def run3phase(phasesToCalculate={'v': True, 't': True, 'd': True, 's': True},
              calculationType='annual', epwFile=None, tmatrixFile=None):


    if phasesToCalculate['v']:
        # Step1: Create the view matrix.
        rfluxPara = RfluxmtxParameters()
        rfluxPara.irradianceCalc = True
        rfluxPara.ambientAccuracy = 0.1
        rfluxPara.ambientBounces = 10
        rfluxPara.ambientDivisions = 65536
        rfluxPara.limitWeight = 1E-5

        # step 1.1 Invert glazing surface with xform so that it faces inwards
        xfrPara = XformParameters()
        xfrPara.invertSurfaces = True

        xfr = Xform()
        xfr.xformParameters = xfrPara
        xfr.radFile = 'glazing.rad'
        xfr.outputFile = 'glazingI.rad'
        xfr.execute()

        rflux = Rfluxmtx()
        rflux.sender = '-'

        # This needs to be automated based on the normal of each window.
        # Klems full basis sampling and the window faces +Y
        recCtrlPar = rflux.ControlParameters(hemiType='kf', hemiUpDirection='+Z')
        rflux.receiverFile = rflux.addControlParameters('glazingI.rad',
                                                        {'Exterior_Window': recCtrlPar})

        rflux.rfluxmtxParameters = rfluxPara
        rflux.pointsFile = 'indoor_points.pts'
        rflux.outputMatrix = r'temp/vmatrix.vmx'
        rflux.radFiles = ['room.mat', 'room.rad']
        rflux.execute()

    vMatrix = r'temp/vmatrix.vmx'

    # Step2: Assign T matrix from precalculated XML files.
    tMatrix = tmatrixFile or r'xmls/clear.xml'

    if phasesToCalculate['d']:
        # Step3: Create D matrix.
        rfluxPara = RfluxmtxParameters()
        rfluxPara.ambientAccuracy = 0.1
        rfluxPara.ambientDivisions = 1024
        rfluxPara.ambientBounces = 2
        rfluxPara.limitWeight = 0.0000001

        rflux2 = Rfluxmtx()
        rflux2.samplingRaysCount = 1000
        rflux2.sender = 'glazingI_m.rad'
        skyFile = rflux2.defaultSkyGround(r'temp/rfluxSky.rad', skyType='r1')
        rflux2.receiverFile = skyFile
        rflux2.rfluxmtxParameters = rfluxPara
        rflux2.radFiles = [r"room.mat",
                          r"room.rad"]
        rflux2.outputMatrix = r"temp/dmatrix.dmx"
        rflux2.execute()
    dMatrix = r"temp/dmatrix.dmx"

    # Step4a: Create the sky vector.

    # Step4a.1: Create a sky defintion
    # Step s: Creating the sky matrix
    if phasesToCalculate['s']:
        if calculationType == 'annual':
            weaFile = Epw2wea(epwFile=epwFile or 'test.epw', outputWeaFile=r'temp/test.wea')
            weaFile.execute()

            gendayParam = GendaymtxParameters()
            gendayParam.skyDensity = 1

            genday = Gendaymtx(weaFile=r'temp/test.wea', outputName=r'temp/day.smx')
            genday.gendaymtxParameters = gendayParam
            genday.execute()

            skyVector = r'temp/day.smx'
        else:
            gensk = Gensky()
            gensk.monthDayHour = (11, 11, 11)
            gensk.outputFile = 'temp/sky.rad'
            # gensk.execute()

            genskv = Genskyvec()
            genskv.inputSkyFile = r'temp/sky.rad'
            genskv.outputFile = r'temp/sky.vec'
            genskv.skySubdivision = 1
            genskv.execute()
            skyVector = r'temp/sky.vec'
    else:
        skyVector = r'temp/sky.vec'

    # Step5: Generate results
    dct = Dctimestep()
    dct.tmatrixFile = tMatrix
    dct.vmatrixSpec = vMatrix
    dct.dmatrixFile = dMatrix
    dct.skyVectorFile = skyVector
    dct.outputFileName = r'temp/results3p.tmp'
    dct.execute()




    mtx2Param = RmtxopParameters()
    mtx2Param.outputFormat = 'a'
    mtx2Param.combineValues = (47.4, 119.9, 11.6)
    mtx2Param.transposeMatrix = True
    mtx2 = Rmtxop(matrixFiles=[r'temp/results3p.tmp'], outputFile=r'temp/illuminance3p.ill')
    mtx2.rmtxopParameters = mtx2Param
    mtx2.execute()

    return  'temp/illuminance3p.ill'
Exemple #2
0
def calcDirectIlluminance(epwFile,
                          analemmaPath,
                          sunListPath,
                          sunMatrixPath,
                          materialFile,
                          geometryFiles,
                          pointsFile,
                          folderForCalculations,
                          outputIllFilePath,
                          HOYList=range(8760),
                          overWriteExistingFiles=True):
    """
    Calculate direct illuminance from the Sun.
    Args:
        epwFile: EPW file path.
        solarDiscPath:
        sunListPath:
        sunMatrixPath:
        materialFile: A single material file.
        geometryFiles: One or more geometry files.
        pointsFile: A points file in Daysim compatible format.
        folderForCalculations: A folder where all the intermediate files can be stored.
        outputIllFilePath:
        HOYList:
        overWriteExistingFiles:

    Returns:

    """

    # a sad logging hack
    statusMsg = lambda msg: "\n%s:%s\n%s\n" % (time.ctime(), msg, "*~" * 25)

    # over-write warning.
    def overWriteWarning(filePath,
                         overWriteExistingFiles=overWriteExistingFiles):
        if os.path.exists(filePath):
            if not overWriteExistingFiles:
                raise Exception(
                    "The file %s already exists. Set the variable overWriteExistingFiles"
                    "to True to overWrite this and other files." % filePath)
            else:
                msg = "The file %s already existed and was overwritten" % filePath
                warnings.warn(msg)

    statusMsg('Generating sunpath and sunmatrix')
    analemmaPath, sunListPath, sunMatrixPath = analemmacalculator(
        epwFile=epwFile,
        sunDiscRadPath=analemmaPath,
        sunListPath=sunListPath,
        solarRadiationMatrixPath=sunMatrixPath,
        HOYlist=HOYList)

    sceneData = [materialFile]
    # Append if single, extend if multiple
    if isinstance(geometryFiles, basestring):
        sceneData.append(geometryFiles)
    elif isinstance(geometryFiles, (tuple, list)):
        sceneData.extend(geometryFiles)

    octreeFile = os.path.join(folderForCalculations, 'solar.oct')
    # overWriteWarning(octreeFile)

    statusMsg('Creating octree')
    octree = Oconv()
    octree.sceneFiles = sceneData + [analemmaPath]
    octree.outputFile = octreeFile
    octree.execute()

    statusMsg('Creating sun coefficients')
    dcFile = os.path.join(folderForCalculations, 'sunCoeff.dc')
    overWriteWarning(dcFile)

    tmpIllFile = os.path.join(folderForCalculations, 'illum.tmp')
    overWriteWarning(tmpIllFile)

