calls_sms_features() now returns all communication features.

Compile a list of contact features and add a test.
Add a test for SMS features.
2021-08-18 15:41:47 +02:00 · 2021-08-18 15:35:42 +02:00 · 2021-08-18 15:28:46 +02:00 · 2021-08-18 15:23:30 +02:00 · 2021-08-18 10:54:54 +02:00 · 2021-08-18 10:51:48 +02:00
9 changed files with 365 additions and 106 deletions
--- a/data/example_proximity.csv
+++ b/data/example_proximity.csv
@ -0,0 +1,63 @@
 id,timestamp,device_id,_id,double_proximity,accuracy,label,dateTime
 39017,1565802024310,f67354f7-d675-4b76-80c8-123cc4744a5b,2962,0,3,,2019-08-14T17:00:24Z
 39018,1565802051075,f67354f7-d675-4b76-80c8-123cc4744a5b,2963,0,3,,2019-08-14T17:00:51Z
 39019,1565802051354,f67354f7-d675-4b76-80c8-123cc4744a5b,2964,8,3,,2019-08-14T17:00:51Z
 39089,1565010418305,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,51,5,3,,2019-08-05T13:06:58Z
 39090,1565010772188,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,52,5,3,,2019-08-05T13:12:52Z
 39091,1565012334450,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,53,5,3,,2019-08-05T13:38:54Z
 39092,1565013000660,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,54,5,3,,2019-08-05T13:50:00Z
 39093,1565022742894,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,55,0,3,,2019-08-05T16:32:22Z
 39094,1565089295906,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,56,5,3,,2019-08-06T11:01:35Z
 39095,1565096030817,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,57,0,3,,2019-08-06T12:53:50Z
 39096,1565096367694,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,58,5,3,,2019-08-06T12:59:27Z
 39097,1565096408570,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,59,5,3,,2019-08-06T13:00:08Z
 39098,1565116821528,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,60,5,3,,2019-08-06T18:40:21Z
 39099,1565131345333,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,61,0,3,,2019-08-06T22:42:25Z
 39100,1565131375072,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,62,5,3,,2019-08-06T22:42:55Z
 39101,1565131386353,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,63,0,3,,2019-08-06T22:43:06Z
 39102,1565131389213,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,64,5,3,,2019-08-06T22:43:09Z
 39103,1565131448891,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,65,0,3,,2019-08-06T22:44:08Z
 39104,1565131454131,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,66,5,3,,2019-08-06T22:44:14Z
 39105,1565176143083,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,67,0,3,,2019-08-07T11:09:03Z
 39106,1565179569310,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,68,5,3,,2019-08-07T12:06:09Z
 39107,1565180699173,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,69,5,3,,2019-08-07T12:24:59Z
 39108,1565182538578,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,70,5,3,,2019-08-07T12:55:38Z
 39109,1565192592776,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,71,0,3,,2019-08-07T15:43:12Z
 39110,1565216023797,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,72,5,3,,2019-08-07T22:13:43Z
 39111,1565248358647,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,73,0,3,,2019-08-08T07:12:38Z
 39112,1565275859157,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,74,5,3,,2019-08-08T14:50:59Z
 39113,1565304201431,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,75,0,3,,2019-08-08T22:43:21Z
 39114,1565304229591,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,76,5,3,,2019-08-08T22:43:49Z
 39115,1565304262050,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,77,0,3,,2019-08-08T22:44:22Z
 39116,1565613142970,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,78,5,3,,2019-08-12T12:32:22Z
 39117,1565618266531,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,79,5,3,,2019-08-12T13:57:46Z
 39118,1565618410488,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,80,5,3,,2019-08-12T14:00:10Z
 39119,1565618704942,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,81,5,3,,2019-08-12T14:05:04Z
 39120,1565619005315,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,82,5,3,,2019-08-12T14:10:05Z
 39121,1565619405904,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,83,5,3,,2019-08-12T14:16:45Z
 39122,1565619678037,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,84,5,3,,2019-08-12T14:21:18Z
 39123,1565621206713,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,85,5,3,,2019-08-12T14:46:46Z
 39124,1565626622125,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,86,5,3,,2019-08-12T16:17:02Z
 39125,1565684876738,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,87,5,3,,2019-08-13T08:27:56Z
 39126,1565684956618,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,88,5,3,,2019-08-13T08:29:16Z
