OPEN-SOURCE SCRIPT

BSM OPM 1973 w/ Continuous Dividend Yield [Loxx]

Generalized Black-Scholes-Merton w/ Analytical Greeks is an adaptation of the Black-Scholes-Merton Option Pricing Model including Analytical Greeks and implied volatility calculations. The following information is an excerpt from Espen Gaarder Haug's book "Option Pricing Formulas". The options sensitivities (Greeks) are the partial derivatives of the Black-Scholes-Merton ( BSM ) formula. Analytical Greeks for our purposes here are broken down into various categories:

Delta Greeks: Delta, DDeltaDvol, Elasticity
  • Gamma Greeks: Gamma, GammaP, DGammaDSpot/speed, DGammaDvol/Zomma
  • Vega Greeks: Vega , DVegaDvol/Vomma, VegaP
  • Theta Greeks: Theta
  • Rate/Carry Greeks: Rho, Rho futures option, Carry Rho, Phi/Rho2
  • Probability Greeks: StrikeDelta, Risk Neutral Density

(See the code for more details)

Black-Scholes-Merton Option Pricing
The Black-Scholes-Merton model can be "generalized" by incorporating a cost-of-carry rate b. This model can be used to price European options on stocks, stocks paying a continuous dividend yield, options on futures, and currency options:

c = S * e^((b - r) * T) * N(d1) - X * e^(-r * T) * N(d2)

p = X * e^(-r * T) * N(-d2) - S * e^((b - r) * T) * N(-d1)

where

d1 = (log(S / X) + (b + v^2 / 2) * T) / (v * T^0.5)

d2 = d1 - v * T^0.5

b = r ... gives the Black and Scholes (1973) stock option model.
b = r — q ... gives the Merton (1973) stock option model with continuous dividend yield q. <== this is the one used for this indicator!
b = 0 ... gives the Black (1976) futures option model.
b = 0 and r = 0 ... gives the Asay (1982) margined futures option model.
b = r — rf ... gives the Garman and Kohlhagen (1983) currency option model.

Inputs
S = Stock price.
X = Strike price of option.
T = Time to expiration in years.
r = Risk-free rate
d = dividend yield
v = Volatility of the underlying asset price
cnd (x) = The cumulative normal distribution function
nd(x) = The standard normal density function
convertingToCCRate(r, cmp ) = Rate compounder
gImpliedVolatilityNR(string CallPutFlag, float S, float x, float T, float r, float b, float cm , float epsilon) = Implied volatility via Newton Raphson
gBlackScholesImpVolBisection(string CallPutFlag, float S, float x, float T, float r, float b, float cm ) = implied volatility via bisection

Implied Volatility: The Bisection Method
The Newton-Raphson method requires knowledge of the partial derivative of the option pricing formula with respect to volatility ( vega ) when searching for the implied volatility . For some options (exotic and American options in particular), vega is not known analytically. The bisection method is an even simpler method to estimate implied volatility when vega is unknown. The bisection method requires two initial volatility estimates (seed values):

1. A "low" estimate of the implied volatility , al, corresponding to an option value, CL
2. A "high" volatility estimate, aH, corresponding to an option value, CH

The option market price, Cm , lies between CL and cH . The bisection estimate is given as the linear interpolation between the two estimates:

v(i + 1) = v(L) + (c(m) - c(L)) * (v(H) - v(L)) / (c(H) - c(L))

Replace v(L) with v(i + 1) if c(v(i + 1)) < c(m), or else replace v(H) with v(i + 1) if c(v(i + 1)) > c(m) until |c(m) - c(v(i + 1))| <= E, at which point v(i + 1) is the implied volatility and E is the desired degree of accuracy.

Implied Volatility: Newton-Raphson Method
The Newton-Raphson method is an efficient way to find the implied volatility of an option contract. It is nothing more than a simple iteration technique for solving one-dimensional nonlinear equations (any introductory textbook in calculus will offer an intuitive explanation). The method seldom uses more than two to three iterations before it converges to the implied volatility . Let

v(i + 1) = v(i) + (c(v(i)) - c(m)) / (dc / dv (i))

until |c(m) - c(v(i + 1))| <= E at which point v(i + 1) is the implied volatility , E is the desired degree of accuracy, c(m) is the market price of the option, and dc/ dv (i) is the vega of the option evaluaated at v(i) (the sensitivity of the option value for a small change in volatility ).

Things to know
  • Only works on the daily timeframe and for the current source price.
  • You can adjust the text size to fit the screen
Phát hành các Ghi chú
Updated output title to reflect correct Greeks type
blackscholesmertonblackscholesoptionpricingblacksholescostofcarryHistorical VolatilityoptionsVolatility

Mã nguồn mở

Theo tinh thần TradingView thực sự, tác giả của tập lệnh này đã xuất bản dưới dạng nguồn mở để các nhà giao dịch có thể hiểu và xác minh. Chúc mừng tác giả! Bạn có thể sử dụng miễn phí. Tuy nhiên, bạn cần sử dụng lại mã này theo Quy tắc nội bộ. Bạn có thể yêu thích nó để sử dụng nó trên biểu đồ.

Bạn muốn sử dụng tập lệnh này trên biểu đồ?


Public Telegram Group, t.me/algxtrading_public

VIP Membership Info: patreon.com/algxtrading/membership
Ngoài ra, trên:

Thông báo miễn trừ trách nhiệm