@Override
public Double evaluate(final Double x) {
return presentValueDeltaStandard(
_forward,
x,
_expiry,
_capStandard.isCap(),
_df,
_capStandard.getNotional(),
_capStandard.getPaymentYearFraction());
}
public InArrearsDeltaIntegrant(
final CapFloorIbor capStandard, final MulticurveProviderInterface curves) {
_capStandard = capStandard;
_forward =
curves.getSimplyCompoundForwardRate(
capStandard.getIndex(),
capStandard.getFixingPeriodStartTime(),
capStandard.getFixingPeriodEndTime(),
capStandard.getFixingAccrualFactor());
_expiry = capStandard.getFixingTime();
_df = curves.getDiscountFactor(capStandard.getCurrency(), capStandard.getPaymentTime());
}
@Test
/** Test the present value using the method with the direct formula with extrapolation. */
public void presentValueCurveSensitivityMethodVsCalculator() {
final SABRInterestRateDataBundle sabrExtraBundle =
new SABRInterestRateDataBundle(SABR_PARAMETERS, CURVES);
final InterestRateCurveSensitivity pvsMethod =
METHOD.presentValueSensitivity(CAP_HIGH_LONG, SABR_BUNDLE);
final InterestRateCurveSensitivity pvsCalculator =
new InterestRateCurveSensitivity(CAP_HIGH_LONG.accept(PVSC, sabrExtraBundle));
assertEquals(
"Cap/floor: SABR with extrapolation pv curve sensitivity - Method vs Calculator",
pvsMethod,
pvsCalculator);
}
@Test
/** Test the present value using the method with the direct formula with extrapolation. */
public void presentValueMethodVsCalculator() {
final SABRInterestRateDataBundle sabrExtraBundle =
new SABRInterestRateDataBundle(SABR_PARAMETERS, CURVES);
final CurrencyAmount pvMethod = METHOD.presentValue(CAP_LONG, SABR_BUNDLE);
final PresentValueSABRExtrapolationCalculator pvc =
new PresentValueSABRExtrapolationCalculator(CUT_OFF_STRIKE, MU);
final double pvCalculator = CAP_LONG.accept(pvc, sabrExtraBundle);
assertEquals(
"Cap/floor: SABR with extrapolation pricing - Method vs Calculator",
pvMethod.getAmount(),
pvCalculator,
1E-2);
}
@Test
/**
* Test the present value SABR parameters sensitivity against a finite difference computation;
* strike above the cut-off strike.
*/
public void testPresentValueSABRSensitivityAboveCutOff() {
final YieldCurveBundle curves = TestsDataSetsSABR.createCurves1();
final SABRInterestRateParameters sabrParameter = TestsDataSetsSABR.createSABR1();
final SABRInterestRateDataBundle sabrBundle =
new SABRInterestRateDataBundle(sabrParameter, curves);
final CurrencyAmount pv = METHOD.presentValue(CAP_HIGH_LONG, sabrBundle);
final PresentValueSABRSensitivityDataBundle pvsCapLong =
METHOD.presentValueSABRSensitivity(CAP_HIGH_LONG, sabrBundle);
PresentValueSABRSensitivityDataBundle pvsCapShort =
METHOD.presentValueSABRSensitivity(CAP_HIGH_SHORT, sabrBundle);
// Long/short parity
pvsCapShort = pvsCapShort.multiplyBy(-1.0);
assertEquals(pvsCapShort.getAlpha(), pvsCapLong.getAlpha());
// SABR sensitivity vs finite difference
final double shift = 0.0001;
final double shiftAlpha = 0.00001;
final DoublesPair expectedExpiryTenor =
new DoublesPair(
CAP_HIGH_LONG.getFixingTime(),
CAP_HIGH_LONG.getFixingPeriodEndTime() - CAP_HIGH_LONG.getFixingPeriodStartTime());
// Alpha sensitivity vs finite difference computation
final SABRInterestRateParameters sabrParameterAlphaBumped =
TestsDataSetsSABR.createSABR1AlphaBumped(shiftAlpha);
final SABRInterestRateDataBundle sabrBundleAlphaBumped =