 39127,1565684965647,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,89,5,3,,2019-08-13T08:29:25Z
 39128,1565685092246,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,90,5,3,,2019-08-13T08:31:32Z
 39129,1565685136337,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,91,5,3,,2019-08-13T08:32:16Z
 39130,1565685147453,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,92,5,3,,2019-08-13T08:32:27Z
 39131,1565685212523,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,93,5,3,,2019-08-13T08:33:32Z
 39132,1565703397796,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,94,0,3,,2019-08-13T13:36:37Z
 39133,1565776203019,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,95,5,3,,2019-08-14T09:50:03Z
 39134,1565776434168,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,96,5,3,,2019-08-14T09:53:54Z
 39135,1565776435231,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,97,0,3,,2019-08-14T09:53:55Z
 39136,1565776443368,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,98,5,3,,2019-08-14T09:54:03Z
 39137,1565779277109,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,99,0,3,,2019-08-14T10:41:17Z
 39138,1565780016327,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,100,5,3,,2019-08-14T10:53:36Z
 39139,1565780027437,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,101,5,3,,2019-08-14T10:53:47Z
 39140,1565783470934,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,102,5,3,,2019-08-14T11:51:10Z
 39141,1565783801540,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,103,0,3,,2019-08-14T11:56:41Z
 39142,1565783802120,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,104,5,3,,2019-08-14T11:56:42Z
 39143,1565783861495,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,105,5,3,,2019-08-14T11:57:41Z
 39144,1565785318762,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,106,0,3,,2019-08-14T12:21:58Z
 39145,1565785319346,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,107,5,3,,2019-08-14T12:21:59Z
 39146,1565960121019,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,108,5,3,,2019-08-16T12:55:21Z
 39147,1565960226792,fdb06d4a-ee6e-4336-9a96-fc8d2715f243,109,5,3,,2019-08-16T12:57:06Z
--- a/exploration/ex_ml_pipeline.py
+++ b/exploration/ex_ml_pipeline.py
@ -148,3 +148,28 @@ lin_reg_proximity.score(
    df_full_data_daily_means[["freq_prox_near", "prop_prox_near"]],
    df_full_data_daily_means["PA"],
 )
 # %% [markdown]
 # # Merging these into a pipeline
 # %%
 from machine_learning import pipeline
 # %%
 ml_pipeline = pipeline.MachineLearningPipeline(
    labels_questionnaire="PANAS", data_types="proximity"
 )
 # %%
 ml_pipeline.get_labels()
 # %% tags=[]
 ml_pipeline.get_sensor_data()
 # %%
 ml_pipeline.aggregate_daily()
 # %%
 ml_pipeline.df_full_data_daily_means
 # %%
--- a/features/communication.py
+++ b/features/communication.py
@ -8,6 +8,43 @@ from setup import db_engine, session
 call_types = {1: "incoming", 2: "outgoing", 3: "missed"}
 sms_types = {1: "received", 2: "sent"}
 FEATURES_CALLS = (
    ["no_calls_all"]
    + ["no_" + call_type for call_type in call_types.values()]
    + ["duration_total_" + call_types.get(1), "duration_total_" + call_types.get(2)]
    + ["duration_max_" + call_types.get(1), "duration_max_" + call_types.get(2)]
    + ["no_" + call_types.get(1) + "_ratio", "no_" + call_types.get(2) + "_ratio"]
    + ["no_contacts_calls"]
 )
 # FEATURES_CALLS =
 # ["no_calls_all",
 # "no_incoming", "no_outgoing", "no_missed",
 # "duration_total_incoming", "duration_total_outgoing",
 # "duration_max_incoming", "duration_max_outgoing",
 # "no_incoming_ratio", "no_outgoing_ratio",
 # "no_contacts"]
 FEATURES_SMS = (
    ["no_sms_all"]
    + ["no_" + sms_type for sms_type in sms_types.values()]
    + ["no_" + sms_types.get(1) + "_ratio", "no_" + sms_types.get(2) + "_ratio"]
    + ["no_contacts_sms"]
 )
 # FEATURES_SMS =
 # ["no_sms_all",
 #  "no_received", "no_sent",
 #  "no_received_ratio", "no_sent_ratio",
 #  "no_contacts"]
 FEATURES_CONTACT = [
    "proportion_calls_all",
    "proportion_calls_incoming",
    "proportion_calls_outgoing",
    "proportion_calls_contacts",
    "proportion_calls_missed_sms_received",
 ]
 def get_call_data(usernames: Collection) -> pd.DataFrame:
    """
@ -114,10 +151,12 @@ def count_comms(comm_df: pd.DataFrame) -> pd.DataFrame:
        These are:
        * the number of calls by type (incoming, outgoing missed) and in total,
        * the ratio of incoming and outgoing calls to the total number of calls,
-        * the total and maximum duration of calls by type, and
+        * the total and maximum duration of calls by type,
-        * the number of messages by type (received, sent).
