Example #1
0
 def get_black_var_surface_50etf2(self,
                                  maturity_dates,
                                  spot,
                                  dS=0.0,
                                  strikes=np.arange(1.0, 5.0, 0.1 / 100)):
     volset = []
     for idx_mdt, mdt in enumerate(maturity_dates):
         params = self.calibrated_params[idx_mdt]
         a_star, b_star, rho_star, m_star, sigma_star = params
         ttm = self.daycounter.yearFraction(self.evalDate, mdt)
         rf = util.get_rf_tbcurve(self.evalDate, self.daycounter, mdt)
         Ft = (spot + dS) * math.exp(rf * ttm)
         x_svi = np.log(strikes / Ft)
         vol = np.sqrt(
             np.maximum(
                 0,
                 a_star + b_star * (rho_star * (x_svi - m_star) + np.sqrt(
                     (x_svi - m_star)**2 + sigma_star**2))))
         volset.append(vol)
     implied_vols = ql.Matrix(len(strikes), len(maturity_dates))
     for i in range(implied_vols.rows()):
         for j in range(implied_vols.columns()):
             implied_vols[i][j] = volset[j][i]
     black_var_surface = ql.BlackVarianceSurface(self.evalDate,
                                                 self.calendar,
                                                 maturity_dates, strikes,
                                                 implied_vols,
                                                 self.daycounter)
     return black_var_surface
Example #2
0
 def get_black_var_surface_50etf(self,
                                 spot,
                                 dS=0.0,
                                 strikes=np.arange(1.0, 5.0, 0.1 / 100)):
     volset = []
     maturity_dates = self.calibrated_params.keys()
     #print(maturity_dates)
     maturity_dates = sorted(maturity_dates)
     maturity_dates = maturity_dates[1:]
     #print(maturity_dates)
     for mdt in maturity_dates:
         params = self.calibrated_params.get(mdt)
         a_star, b_star, rho_star, m_star, sigma_star = params
         maturitydt = ql.Date(mdt.day, mdt.month, mdt.year)
         ttm = self.daycounter.yearFraction(self.evalDate, maturitydt)
         rf = util.get_rf_tbcurve(self.evalDate, self.daycounter,
                                  maturitydt)
         Ft = (spot + dS) * math.exp(rf * ttm)
         x_svi = np.log(strikes / Ft)
         vol = np.sqrt(
             np.maximum(
                 0,
                 a_star + b_star * (rho_star * (x_svi - m_star) + np.sqrt(
                     (x_svi - m_star)**2 + sigma_star**2))))
         volset.append(vol)
     implied_vols = ql.Matrix(len(strikes), len(maturity_dates))
     for i in range(implied_vols.rows()):
         for j in range(implied_vols.columns()):
             implied_vols[i][j] = volset[j][i]
     black_var_surface = ql.BlackVarianceSurface(
         self.evalDate, self.calendar, util.to_ql_dates(maturity_dates),
         strikes, implied_vols, self.daycounter)
     return black_var_surface
Example #3
0
def get_black_variance_surface_cmd(calibrated_params,calibrate_date,daycounter,calendar,underlying_prices,contractType,strikes):
    #strikes = np.arange(2400, 3200, 1)
    volset = []
    maturity_dates = []
    contract_ids = sorted(calibrated_params.keys())
    for contractId in contract_ids:
        params = calibrated_params.get(contractId)
        a_star, b_star, rho_star, m_star, sigma_star = params
        mdt = util.get_mdate_by_contractid(contractType,contractId,calendar)
        maturity_dates.append(mdt)
        ttm = daycounter.yearFraction(calibrate_date,mdt)
        rf = util.get_rf_tbcurve(calibrate_date,daycounter,mdt)