new SABRInterestRateDataBundle(sabrParameterAlphaBumped, curves);
final CurrencyAmount pvLongPayerAlphaBumped =
METHOD.presentValue(CAP_HIGH_LONG, sabrBundleAlphaBumped);
final double expectedAlphaSensi =
(pvLongPayerAlphaBumped.getAmount() - pv.getAmount()) / shiftAlpha;
assertEquals("Number of alpha sensitivity", pvsCapLong.getAlpha().getMap().keySet().size(), 1);
assertEquals(
"Alpha sensitivity expiry/tenor",
pvsCapLong.getAlpha().getMap().keySet().contains(expectedExpiryTenor),
true);
assertEquals(
"Alpha sensitivity value",
expectedAlphaSensi,
pvsCapLong.getAlpha().getMap().get(expectedExpiryTenor),
1.0E-0);
// Rho sensitivity vs finite difference computation
final SABRInterestRateParameters sabrParameterRhoBumped =
TestsDataSetsSABR.createSABR1RhoBumped();
final SABRInterestRateDataBundle sabrBundleRhoBumped =
new SABRInterestRateDataBundle(sabrParameterRhoBumped, curves);
final CurrencyAmount pvLongPayerRhoBumped =
METHOD.presentValue(CAP_HIGH_LONG, sabrBundleRhoBumped);
final double expectedRhoSensi = (pvLongPayerRhoBumped.getAmount() - pv.getAmount()) / shift;
assertEquals("Number of rho sensitivity", pvsCapLong.getRho().getMap().keySet().size(), 1);
assertEquals(
"Rho sensitivity expiry/tenor",
pvsCapLong.getRho().getMap().keySet().contains(expectedExpiryTenor),
true);
assertEquals(
"Rho sensitivity value",
pvsCapLong.getRho().getMap().get(expectedExpiryTenor),
expectedRhoSensi,
1.0E-1);
// Alpha sensitivity vs finite difference computation
final SABRInterestRateParameters sabrParameterNuBumped =
TestsDataSetsSABR.createSABR1NuBumped();
final SABRInterestRateDataBundle sabrBundleNuBumped =
new SABRInterestRateDataBundle(sabrParameterNuBumped, curves);
final CurrencyAmount pvLongPayerNuBumped =
METHOD.presentValue(CAP_HIGH_LONG, sabrBundleNuBumped);
final double expectedNuSensi = (pvLongPayerNuBumped.getAmount() - pv.getAmount()) / shift;
assertEquals("Number of nu sensitivity", pvsCapLong.getNu().getMap().keySet().size(), 1);
assertEquals(
"Nu sensitivity expiry/tenor",
pvsCapLong.getNu().getMap().keySet().contains(expectedExpiryTenor),
true);
assertEquals(
"Nu sensitivity value",
pvsCapLong.getNu().getMap().get(expectedExpiryTenor),
expectedNuSensi,
2.0E-1);
}
@Test
/**
* Test the present value rate sensitivity against a finite difference computation; strike above
* the cut-off strike. Test sensitivity long/short parity.
*/
public void testPresentValueSensitivityAboveCutOff() {
final YieldCurveBundle curves = TestsDataSetsSABR.createCurves1();
final SABRInterestRateParameters sabrParameter = TestsDataSetsSABR.createSABR1();
final SABRInterestRateDataBundle sabrBundle =
new SABRInterestRateDataBundle(sabrParameter, curves);
InterestRateCurveSensitivity pvsCapLong =
METHOD.presentValueSensitivity(CAP_HIGH_LONG, sabrBundle);
final InterestRateCurveSensitivity pvsCapShort =
METHOD.presentValueSensitivity(CAP_HIGH_SHORT, sabrBundle);
// Long/short parity
final InterestRateCurveSensitivity pvsCapShort_1 = pvsCapShort.multipliedBy(-1);
assertEquals(pvsCapLong.getSensitivities(), pvsCapShort_1.getSensitivities());
// Present value sensitivity comparison with finite difference.
final double deltaTolerancePrice = 1.0E-1;
// Testing note: Sensitivity is for a movement of 1. 1E+2 = 1 cent for a 1 bp move.