+        * the number of messages by type (received, sent), and
        * the number of communication contacts by type. 
    """
    if "call_type" in comm_df:
        data_type = "calls"
        comm_counts = (
            comm_df.value_counts(subset=["participant_id", "call_type"])
            .unstack()
@ -125,11 +164,11 @@ def count_comms(comm_df: pd.DataFrame) -> pd.DataFrame:
            .add_prefix("no_")
        )
        # Count calls by type.
-        comm_counts["no_all"] = comm_counts.sum(axis=1)
+        comm_counts["no_calls_all"] = comm_counts.sum(axis=1)
        # Add a total count of calls.
        comm_counts = comm_counts.assign(
-            no_incoming_ratio=lambda x: x.no_incoming / x.no_all,
+            no_incoming_ratio=lambda x: x.no_incoming / x.no_calls_all,
-            no_outgoing_ratio=lambda x: x.no_outgoing / x.no_all,
+            no_outgoing_ratio=lambda x: x.no_outgoing / x.no_calls_all,
        )
        # Ratio of incoming and outgoing calls to all calls.
        comm_duration_total = (
@ -159,44 +198,56 @@ def count_comms(comm_df: pd.DataFrame) -> pd.DataFrame:
        # If there were no missed calls, this exception is raised.
        # But we are dropping the column anyway, so no need to deal with the exception.
    elif "message_type" in comm_df:
        data_type = "sms"
        comm_counts = (
            comm_df.value_counts(subset=["participant_id", "message_type"])
            .unstack()
            .rename(columns=sms_types)
            .add_prefix("no_")
        )
-        comm_counts["no_all"] = comm_counts.sum(axis=1)
+        comm_counts["no_sms_all"] = comm_counts.sum(axis=1)
        # Add a total count of messages.
        comm_features = comm_counts.assign(
-            no_received_ratio=lambda x: x.no_received / x.no_all,
+            no_received_ratio=lambda x: x.no_received / x.no_sms_all,
-            no_sent_ratio=lambda x: x.no_sent / x.no_all,
+            no_sent_ratio=lambda x: x.no_sent / x.no_sms_all,
        )
        # Ratio of incoming and outgoing messages to all messages.
    else:
        raise KeyError("The dataframe contains neither call_type or message_type")
    comm_contacts_counts = (
        enumerate_contacts(comm_df)
        .groupby(["participant_id"])
        .nunique()["contact_id"]
        .rename("no_contacts_" + data_type)
    )
    # Number of communication contacts
    comm_features = comm_features.join(comm_contacts_counts)
    return comm_features
-def contact_features(df_enumerated: pd.DataFrame) -> pd.DataFrame:
+def contact_features(comm_df: pd.DataFrame) -> pd.DataFrame:
    """
-    Counts the number of people contacted (for each participant) and, if
+    For each participant and for each of his contacts, this function
-    df_enumerated is a dataframe containing calls data, the total duration
+    counts the number of communications (by type) between them. If the
-    of calls between a participant and each of her contacts. 
+    argument passed is a dataframe with calls data, it additionally counts
    the total duration of calls between every pair (participant, contact).
    Parameters
    ----------
-    df_enumerated: pd.DataFrame
+    comm_df: pd.DataFrame
-        A dataframe of calls or SMSes; return of function enumerate_contacts.
+        A dataframe of calls or SMSes.