    rctPara = RcontribParameters()
    rctPara.ambientBounces = 0
    rctPara.directJitter = 0
    rctPara.directCertainty = 1
    rctPara.directThreshold = 0
    rctPara.modFile = sunListPath
    rctPara.irradianceCalc = True

    rctb = Rcontrib()
    rctb.octreeFile = octreeFile
    rctb.outputFile = dcFile
    rctb.pointsFile = pointsFile
    rctb.rcontribParameters = rctPara

    rctb.execute()

    statusMsg('Performing matrix multiplication between the coefficients'
              ' and the sun matrix.')
    dct = Dctimestep()
    dct.daylightCoeffSpec = dcFile
    dct.skyVectorFile = sunMatrixPath
    dct.outputFile = tmpIllFile
    dct.execute()

    statusMsg(
        'Transposing the matrix as per time-series and calculating illuminance.'
    )
    mtx2Param = RmtxopParameters()
    mtx2Param.outputFormat = 'a'
    mtx2Param.combineValues = (47.4, 119.9, 11.6)
    mtx2Param.transposeMatrix = True
    mtx2 = Rmtxop(matrixFiles=[tmpIllFile], outputFile=outputIllFilePath)
    mtx2.rmtxopParameters = mtx2Param
    mtx2.execute()

    return outputIllFilePath
Exemple #3
0
def run3phaseMulti(pointsFile,
                   outputIllName,
                   windowConfig=(),
                   epwFile=None,
                   skyFile=None,
                   geometryFile=None,
                   materialFile=None,
                   reuseVmtx=True,
                   reuseSkyVector=True,
                   reuseDmtx=True,
                   skyDescr=1,
                   klemsForVmtx='kf',
                   vmtxParam=None,
                   dmtxParam=None,
                   TransposeAnnualResults=True,
                   skyVectorParam=None):
    """
    Notes:
        1. It is assumed that the surfaces used for the vmtx are inward facing .i.e they
            need not be flipped.
        2. It is also assumed that the surfaces used for vmtx already have a glow modifier
            assigned to them.
    Args:

        outputIllName: Name of the file to which the results should be written.
        windowConfig: A tuple containing the windowGroupGeometry,
            the direction of the surface Normal, the corresponding T matrix XML and an
            option to include or exclude the results from the windowgroup in the
            calculation. A typical option will be something like ('glazing.rad','+Z',
            'blinds.xml',True), specifying that the radiance geometry 'glazing.rad', whose
            direction normal faces +Z will be used for the calculation of that particular
            V matrix. 'blinds.xml' indicates the XML file that will be used as T matrix
            for that window group and True indicates that this window group will be
            considered for the calculations.

        epwFile: epwFile corresponding to a particular location. If epwFile and skyFile
            are provided, the option for epwFile will be prioritized .i.e. the calculation
            will be annual.
        skyFile: An input from gensky or gendaylit for creating a point-in-time sky vector.
        geometryFile: Geometry for All the files in the calculation except the ones for
            the glazing.
        materialFile: Materials for all the geometry described in the geometryFile input.
        reuseVmtx: A boolean value for specifying if the Vmtx needs to be recalculated if
            it is already present.
        reuseDmtx: A boolean value for specifying if the Dmtx needs to be recalculated.
        reuseSkyVector: A boolean value for specifying if sky vector needs to be recalculated.
        pointsFile: The file containing the grid points that will be used for illumiance
            calcuations.
        skyDescr: An integer specifying the sky descretization value to be considered for
            generating the sky matrix. The values (number, skypataches)corresponding to
            different sky descretizations are : (1, 145),(2,577),(3,1297),(4,2305),
            (5,3601),(6,5185). Higher discretizations equal higher values.
        klemsForVmtx: The klems basis to be considered for sampling the vmtx. Default value
         is 'kf'
        vmtxParam: Calculation parameters corresponding to the V matrix. This should be
            an instance of the class RfluxParameters. If not specified, a default value
            will be assigned.
        dmtxParam: Calculation parameters corresponding to the D matrix. This should be
            an instance of the class RfluxParameters. If not specified, a default value
            will be assigned.
        TransposeAnnualResults: A boolean value, which if set to True, will transpose
         the results of an annual calculation as per the 8760 lines format.

    Returns:

    """
    def createWinGroupReceivers(surfaceFile, surfaceNormal, klemsBasis):
        # remove the + or - sign if specified.
        surfaceNormal = surfaceNormal[-1] if len(
            surfaceNormal) > 1 else surfaceNormal
        hemiUp = "+Z" if surfaceNormal.lower() in "xy" else "+X"

        # check if there is a glow material assigned in the file.
        # retrieve the first polygon surface for assigning rfluxmtxParameters.
        surfaceStringNoComments = ''
        with open(surfaceFile) as surfaceData:
            for lines in surfaceData:
                if not lines.strip().startswith("#"):
                    surfaceStringNoComments += lines

        surfaceStringNoComSplit = surfaceStringNoComments.split()
        assert surfaceStringNoComSplit[1] == 'glow',\
            'It appears that the glow material has not been applied to this surface.This' \
            ' is essential for the Three Phase Method. '
        firstPolyPosition = surfaceStringNoComSplit.index('polygon')
        surfaceName = surfaceStringNoComSplit[firstPolyPosition - 1]
        rflux = Rfluxmtx()
        receiverParam = rflux.ControlParameters(hemiType=klemsBasis,
                                                hemiUpDirection=hemiUp)
        receiverFile = rflux.addControlParameters(surfaceFile,
                                                  {surfaceName: receiverParam})
        return receiverFile

    def calcVmtx(surfaceFile, receiverFile, reuse, vmtxParam, pointsFile,
                 materialFile, geometryFile):

        vmtxFile = os.path.join('temp',
                                os.path.splitext(surfaceFile)[0] + '.vmtx')
        if os.path.exists(vmtxFile) and reuse:
            return vmtxFile

        if vmtxParam:
            assert isinstance(vmtxParam, RfluxmtxParameters),\
                'The input for vmtxParam must be an instance of RfluxmtxParamters. ' \
                'The current input is an instance of %s' % (type(vmtxParam))
        else:
            vmtxParam = RfluxmtxParameters()
            vmtxParam.irradianceCalc = True
            vmtxParam.ambientAccuracy = 0.1
            vmtxParam.ambientBounces = 10
            vmtxParam.ambientDivisions = 65536
            vmtxParam.limitWeight = 1E-5

        rflux = Rfluxmtx()
        rflux.receiverFile = receiverFile
        rflux.rfluxmtxParameters = vmtxParam
        rflux.pointsFile = pointsFile
        rflux.sender = '-'
        rflux.outputMatrix = vmtxFile
        rflux.radFiles = [materialFile, geometryFile]
        print(rflux.toRadString())
        rflux.execute()
        return vmtxFile

    def calcDmtx(surfaceFile, senderFile, reuse, skyDescr, dmtxParam,
                 materialFile, geometryFile):

        dmtxFile = os.path.join('temp',
                                os.path.splitext(surfaceFile)[0] + '.dmtx')
        if os.path.exists(dmtxFile) and reuse:
            return dmtxFile

