► bin | |
lalinspiral_injfind.py | |
lalinspiral_thinca.py | |
version.c | |
► lib | |
BandPassInspiralTemplate.c | |
BBHPhenomCoeffs.h | |
CoincInspiralEllipsoid.h | |
FindChirp.h | |
FindChirpPhenomWaveform.c | |
FindChirpPTF.h | |
FindChirpPTFWaveform.c | Provides functions to create physical template family templates in a form that can be used by the FindChirpPTFFilter() function |
FindChirpSimulation.c | Provides an interface between code build from findchirp and various simulation packages for injecting chirps into data |
GenerateInspiral.c | |
GenerateInspiral.h | |
GenerateInspRing.c | |
GenerateInspRing.h | |
GeneratePPNAmpCorInspiral.c | |
GeneratePPNInspiral.c | |
GeneratePPNInspiral.h | |
GetErrorMatrixFromSnglInspiral.c | Blah |
GetInspiralParams.c | |
InspiralBankGeneration.c | |
InspiralInjectionParams.c | Functions for generating random distributions of inspiral parameters for injection purposes |
InspiralInjectionParams.h | |
InspiralSpinBank.c | |
LALBCVWaveform.c | This module contains a single function LALBCVWaveform() |
LALEOBGetFactorizedWaveform.c | |
LALEOBNonQCCorrection.c | |
LALEOBNRv2Waveform.h | |
LALEOBPPWaveform.c | Functions to generate the EOBNRv2 waveforms, as defined in Pan et al, arXiv:1106.1021v1 [gr-qc] |
LALEOBWaveform.c | Module to generate effective-one-body waveforms |
LALEtaTau02.c | Given \(\tau_0\) and \(\tau_2\) compute the mass ratio \(\eta.\) |
LALEtaTau04.c | Given \(\tau_0\) and \(\tau_4\) solve for the mass ratio \(\eta.\) |
LALFactorizedFlux.c | |
LALHexagonVertices.c | Module to find the vertices of an hexagon inscribed in an ellipse given its centre, half side-lengths and orientation angle |
LALInsidePolygon.c | |
LALInspiral.h | |
LALInspiralAmplitude.c | Given an inspiral template structure containing the binary distance and a set of mass parameters, that module provides functions to compute the related amplitude |
LALInspiralAmplitudeCorrectedWave.c | The code LALInspiralAmplitudeCorrectedWave generates an time-domain inspiral waveform corresponding to the approximant TaylorT1 and PadeT1 as outlined in the documentation for the function LALInspiralWave |
LALInspiralBank.h | |
LALInspiralBankList.c | |
LALInspiralBankUtils.c | |
LALInspiralBCVBank.c | |
LALInspiralChooseModel.c | Module to set the pointers to the required energy and flux functions. Normally, a user is not required to call this function to generate a waveform |
LALInspiralComputeMetric.c | |
LALInspiralComputeParams.c | |
LALInspiralComputePTFMetric.c | Module to compute the components of the metric which is used to describe distances on Physical Template Family signal manifold |
LALInspiralConfig.h | |
LALInspiralCreateCoarseBank.c | |
LALInspiralCreateFineBank.c | |
LALInspiralDerivatives.c | Module to calculate the RHS of the differential equations in Eq. \eqref{eq_ode2} |
LALInspiralEccentricity.c | The code LALInspiralEccentricity generates a time-domain inspiral waveform corresponding to the approximant Eccentricity as outlined PRD 60 for the Newtonian case |
LALInspiralFrequency3.c | The code LALInspiralFrequency3.c calculates the frequency the waveform from an inspiralling binary system as a function of time up to 3.5 post-Nowtonian order |
LALInspiralGetApproximantString.c | Function for creating the approximant string which gets written to output files for a given approximant and PN order of the phasing |
LALInspiralHexagonalBank.c | NONE |
LALInspiralHybridHexagonalBank.c | |
LALInspiralIIR.c | |
LALInspiralInit.c | Module to initialize some parameters for waveform generation |
LALInspiralLongestTemplateInBank.c | |
LALInspiralMoments.c | |
LALInspiralNextTemplate.c | |
LALInspiralNinjaInject.c | |
LALInspiralParameterCalc.c | Given a pair of masses (or other equivalent parameters) compute related chirp parameters |
