]
tag_POIs[idx] = df_pois.at[index_min, label_poi_name]
data[ID_POI] = ids_POIs
data[DIST_POI] = current_distances
data[NAME_POI] = tag_POIs
print('Integration with POI was finalized')
def join_with_home_by_id(
data: DataFrame,
df_home: DataFrame,
label_id: Optional[Text] = TRAJ_ID,
label_address: Optional[Text] = ADDRESS,
label_city: Optional[Text] = CITY,
drop_id_without_home: Optional[bool] = False,
):
"""
It performs the integration between trajectories and home points,
generating new columns referring to the distance of the nearest
home point, address and city of each trajectory point.
Parameters
----------
data : DataFrame
The input trajectory data.
df_home : DataFrame
The input home points data.
label_id : str, optional
Label of df_home referring to the home point id, by default TRAJ_ID
label_address : str, optional
Label of df_home referring to the home point address, by default ADDRESS
label_city : str, optional
Label of df_home referring to the point city, by default CITY
drop_id_without_home : bool, optional
flag as an option to drop id's that don't have houses, by default FALSE
"""
print('Integration with Home...')
ids_without_home = []
if data.index.name is None:
print('...setting {} as index'.format(label_id))
data.set_index(label_id, inplace=True)
for idx in progress_bar(data.index.unique()):
filter_home = df_home[label_id] == idx
if df_home[filter_home].shape[0] == 0:
print('...id: {} has not HOME'.format(idx))
ids_without_home.append(idx)
else:
home = df_home[filter_home].iloc[0]
lat_user = data.at[idx, LATITUDE].values
lon_user = data.at[idx, LONGITUDE].values
# if user has a single tuple
if not isinstance(lat_user, np.ndarray):
lat_home = home[LATITUDE].values
lon_home = home[LONGITUDE].values
data.at[idx, DIST_HOME] = haversine(lat_user, lon_user,
lat_home, lon_home)
data.at[idx, HOME] = home[label_address]
data.at[idx, label_city] = home[label_city]
else:
lat_home = np.full(data.loc[idx].shape[0],
home[LATITUDE],
dtype=np.float64)
lon_home = np.full(data.loc[idx].shape[0],
home[LONGITUDE],
dtype=np.float64)
data.at[idx, DIST_HOME] = haversine(lat_user, lon_user,
lat_home, lon_home)
data.at[idx, HOME] = np.array(home[label_address])
data.at[idx, label_city] = np.array(home[label_city])
data.reset_index(inplace=True)
print('... Resetting index')
if drop_id_without_home:
data.drop(data.loc[data[TRAJ_ID].isin(ids_without_home)].index,
inplace=True)
def join_with_pois_by_dist_and_datetime(
data: DataFrame,
df_pois: DataFrame,
label_date: Optional[Text] = DATETIME,
label_event_id: Optional[Text] = EVENT_ID,
label_event_type: Optional[Text] = EVENT_TYPE,
time_window: Optional[float] = 3600,
radius: Optional[float] = 1000,
):
"""
It performs the integration between trajectories and points of interest,
generating new columns referring to the category of the point of interest,
the distance between the location of the user and location of the poi
based on the distance and on time of each point of the trajectories.
Parameters
----------
data : DataFrame
The input trajectory data.
df_pois : DataFrame
The input events points of interest data.
label_date : str, optional
Label of data referring to the datetime of the input trajectory data,
by default DATETIME
label_event_id : str, optional
Label of df_events referring to the id of the event, by default EVENT_ID
label_event_type : str, optional
Label of df_events referring to the type of the event, by default EVENT_TYPE
time_window : float, optional
tolerable length of time range for assigning the event's
point of interest to the trajectory point, by default 3600
radius: float, optional
maximum radius of pois, by default 1000
"""
print('Integration with Events...')