        if dmtxParam:
            assert isinstance(dmtxParam, RfluxmtxParameters), \
                'The input for vmtxParam must be an instance of RfluxmtxParamters. ' \
                'The current input is an instance of %s' % (type(dmtxParam))
        else:
            dmtxParam = RfluxmtxParameters()
            dmtxParam.ambientAccuracy = 0.1
            dmtxParam.ambientBounces = 2
            dmtxParam.ambientDivisions = 1024
            dmtxParam.limitWeight = 1E-5

        rflux2 = Rfluxmtx()
        rflux2.samplingRaysCount = 1000
        rflux2.sender = senderFile
        skyFile = rflux2.defaultSkyGround(r'temp/rfluxSky.rad',
                                          skyType="r%s" % skyDescr)
        rflux2.receiverFile = skyFile
        rflux2.rfluxmtxParameters = dmtxParam
        rflux2.radFiles = [materialFile, geometryFile]
        rflux2.outputMatrix = dmtxFile
        rflux2.execute()

        return dmtxFile

    def calcSkyVector(skyDescr,
                      epwFile=None,
                      skyFile=None,
                      reuse=True,
                      skyVectorParam=None):
        assert epwFile or skyFile,\
            'Either an epwFile or a skyFile need to be provided for the skyVector to' \
            'be calculated.'

        if epwFile and os.path.exists(epwFile):
            epwName = os.path.split(epwFile)[1]
            skyMtxName = os.path.splitext(epwName)[0] + '%s.smx' % skyDescr
            weaName = os.path.splitext(epwFile)[0] + '.wea'
            if os.path.exists(skyMtxName) and reuse:
                return skyMtxName

            weaFile = Epw2wea(epwFile=epwFile, outputWeaFile=weaName)
            weaFile.execute()

            if skyVectorParam:
                assert isinstance(skyVectorParam, GendaymtxParameters),\
                    'The input for skyVectorParam must be an instance of GendaymtxParameters.'
                gendayParam = skyVectorParam
            else:
                gendayParam = GendaymtxParameters()

            gendayParam.skyDensity = skyDescr

            genday = Gendaymtx(weaFile=weaName, outputName=skyMtxName)
            genday.gendaymtxParameters = skyVectorParam
            genday.execute()

            return skyMtxName
        elif skyFile and os.path.exists(skyFile):
            skyMtxName = os.path.splitext(skyFile)[0] + '%s.smx' % skyDescr

            if os.path.exists(skyMtxName) and reuse:
                return skyMtxName
            genskv = Genskyvec()
            genskv.inputSkyFile = skyFile
            genskv.skySubdivision = skyDescr
            genskv.outputFile = skyMtxName
            genskv.execute()
            return skyMtxName

        else:
            raise Exception(
                'The input path for the skyFile or epwFile are not valid.')

    # generate receiver surfaces for all window groups..This is not an intensive process.
    receiverFiles = [
        createWinGroupReceivers(win['windowSurface'], win['surfaceNormal'],
                                klemsForVmtx) for win in windowConfig
    ]

    # create the skyVector.
    skyVector = calcSkyVector(skyDescr=skyDescr,
                              epwFile=epwFile,
                              skyFile=skyFile,
                              reuse=reuseSkyVector,
                              skyVectorParam=skyVectorParam)

    # create V and D matrices corresponding to each window Group.

    matrixFilesForResult = []
    resultFiles = 0
    for idx, recFile in enumerate(receiverFiles):

        vmtxFile = calcVmtx(windowConfig[idx]['windowSurface'],
                            recFile,
                            reuse=reuseVmtx,
                            vmtxParam=vmtxParam,
                            pointsFile=pointsFile,
                            materialFile=materialFile,
                            geometryFile=geometryFile)

        dmtxFile = calcDmtx(windowConfig[idx]['windowSurface'],
                            senderFile=recFile,
                            skyDescr=skyDescr,
                            dmtxParam=dmtxParam,
                            materialFile=materialFile,
                            geometryFile=geometryFile,
                            reuse=reuseDmtx)

        if windowConfig[idx]['includeInCalc']:
            windowName = os.path.splitext(
                windowConfig[idx]['windowSurface'])[0] + 'Res.tmp'
            dctResult = os.path.join('temp', windowName)
            dct = Dctimestep()
            dct.dmatrixFile = dmtxFile
            dct.vmatrixSpec = vmtxFile
            dct.skyVectorFile = skyVector
            dct.tmatrixFile = windowConfig[idx]['tMatrix']
            dct.outputFileName = dctResult
            dct.execute()
            matrixFilesForResult.append(dctResult)

            resultFiles += 1
    assert resultFiles, 'None of the Window Groups were chosen for calculating the results !'

    # add up values into a single tmp file
    rmtxAdd = Rmtxop()
    rmtxAdd.matrixFiles = matrixFilesForResult
    rmtxAdd.outputFile = os.path.splitext(outputIllName)[0] + '.tmp'
    rmtxAdd.execute()

    # convert r g b to illuminance
    rmtResParam = RmtxopParameters()
    rmtResParam.combineValues = (47.4, 119.9, 11.6)
    rmtResParam.outputFormat = 'a'
    rmtResParam.transposeMatrix = TransposeAnnualResults

    rmtxRes = Rmtxop()
    rmtxRes.matrixFiles = [rmtxAdd.outputFile]
    rmtxRes.outputFile = outputIllName
    rmtxRes.rmtxopParameters = rmtResParam
    rmtxRes.execute()

    return outputIllName
def improvedDCcalc(epwFile,
                   materialFile,
                   geometryFiles,
                   pointsFile,
                   folderForCalculations,
                   outputIllFilePath,
                   reinhartPatches=1,
                   calcDict={
                       'skyVectors': True,
                       'DirectDCCoeff': True,
                       'DCCoeff': True,
                       'DirectSun': True
                   }):
    """
    Args:
        epwFile: Epw file path.
        materialFile: Path for a single material file.
        geometryFiles: One or more geometry files.
        pointsFile: Path for poitns file
        folderForCalculations: Folder for storing intermediate files.
        outputIllFilePath:
        reinhartPatches: Default is 1.
        calcDict: This is useful for selectively running different parts of the simulation.