LALInspiralPhasing1.c | This module is used to set the phase of the waveform so that it is equal to the user specified phase \(\phi_0\) when the ‘velocity’ of the system is equal to \(v.\) |
LALInspiralPhasing2.c | The code LALInspiralPhasing2.c calculates the phase of an inspiral waveform as a function of the instantaneous frequency of the wave, up to \(2^{nd}\) post–Newtonian order |
LALInspiralPhasing3.c | The code LALInspiralPhasing3.c calculates the phase the waveform from an inspiralling binary system as a function of time up to second post-Nowtonian order |
LALInspiralPhiofVIntegrand.c | The function XLALInspiralPhiofVIntegrand() calculates the quantity \(v^{3} E^{\prime}(v)/\mathcal{F}(v)\) |
LALInspiralPolarizations.c | This code generates the two GW polarizations of the inspiral waveform for a given phase model |
LALInspiralRingdownWave.c | Module to compute the ring-down waveform as linear combination of quasi-normal-modes decaying waveforms, which can be attached to the inspiral part of the compat binary coalescing waveform |
LALInspiralSBankOverlap.c | |
LALInspiralSBankOverlap.h | |
LALInspiralSetParams.c | |
LALInspiralSetSearchLimits.c | |
LALInspiralSetup.c | Module to generate all the Taylor and Pade coefficients needed in waveform generation |
LALInspiralSpinningBHBinary.c | This module generates the inspiral waveform from a binary consisting of two spinning compact stars |
LALInspiralStationaryPhaseApprox1.c | This module computes the stationary phase approximation to the Fourier transform of a chirp waveform by integrating Eq. \eqref{eq_InspiralFourierPhase} |
LALInspiralStationaryPhaseApprox2.c | This module computes the usual stationary phase approximation to the Fourier transform of a chirp waveform given by Eq. \eqref{eq_InspiralFourierPhase_f2} |
LALInspiralTaylorEtWaveform.c | NONE |
LALInspiralTaylorNWaveform.c | NONE |
LALInspiralTaylorT4Waveform.c | NONE |
LALInspiralTiming2.c | Module used in solving the timing and phasing functions in quadrature for the Approximant TaylorT2 |
LALInspiralTofV.c | NONE |
LALInspiralTofVIntegrand.c | The function LALInspiralTofVIntegrand() calculates the quantity \(E^{\prime}(v)/\mathcal{F}(v)\) |
LALInspiralUpdateParams.c | |
LALInspiralValidParams.c | |
LALInspiralValidTemplate.c | |
LALInspiralVCSInfo.h | |
LALInspiralVCSInfoHeader.h | |
LALInspiralVelocity.c | The function XLALInspiralVelocity() calculates the velocity \(v\) which corresponds to a time \(t\) in the inspiralling binary system |
LALInspiralWave.c | Interface routine needed to generate all waveforms in the Inspiral Waveforms package |
LALInspiralWave1.c | The code LALInspiralWave1() generates an time-domain inspiral waveform corresponding to the Approximant TaylorT1 and PadeT1 as outlined in the documentation for the function LALInspiralWave() |
LALInspiralWave2.c | These modules generate a time-domain chirp waveform of type TaylorT2 |
LALInspiralWave3.c | These modules generate a time-domain chirp waveform of type TaylorT3 |
LALInspiralWaveCorrelate.c | Module to compute the correlation of two data sets |
LALInspiralWaveLength.c | Module to calculate the number of data points (to the nearest power of 2) needed to store a waveform |
LALInspiralWaveNormalise.c | Module to find the norm of a signal and to return a normalised array. The original signal is left untouched |
LALInspiralWaveNormaliseLSO.c | Module to find the norm of a signal and to return a normaliseLSOd array. The original signal is left untouched |
LALInspiralWaveOverlap.c | Module to compute the overlap of a given data set with two orthogonal inspiral signals of specified parameters with a weight specified in a psd array. The code also returns in a parameter structure the maximum of the overlap, the bin where the maximum occured and the phase at the maximum |
LALNewtonianMultipole.c | |
LALNoiseModelsInspiral.h | |
LALPhenomWaveform.c | |