if label_date not in df_pois:
raise KeyError("POI's DataFrame must contain a %s column" % label_date)
values = _reset_set_window_and_creates_event_id_type_all(
data, df_pois, label_date, time_window)
window_start, window_end, current_distances, event_id, event_type = values
for idx, row in progress_bar(data.iterrows(), total=data.shape[0]):
# set min and max of coordinates by radius
bbox = filters.get_bbox_by_radius((row[LATITUDE], row[LONGITUDE]),
radius)
# filter event by radius
df_filtered = filters.by_bbox(df_pois, bbox)
# filter event by datetime
filters.by_datetime(df_filtered,
start_datetime=window_start[idx],
end_datetime=window_end[idx],
inplace=True)
# get df_filtered size
size_filter = df_filtered.shape[0]
if size_filter > 0:
# reseting index of data frame
df_filtered.reset_index(drop=True, inplace=True)
# create lat and lon array to operation
lat_user = np.full(size_filter, row[LATITUDE], dtype=np.float64)
lon_user = np.full(size_filter, row[LONGITUDE], dtype=np.float64)
# calculate of distances between points
distances = haversine(lat_user, lon_user,
df_filtered[LATITUDE].to_numpy(),
df_filtered[LONGITUDE].to_numpy())
current_distances[idx] = distances
event_type[idx] = df_filtered[label_event_type].to_numpy(
dtype=np.ndarray)
event_id[idx] = df_filtered[label_event_id].to_numpy(
dtype=np.ndarray)
data[label_event_id] = event_id
data[DIST_EVENT] = current_distances
data[label_event_type] = event_type
print('Integration with event was completed')
def join_with_poi_datetime_optimizer(
data: DataFrame,
df_events: DataFrame,
label_date: Optional[Text] = DATETIME,
time_window: Optional[int] = 900,
label_event_id: Optional[Text] = EVENT_ID,
label_event_type: Optional[Text] = EVENT_TYPE):
"""
It performs a optimized integration between trajectories and points
of interest of events, generating new columns referring to
the category of the event, the distance from the nearest
event and the time when the event happened at each point of
the trajectories.
Parameters
----------
data : DataFrame
The input trajectory data.
df_events : DataFrame
The input events points of interest data.
label_date : str, optional
Label of data referring to the datetime of the input trajectory data,
by default DATETIME
time_window : float, optional
tolerable length of time range for assigning the event's
point of interest to the trajectory point, by default 900
label_event_id : str, optional
Label of df_events referring to the id of the event, by default EVENT_ID
label_event_type : str, optional
Label of df_events referring to the type of the event, by default EVENT_TYPE
"""
print('Integration with Events...')
values = _reset_set_window__and_creates_event_id_type(
data, df_events, label_date, time_window)
window_starts, window_ends, current_distances, event_id, event_type = values
minimum_distances = np.full(data.shape[0], np.Infinity, dtype=np.float64)
# Rename for access columns of each row directly
df_events.rename(columns={
label_event_id: label_event_id,
label_event_type: label_event_type
},
inplace=True)
for idx, row in progress_bar(df_events.iterrows(), total=len(df_events)):
df_filtered = filters.by_datetime(data, window_starts[idx],
window_ends[idx])
size_filter = df_filtered.shape[0]
if size_filter > 0:
indexes = df_filtered.index
lat_event = np.full(df_filtered.shape[0],
row[LATITUDE],
dtype=np.float64)
lon_event = np.full(df_filtered.shape[0],
row[LONGITUDE],
dtype=np.float64)
# First iteration is minimum distances
if idx == 0:
minimum_distances[indexes] = haversine(
lat_event,
lon_event,
df_filtered[LATITUDE].values,
df_filtered[LONGITUDE].values,
)
event_id[indexes] = row.event_id
event_type[indexes] = row.event_type
else:
current_distances[indexes] = haversine(
lat_event,
lon_event,
df_filtered[LATITUDE].values,
df_filtered[LONGITUDE].values,
)
compare = current_distances < minimum_distances
index_True = np.where(compare is True)[0]
minimum_distances = np.minimum(current_distances,
minimum_distances)
event_id[index_True] = row.event_id
event_type[index_True] = row.event_type
data[label_event_id] = event_id
data[DIST_EVENT] = minimum_distances
data[label_event_type] = event_type
print('Integration with events was completed')
def join_with_poi_datetime(data: DataFrame,
df_events: DataFrame,
label_date: Optional[Text] = DATETIME,
time_window: Optional[int] = 900,
label_event_id: Optional[Text] = EVENT_ID,
label_event_type: Optional[Text] = EVENT_TYPE):
"""
It performs the integration between trajectories and points
of interest, generating new columns referring to the
category of the point of interest, the distance from the
nearest point of interest based on time of each point of
the trajectories.
