I'm a python newbie, so I hope my two questions are clear and complete. I posted the actual code and a test data set in csv format below.
I've been able to construct the following code (mostly with the help from the StackOverflow contributors) to calculate the Implied Volatility of an option contract using Newton-Raphson method. The process calculates Vega when determining the Implied Volatility. Although I'm able to create a new DataFrame column for Implied Volatility using the Pandas DataFrame apply method, I'm unable to create a second column for Vega. Is there a way create two separate DataFrame columns when the function to returns IV & Vega together?
I tried:
return iv, vega
from functiondf[['myIV', 'Vega']] = df.apply(newtonRap, axis=1)
ValueError: Shape of passed values is (56, 2), indices imply (56, 13)
Also tried:
return iv, vega
from functiondf['myIV'], df['Vega'] = df.apply(newtonRap, axis=1)
ValueError: Shape of passed values is (56, 2), indices imply (56, 13)
Additionally, the calculation process is slow. I imported numba and implemented the @jit(nogil=True) decorator, but I only see a performance improvement of 25%. The test data set is the performance test has almost 900,000 records. The run time is 2 hours and 9 minutes without numba or with numba, but witout nogil=True. The run time when using numba and @jit(nogil=True) is 1 hour and 32 minutes. Can I do better?
from datetime import datetime
from math import sqrt, pi, log, exp, isnan
from scipy.stats import norm
from numba import jit
# dff = Daily Fed Funds (Posted rate is usually one day behind)
dff = pd.read_csv('https://research.stlouisfed.org/fred2/data/DFF.csv', parse_dates=[0], index_col='DATE')
rf = float('%.4f' % (dff['VALUE'][-1:][0] / 100))
# rf = .0015 # Get Fed Funds Rate https://research.stlouisfed.org/fred2/data/DFF.csv
tradingMinutesDay = 450 # 7.5 hours per day * 60 minutes per hour
tradingMinutesAnnum = 113400 # trading minutes per day * 252 trading days per year
cal = USFederalHolidayCalendar() # Load US Federal holiday calendar
@jit(nogil=True) # nogil=True arg improves performance by 25%
def newtonRap(row):
"""Estimate Implied Volatility (IV) using Newton-Raphson method
:param row (dataframe): Options contract params for function
TimeStamp (datetime): Close date
Expiry (datetime): Option contract expiration date
Strike (float): Option strike
OptType (object): 'C' for call; 'P' for put
RootPrice (float): Underlying close price
Bid (float): Option contact closing bid
Ask (float): Option contact closing ask
:return:
float: Estimated implied volatility
"""
if row['Bid'] == 0.0 or row['Ask'] == 0.0 or row['RootPrice'] == 0.0 or row['Strike'] == 0.0 or \
row['TimeStamp'] == row['Expiry']:
iv, vega = 0.0, 0.0 # Set iv and vega to zero if option contract is invalid or expired
else:
# dte (Days to expiration) uses pandas bdate_range method to determine the number of business days to expiration
# minus USFederalHolidays minus constant of 1 for the TimeStamp date
dte = float(len(pd.bdate_range(row['TimeStamp'], row['Expiry'])) -
len(cal.holidays(row['TimeStamp'], row['Expiry']).to_pydatetime()) - 1)
mark = (row['Bid'] + row['Ask']) / 2
cp = 1 if row['OptType'] == 'C' else -1
S = row['RootPrice']
K = row['Strike']
# T = the number of trading minutes to expiration divided by the number of trading minutes in year
T = (dte * tradingMinutesDay) / tradingMinutesAnnum
# TODO get dividend value
d = 0.00
iv = sqrt(2 * pi / T) * mark / S # Closed form estimate of IV Brenner and Subrahmanyam (1988)
vega = 0.0
for i in range(1, 100):
d1 = (log(S / K) + T * (rf - d + iv ** 2 / 2)) / (iv * sqrt(T))
d2 = d1 - iv * sqrt(T)
vega = S * norm.pdf(d1) * sqrt(T)
model = cp * S * norm.cdf(cp * d1) - cp * K * exp(-rf * T) * norm.cdf(cp * d2)
iv -= (model - mark) / vega
if abs(model - mark) < 1.0e-9:
break
if isnan(iv) or isnan(vega):
iv, vega = 0.0, 0.0
# TODO Return vega with iv if add'l pandas column possible
# return iv, vega
return iv
if __name__ == "__main__":
# test function from baseline data
get_csv = True
if get_csv:
csvHeaderList = ['TimeStamp', 'OpraSymbol', 'RootSymbol', 'Expiry', 'Strike', 'OptType', 'RootPrice', 'Last',
'Bid', 'Ask', 'Volume', 'OpenInt', 'IV']
fileName = 'C:/tmp/test-20150930-56records.csv'
df = pd.read_csv(fileName, parse_dates=[0, 3], names=csvHeaderList)
else:
pass
start = datetime.now()
# TODO Create add'l pandas dataframe column, if possible, for vega
# df[['myIV', 'Vega']] = df.apply(newtonRap, axis=1)
# df['myIV'], df['Vega'] = df.apply(newtonRap, axis=1)
df['myIV'] = df.apply(newtonRap, axis=1)
end = datetime.now()
print end - start
Test Data: C:/tmp/test-20150930-56records.csv
2015-09-30 16:00:00,AAPL151016C00109000,AAPL,2015-10-16 16:00:00,109,C,109.95,3.46,3.6,3.7,1565,1290,0.3497 2015-09-30 16:00:00,AAPL151016P00109000,AAPL,2015-10-16 16:00:00,109,P,109.95,2.4,2.34,2.42,3790,3087,0.3146 2015-09-30 16:00:00,AAPL151016C00110000,AAPL,2015-10-16 16:00:00,110,C,109.95,3,2.86,3,10217,28850,0.3288 2015-09-30 16:00:00,AAPL151016P00110000,AAPL,2015-10-16 16:00:00,110,P,109.95,2.81,2.74,2.8,12113,44427,0.3029 2015-09-30 16:00:00,AAPL151016C00111000,AAPL,2015-10-16 16:00:00,111,C,109.95,2.35,2.44,2.45,6674,2318,0.3187 2015-09-30 16:00:00,AAPL151016P00111000,AAPL,2015-10-16 16:00:00,111,P,109.95,3.2,3.1,3.25,2031,3773,0.2926 2015-09-30 16:00:00,AAPL151120C00110000,AAPL,2015-11-20 16:00:00,110,C,109.95,5.9,5.7,5.95,5330,17112,0.3635 2015-09-30 16:00:00,AAPL151120P00110000,AAPL,2015-11-20 16:00:00,110,P,109.95,6.15,6.1,6.3,3724,15704,0.3842
If I understand you right, what you should be doing is returning a Series from your function. Something like:
return pandas.Series({"IV": iv, "Vega": vega})
If you want to put the result into new columns of the same input DataFrame, then just do:
df[["IV", "Vega"]] = df.apply(newtonRap, axis=1)