    Returns:

    """
    #a sad logging hack
    statusMsg = lambda msg: "\n%s:%s\n%s\n" % (time.ctime(), msg, "*~" * 25)

    weaFilePath = os.path.join(
        folderForCalculations,
        os.path.splitext(os.path.split(epwFile)[1])[0] + '.wea')

    weaFile = Epw2wea(epwFile=epwFile, outputWeaFile=weaFilePath)
    weaFile.execute()

    #Calculate complete sky matrix.
    skyMatrix = os.path.join(folderForCalculations, 'skyMatrix.mtx')
    gendayParam = GendaymtxParameters()
    gendayParam.skyDensity = reinhartPatches
    genday = Gendaymtx(weaFile=weaFilePath, outputName=skyMatrix)
    genday.gendaymtxParameters = gendayParam
    if calcDict['skyVectors']:
        print(genday.toRadString())
        genday.execute()

    #Calculate direct only matrix.
    skyMatrixDirect = os.path.join(folderForCalculations,
                                   'skyMatrixDirect.mtx')
    gendayParam = GendaymtxParameters()
    gendayParam.skyDensity = reinhartPatches
    gendayParam.onlyDirect = True
    genday = Gendaymtx(weaFile=weaFilePath, outputName=skyMatrixDirect)
    genday.gendaymtxParameters = gendayParam
    if calcDict['skyVectors']:
        print(genday.toRadString())
        genday.execute()

    skyDomeFile = os.path.join(folderForCalculations, 'rfluxSky.rad')
    dcCoeffMatrix = os.path.join(folderForCalculations, 'dc.mtx')
    dcCoeffMatrixDirect = os.path.join(folderForCalculations, 'dcDirect.mtx')

    sceneData = [materialFile]
    #Append if single, extend if multiple
    if isinstance(geometryFiles, basestring):
        sceneData.append(geometryFiles)
    elif isinstance(geometryFiles, (tuple, list)):
        sceneData.extend(geometryFiles)

    # Step2: Generate daylight coefficients for normal sky-matrix using rfluxmtx.
    rfluxPara = RfluxmtxParameters()
    rfluxPara.irradianceCalc = True
    rfluxPara.ambientAccuracy = 0.1
    rfluxPara.ambientDivisions = 20000
    rfluxPara.ambientBounces = 5
    rfluxPara.limitWeight = 1E-7
    rfluxPara.ambientResolution = 10000

    rflux = Rfluxmtx()
    rflux.sender = '-'
    skyFile = rflux.defaultSkyGround(skyDomeFile,
                                     skyType='r%s' % reinhartPatches)
    rflux.receiverFile = skyDomeFile
    rflux.rfluxmtxParameters = rfluxPara
    rflux.radFiles = sceneData
    rflux.samplingRaysCount = 1

    rflux.pointsFile = pointsFile
    rflux.outputMatrix = dcCoeffMatrix
    if calcDict['DCCoeff']:
        rflux.execute()

    tempIll = os.path.join(folderForCalculations, 'temp.ill')
    ill = os.path.join(folderForCalculations, 'Illuminance.ill')

    dct = Dctimestep()
    dct.daylightCoeffSpec = dcCoeffMatrix
    dct.skyVectorFile = skyMatrix
    dct.outputFile = tempIll
    if calcDict['DCCoeff']:
        dct.execute()

    mtx2Param = RmtxopParameters()
    mtx2Param.outputFormat = 'a'
    mtx2Param.combineValues = (47.4, 119.9, 11.6)
    mtx2Param.transposeMatrix = True
    mtx2 = Rmtxop(matrixFiles=[tempIll], outputFile=ill)
    mtx2.rmtxopParameters = mtx2Param
    if calcDict['DCCoeff']:
        mtx2.execute()

    # Step3: Generate direct daylight coefficients for normal sky-matrix using rfluxmtx.
    rfluxPara = RfluxmtxParameters()
    rfluxPara.irradianceCalc = True
    rfluxPara.ambientAccuracy = 0.01
    rfluxPara.ambientDivisions = 20000
    rfluxPara.ambientBounces = 1
    rfluxPara.limitWeight = 1E-7
    rfluxPara.ambientResolution = 10000

    rflux = Rfluxmtx()
    rflux.sender = '-'
    skyFile = rflux.defaultSkyGround(skyDomeFile,
                                     skyType='r%s' % reinhartPatches)
    rflux.receiverFile = skyDomeFile
    rflux.rfluxmtxParameters = rfluxPara
    rflux.radFiles = sceneData
    rflux.samplingRaysCount = 1

    rflux.pointsFile = pointsFile
    rflux.outputMatrix = dcCoeffMatrixDirect
    if calcDict['DirectDCCoeff']:
        rflux.execute()

    tempDirectIll = os.path.join(folderForCalculations, 'tempDirect.ill')
    illDirect = os.path.join(folderForCalculations, 'IlluminanceDirect.ill')

    dct = Dctimestep()
    dct.daylightCoeffSpec = dcCoeffMatrixDirect
    dct.skyVectorFile = skyMatrixDirect
    dct.outputFile = tempDirectIll
    if calcDict['DCCoeff']:
        dct.execute()

    mtx2Param = RmtxopParameters()
    mtx2Param.outputFormat = 'a'
    mtx2Param.combineValues = (47.4, 119.9, 11.6)
    mtx2Param.transposeMatrix = True
    mtx2 = Rmtxop(matrixFiles=[tempDirectIll], outputFile=illDirect)
    mtx2.rmtxopParameters = mtx2Param
    if calcDict['DirectDCCoeff']:
        mtx2.execute()

    solarDiscPath = os.path.join(folderForCalculations, 'solarDiscs.rad')
    sunListPath = os.path.join(folderForCalculations, 'sunList.txt')
    sunMatrixPath = os.path.join(folderForCalculations, 'sunMatrix.mtx')
    #Calculate direct only ill files.
    directSunIll = os.path.join(folderForCalculations, 'directSunIll.ill')

    if calcDict['DirectSun']:
        sunOnlyIll = calcDirectIlluminance(
            epwFile=epwFile,
            solarDiscPath=solarDiscPath,
            sunListPath=sunListPath,
            sunMatrixPath=sunMatrixPath,
            materialFile=materialFile,
            geometryFiles=geometryFiles,
            pointsFile=pointsFile,
            folderForCalculations=folderForCalculations,
            outputIllFilePath=directSunIll)

    #Instantiate matrices for subtraction and addition.
    finalMatrix = Rmtxop()

    #std. dc matrix.
    dcMatrix = RmtxopMatrix()
    dcMatrix.matrixFile = ill

    #direct dc matrix. -1 indicates that this one is being subtracted from dc matrix.
    dcDirectMatrix = RmtxopMatrix()
    dcDirectMatrix.matrixFile = illDirect
    dcDirectMatrix.scalarFactors = [-1]

    #Sun coefficient matrix.
    sunCoeffMatrix = RmtxopMatrix()
    sunCoeffMatrix.matrixFile = directSunIll

    #combine the matrices together. Sequence is extremely important
    finalMatrix.rmtxopMatrices = [dcMatrix, dcDirectMatrix, sunCoeffMatrix]
    finalMatrix.outputFile = outputIllFilePath