Parameters
----------
data : DataFrame
The input trajectory data.
df_events : DataFrame
The input events points of interest data.
label_date : str, optional
Label of data referring to the datetime of the input trajectory data,
by default DATETIME
time_window : float, optional
tolerable length of time range for assigning the event's
point of interest to the trajectory point, by default 900
label_event_id : str, optional
Label of df_events referring to the id of the event, by default EVENT_ID
label_event_type : str, optional
Label of df_events referring to the type of the event, by default EVENT_TYPE
"""
print('Integration with Events...')
values = _reset_set_window__and_creates_event_id_type(
data, df_events, label_date, time_window)
window_starts, window_ends, current_distances, event_id, event_type = values
for idx in progress_bar(data.index):
# filter event by datetime
df_filtered = filters.by_datetime(df_events, window_starts[idx],
window_ends[idx])
size_filter = df_filtered.shape[0]
if size_filter > 0:
df_filtered.reset_index(drop=True, inplace=True)
lat_user = np.full(size_filter,
data.at[idx, LATITUDE],
dtype=np.float64)
lon_user = np.full(size_filter,
data.at[idx, LONGITUDE],
dtype=np.float64)
# compute dist to poi filtered
distances = haversine(
lat_user,
lon_user,
df_filtered[LATITUDE].values,
df_filtered[LONGITUDE].values,
)
# get index to arg_min
index_arg_min = np.argmin(distances)
# get min distances
min_distance = np.min(distances)
# store data
current_distances[idx] = min_distance
event_type[idx] = df_filtered.at[index_arg_min, label_event_type]
event_id[idx] = df_filtered.at[index_arg_min, label_event_id]
data[label_event_id] = event_id
data[DIST_EVENT] = current_distances
data[label_event_type] = event_type
print('Integration with event was completed')
def join_with_pois_by_category(data: DataFrame,
df_pois: DataFrame,
label_category: Optional[Text] = TYPE_POI,
label_id: Optional[Text] = TRAJ_ID):
"""
It performs the integration between trajectories and points
of interest, generating new columns referring to the
category and distance from the nearest point of interest
that has this category at each point of the trajectory.
Parameters
----------
data : DataFrame
The input trajectory data.
df_pois : DataFrame
The input point of interest data.
label_category : str, optional
Label of df_pois referring to the point of interest category, by default TYPE_POI
label_id : str, optional
Label of df_pois referring to the point of interest id, by default TRAJ_ID
"""
print('Integration with POIs...')
