Expanded the volatility function, added annualisation

parameter changes in calculate retuns & rolling returns
Added volatility function
3 changed files with 126 additions and 49 deletions
--- a/fincal/fincal.py
+++ b/fincal/fincal.py
@ -1,6 +1,8 @@
 from __future__ import annotations

 import datetime
+import math
+import statistics
 from typing import Iterable, List, Literal, Mapping, Union

 from dateutil.relativedelta import relativedelta
@ -190,7 +192,7 @@ class TimeSeries(TimeSeriesCore):
        closest: Literal["previous", "next", "exact"] = "previous",
        closest_max_days: int = -1,
        if_not_found: Literal["fail", "nan"] = "fail",
-        compounding: bool = True,
+        annual_compounded_returns: bool = True,
        interval_type: Literal["years", "months", "days"] = "years",
        interval_value: int = 1,
        date_format: str = None,
@ -268,7 +270,7 @@ class TimeSeries(TimeSeriesCore):
            return as_on, float("NaN")

        returns = current[1] / previous[1]
-        if compounding:
+        if annual_compounded_returns:
            years = _interval_to_years(interval_type, interval_value)
            returns = returns ** (1 / years)
        return (current[0] if return_actual_date else as_on), returns - 1
@ -283,7 +285,7 @@ class TimeSeries(TimeSeriesCore):
        prior_match: str = "closest",
        closest: Literal["previous", "next", "exact"] = "previous",
        if_not_found: Literal["fail", "nan"] = "fail",
-        compounding: bool = True,
+        annual_compounded_returns: bool = True,
        interval_type: Literal["years", "months", "days"] = "years",
        interval_value: int = 1,
        date_format: str = None,
@ -370,7 +372,7 @@ class TimeSeries(TimeSeriesCore):
        for i in dates:
            returns = self.calculate_returns(
                as_on=i,
-                compounding=compounding,
+                annual_compounded_returns=annual_compounded_returns,
                interval_type=interval_type,
                interval_value=interval_value,
                as_on_match=as_on_match,
@ -382,6 +384,60 @@ class TimeSeries(TimeSeriesCore):
        rolling_returns.sort()
        return self.__class__(rolling_returns, self.frequency.symbol)

+    @date_parser(1, 2)
+    def volatility(
+        self,
+        from_date: Union[datetime.date, str],
+        to_date: Union[datetime.date, str],
+        frequency: Literal["D", "W", "M", "Q", "H", "Y"] = None,
+        as_on_match: str = "closest",
+        prior_match: str = "closest",
+        closest: Literal["previous", "next", "exact"] = "previous",
+        if_not_found: Literal["fail", "nan"] = "fail",
+        annual_compounded_returns: bool = None,
+        interval_type: Literal["years", "months", "days"] = "days",
+        interval_value: int = 1,
+        date_format: str = None,
+        annualize_volatility: bool = True,
+    ):
+        """Calculates the volatility of the time series.add()
+
+        The volatility is calculated as the standard deviaion of periodic returns.
+        The periodicity of returns is based on the periodicity of underlying data.
+        """
+
+        if frequency is None:
+            frequency = self.frequency
+        else:
+            try:
+                frequency = getattr(AllFrequencies, frequency)
+            except AttributeError:
+                raise ValueError(f"Invalid argument for frequency {frequency}")
+
+        if annual_compounded_returns is None:
+            annual_compounded_returns = False if frequency.days <= 366 else True
+
+        rolling_returns = self.calculate_rolling_returns(
+            from_date=from_date,
+            to_date=to_date,
+            frequency=frequency.symbol,
+            as_on_match=as_on_match,
+            prior_match=prior_match,
+            closest=closest,
+            if_not_found=if_not_found,
+            annual_compounded_returns=annual_compounded_returns,
+            interval_type=interval_type,
+            interval_value=interval_value,
+        )
+        sd = statistics.stdev(rolling_returns.values)
+        if annualize_volatility:
+            if interval_type == "months":
+                sd *= math.sqrt(12)
+            elif interval_type == "days":
+                sd *= math.sqrt(252)
+
+        return sd
+

 if __name__ == "__main__":
    date_series = [
--- a/test2.py
+++ b/test2.py
@ -1,37 +1,58 @@
-# type: ignore
+import pandas as pd

-if __name__ == "__main__":
+from fincal.fincal import TimeSeries, create_date_series

-    import datetime
-    import time
+dfd = pd.read_csv("test_files/nav_history_daily - Copy.csv")
+dfd = dfd[dfd["amfi_code"] == 118825].reset_index(drop=True)
+ts = TimeSeries([(i.date, i.nav) for i in dfd.itertuples()], frequency="D")
+repr(ts)
+# print(ts[['2022-01-31', '2021-05-28']])

-    import pandas as pd
+# rr = ts.calculate_rolling_returns(from_date='2021-01-01', to_date='2022-01-01', frequency='D', interval_type='days', interval_value=30, compounding=False)
+
+
+# data = [
+#     ("2020-01-01", 10),
+#     ("2020-02-01", 12),
+#     ("2020-03-01", 14),
+#     ("2020-04-01", 16),
+#     ("2020-05-01", 18),
+#     ("2020-06-01", 20),
+#     ("2020-07-01", 22),
+#     ("2020-08-01", 24),
+#     ("2020-09-01", 26),
+#     ("2020-10-01", 28),
+#     ("2020-11-01", 30),
+#     ("2020-12-01", 32),
+#     ("2021-01-01", 34),
+# ]
+
+# ts = TimeSeries(data, frequency="M")
+# rr = ts.calculate_rolling_returns(
+#     "2020-02-01",
+#     "2021-01-01",
+#     if_not_found="nan",
+#     compounding=False,
+#     interval_type="months",
+#     interval_value=1,
+#     as_on_match="exact",
+# )
+
+# for i in rr:
+#     print(i)
+
+# returns = ts.calculate_returns(
+#     "2020-04-25",
+#     return_actual_date=True,
+#     closest_max_days=15,
+#     compounding=True,
+#     interval_type="days",
+#     interval_value=90,
+#     closest="previous",
+#     if_not_found="fail",
+# )
+
+# print(returns)