    #Done!
    finalMatrix.execute()

    return outputIllFilePath
Exemple #5
0
from honeybee.radiance.parameters.genBsdf import GenbsdfParameters
from honeybee.radiance.command.genBSDF import GenBSDF, RtraceParameters
from honeybee.radiance.command.rmtxop import Rmtxop, RmtxopParameters
import os

y = GenbsdfParameters()
y.num_processors = 10
y.geom_unit_incl = 'meter'

z = GenBSDF()
z.grid_based_parameters = RtraceParameters()
z.grid_based_parameters.ambient_bounces = 1
z.gen_bsdf_parameters = y
z.input_geometry = ['room/room.mat', 'room/glazing.rad']
z.output_file = 'room/test.xml'
z.normal_orientation = '-Y'
z.execute()

rmt_para = RmtxopParameters()
rmt_para.output_format = 'c'

rmt = Rmtxop()
rmt.rmtxop_parameters = rmt_para
rmt.matrixF_files = ['room/test.xml']
rmt.output_file = 'room/testhdr.tmp'
rmt.execute()

os.system('pfilt -x 800 -y 800 %s > room/testhdr.hdr' % rmt.output_file)
os.system('ra_bmp %s > room/testhdr.bmp' % 'room/testhdr.hdr')
os.startfile(os.path.abspath('room/testhdr.bmp'))
Exemple #6
0
def improvedDCcalc(epwFile,
                   materialFile,
                   geometryFiles,
                   pointsFile,
                   folderForCalculations,
                   outputIllFilePath,
                   glazingGeometry=None,
                   reinhartPatches=1,
                   ambBounces=5,
                   ambDiv=5000,
                   limitWt=0.0002,
                   calcDict={
                       'skyVectors': True,
                       'DirectDCCoeff': True,
                       'DCCoeff': True,
                       'DirectSun': True
                   },
                   cleanUpTempFiles=True):
    """
    Args:
        epwFile: Epw file path.
        materialFile: Path for a single material file.
        geometryFiles: One or more geometry files.
        pointsFile: Path for poitns file
        folderForCalculations: Folder for storing intermediate files.
        outputIllFilePath:
        reinhartPatches: Default is 1.
        calcDict: This is useful for selectively running different parts of the
            simulation.
        ambBounces: Ambient bounces. Defaults to 5
        ambDiv: Ambient divisions. Defaults to 5000.
        limitWt: Limit weight. Defaults to 0.0002
        cleanUpTempFiles: Delete all the temporary files that were created during the
            calculations.
    Returns: The path of the illuminance file generated through the calculations.

    """

    # a sad logging hack
    statusMsg = lambda msg: "\n%s:%s\n%s\n" % (time.ctime(), msg, "*~" * 25)

    blackMaterial = "void plastic black 0 0 5 0 0 0 0 0"

    if limitWt > (1 / ambDiv):
        warnings.warn(
            "The value for limitWt(%s) should be set to a value equal to or "
            "less (%s) which is 1/ambDiv(%s)" % (limitWt, 1 / ambDiv, ambDiv))

    # crate a tempfolder inside the folderForCalculations.
    tmpFolder = os.path.join(folderForCalculations, 'tmp')
    if not os.path.exists(tmpFolder):
        os.mkdir(tmpFolder)

    weaFilePath = os.path.join(
        tmpFolder,
        os.path.splitext(os.path.split(epwFile)[1])[0] + '.wea')

    weaFile = Epw2wea(epwFile=epwFile, outputWeaFile=weaFilePath)
    weaFile.execute()

    # Calculate complete sky matrix.
    skyMatrix = os.path.join(tmpFolder, 'skyMatrix.mtx')
    gendayParam = GendaymtxParameters()
    gendayParam.skyDensity = reinhartPatches
    genday = Gendaymtx(weaFile=weaFilePath, outputName=skyMatrix)
    genday.gendaymtxParameters = gendayParam
    if calcDict['skyVectors']:
        print(genday.toRadString())
        genday.execute()

    # Calculate direct only matrix.
    skyMatrixDirect = os.path.join(tmpFolder, 'skyMatrixDirect.mtx')
    gendayParam = GendaymtxParameters()
    gendayParam.skyDensity = reinhartPatches
    gendayParam.onlyDirect = True
    genday = Gendaymtx(weaFile=weaFilePath, outputName=skyMatrixDirect)
    genday.gendaymtxParameters = gendayParam
    if calcDict['skyVectors']:
        print(genday.toRadString())
        genday.execute()

    skyDomeFile = os.path.join(tmpFolder, 'rfluxSky.rad')
    dcCoeffMatrix = os.path.join(tmpFolder, 'dc.mtx')
    dcCoeffMatrixDirect = os.path.join(tmpFolder, 'dcDirect.mtx')

    blackMaterial = os.path.join(tmpFolder, 'black.mat')

    with open(blackMaterial, 'w') as blackMat:
        blackMat.write("void plastic black 0 0 5 0 0 0 0 0")

    sceneData = [materialFile]
    sceneDataBlack = [blackMaterial]

    geometryData = []

    # Append if single, extend if multiple
    if isinstance(geometryFiles, basestring):
        geometryData.append(geometryFiles)
    elif isinstance(geometryFiles, (tuple, list)):
        geometryData.extend(geometryFiles)

    sceneData = sceneData + geometryData

    xfrPara = XformParameters()
    xfrPara.modReplace = 'black'

    # Note: Xform has this thing it only works well if the paths are absolute.
    blackGeometry = os.path.join(tmpFolder, 'blackGeometry.rad')
    xfr = Xform()
    xfr.xformParameters = xfrPara
    xfr.radFile = geometryData
    xfr.outputFile = blackGeometry
    xfr.execute()

    # Material file added in the end with the assumption that the material props for the
    # glazing are defined in the material file. As Radiance parses scene data in a
    # strictly linear fashion, even if the material for glazing is defined inside
    # the glazing geometry, it will still be fine.
    sceneDataBlack = sceneDataBlack + [blackGeometry] + [materialFile]

    if isinstance(glazingGeometry, basestring):
        sceneData.append(glazingGeometry)
        sceneDataBlack.append(glazingGeometry)

    elif isinstance(glazingGeometry, (tuple, list)):
        sceneData.extend(glazingGeometry)
        sceneDataBlack.extend(glazingGeometry)

    # Step2: Generate daylight coefficients for normal sky-matrix using rfluxmtx.
    rfluxPara = RfluxmtxParameters()
    rfluxPara.irradianceCalc = True
    rfluxPara.ambientDivisions = ambDiv
    rfluxPara.ambientBounces = ambBounces
    rfluxPara.limitWeight = limitWt

    rflux = Rfluxmtx()
    rflux.sender = '-'
    skyFile = rflux.defaultSkyGround(skyDomeFile,
                                     skyType='r%s' % reinhartPatches)
    rflux.receiverFile = skyDomeFile
    rflux.rfluxmtxParameters = rfluxPara
    rflux.radFiles = sceneData
    rflux.samplingRaysCount = 1

    rflux.pointsFile = pointsFile
    rflux.outputMatrix = dcCoeffMatrix
    if calcDict['DCCoeff']:
        print(rflux.toRadString())
        rflux.execute()

    tempIll = os.path.join(tmpFolder, 'temp.ill')
    ill = os.path.join(tmpFolder, 'Illuminance.ill')

    dct = Dctimestep()
    dct.daylightCoeffSpec = dcCoeffMatrix
    dct.skyVectorFile = skyMatrix
    dct.outputFile = tempIll
    if calcDict['DCCoeff']:
        print(dct.toRadString())
        dct.execute()

    mtx2Param = RmtxopParameters()
    mtx2Param.outputFormat = 'a'
    mtx2Param.combineValues = (47.4, 119.9, 11.6)
    mtx2Param.transposeMatrix = True
    mtx2 = Rmtxop(matrixFiles=[tempIll], outputFile=ill)
    mtx2.rmtxopParameters = mtx2Param
    if calcDict['DCCoeff']:
        mtx2.execute()

