upstream/ipython Files · docs/examples/newparallel/mcpricer.py

Misc updates the display system....

Misc updates the display system. * PNG base64 encoding is now done at the ZMQ level, not in the display formatter itself. * All formatters are documented as to the exact nature of their return value. PNGs are not base64 encoded, LaTeX must include $/$$, Javascript should not have the <script> tags, etc. * Updated the Circle display example in docs/examples/core. * Renamed the sympy printing extension to sympyprinting.py.

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      def price_options(S=100.0, K=100.0, sigma=0.25, r=0.05, days=260, paths=10000):

          """

          Price European and Asian options using a Monte Carlo method.

          Parameters

          ----------

          S : float

              The initial price of the stock.

          K : float

              The strike price of the option.

          sigma : float

              The volatility of the stock.

          r : float

              The risk free interest rate.

          days : int

              The number of days until the option expires.

          paths : int

              The number of Monte Carlo paths used to price the option.

          Returns

          -------

          A tuple of (E. call, E. put, A. call, A. put) option prices.

          """

          import numpy as np

          from math import exp,sqrt

          h = 1.0/days

          const1 = exp((r-0.5*sigma**2)*h)

          const2 = sigma*sqrt(h)

          stock_price = S*np.ones(paths, dtype='float64')

          stock_price_sum = np.zeros(paths, dtype='float64')

          for j in range(days):

              growth_factor = const1*np.exp(const2*np.random.standard_normal(paths))

              stock_price = stock_price*growth_factor

              stock_price_sum = stock_price_sum + stock_price

          stock_price_avg = stock_price_sum/days

          zeros = np.zeros(paths, dtype='float64')

          r_factor = exp(-r*h*days)

          euro_put = r_factor*np.mean(np.maximum(zeros, K-stock_price))

          asian_put = r_factor*np.mean(np.maximum(zeros, K-stock_price_avg))

          euro_call = r_factor*np.mean(np.maximum(zeros, stock_price-K))

          asian_call = r_factor*np.mean(np.maximum(zeros, stock_price_avg-K))

          return (euro_call, euro_put, asian_call, asian_put)

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				def price_options(S=100.0, K=100.0, sigma=0.25, r=0.05, days=260, paths=10000):
				"""
				Price European and Asian options using a Monte Carlo method.

				Parameters
				----------
				S : float
				The initial price of the stock.
				K : float
				The strike price of the option.
				sigma : float
				The volatility of the stock.
				r : float
				The risk free interest rate.
				days : int
				The number of days until the option expires.
				paths : int
				The number of Monte Carlo paths used to price the option.

				Returns
				-------
				A tuple of (E. call, E. put, A. call, A. put) option prices.
				"""
				import numpy as np
				from math import exp,sqrt

				h = 1.0/days
				const1 = exp((r-0.5sigma2)h)
				const2 = sigma*sqrt(h)
				stock_price = S*np.ones(paths, dtype='float64')
				stock_price_sum = np.zeros(paths, dtype='float64')
				for j in range(days):
				growth_factor = const1np.exp(const2np.random.standard_normal(paths))
				stock_price = stock_price*growth_factor
				stock_price_sum = stock_price_sum + stock_price
				stock_price_avg = stock_price_sum/days
				zeros = np.zeros(paths, dtype='float64')
				r_factor = exp(-rhdays)
				euro_put = r_factor*np.mean(np.maximum(zeros, K-stock_price))
				asian_put = r_factor*np.mean(np.maximum(zeros, K-stock_price_avg))
				euro_call = r_factor*np.mean(np.maximum(zeros, stock_price-K))
				asian_call = r_factor*np.mean(np.maximum(zeros, stock_price_avg-K))
				return (euro_call, euro_put, asian_call, asian_put)