final double deltaShift = 1.0E-7;
pvsCapLong = pvsCapLong.cleaned();
final String bumpedCurveName = "Bumped Curve";
// 1. Forward curve sensitivity
final String[] CurveNameBumpedForward = {FUNDING_CURVE_NAME, bumpedCurveName};
final CapFloorIbor capBumpedForward =
(CapFloorIbor)
CAP_HIGH_LONG_DEFINITION.toDerivative(REFERENCE_DATE, CurveNameBumpedForward);
final double[] nodeTimesForward =
new double[] {
capBumpedForward.getFixingPeriodStartTime(), capBumpedForward.getFixingPeriodEndTime()
};
final double[] sensiForwardMethod =
SensitivityFiniteDifference.curveSensitivity(
capBumpedForward,
SABR_BUNDLE,
FORWARD_CURVE_NAME,
bumpedCurveName,
nodeTimesForward,
deltaShift,
METHOD);
assertEquals(
"Sensitivity finite difference method: number of node", 2, sensiForwardMethod.length);
final List<DoublesPair> sensiPvForward = pvsCapLong.getSensitivities().get(FORWARD_CURVE_NAME);
for (int loopnode = 0; loopnode < sensiForwardMethod.length; loopnode++) {
final DoublesPair pairPv = sensiPvForward.get(loopnode);
assertEquals(
"Sensitivity cap/floor pv to forward curve: Node " + loopnode,
nodeTimesForward[loopnode],
pairPv.getFirst(),
1E-8);
// assertEquals("Sensitivity finite difference method: node sensitivity: Node " +
// loopnode, pairPv.second, sensiForwardMethod[loopnode], deltaTolerancePrice);
}
// 2. Discounting curve sensitivity
final String[] CurveNameBumpedDisc = {bumpedCurveName, FORWARD_CURVE_NAME};
final CapFloorIbor capBumpedDisc =
(CapFloorIbor) CAP_HIGH_LONG_DEFINITION.toDerivative(REFERENCE_DATE, CurveNameBumpedDisc);
final double[] nodeTimesDisc = new double[] {capBumpedDisc.getPaymentTime()};
final double[] sensiDiscMethod =
SensitivityFiniteDifference.curveSensitivity(
capBumpedDisc,
SABR_BUNDLE,
FUNDING_CURVE_NAME,
bumpedCurveName,
nodeTimesDisc,
deltaShift,
METHOD);
assertEquals("Sensitivity finite difference method: number of node", 1, sensiDiscMethod.length);
final List<DoublesPair> sensiPvDisc = pvsCapLong.getSensitivities().get(FUNDING_CURVE_NAME);
for (int loopnode = 0; loopnode < sensiDiscMethod.length; loopnode++) {
final DoublesPair pairPv = sensiPvDisc.get(loopnode);
assertEquals(
"Sensitivity cap/floor pv to forward curve: Node " + loopnode,
nodeTimesDisc[loopnode],
pairPv.getFirst(),
1E-8);
assertEquals(
"Sensitivity finite difference method: node sensitivity",
pairPv.second,
sensiDiscMethod[loopnode],
deltaTolerancePrice);
}
}
@Test
/** Test the present value using the method with the direct formula with extrapolation. */
public void presentValueAboveCutOff() {
CurrencyAmount methodPrice = METHOD.presentValue(CAP_HIGH_LONG, SABR_BUNDLE);
final double df =
CURVES.getCurve(FUNDING_CURVE_NAME).getDiscountFactor(CAP_HIGH_LONG.getPaymentTime());
final double forward = CAP_HIGH_LONG.accept(PRC, CURVES);
final double maturity =
CAP_HIGH_LONG.getFixingPeriodEndTime() - CAP_LONG.getFixingPeriodStartTime();
final DoublesPair expiryMaturity = new DoublesPair(CAP_HIGH_LONG.getFixingTime(), maturity);
final double alpha = SABR_PARAMETERS.getAlpha(expiryMaturity);
final double beta = SABR_PARAMETERS.getBeta(expiryMaturity);
final double rho = SABR_PARAMETERS.getRho(expiryMaturity);
final double nu = SABR_PARAMETERS.getNu(expiryMaturity);
final SABRFormulaData sabrParam = new SABRFormulaData(alpha, beta, rho, nu);
final SABRExtrapolationRightFunction sabrExtrapolation =
new SABRExtrapolationRightFunction(
forward, sabrParam, CUT_OFF_STRIKE, CAP_HIGH_LONG.getFixingTime(), MU);