    Returns
    -------
    comm_df: pd.DataFrame
-        The altered dataframe with the column no_contacts and, if df_enumerated
+        A new dataframe with a row for each pair (participant, contact).
        contains calls data, an additional column total_call_duration.
    """
-
+    df_enumerated = enumerate_contacts(comm_df)
    contacts_count = (
        df_enumerated.groupby(["participant_id", "contact_id"]).size().reset_index()
    )
    # Check whether df contains calls or SMS data since some
-    # features we want to calculate are type-specyfic
+    # features we want to calculate are type-specific
    if "call_duration" in df_enumerated:
        # Add a column with the total duration of calls between two people
        duration_count = (
@ -207,33 +258,14 @@ def contact_features(df_enumerated: pd.DataFrame) -> pd.DataFrame:
            .reset_index()  # Make index (which is actually the participant id) a normal column
            .rename(columns={"call_duration": "total_call_duration"})
        )
-        # The new dataframe now contains columns containing information about
+        contacts_count = contacts_count.merge(
        # participants, callers and the total duration of their calls. All that
        # is now left to do is to merge the original df with the new one.
        df_enumerated = df_enumerated.merge(
            duration_count, on=["participant_id", "contact_id"]
        )
-
+        contacts_count.rename(columns={0: "no_calls"}, inplace=True)
-    contact_count = (
+    else:
-        df_enumerated.groupby(["participant_id"])
+        contacts_count.rename(columns={0: "no_sms"}, inplace=True)
        .nunique()[
            "contact_id"
        ]  # For each participant, count the number of distinct contacts
        .reset_index()  # Make index (which is actually the participant id) a normal column
        .rename(columns={"contact_id": "no_contacts"})
    )
    df_enumerated = (
        # Merge df with the newely created df containing info about number of contacts
        df_enumerated.merge(contact_count, on="participant_id")
        # Sort first by participant_id and then by contact_id and
        # thereby restore the inital ordering of input dataframes.
        .sort_values(["participant_id", "contact_id"])
    )
    # TODO:Determine work vs non-work contacts by work hours heuristics
-
+    return contacts_count
    return df_enumerated
 def calls_sms_features(df_calls: pd.DataFrame, df_sms: pd.DataFrame) -> pd.DataFrame:
@ -245,14 +277,14 @@ def calls_sms_features(df_calls: pd.DataFrame, df_sms: pd.DataFrame) -> pd.DataF
    df_calls: pd.DataFrame
        A dataframe of calls (return of get_call_data).
    df_sms: pd.DataFrame
-        A dataframe of calls (return of get_sms_data).
+        A dataframe of SMSes (return of get_sms_data).
    Returns
    -------
    df_calls_sms: pd.DataFrame
        The list of features relating calls and sms data for every participant.
        These are:
-        * proportion_calls:
+        * proportion_calls_all:
            proportion of calls in total number of communications
        * proportion_calls_incoming:
            proportion of incoming calls in total number of incoming/received communications
@ -263,18 +295,11 @@ def calls_sms_features(df_calls: pd.DataFrame, df_sms: pd.DataFrame) -> pd.DataF
        * proportion_calls_contacts:
            proportion of calls contacts in total number of communication contacts
    """
    count_calls = count_comms(df_calls)
    count_sms = count_comms(df_sms)
-
+    count_joined = count_calls.join(count_sms).assign(
-    count_joined = (
+        proportion_calls_all=(
-        count_calls.merge(
+            lambda x: x.no_calls_all / (x.no_calls_all + x.no_sms_all)
            count_sms, on="participant_id", suffixes=("_calls", "_sms")
        )  # Merge calls and sms features
        .reset_index()  # Make participant_id a regular column
        .assign(
            proportion_calls=(
                lambda x: x.no_all_calls / (x.no_all_calls + x.no_all_sms)
        ),
        proportion_calls_incoming=(
            lambda x: x.no_incoming / (x.no_incoming + x.no_received)
@ -284,41 +309,10 @@ def calls_sms_features(df_calls: pd.DataFrame, df_sms: pd.DataFrame) -> pd.DataF
        ),
        proportion_calls_outgoing=(
            lambda x: x.no_outgoing / (x.no_outgoing + x.no_sent)
        ),
        proportion_calls_contacts=(
            lambda x: x.no_contacts_calls / (x.no_contacts_calls + x.no_contacts_sms)
        )
        # Calculate new features and create additional columns
        )[
            [
                "participant_id",
                "proportion_calls",
                "proportion_calls_incoming",
                "proportion_calls_outgoing",
                "proportion_calls_missed_sms_received",
            ]
        ]  # Filter out only the relevant features
    )
-
+    return count_joined
    features_calls = contact_features(enumerate_contacts(df_calls))
    features_sms = contact_features(enumerate_contacts(df_sms))
    features_joined = (
        features_calls.merge(
            features_sms, on="participant_id", suffixes=("_calls", "_sms")
        )  # Merge calls and sms features
        .reset_index()  # Make participant_id a regular column
        .assign(
            proportion_calls_contacts=(
                lambda x: x.no_contacts_calls
                / (x.no_contacts_calls + x.no_contacts_sms)
            )  # Calculate new features and create additional columns
        )[
            ["participant_id", "proportion_calls_contacts"]