-    from fincal.fincal import TimeSeries
-
-    df = pd.read_csv('test_files/msft.csv')
-    df = df.sort_values(by='Date')  # type: ignore
-    data_list = [(i.Date, i.Close) for i in df.itertuples()]
-
-    start = time.time()
-    ts_data = TimeSeries(data_list, frequency='D', date_format='%d-%m-%Y')
-    print(f"Instantiation took {round((time.time() - start)*1000, 2)} ms")
-    # ts_data.fill_missing_days()
-    start = time.time()
-    # ts_data.calculate_returns(as_on=datetime.datetime(2022, 1, 4), closest='next', years=1)
-    rr = ts_data.calculate_rolling_returns(datetime.datetime(1994, 1, 1),
-                                        datetime.datetime(2022, 2, 17),
-                                        frequency='D',
-                                        as_on_match='next',
-                                        prior_match='previous',
-                                        closest='previous',
-                                        years=1)
-
-    # ffill_data = ts_data.bfill()
-    print(f"Calculation took {round((time.time() - start)*1000, 2)} ms")
-    rr.sort()
-    for i in rr[:10]:
-        print(i)
-    # print(ffill_data)
-    # print(ts_data)
-    # print(repr(ts_data))
+volatility = ts.volatility(start_date="2018-01-01", end_date="2021-01-01")
+print(volatility)
--- a/tests/test_fincal.py
+++ b/tests/test_fincal.py
@ -199,17 +199,17 @@ class TestReturns:

    def test_returns_calc(self):
        ts = TimeSeries(self.data, frequency="M")
-        returns = ts.calculate_returns("2021-01-01", compounding=False, interval_type="years", interval_value=1)
+        returns = ts.calculate_returns("2021-01-01", annual_compounded_returns=False, interval_type="years", interval_value=1)
        assert returns[1] == 2.4
-        returns = ts.calculate_returns("2020-04-01", compounding=False, interval_type="months", interval_value=3)
+        returns = ts.calculate_returns("2020-04-01", annual_compounded_returns=False, interval_type="months", interval_value=3)
        assert round(returns[1], 4) == 0.6
-        returns = ts.calculate_returns("2020-04-01", compounding=True, interval_type="months", interval_value=3)
+        returns = ts.calculate_returns("2020-04-01", annual_compounded_returns=True, interval_type="months", interval_value=3)
        assert round(returns[1], 4) == 5.5536
-        returns = ts.calculate_returns("2020-04-01", compounding=False, interval_type="days", interval_value=90)
+        returns = ts.calculate_returns("2020-04-01", annual_compounded_returns=False, interval_type="days", interval_value=90)
        assert round(returns[1], 4) == 0.6
-        returns = ts.calculate_returns("2020-04-01", compounding=True, interval_type="days", interval_value=90)
+        returns = ts.calculate_returns("2020-04-01", annual_compounded_returns=True, interval_type="days", interval_value=90)
        assert round(returns[1], 4) == 5.727
-        returns = ts.calculate_returns("2020-04-10", compounding=True, interval_type="days", interval_value=90)
+        returns = ts.calculate_returns("2020-04-10", annual_compounded_returns=True, interval_type="days", interval_value=90)
        assert round(returns[1], 4) == 5.727
        with pytest.raises(DateNotFoundError):
            ts.calculate_returns("2020-04-10", interval_type="days", interval_value=90, as_on_match="exact")
@ -220,7 +220,7 @@ class TestReturns:
        ts = TimeSeries(self.data, frequency="M")
        FincalOptions.date_format = "%d-%m-%Y"
        with pytest.raises(ValueError):
-            ts.calculate_returns("2020-04-10", compounding=True, interval_type="days", interval_value=90)
+            ts.calculate_returns("2020-04-10", annual_compounded_returns=True, interval_type="days", interval_value=90)

        returns1 = ts.calculate_returns("2020-04-10", interval_type="days", interval_value=90, date_format="%Y-%m-%d")
        returns2 = ts.calculate_returns("10-04-2020", interval_type="days", interval_value=90)
@ -228,7 +228,7 @@ class TestReturns:

        FincalOptions.date_format = "%m-%d-%Y"
        with pytest.raises(ValueError):
-            ts.calculate_returns("2020-04-10", compounding=True, interval_type="days", interval_value=90)
+            ts.calculate_returns("2020-04-10", annual_compounded_returns=True, interval_type="days", interval_value=90)

        returns1 = ts.calculate_returns("2020-04-10", interval_type="days", interval_value=90, date_format="%Y-%m-%d")
        returns2 = ts.calculate_returns("04-10-2020", interval_type="days", interval_value=90)
Author	SHA1	Message	Date
Gourav Kumar	793d5b1ad7	Expanded the volatility function, added annualisation	2 years ago
Gourav Kumar	7b541290c6	parameter changes in calculate retuns & rolling returns	2 years ago
Gourav Kumar	24d5d253b5	Added volatility function	2 years ago