        spot = underlying_prices.get(contractId)
        Ft = spot * math.exp(rf * ttm)
        x_svi =  np.log(strikes/Ft)
        vol = np.sqrt(np.maximum(0,a_star + b_star * (rho_star * (x_svi - m_star) + np.sqrt((x_svi - m_star) ** 2 + sigma_star ** 2))))
        volset.append(vol)
    implied_vols = ql.Matrix(len(strikes), len(maturity_dates))
    for i in range(implied_vols.rows()):
        for j in range(implied_vols.columns()):
            implied_vols[i][j] = volset[j][i]
    #maturity_dates = [maturity_dates[1],maturity_dates[0]]
    #print(type(strikes))
    #print(type(implied_vols))
    #print(strikes)
    #print(implied_vols)
    black_var_surface = ql.BlackVarianceSurface(calibrate_date, calendar,maturity_dates, strikes,implied_vols, daycounter)
    return black_var_surface
 def knock_out_call(self,
                    portfolio,
                    instrument_ratio,
                    evaluation,
                    spot,
                    vol_ts,
                    call_strikes=[],
                    put_strikes=[]):
     barrier = self.exoticOption.barrier
     strike = self.exoticOption.strike
     maturitydt = self.exoticOption.maturitydt
     evalDate = evaluation.evalDate
     daycounter = evaluation.daycounter
     rf = util.get_rf_tbcurve(evalDate, daycounter, maturitydt)
     ttm = daycounter.yearFraction(evalDate, maturitydt)
     underlying = ql.SimpleQuote(spot)
     process = evaluation.get_bsmprocess(daycounter, underlying, vol_ts)
     european_engine = ql.AnalyticEuropeanEngine(process)
     exercise = ql.EuropeanExercise(maturitydt)
     if len(call_strikes) == 0:
         k_call = strike
     else:
         k_call = util.get_closest_strike(call_strikes, strike)
     payoff = ql.PlainVanillaPayoff(ql.Option.Call, k_call)
     call = ql.EuropeanOption(payoff, exercise)
     call.setPricingEngine(european_engine)
     instrument_ratio.update({'call-' + str(k_call): 1.0})
     portfolio.add(call)
     b_forward = ((barrier * np.exp(rf * ttm))**2) / k_call
     if len(put_strikes) == 0:
         k_put = b_forward
     else:
         k_put = util.get_closest_strike(put_strikes, b_forward)
     put_payoff = ql.PlainVanillaPayoff(ql.Option.Put, k_put)
     put = ql.EuropeanOption(put_payoff, exercise)
     put.setPricingEngine(european_engine)
     underlying.setValue(barrier)
     callprice_at_barrier = call.NPV()
     putprice_at_barrier = put.NPV()
     put_ratio = callprice_at_barrier / putprice_at_barrier
     portfolio.subtract(put, put_ratio)
     instrument_ratio.update({'put-' + str(k_put): -put_ratio})
     return portfolio, instrument_ratio
Example #5
0
        'rb') as f:
    daily_params_p = pickle.load(f)[0]

date = datetime.date(2017, 7, 17)
date_ql = util.to_ql_date(date)

paramset_c = daily_params_c.get(date)
paramset_p = daily_params_p.get(date)
dataset = daily_svi_dataset.get(date)
cal_vols, put_vols, maturity_dates, s, rfs = dataset
index = 0
mdate = maturity_dates[index]
maturitydt = util.to_ql_date(mdate)
params_c = paramset_c[index]
params_p = paramset_p[index]
rf = util.get_rf_tbcurve(date_ql, daycounter, maturitydt)
ttm = daycounter.yearFraction(date_ql, maturitydt)
discount = math.exp(-rf * ttm)

# Example
strike = 2.4
dS = 0.001
iscall = True
curve = get_curve_treasury_bond(date_ql, daycounter)
yield_ts = util.get_yield_ts(date_ql, curve, maturitydt, daycounter)
dividend_ts = util.get_dividend_ts(date_ql, daycounter)

print('strike = ', strike, ', option type : call')
print('=' * 100)
print("%10s %25s %25s %25s %25s" %
      ("Spot", "delta_total", "delta_eff", "delta_constant_vol ", "diff"))