        ]  # Filter out only the relevant features
        # Since we are interested only in some features and ignored
        # others, a lot of duplicate rows were created. Remove them.
        .drop_duplicates()
    )
    # Join the newly created dataframes
    df_calls_sms = count_joined.merge(features_joined, on="participant_id")
    return df_calls_sms
--- a/features/proximity.py
+++ b/features/proximity.py
@ -5,6 +5,8 @@ import pandas as pd
 from config.models import Participant, Proximity
 from setup import db_engine, session
 FEATURES_PROXIMITY = ["freq_prox_near", "prop_prox_near"]
 def get_proximity_data(usernames: Collection) -> pd.DataFrame:
    """
@ -56,7 +58,7 @@ def recode_proximity(df_proximity: pd.DataFrame) -> pd.DataFrame:
 def count_proximity(
-    df_proximity: pd.DataFrame, group_by: Collection = ["participant_id"]
+    df_proximity: pd.DataFrame, group_by: Collection = None
 ) -> pd.DataFrame:
    """
    The function counts how many times a "near" value occurs in proximity
@ -75,6 +77,8 @@ def count_proximity(
    df_proximity_features: pd.DataFrame
        A dataframe with the count of "near" proximity values and their relative count.
    """
    if group_by is None:
        group_by = ["participant_id"]
    if "bool_prox_near" not in df_proximity:
        df_proximity = recode_proximity(df_proximity)
    df_proximity["bool_prox_far"] = ~df_proximity["bool_prox_near"]
--- a/features/screen.py
+++ b/features/screen.py
@ -38,8 +38,10 @@ def identify_screen_sequence(df_screen: pd.DataFrame) -> pd.DataFrame:
    # - OFF -> ON -> unlocked (a true phone unlock)
    # - OFF -> ON -> OFF/locked (no unlocking, i.e. a screen status check)
    # Consider that screen data is sometimes unreliable as shown in expl_screen.ipynb:
-    # "I have also seen off -> on -> unlocked (with 2 - locked missing)
+    # "I have also seen
-    #   and off -> locked -> on -> off -> locked (*again*)."
+    # off -> on -> unlocked (with 2 - locked missing)