final EuropeanVanillaOption option =
new EuropeanVanillaOption(
CAP_HIGH_LONG.getStrike(), CAP_HIGH_LONG.getFixingTime(), CAP_HIGH_LONG.isCap());
final double expectedPrice =
sabrExtrapolation.price(option)
* CAP_HIGH_LONG.getNotional()
* CAP_HIGH_LONG.getPaymentYearFraction()
* df;
assertEquals(
"Cap/floor: SABR with extrapolation pricing", expectedPrice, methodPrice.getAmount(), 1E-2);
methodPrice = METHOD.presentValue(CAP_HIGH_LONG, SABR_BUNDLE);
assertEquals(
"Cap/floor: SABR with extrapolation pricing", expectedPrice, methodPrice.getAmount(), 1E-2);
}
@Override
public Double visitCapFloorIbor(final CapFloorIbor payment, final YieldCurveBundle data) {
return visitCouponIborSpread(payment.toCoupon(), data);
}
/**
* Computes the present value of an Ibor cap/floor in arrears by replication based on the paper,
* "Swap and Cap/Floors with Fixing in Arrears or Payment Delay," OpenGamma Quantitative
* Documentation
* http://developers.opengamma.com/quantitative-research/In-Arrears-and-Payment-Delay-Swaps-and-Caps-OpenGamma.pdf
*
* @param cap The cap/floor
* @param curves The curves
* @return The present value
*/
public MultipleCurrencyAmount presentValue(
final CapFloorIbor cap, final MulticurveProviderInterface curves) {
ArgumentChecker.notNull(cap, "The cap/floor shoud not be null");
ArgumentChecker.notNull(curves, "curves");
final Currency ccy = cap.getCurrency();
// Construct a "standard" CapFloorIbor whose paymentTime is set to be fixingPeriodEndTime
CapFloorIbor capStandard =
new CapFloorIbor(
cap.getCurrency(),
cap.getFixingPeriodEndTime(),
cap.getPaymentYearFraction(),
cap.getNotional(),
cap.getFixingTime(),
cap.getIndex(),
cap.getFixingPeriodStartTime(),
cap.getFixingPeriodEndTime(),
cap.getFixingAccrualFactor(),
cap.getStrike(),
cap.isCap());
final double forward =
curves.getSimplyCompoundForwardRate(
cap.getIndex(),
cap.getFixingPeriodStartTime(),
cap.getFixingPeriodEndTime(),
cap.getFixingAccrualFactor());
final double beta =
(1.0 + cap.getFixingAccrualFactor() * forward)
* curves.getDiscountFactor(ccy, cap.getFixingPeriodEndTime())
/ curves.getDiscountFactor(ccy, cap.getFixingPeriodStartTime());
final double df =
curves.getDiscountFactor(capStandard.getCurrency(), capStandard.getPaymentTime());
final double strikePart =
(1.0 + cap.getFixingAccrualFactor() * capStandard.getStrike())
* presentValueStandard(
forward,
capStandard.getStrike(),
capStandard.getFixingTime(),
capStandard.isCap(),
df,
capStandard.getNotional(),
capStandard.getPaymentYearFraction());
final InArrearsIntegrant integrant = new InArrearsIntegrant(capStandard, curves);
double integralPart;
try {
if (cap.isCap()) {
double atmVol = _smileFunction.getVolatility(forward);
double upper = forward * Math.exp(6.0 * atmVol * Math.sqrt(cap.getFixingTime()));
double strike = cap.getStrike();
integralPart = INTEGRATOR.integrate(integrant, strike, upper);
double reminder = integrant.evaluate(upper) * upper;
double error = reminder / integralPart;
int count = 0;
while (Math.abs(error) > REL_ERROR && count < MAX_COUNT) {
integralPart += INTEGRATOR.integrate(integrant, upper, 2.0 * upper);
upper *= 2.0;
// The increase of integralPart in the next loop is bounded by reminder
reminder = integrant.evaluate(upper) * upper;
error = reminder / integralPart;
++count;
if (count == MAX_COUNT) {
LOGGER.info(
"Maximum iteration count, "
+ MAX_COUNT
+ ", has been reached. Relative error is greater than "