    # Step3: Generate direct daylight coefficients for normal sky-matrix using rfluxmtx.
    rfluxPara = RfluxmtxParameters()
    rfluxPara.irradianceCalc = True
    rfluxPara.ambientDivisions = ambDiv
    rfluxPara.ambientBounces = 1
    rfluxPara.limitWeight = limitWt

    rflux = Rfluxmtx()
    rflux.sender = '-'
    skyFile = rflux.defaultSkyGround(skyDomeFile,
                                     skyType='r%s' % reinhartPatches)
    rflux.receiverFile = skyDomeFile
    rflux.rfluxmtxParameters = rfluxPara
    rflux.radFiles = sceneDataBlack
    rflux.samplingRaysCount = 1

    rflux.pointsFile = pointsFile
    rflux.outputMatrix = dcCoeffMatrixDirect
    if calcDict['DirectDCCoeff']:
        rflux.execute()

    tempDirectIll = os.path.join(tmpFolder, 'tempDirect.ill')
    illDirect = os.path.join(tmpFolder, 'IlluminanceDirect.ill')

    dct = Dctimestep()
    dct.daylightCoeffSpec = dcCoeffMatrixDirect
    dct.skyVectorFile = skyMatrixDirect
    dct.outputFile = tempDirectIll
    if calcDict['DCCoeff']:
        dct.execute()

    mtx2Param = RmtxopParameters()
    mtx2Param.outputFormat = 'a'
    mtx2Param.combineValues = (47.4, 119.9, 11.6)
    mtx2Param.transposeMatrix = True
    mtx2 = Rmtxop(matrixFiles=[tempDirectIll], outputFile=illDirect)
    mtx2.rmtxopParameters = mtx2Param
    if calcDict['DirectDCCoeff']:
        mtx2.execute()

    solarDiscPath = os.path.join(tmpFolder, 'solarDiscs.rad')
    sunListPath = os.path.join(tmpFolder, 'sunList.txt')
    sunMatrixPath = os.path.join(tmpFolder, 'sunMatrix.mtx')
    # Calculate direct only ill files.
    directSunIll = os.path.join(tmpFolder, 'directSunIll.ill')

    if calcDict['DirectSun']:
        calcDirectIlluminance(epwFile=epwFile,
                              solarDiscPath=solarDiscPath,
                              sunListPath=sunListPath,
                              sunMatrixPath=sunMatrixPath,
                              materialFile=blackMaterial,
                              geometryFiles=sceneDataBlack,
                              pointsFile=pointsFile,
                              folderForCalculations=folderForCalculations,
                              outputIllFilePath=directSunIll)

    # Instantiate matrices for subtraction and addition.
    finalMatrix = Rmtxop()

    # std. dc matrix.
    dcMatrix = RmtxopMatrix()
    dcMatrix.matrixFile = ill

    # direct dc matrix. -1 indicates that this one is being subtracted from dc matrix.
    dcDirectMatrix = RmtxopMatrix()
    dcDirectMatrix.matrixFile = illDirect
    dcDirectMatrix.scalarFactors = [-1]

    # Sun coefficient matrix.
    sunCoeffMatrix = RmtxopMatrix()
    sunCoeffMatrix.matrixFile = directSunIll

    # combine the matrices together. Sequence is extremely important
    finalMatrix.rmtxopMatrices = [dcMatrix, dcDirectMatrix, sunCoeffMatrix]
    finalMatrix.outputFile = outputIllFilePath

    # Done!
    finalMatrix.execute()

    return outputIllFilePath
Exemple #7
0
def run2Phase(calculationType='annual'):
    if calculationType == 'annual':
        weaFile = Epw2wea(epwFile='test.epw', outputWeaFile=r'temp/test.wea')
        weaFile.execute()
        gendayParam = GendaymtxParameters()
        gendayParam.skyDensity = 4

        genday = Gendaymtx(weaFile=r'temp/test.wea', outputName=r'temp/day.smx')
        genday.gendaymtxParameters = gendayParam
        # genday.execute()
        skyVector = r'temp/day.smx'
    else:
        gensk = Gensky()
        gensk.monthDayHour = (11, 11, 11)
        gensk.outputFile = 'temp/sky.rad'
        gensk.execute()

        genskv = Genskyvec()
        genskv.inputSkyFile = r'temp/sky.rad'
        genskv.outputFile = r'temp/sky.vec'
        genskv.skySubdivision = 4
        genskv.execute()
        skyVector = r'temp/sky.vec'

    #
    # Step2: Generate daylight coefficients using rfluxmtx.
    rfluxPara = RfluxmtxParameters()
    rfluxPara.irradianceCalc = False
    rfluxPara.ambientAccuracy = 0.1
    rfluxPara.ambientDivisions = 10
    rfluxPara.ambientBounces = 1
    rfluxPara.limitWeight = 0.1
    rfluxPara.quality = 0
    rflux = Rfluxmtx()
    rflux.sender = '-'
    skyFile = rflux.defaultSkyGround(r'temp/rfluxSky.rad',skyType='r4')
    rflux.receiverFile = skyFile
    rflux.rfluxmtxParameters = rfluxPara
    rflux.radFiles = [r"room.mat",
                      r"room.rad"]

    rflux.pointsFile = r"indoor_points.pts"
    rflux.outputMatrix = r"temp/dayCoeff.dc"
    rflux.execute()


    mtx1 = Rmtxop(matrixFiles=(os.path.abspath(r'temp/dayCoeff.dc'),
                               os.path.abspath(skyVector)),
                  outputFile=r'temp/illuminance.tmp')

    mtx1.execute()


    mtx2Param = RmtxopParameters()
    mtx2Param.outputFormat = 'a'
    mtx2Param.combineValues = (47.4, 119.9, 11.6)
    # mtx2Param.transposeMatrix = True
    mtx2 = Rmtxop(matrixFiles=[r'temp/illuminance.tmp'], outputFile=r'temp/illuminance.ill')
    mtx2.rmtxopParameters = mtx2Param
    mtx2.execute()

    with open(r'temp/illuminance.ill') as illFile:
        for lines in illFile:
            try:
                print(map(float, lines.split()))
            except ValueError:
                pass
import os


y = GenbsdfParameters()
y.num_processors = 10
y.geom_unit_incl = 'meter'


z = GenBSDF()
z.grid_based_parameters = RtraceParameters()
z.grid_based_parameters.ambient_bounces = 1
z.gen_bsdf_parameters = y
z.input_geometry = ['room/room.mat', 'room/glazing.rad']
z.output_file = 'room/test.xml'
z.normal_orientation = '-Y'
z.execute()

rmt_para = RmtxopParameters()
rmt_para.output_format = 'c'

rmt = Rmtxop()
rmt.rmtxop_parameters = rmt_para
rmt.matrixF_files = ['room/test.xml']
rmt.output_file = 'room/testhdr.tmp'
rmt.execute()


os.system('pfilt -x 800 -y 800 %s > room/testhdr.hdr' % rmt.output_file)
os.system('ra_bmp %s > room/testhdr.bmp' % 'room/testhdr.hdr')
os.startfile(os.path.abspath('room/testhdr.bmp'))
from honeybee.radiance.command.rmtxop import Rmtxop, RmtxopParameters