    # and
    # off -> locked -> on -> off -> locked (*again*)."
    # Either clean the data beforehand or deal with these inconsistencies in this function.
    pass
--- a/machine_learning/init.py
+++ b/machine_learning/init.py
@ -0,0 +1,7 @@
 QUESTIONNAIRE_IDS = {"PANAS": {"PA": 8.0, "NA": 9.0}}
 QUESTIONNAIRE_IDS_RENAME = {}
 for questionnaire in QUESTIONNAIRE_IDS.items():
    for k, v in questionnaire[1].items():
        QUESTIONNAIRE_IDS_RENAME[v] = k
--- a/machine_learning/pipeline.py
+++ b/machine_learning/pipeline.py
@ -0,0 +1,125 @@
 import datetime
 import pandas as pd
 from sklearn.model_selection import cross_val_score
 import participants.query_db
 from features import esm, helper, proximity
 from machine_learning import QUESTIONNAIRE_IDS, QUESTIONNAIRE_IDS_RENAME
 class MachineLearningPipeline:
    def __init__(
        self,
        labels_questionnaire,
        labels_scale,
        data_types,
        participants_usernames=None,
        feature_names=None,
        grouping_variable=None,
    ):
        if participants_usernames is None:
            participants_usernames = participants.query_db.get_usernames(
                collection_start=datetime.date.fromisoformat("2020-08-01")
            )
        self.participants_usernames = participants_usernames
        self.labels_questionnaire = labels_questionnaire
        self.data_types = data_types
        if feature_names is None:
            self.feature_names = []
        self.df_features = pd.DataFrame()
        self.labels_scale = labels_scale
        self.df_labels = pd.DataFrame()
        self.grouping_variable = grouping_variable
        self.df_groups = pd.DataFrame()
        self.model = None
        self.validation_method = None
        self.df_esm = pd.DataFrame()
        self.df_esm_preprocessed = pd.DataFrame()
        self.df_esm_interest = pd.DataFrame()
        self.df_esm_clean = pd.DataFrame()
        self.df_proximity = pd.DataFrame()
        self.df_full_data_daily_means = pd.DataFrame()
        self.df_esm_daily_means = pd.DataFrame()
        self.df_proximity_daily_counts = pd.DataFrame()
    def get_labels(self):
        self.df_esm = esm.get_esm_data(self.participants_usernames)
        self.df_esm_preprocessed = esm.preprocess_esm(self.df_esm)
        if self.labels_questionnaire == "PANAS":
            self.df_esm_interest = self.df_esm_preprocessed[
                (
                    self.df_esm_preprocessed["questionnaire_id"]
                    == QUESTIONNAIRE_IDS.get("PANAS").get("PA")
                )
                | (
                    self.df_esm_preprocessed["questionnaire_id"]
                    == QUESTIONNAIRE_IDS.get("PANAS").get("NA")
                )
            ]
        self.df_esm_clean = esm.clean_up_esm(self.df_esm_interest)
    def get_sensor_data(self):
        if "proximity" in self.data_types:
            self.df_proximity = proximity.get_proximity_data(
                self.participants_usernames
            )
            self.df_proximity = helper.get_date_from_timestamp(self.df_proximity)
            self.df_proximity = proximity.recode_proximity(self.df_proximity)
    def aggregate_daily(self):
        self.df_esm_daily_means = (
            self.df_esm_clean.groupby(["participant_id", "date_lj", "questionnaire_id"])
            .esm_user_answer_numeric.agg("mean")
            .reset_index()
            .rename(columns={"esm_user_answer_numeric": "esm_numeric_mean"})
        )
        self.df_esm_daily_means = (
            self.df_esm_daily_means.pivot(
                index=["participant_id", "date_lj"],
                columns="questionnaire_id",
                values="esm_numeric_mean",
            )
            .reset_index(col_level=1)
            .rename(columns=QUESTIONNAIRE_IDS_RENAME)
            .set_index(["participant_id", "date_lj"])
        )
        self.df_full_data_daily_means = self.df_esm_daily_means.copy()
        if "proximity" in self.data_types:
            self.df_proximity_daily_counts = proximity.count_proximity(
                self.df_proximity, ["participant_id", "date_lj"]
            )
            self.df_full_data_daily_means = self.df_full_data_daily_means.join(
                self.df_proximity_daily_counts
            )
    def assign_columns(self):
        self.df_features = self.df_full_data_daily_means[self.feature_names]
        self.df_labels = self.df_full_data_daily_means[self.labels_scale]
        if self.grouping_variable:
            self.df_groups = self.df_full_data_daily_means[self.grouping_variable]
        else:
            self.df_groups = None
    def validate_model(self):
        if self.model is None:
            raise AttributeError(
                "Please, specify a machine learning model first, by setting the .model attribute."
            )
        if self.validation_method is None:
            raise AttributeError(
                "Please, specify a cross validation method first, by setting the .validation_method attribute."