+ REL_ERROR);
}
}
} else {
double strike = cap.getStrike();
integralPart = INTEGRATOR.integrate(integrant, REL_TOL * strike, strike);
}
} catch (final Exception e) {
throw new MathException(e);
}
integralPart *= 2.0 * cap.getFixingAccrualFactor();
final double pv = (strikePart + integralPart) / beta;
return MultipleCurrencyAmount.of(cap.getCurrency(), pv);
}
/**
* Computes the pv sensitivity of an Ibor cap/floor in arrears
*
* @param cap The cap/floor
* @param curves The curves
* @return The sensitivity
*/
public MultipleCurrencyMulticurveSensitivity presentValueCurveSensitivity(
final CapFloorIbor cap, final MulticurveProviderInterface curves) {
ArgumentChecker.notNull(cap, "The cap/floor shoud not be null");
ArgumentChecker.notNull(curves, "curves");
final Currency ccy = cap.getCurrency();
// Construct a "standard" CapFloorIbor whose paymentTime is set to be fixingPeriodEndTime
CapFloorIbor capStandard =
new CapFloorIbor(
cap.getCurrency(),
cap.getFixingPeriodEndTime(),
cap.getPaymentYearFraction(),
cap.getNotional(),
cap.getFixingTime(),
cap.getIndex(),
cap.getFixingPeriodStartTime(),
cap.getFixingPeriodEndTime(),
cap.getFixingAccrualFactor(),
cap.getStrike(),
cap.isCap());
final double forward =
curves.getSimplyCompoundForwardRate(
cap.getIndex(),
cap.getFixingPeriodStartTime(),
cap.getFixingPeriodEndTime(),
cap.getFixingAccrualFactor());
final double beta =
(1.0 + cap.getFixingAccrualFactor() * forward)
* curves.getDiscountFactor(ccy, cap.getFixingPeriodEndTime())
/ curves.getDiscountFactor(ccy, cap.getFixingPeriodStartTime());
double df = curves.getDiscountFactor(capStandard.getCurrency(), capStandard.getPaymentTime());
double strikePart =
(1.0 + cap.getFixingAccrualFactor() * capStandard.getStrike())
* presentValueStandard(
forward,
capStandard.getStrike(),
capStandard.getFixingTime(),
capStandard.isCap(),
df,
capStandard.getNotional(),
capStandard.getPaymentYearFraction());
double strikePartDelta =
(1.0 + cap.getFixingAccrualFactor() * capStandard.getStrike())
* presentValueDeltaStandard(
forward,
capStandard.getStrike(),
capStandard.getFixingTime(),
capStandard.isCap(),
df,
capStandard.getNotional(),
capStandard.getPaymentYearFraction());
final InArrearsIntegrant integrant = new InArrearsIntegrant(capStandard, curves);
double integralPart;
double upper = 0.0;
try {
if (cap.isCap()) {
double atmVol = _smileFunction.getVolatility(forward);
upper = forward * Math.exp(6.0 * atmVol * Math.sqrt(cap.getFixingTime()));
double strike = cap.getStrike();
integralPart = INTEGRATOR.integrate(integrant, strike, upper);
double reminder = integrant.evaluate(upper) * upper;
double error = reminder / integralPart;
int count = 0;
while (Math.abs(error) > REL_ERROR && count < MAX_COUNT) {
integralPart += INTEGRATOR.integrate(integrant, upper, 2.0 * upper);
upper *= 2.0;
// The increase of integralPart in the next loop is bounded by reminder
reminder = integrant.evaluate(upper) * upper;
error = reminder / integralPart;
++count;
if (count == MAX_COUNT) {
LOGGER.info(
"Maximum iteration count, "
+ MAX_COUNT
+ ", has been reached. Relative error is greater than "
+ REL_ERROR);
}
}
} else {
double strike = cap.getStrike();
integralPart = INTEGRATOR.integrate(integrant, REL_TOL * strike, strike);
}
} catch (final Exception e) {
throw new MathException(e);
}
integralPart *= 2.0 * cap.getFixingAccrualFactor();
double pv = (strikePart + integralPart) / beta;
double betaFwd =