y = GenbsdfParameters()
y.numProcessors = 10
y.geomUnitIncl = 'meter'

z = GenBSDF()
z.gridBasedParameters = GridBasedParameters()
z.gridBasedParameters.ambientBounces = 1
z.genBsdfParameters = y
z.inputGeometry = ['room/room.mat', 'room/glazing.rad']
z.outputFile = 'room/test.xml'
z.normalOrientation = '-Y'
z.execute()

rmtPara = RmtxopParameters()
rmtPara.outputFormat = 'c'

rmt = Rmtxop()
rmt.rmtxopParameters = rmtPara
rmt.matrixFiles = ['room/test.xml']
rmt.outputFile = 'room/testhdr.tmp'
rmt.execute()

import os

os.system('pfilt -x 800 -y 800 %s > room/testhdr.hdr' % rmt.outputFile)
os.system('ra_bmp %s > room/testhdr.bmp' % 'room/testhdr.hdr')

os.startfile(os.path.abspath('room/testhdr.bmp'))
Exemple #10
0
def directSunCalcs(epwFile,
                   materialFile,
                   geometryFiles,
                   pointsFile,
                   calcASE=True,
                   calcASEptsSummary=True,
                   illumForASE=1000,
                   hoursForASE=250,
                   hoyForValidation=13,
                   repeatValidationOnly=False):
    """

    Args:
        epwFile: path.
        materialFile: path.
        geometryFiles: path(s).
        pointsFile: path.
        calcASE: Boolean. If set to False, only raytrace and illuminance calcs will be
            performed.
        calcASEptsSummary: If set to True, will produce a summary of points and the number
            of hours for which they are above the value set for illumForASE. If set to
            False only the direct value of ASE (as specified by LM-83-12 will be calculated.)
        illumForASE: Illuminance for ASE. Has been set to a default of 1000 lux as per
            LM-83-12.
        hoursForASE: Hour-threshold for ASE. Has been set to a default of 250 hours as per
            LM-83-12. This option is only relevant if the the calcASEptsSummary option has
            been set to False. As otherwise, an entire list of hours will be produced regardless.
        hoyForValidation: A value between 0 to 8759 to check the annual results against an
            independent point-in-time ray-trace calc using rtrace. No validation will be
            performed if this value is set to None.
        repeatValidationOnly: Once the claculations have been run. Validation for more
            hours can be performed by setting this to True. Default is False.

    Returns: This function prints out. Does not return anything.

    """

    #a sad logging hack
    statusMsg = lambda msg: "\n%s:%s\n%s\n" % (time.ctime(), msg, "*~" * 25)

    print(statusMsg('Starting calculations'))

    sceneData = [materialFile]
    #Append if single, extend if multiple
    if isinstance(geometryFiles, basestring):
        sceneData.append(geometryFiles)
    elif isinstance(geometryFiles, (tuple, list)):
        sceneData.extend(geometryFiles)

    monthDateTime = [DateTime.fromHoy(idx) for idx in xrange(8760)]

    epw = EPW(epwFile)
    latitude, longitude = epw.location.latitude, -epw.location.longitude
    meridian = -(15 * epw.location.timezone)

    #Create a directory for ASE test.
    dirName = 'tests/ASEtest'
    if not os.path.exists(dirName):
        os.mkdir(dirName)
    #Defining these upfront so that this data may be used for validation without rerunning
    #calcs every time
    sunList = os.path.join(dirName, 'sunlist')
    sunDiscRadFile = os.path.join(dirName, 'sunFile.rad')
    radiationMatrix = os.path.join(dirName, 'sunRadiation.mtx')
    annualResultsFile = os.path.join(dirName, 'illum.ill')

    if not repeatValidationOnly:
        # preCalcFiles = (sunList,sunDiscRadFile,radiationMatrix,annualResultsFile)
        # for files in preCalcFiles:
        #     assert os.path.exists(files),'Precalculated data cannot be used as the file ' \
        #                                  '%s, which is required for calculations cannot be' \
        #                                  'found.'

        #instantiating classes before looping makes sense as it will avoid the same calls over
        #   and over.
        genParam = GendaylitParameters()
        genParam.meridian = meridian
        genParam.longitude = longitude
        genParam.latitude = latitude

        genDay = Gendaylit()

        sunValues = []
        sunValuesHour = []

        print(statusMsg('Calculating sun positions and radiation values'))

        # We need to throw out all the warning values arising from times when sun isn't present.
        # os.devnull serves that purpose.
        with open(os.devnull, 'w') as warningDump:
            for idx, timeStamp in enumerate(monthDateTime):
                month, day, hour = timeStamp.month, timeStamp.day, timeStamp.hour + 0.5
                genParam.dirNormDifHorzIrrad = (
                    epw.directNormalRadiation[idx],
                    epw.diffuseHorizontalRadiation[idx])

                genDay.monthDayHour = (month, day, hour)
                genDay.gendaylitParameters = genParam
                gendayCmd = genDay.toRadString().split('|')[0]

                #run cmd, get results in the form of a list of lines.
                cmdRun = Popen(gendayCmd, stdout=PIPE, stderr=warningDump)
                data = cmdRun.stdout.read().split('\n')

                #clean the output by throwing out comments as well as brightness functions.
                sunCurrentValue = []
                for lines in data:
                    if not lines.strip().startswith("#"):
                        if "brightfunc" in lines:
                            break
                        if lines.strip():
                            sunCurrentValue.extend(lines.strip().split())

                #If a sun definition was captured in the last for-loop, store info.
                if sunCurrentValue and max(map(float, sunCurrentValue[6:9])):
                    sunCurrentValue[2] = 'solar%s' % (len(sunValues) + 1)
                    sunCurrentValue[9] = 'solar%s' % (len(sunValues) + 1)
                    sunValues.append(sunCurrentValue)
                    sunValuesHour.append(idx)

        numOfSuns = len(sunValues)

        print(statusMsg('Writing sun definitions to disc'))
        #create list of suns.
        with open(sunList, 'w') as sunList:
            sunList.write("\n".join(
                ["solar%s" % (idx + 1) for idx in xrange(numOfSuns)]))

        #create solar discs.
        with open(sunDiscRadFile, 'w') as solarDiscFile:
            solarDiscFile.write("\n".join([" ".join(sun)
                                           for sun in sunValues]))

        #Start creating header for the sun matrix.
        fileHeader = ['#?RADIANCE']
        fileHeader += ['Sun matrix created by Honeybee']
        fileHeader += ['LATLONG= %s %s' % (latitude, -longitude)]
        fileHeader += ['NROWS=%s' % numOfSuns]
        fileHeader += ['NCOLS=8760']
        fileHeader += ['NCOMP=3']
        fileHeader += ['FORMAT=ascii']

        #Write the matrix to file.
        with open(radiationMatrix, 'w') as sunMtx:
            sunMtx.write("\n".join(fileHeader) + '\n' + '\n')
            for idx, sunValue in enumerate(sunValues):
                sunRadList = ["0 0 0"] * 8760
                sunRadList[sunValuesHour[idx]] = " ".join(sunValue[6:9])
                sunMtx.write("\n".join(sunRadList) + "\n" + "\n")