# get a vector with windows time to each point
data.reset_index(drop=True, inplace=True)
df_pois.reset_index(drop=True, inplace=True)
# create numpy array to store new column to DataFrame of movement objects
current_distances = np.full(data.shape[0], np.Infinity, dtype=np.float64)
ids_POIs = np.full(data.shape[0], np.NAN, dtype='object_')
unique_categories = df_pois[label_category].unique()
size_categories = len(unique_categories)
print('There are %s categories' % size_categories)
for i, c in enumerate(unique_categories, start=1):
# creating lat and lon array to operation
df_category = df_pois[df_pois[label_category] == c]
df_category.reset_index(drop=True, inplace=True)
desc = 'computing dist to {} category ({}/{})'.format(
c, i, size_categories)
for idx, row in progress_bar(data.iterrows(),
total=len(data),
desc=desc):
lat_user = np.full(df_category.shape[0],
row[LATITUDE],
dtype=np.float64)
lon_user = np.full(df_category.shape[0],
row[LONGITUDE],
dtype=np.float64)
# computing distances to
distances = haversine(
lat_user,
lon_user,
df_category[LATITUDE].values,
df_category[LONGITUDE].values,
)
# get index to arg_min and min distance
index_min = np.argmin(distances)
# setting data for a single object movement
current_distances[idx] = np.min(distances)
ids_POIs[idx] = df_category.at[index_min, label_id]
data['id_%s' % c] = ids_POIs
data['dist_%s' % c] = current_distances
print('Integration with POI was finalized')
def join_with_pois_optimizer(data,
df_pois: DataFrame,
label_id: Optional[Text] = TRAJ_ID,
label_poi_name: Optional[Text] = NAME_POI,
dist_poi: Optional[List] = None,
reset_index: Optional[Text] = True):
"""
Performs the integration between trajectories and points
of interest, generating two new columns referring to the
name and distance from the nearest point of interest,
within the limit of distance determined by the parameter 'dist_poi',
of each point in the trajectory.
Parameters
----------
data : DataFrame
The input trajectory data.
df_pois : DataFrame
The input point of interest data.
label_id : str, optional
Label of df_pois referring to the Point of Interest id, by default TRAJ_ID
label_poi_name : str, optional
Label of df_pois referring to the Point of Interest name, by default NAME_POI
dist_poi : list, optional
List containing the minimum distance limit between each type of
point of interest and each point of the trajectory to classify the
point of interest closest to each point of the trajectory, by default None
reset_index : bool, optional
Flag for reset index of the df_pois and data dataframes before the join,
by default True
"""
print('Integration with POIs optimized...')
if len(df_pois[label_poi_name].unique()) == len(dist_poi):
values = _reset_and_creates_id_and_lat_lon(data, df_pois, False,
reset_index)
minimum_distances, ids_POIs, tag_POIs, lat_POI, lon_POI = values
df_pois.rename(columns={
label_id: TRAJ_ID,
label_poi_name: NAME_POI
},
inplace=True)
for idx, row in progress_bar(df_pois.iterrows(), total=len(df_pois)):
# update lat and lon of current index
lat_POI.fill(row[LATITUDE])
lon_POI.fill(row[LONGITUDE])
# First iteration is minimum distances
if idx == 0:
minimum_distances = np.float64(
haversine(lat_POI, lon_POI, data[LATITUDE].values,
data[LONGITUDE].values))
ids_POIs.fill(row.id)
tag_POIs.fill(row.type_poi)
else:
# compute dist between a POI and ALL
print(data[LONGITUDE].values)
current_distances = np.float64(
haversine(lat_POI, lon_POI, data[LATITUDE].values,
data[LONGITUDE].values))
compare = current_distances < minimum_distances
index_True = np.where(compare is True)[0]
minimum_distances = np.minimum(current_distances,
minimum_distances,
dtype=np.float64)
if index_True.shape[0] > 0:
ids_POIs[index_True] = row.id
tag_POIs[index_True] = row.type_poi
data[ID_POI] = ids_POIs
data[DIST_POI] = minimum_distances
data[NAME_POI] = tag_POIs
print('Integration with POI was finalized')
else:
print('the size of the dist_poi is different from the size of pois')
def join_with_home_by_id(
df_,
df_home,
label_id=TRAJ_ID,
label_address=ADDRESS,
label_city=CITY,
drop_id_without_home=False,
):
"""
It performs the integration between trajectories and home points,
generating new columns referring to the distance of the nearest
home point, address and city of each trajectory point.