cap.getFixingAccrualFactor()
* curves.getDiscountFactor(ccy, cap.getFixingPeriodEndTime())
/ curves.getDiscountFactor(ccy, cap.getFixingPeriodStartTime());
double betaDscStart =
(1.0 + cap.getFixingAccrualFactor() * forward)
* curves.getDiscountFactor(ccy, cap.getFixingPeriodEndTime())
* cap.getFixingPeriodStartTime()
/ curves.getDiscountFactor(ccy, cap.getFixingPeriodStartTime());
double betaDscEnd =
-(1.0 + cap.getFixingAccrualFactor() * forward)
* curves.getDiscountFactor(ccy, cap.getFixingPeriodEndTime())
* cap.getFixingPeriodEndTime()
/ curves.getDiscountFactor(ccy, cap.getFixingPeriodStartTime());
List<DoublesPair> listDiscounting = new ArrayList<>();
double strikePartDsc = -capStandard.getPaymentTime() * strikePart;
double integralPartDsc = -capStandard.getPaymentTime() * integralPart;
listDiscounting.add(
DoublesPair.of(capStandard.getPaymentTime(), (strikePartDsc + integralPartDsc) / beta));
listDiscounting.add(DoublesPair.of(cap.getFixingPeriodStartTime(), -pv * betaDscStart / beta));
listDiscounting.add(DoublesPair.of(cap.getFixingPeriodEndTime(), -pv * betaDscEnd / beta));
Map<String, List<DoublesPair>> mapDsc = new HashMap<>();
mapDsc.put(curves.getName(capStandard.getCurrency()), listDiscounting);
final List<ForwardSensitivity> listForward = new ArrayList<>();
double strikePartFwd = strikePartDelta;
double integralPartFwd = 0.0;
final InArrearsDeltaIntegrant integrantFwd = new InArrearsDeltaIntegrant(capStandard, curves);
try {
if (cap.isCap()) {
double strike = cap.getStrike();
integralPartFwd = INTEGRATOR.integrate(integrantFwd, strike, upper);
} else {
double strike = cap.getStrike();
integralPartFwd = INTEGRATOR.integrate(integrantFwd, REL_TOL * strike, strike);
}
} catch (final Exception e) {
throw new MathException(e);
}
integralPartFwd *= 2.0 * cap.getFixingAccrualFactor();
listForward.add(
new SimplyCompoundedForwardSensitivity(
capStandard.getFixingPeriodStartTime(),
capStandard.getFixingPeriodEndTime(),
capStandard.getFixingAccrualFactor(),
(strikePartFwd + integralPartFwd - pv * betaFwd) / beta));
Map<String, List<ForwardSensitivity>> mapFwd = new HashMap<>();
mapFwd.put(curves.getName(capStandard.getIndex()), listForward);
return MultipleCurrencyMulticurveSensitivity.of(
cap.getCurrency(), MulticurveSensitivity.of(mapDsc, mapFwd));
}
@Override
public DecisionSchedule visitCapFloorIbor(
final CapFloorIbor payment, final MulticurveProviderInterface multicurves) {
final double[] decisionTime = new double[] {payment.getFixingTime()};
final double fixingStartTime = payment.getFixingPeriodStartTime();
final double fixingEndTime = payment.getFixingPeriodEndTime();
final double paymentTime = payment.getPaymentTime();
final double[][] impactTime = new double[1][];
impactTime[0] = new double[] {fixingStartTime, fixingEndTime, paymentTime};
final double[][] impactAmount = new double[1][];
double forward =
multicurves.getForwardRate(
payment.getIndex(),
payment.getFixingPeriodStartTime(),
payment.getFixingPeriodEndTime(),
payment.getFixingAccrualFactor());
final double beta =
(1.0 + payment.getFixingAccrualFactor() * forward)
* multicurves.getDiscountFactor(payment.getCurrency(), payment.getFixingPeriodEndTime())
/ multicurves.getDiscountFactor(
payment.getCurrency(), payment.getFixingPeriodStartTime());
impactAmount[0] = new double[] {beta, -1.0, 1.0};
final DecisionSchedule decision = new DecisionSchedule(decisionTime, impactTime, impactAmount);
return decision;
}