LALPrintTimeseries.c | |
LALPSpinInspiralRD.c | |
LALPSpinInspiralRingdownWave.c | Module to compute the ring-down waveform as linear combination of quasi-normal-modes decaying waveforms, which can be attached to the phenomenological spin Taylor waveform |
LALRectangleVertices.c | |
LALRungeKutta4.c | NONE |
LALSQTPNIntegrator.c | Contains the function definitions needed by the integration method |
LALSQTPNIntegrator.h | |
LALSQTPNWaveform.c | Contains the function definition to create GWforms |
LALSQTPNWaveform.h | |
LALSQTPNWaveformInterface.c | Contains function definitions to integrate the SpinQuadTaylor code into the other parts of the LALSuit |
LALSQTPNWaveformInterface.h | |
LALSTPNWaveform.c | Module to generate STPN (spinning binaries) waveforms in agreement with the injecttion package (return a CoherentGW structure) |
LALSTPNWaveform2.c | |
LALSTPNWaveform2.h | |
LALSTPNWaveformErrors.h | |
LALSTPNWaveformFrameless.c | |
LALSTPNWaveformFrameless.h | |
LALTaylorF2ReducedSpin.c | |
LALTrigScanCluster.c | Functions for trigScan clustering |
LALTrigScanCluster.h | |
LIGOMetadataInspiralUtils.h | |
LIGOMetadataRingdownUtils.h | |
NDTemplateBank.c | This module handles template bank generation for up to searches with \(<=\) 12 dimensional parameter spaces |
NRWaveInject.c | |
NRWaveInject.h | |
NRWaveIO.c | Functions for reading/writing numerical relativity waveforms |
NRWaveIO.h | |
RingUtils.c | |
RingUtils.h | |
SimInspiralUtils.c | Provides a set of utilities for manipulating simInspiralTables |
SnglInspiralUtils.c | Provides a set of utilities for manipulating snglInspiralTables |
TemplateBankGeneration.h | |
TrigScanEThincaCommon.c | Provides helper functions used in TrigScan and E-thinca |
TrigScanEThincaCommon.h | |
► python | |
► lalinspiral | |
__init__.py | |
_thinca.c | |
git_version.py | |
inspinjfind.py | |
src | |
► swig | |
SWIGLALInspiralAlpha.i | |
SWIGLALInspiralOmega.i | |
SWIGLALInspiralTest.h | |
SWIGTest.c | |
SWIGTestLALInspiralPython.py | |
► test | |
► python | |
test_python_imports.py | |
test_python_scripts.py | |
thinca_brute_force_coinc.py | |
thinca_compare_coinc_lists.py | |
BasicInjectTest.c | Injects inspiral signals into detector noise |
BCVTemplates.c | Creates a template mesh for BCV (or, alternatively, for SPA but assuing a constant metric) using the mismatch metric |
CoarseTest.c | Test code for the inspiral modules |
CoarseTest2.c | Test code for the bank modules |
GenerateInspiralWaveform.c | Test routine for wave generation codes |
GeneratePPNAmpCorInspiralTest.c | Generates a parametrized post-Newtonian inspiral waveform |
GeneratePPNInspiralTest.c | Generates a parametrized post-Newtonian inspiral waveform |
GetOrientationEllipse.c | Test code for the bank modules |
InjectionInterfaceTest.c | Interface to generate any kind of gravitational waves signal |
InspiralBCVSpinBankTest.c | Tests InpsiralBCVSpinBankTest() |
InspiralSpinBankTest.c | Tests InpsiralSpinBank() |
LALInspiralSpinningBHBinariesTest.c | Test routine for spin-modulted inspiral waveform generation code |
LALInspiralTaylorT2Test.c | |
LALInspiralTaylorT3Test.c | |
LALInspiralTaylorT4Test.c | |
LALInspiralTest.c | Test routine for codes that generate inspiral waveform from non-spinning black hole binaries |
LALSQTPNWaveformTest.c | The user interface for the SpinQuadTaylor program |
LALSTPNWaveformTest.c | |
MetricTest.c | Creates a template mesh for BCV (or, alternatively, for SPA but assuing a constant metric) using the mismatch metric |
MetricTestBCV.c | Creates a template mesh for BCV (or, alternatively, for SPA but assuing a constant metric) using the mismatch metric |
MetricTestPTF.c | Creates the PTF metric for a single point in the parameter space |
PNTemplates.c | Creates a template mesh for BCV (or, alternatively, for SPA but assuing a constant metric) using the mismatch metric |