Beispiel #1
0
 public ParallelEvolver(List <IOperator> L, BoundaryConditionSet bcs)
 {
     evolvers_ = new List <IMixedScheme>(L.Count);
     for (int i = 0; i < L.Count; i++)
     {
         evolvers_.Add(FastActivator <Evolver> .Create().factory(L[i], bcs[i]));
     }
 }
Beispiel #2
0
        public override void calculate(IPricingEngineResults r)
        {
            OneAssetOption.Results results = r as OneAssetOption.Results;
            setGridLimits();
            initializeInitialCondition();
            initializeOperator();
            initializeBoundaryConditions();
            initializeStepCondition();

            List <IOperator>          operatorSet  = new List <IOperator>();
            List <Vector>             arraySet     = new List <Vector>();
            BoundaryConditionSet      bcSet        = new BoundaryConditionSet();
            StepConditionSet <Vector> conditionSet = new StepConditionSet <Vector>();

            prices_ = (SampledCurve)intrinsicValues_.Clone();

            controlPrices_   = (SampledCurve)intrinsicValues_.Clone();
            controlOperator_ = (TridiagonalOperator)finiteDifferenceOperator_.Clone();
            controlBCs_[0]   = BCs_[0];
            controlBCs_[1]   = BCs_[1];

            operatorSet.Add(finiteDifferenceOperator_);
            operatorSet.Add(controlOperator_);

            arraySet.Add(prices_.values());
            arraySet.Add(controlPrices_.values());

            bcSet.Add(BCs_);
            bcSet.Add(controlBCs_);

            conditionSet.Add(stepCondition_);
            conditionSet.Add(new NullCondition <Vector>());

            var model = new FiniteDifferenceModel <ParallelEvolver <CrankNicolson <TridiagonalOperator> > >(operatorSet, bcSet);

            object temp = arraySet;

            model.rollback(ref temp, getResidualTime(), 0.0, timeSteps_, conditionSet);
            arraySet = (List <Vector>)temp;

            prices_.setValues(arraySet[0]);
            controlPrices_.setValues(arraySet[1]);

            StrikedTypePayoff striked_payoff = payoff_ as StrikedTypePayoff;

            Utils.QL_REQUIRE(striked_payoff != null, () => "non-striked payoff given");

            double variance         = process_.blackVolatility().link.blackVariance(exerciseDate_, striked_payoff.strike());
            double dividendDiscount = process_.dividendYield().link.discount(exerciseDate_);
            double riskFreeDiscount = process_.riskFreeRate().link.discount(exerciseDate_);
            double spot             = process_.stateVariable().link.value();
            double forwardPrice     = spot * dividendDiscount / riskFreeDiscount;

            BlackCalculator black = new BlackCalculator(striked_payoff, forwardPrice, Math.Sqrt(variance), riskFreeDiscount);

            results.value = prices_.valueAtCenter()
                            - controlPrices_.valueAtCenter()
                            + black.value();
            results.delta = prices_.firstDerivativeAtCenter()
                            - controlPrices_.firstDerivativeAtCenter()
                            + black.delta(spot);
            results.gamma = prices_.secondDerivativeAtCenter()
                            - controlPrices_.secondDerivativeAtCenter()
                            + black.gamma(spot);
            results.additionalResults["priceCurve"] = prices_;
        }
Beispiel #3
0
        public override void calculate(IPricingEngineResults r)
        {
            OneAssetOption.Results results = r as OneAssetOption.Results;
            setGridLimits();
            initializeInitialCondition();
            initializeOperator();
            initializeBoundaryConditions();
            initializeStepCondition();

            // typedef StandardSystemFiniteDifferenceModel model_type;

            List<IOperator> operatorSet = new List<IOperator>();
            List<Vector> arraySet = new List<Vector>();
            BoundaryConditionSet bcSet = new BoundaryConditionSet();
            StepConditionSet<Vector> conditionSet = new StepConditionSet<Vector>();

            prices_ = (SampledCurve)intrinsicValues_.Clone();

            controlPrices_ = (SampledCurve)intrinsicValues_.Clone();
            controlOperator_ = (TridiagonalOperator)finiteDifferenceOperator_.Clone();
            controlBCs_[0] = BCs_[0];
            controlBCs_[1] = BCs_[1];

            operatorSet.Add(finiteDifferenceOperator_);
            operatorSet.Add(controlOperator_);

            arraySet.Add(prices_.values());
            arraySet.Add(controlPrices_.values());

            bcSet.Add(BCs_);
            bcSet.Add(controlBCs_);

            conditionSet.Add(stepCondition_);
            conditionSet.Add(new NullCondition<Vector>());

            var model = new FiniteDifferenceModel<ParallelEvolver<CrankNicolson<TridiagonalOperator>>>(operatorSet, bcSet);

            object temp = arraySet;
            model.rollback(ref temp, getResidualTime(), 0.0, timeSteps_, conditionSet);
            arraySet = (List<Vector>)temp;

            prices_.setValues(arraySet[0]);
            controlPrices_.setValues(arraySet[1]);

            StrikedTypePayoff striked_payoff = payoff_ as StrikedTypePayoff;
            if (striked_payoff == null)
                throw new ApplicationException("non-striked payoff given");

            double variance = process_.blackVolatility().link.blackVariance(exerciseDate_, striked_payoff.strike());
            double dividendDiscount = process_.dividendYield().link.discount(exerciseDate_);
            double riskFreeDiscount = process_.riskFreeRate().link.discount(exerciseDate_);
            double spot = process_.stateVariable().link.value();
            double forwardPrice = spot * dividendDiscount / riskFreeDiscount;

            BlackCalculator black = new BlackCalculator(striked_payoff, forwardPrice, Math.Sqrt(variance), riskFreeDiscount);

            results.value = prices_.valueAtCenter()
                - controlPrices_.valueAtCenter()
                + black.value();
            results.delta = prices_.firstDerivativeAtCenter()
                - controlPrices_.firstDerivativeAtCenter()
                + black.delta(spot);
            results.gamma = prices_.secondDerivativeAtCenter()
                - controlPrices_.secondDerivativeAtCenter()
                + black.gamma(spot);
            results.additionalResults.Add("priceCurve", prices_);
        }