Parameters
----------
df_ : dataframe
The input trajectory data.
df_home : dataframe
The input home points data.
label_id : String, optional("id" by default)
Label of df_home referring to the home point id.
label_address : String, optional("formatted_address" by default)
Label of df_home referring to the home point address.
label_city : String, optional("city" by default)
Label of df_home referring to the point city.
drop_id_without_home : Boolean, optional(False by default)
flag as an option to drop id's that don't have houses.
"""
try:
print('Integration with Home...')
ids_without_home = []
if df_.index.name is None:
print('...setting {} as index'.format(label_id))
df_.set_index(label_id, inplace=True)
for idx in progress_bar(df_.index.unique()):
filter_home = df_home[label_id] == idx
if df_home[filter_home].shape[0] == 0:
print('...id: {} has not HOME'.format(idx))
ids_without_home.append(idx)
else:
home = df_home[filter_home].iloc[0]
lat_user = df_.at[idx, LATITUDE]
lon_user = df_.at[idx, LONGITUDE]
# if user has a single tuple
if not isinstance(lat_user, np.ndarray):
df_.at[idx, DIST_HOME] = haversine(lat_user, lon_user,
home[LATITUDE],
home[LONGITUDE])
df_.at[idx, HOME] = home[label_address]
df_.at[idx, label_city] = home[label_city]
else:
lat_home = np.full(df_.loc[idx].shape[0],
home[LATITUDE],
dtype=np.float64)
lon_home = np.full(df_.loc[idx].shape[0],
home[LONGITUDE],
dtype=np.float64)
df_.at[idx, DIST_HOME] = haversine(lat_user, lon_user,
lat_home, lon_home)
df_.at[idx, HOME] = np.array(home[label_address])
df_.at[idx, label_city] = np.array(home[label_city])
df_.reset_index(inplace=True)
print('... Resetting index')
if drop_id_without_home:
for tid in ids_without_home:
df_.drop(df_.loc[df_[TRAJ_ID] == tid].index, inplace=True)
except Exception as e:
raise e
def join_with_pois(df_,
df_pois,
label_id=TRAJ_ID,
label_poi_name=NAME_POI,
reset_index=True):
"""
Performs the integration between trajectories and points
of interest, generating two new columns referring to the
name and the distance from the point of interest closest
to each point of the trajectory.
Parameters
----------
df_ : dataframe
The input trajectory data.
df_pois : dataframe
The input point of interest data.
label_id : String, optional("id" by default)
Label of df_pois referring to the Point of Interest id.
label_poi_name : String, optional("type_poi" by default)
Label of df_pois referring to the Point of Interest name.
reset_index : Boolean, optional(True by default)
Flag for reset index of the df_pois and df_ dataframes before the join.
"""
try:
print('Integration with POIs...')
values = _reset_and_creates_id_and_lat_lon(df_, df_pois, True,
reset_index)
current_distances, ids_POIs, tag_POIs, lat_user, lon_user = values
for idx, row in progress_bar(df_.iterrows(), total=len(df_)):
# create a vector to each lat
lat_user.fill(row[LATITUDE])
lon_user.fill(row[LONGITUDE])
# computing distances to idx
distances = np.float64(
haversine(
lat_user,
lon_user,
df_pois[LATITUDE].values,
df_pois[LONGITUDE].values,
))
# get index to arg_min and min distance
index_min = np.argmin(distances)
current_distances[idx] = np.min(distances)
# setting data for a single object movement
ids_POIs[idx] = df_pois.at[index_min, label_id]
tag_POIs[idx] = df_pois.at[index_min, label_poi_name]
df_[ID_POI] = ids_POIs
df_[DIST_POI] = current_distances
df_[NAME_POI] = tag_POIs
print('Integration with POI was finalized')
except Exception as e:
raise e