            #This last one is for the ground.
            sunRadList = ["0 0 0"] * 8760
            sunMtx.write("\n".join(sunRadList))

        print(statusMsg('Starting Raytrace calculations.'))

        octree = Oconv()
        octree.sceneFiles = sceneData + [r'tests/ASEtest/sunFile.rad']
        octree.outputFile = r'tests/ASEtest/roomSun.oct'
        octree.execute()

        rctPara = RcontribParameters()
        rctPara.ambientBounces = 0
        rctPara.directJitter = 0
        rctPara.directCertainty = 1
        rctPara.directThreshold = 0
        rctPara.modFile = r'tests/ASEtest/sunlist'
        rctPara.irradianceCalc = True

        rctb = Rcontrib()
        rctb.octreeFile = r'tests/ASEtest/roomSun.oct'
        rctb.outputFile = r'tests/ASEtest/sunCoeff.dc'
        rctb.pointsFile = pointsFile
        rctb.rcontribParameters = rctPara

        rctb.execute()

        dct = Dctimestep()
        dct.daylightCoeffSpec = r'tests/ASEtest/sunCoeff.dc'
        dct.skyVectorFile = r'tests/ASEtest/sunRadiation.mtx'
        dct.outputFile = r'tests/ASEtest/illum.tmp'
        dct.execute()

        mtx2Param = RmtxopParameters()
        mtx2Param.outputFormat = 'a'
        mtx2Param.combineValues = (47.4, 119.9, 11.6)
        mtx2Param.transposeMatrix = True
        mtx2 = Rmtxop(matrixFiles=[r'tests/ASEtest/illum.tmp'],
                      outputFile=annualResultsFile)
        mtx2.rmtxopParameters = mtx2Param
        mtx2.execute()

        print(statusMsg('Finished raytrace.'))

    # get points Data
    pointsList = []
    with open(pointsFile) as pointsData:
        for lines in pointsData:
            if lines.strip():
                pointsList.append(map(float, lines.strip().split()[:3]))

    hourlyIlluminanceValues = []
    with open(annualResultsFile) as resData:
        for lines in resData:
            lines = lines.strip()
            if lines:
                try:
                    tempIllData = map(float, lines.split())
                    hourlyIlluminanceValues.append(tempIllData)
                except ValueError:
                    pass
    if calcASE:
        #As per IES-LM-83-12 ASE is the percent of sensors in the analysis area that are
        # found to be exposed to more than 1000lux of direct sunlight for more than 250hrs
        # per year. The present script allows user to define what the lux and hour value
        # should be.
        sensorIllumValues = zip(*hourlyIlluminanceValues)
        aseData = []
        for idx, sensor in enumerate(sensorIllumValues):
            x, y, z = pointsList[idx]
            countAboveThreshold = len(
                [val for val in sensor if val > illumForASE])
            aseData.append([x, y, z, countAboveThreshold])

        sensorsWithHoursAboveLimit = [
            hourCount for x, y, z, hourCount in aseData
            if hourCount > hoursForASE
        ]
        percentOfSensors = len(sensorsWithHoursAboveLimit) / len(
            pointsList) * 100
        print(
            "ASE RESULT: Percent of sensors above %sLux for more than %s hours = %s%%"
            % (illumForASE, hoursForASE, percentOfSensors))

        if calcASEptsSummary:
            print(
                "ASE RESULT: Location of sensors and # of hours above threshold of %sLux\n"
                % illumForASE)
            print("%12s %12s %12s %12s" % ('xCor', 'yCor', 'zCor', 'Hours'))
            for x, y, z, countAboveThreshold in aseData:
                print("%12.4f %12.4f %12.4f %12d" %
                      (x, y, z, countAboveThreshold))

    #Stage 2: Check values from ASE calc against
    if hoyForValidation in xrange(8760):
        print(statusMsg('Starting validation calcs.'))

        #Create a sky for a point in time calc.
        timeStamp = monthDateTime[hoyForValidation]
        month, day, hour = timeStamp.month, timeStamp.day, timeStamp.hour + 0.5
        print(
            "VALIDATION RESULTS: Comparing illuminancevalues for (month,day,hour):(%s, %s, %s)\n"
            % (month, day, hour))

        # msgString="\t\tComparing values for (month,day,hour):(%s, %s, %s)"%(month,day,hour)
        # print(msgString)
        # print("\t\t%s\n"%("~"*len(msgString)))

        genParam = GendaylitParameters()
        genParam.meridian = meridian
        genParam.longitude = longitude
        genParam.latitude = latitude

        genDay = Gendaylit()
        genParam.dirNormDifHorzIrrad = (
            epw.directNormalRadiation[hoyForValidation],
            epw.diffuseHorizontalRadiation[hoyForValidation])

        genDay.monthDayHour = (month, day, hour)
        genDay.gendaylitParameters = genParam
        genDay.outputFile = r'tests/ASEtest/genday.sky'
        genDay.execute()

        octGenday = Oconv()
        octGenday.sceneFiles = sceneData + [r'tests/ASEtest/genday.sky']
        octGenday.outputFile = r'tests/ASEtest/roomSunGenday.oct'
        octGenday.execute()

        rtcPara = GridBasedParameters()
        rtcPara.irradianceCalc = True
        rtcPara.ambientBounces = 0
        rtcPara.directJitter = 1
        rtcPara.directCertainty = 1
        rtcPara.directThreshold = 0

        rtc = Rtrace()
        rtc.radianceParameters = rtcPara
        rtc.octreeFile = r'tests/ASEtest/roomSunGenday.oct'
        rtc.pointsFile = pointsFile
        rtc.outputFile = r'tests/ASEtest/rtraceTest.res'
        rtc.execute()

        #This is a quick hack to get values out of rtrace. I think the option to turn of header is
        # nested inside.

        rtraceIllValues = []
        with open(r'tests/ASEtest/rtraceTest.res') as resFile:
            for lines in resFile:
                lines = lines.strip()
                if lines:
                    try:
                        r, g, b = map(float, lines.strip().split())
                        r, g, b = r * 47.4, g * 119.9, b * 11.6
                        rtraceIllValues.append(r + g + b)
                    except ValueError:
                        pass

        print("%12s %12s %12s %12s %12s %12s%%" %
              ('xCor', 'yCor', 'zCor', 'Annual-Ill', 'Rtrace-Ill', 'Diff'))
        for point, aseVal, rtraceVal in zip(
                pointsList, hourlyIlluminanceValues[hoyForValidation],
                rtraceIllValues):
            x, y, z = point
            if rtraceVal:
                diff = (rtraceVal - aseVal) / rtraceVal
                aseVal, rtraceVal, diff = map(lambda x: round(x, 4),
                                              (aseVal, rtraceVal, diff * 100))
            else:
                aseVal, rtraceVal, diff = 0.0, 0.0, 0.0
                aseVal, rtraceVal, diff = map(lambda x: round(x, 4),
                                              (aseVal, rtraceVal, diff * 100))
            print("%12.4f %12.4f %12.4f %12.4f %12.4f %12.4f%%" %
                  (x, y, z, aseVal, rtraceVal, diff))

    print(statusMsg('Done!'))