            )
        cross_val_score(
            estimator=self.model,
            X=self.df_features,
            y=self.df_labels,
            groups=self.df_groups,
            cv=self.validation_method,
            n_jobs=-1,
        )
--- a/test/test_communication.py
+++ b/test/test_communication.py
@ -5,7 +5,7 @@ import pandas as pd
 from numpy.random import default_rng
 from pandas.testing import assert_series_equal
-from features.communication import count_comms, enumerate_contacts, get_call_data
+from features.communication import *
 rng = default_rng()
@ -76,10 +76,18 @@ class CallsFeatures(unittest.TestCase):
    def test_count_comms_calls(self):
        self.features = count_comms(self.calls)
        print(self.features)
        self.assertIsInstance(self.features, pd.DataFrame)
        self.assertCountEqual(self.features.columns.to_list(), FEATURES_CALLS)
    def test_count_comms_sms(self):
        self.features = count_comms(self.sms)
        print(self.features)
        self.assertIsInstance(self.features, pd.DataFrame)
        self.assertCountEqual(self.features.columns.to_list(), FEATURES_SMS)
    def test_calls_sms_features(self):
        self.features_call_sms = calls_sms_features(self.calls, self.sms)
        self.assertIsInstance(self.features_call_sms, pd.DataFrame)
        self.assertCountEqual(
            self.features_call_sms.columns.to_list(),
            FEATURES_CALLS + FEATURES_SMS + FEATURES_CONTACT,
        )
--- a/test/test_proximity.py
+++ b/test/test_proximity.py
@ -0,0 +1,31 @@
 import unittest
 from features.proximity import *
 class ProximityFeatures(unittest.TestCase):
    df_proximity = pd.DataFrame()
    df_proximity_recoded = pd.DataFrame()
    df_proximity_features = pd.DataFrame()
    @classmethod
    def setUpClass(cls) -> None:
        cls.df_proximity = pd.read_csv("../data/example_proximity.csv")
        cls.df_proximity["participant_id"] = 99
    def test_recode_proximity(self):
        self.df_proximity_recoded = recode_proximity(self.df_proximity)
        self.assertIn("bool_prox_near", self.df_proximity_recoded)
        # Is the recoded column present?
        self.assertIn(True, self.df_proximity_recoded.bool_prox_near)
        # Are there "near" values in the data?
        self.assertIn(False, self.df_proximity_recoded.bool_prox_near)
        # Are there "far" values in the data?
    def test_count_proximity(self):
        self.df_proximity_recoded = recode_proximity(self.df_proximity)
        self.df_proximity_features = count_proximity(self.df_proximity_recoded)
        print(self.df_proximity_features.columns)
        self.assertCountEqual(
            self.df_proximity_features.columns.to_list(), FEATURES_PROXIMITY
        )
Author	SHA1	Message	Date
junos	777e6f0a58	calls_sms_features() now returns all communication features.	2021-08-18 15:41:47 +02:00
junos	2d78aacd18	Compile a list of contact features and add a test.	2021-08-18 15:35:42 +02:00
junos	c88336481e	Add a test for SMS features.	2021-08-18 15:28:46 +02:00
junos	1bc996413e	Clarify names for no_all calls/sms feature. Add another test.	2021-08-18 15:23:30 +02:00
junos	a2a44c202a	Calculate common features outside if...else.	2021-08-18 10:54:54 +02:00
junos	4740e94d37	Fix a bug introduced in `e7fe4e8398` .	2021-08-18 10:51:48 +02:00
junos	b1ad8d1309	List calls features.	2021-08-17 16:27:34 +02:00
junos	bb75abcb9b	Add tests for proximity.	2021-08-17 16:07:52 +02:00
junos	e7fe4e8398	Simplify merge into join.	2021-08-17 13:53:19 +02:00
Junos Lukan	cf28aa547a	Merge branch 'communication' into 'master' separated features See merge request junoslukan/straw2analysis!2	2021-08-17 11:42:03 +00:00
junos	d6f36ec8f8	[WIP] Finish the class by assigning columns and validating model.	2021-08-13 17:41:04 +02:00
junos	b06ec6e1ae	[WIP] Methods to get the labels and data plus aggregate them.	2021-08-12 19:07:14 +02:00
junos	622477f19f	[WIP] Start merging steps into a class for a pipeline.	2021-08-12 17:38:08 +02:00
Ivan Kobe	74b4f9ddbe	separated features	2021-08-10 12:59:47 +02:00