Exemple #1
0
def multi_iterator(dsarray, filter=None):
    from vista.set import MultiIterator, Constants
    if filter == None:
        iterator = MultiIterator(dsarray)
    else:
        iterator = MultiIterator(dsarray, filter)
    return iterator
def dump2text(outfile,rtsarray,filter=Constants.DEFAULT_FLAG_FILTER):
    """
    """
    xfilter = CompositeFilter([filter,NaNFilter()])
    mi = MultiIterator(rtsarray)
    fh = open(outfile,'w')
    for i in range(len(rtsarray)):
	fh.write('%s\n'%rtsarray[i].getName())
    while not mi.atEnd():
	#
	el = mi.getElement()
	fh.write(element2text(el,xfilter))
	#
	mi.advance()
    fh.close()
Exemple #3
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def _test4():
    from ANN import fnet_cccec
    sac = vutils.RegularTimeSeries('inp1','31jan1990 2400', '1mon', [10000.0, 11000.0, 12000.0, 15000.0])
    sac = sac*5.40394e-06+0.178546
    sjr = vutils.RegularTimeSeries('inp1','31jan1990 2400', '1mon', [1000.0, 1100.0, 1200.0, 1500.0])
    sjr = sjr*1.34396e-05+0.199247
    exp = vutils.RegularTimeSeries('inp1','31jan1990 2400', '1mon', [5000.0, 6000.0, 7000.0, 8000.0])
    exp = exp*-4.86697e-05+0.178537
    dxc = vutils.RegularTimeSeries('inp1','31jan1990 2400', '1mon', [0.0, 0.0, 0.0, 0.0])
    dxc = (1.-dxc/31)*0.6+0.2
    inps = [dxc,exp,sac,sjr]
    inps = map(lambda x: vutils.interpolate(x,'1day'), inps)
    inputs = []
    for i in range(len(inps)):
	print 'Building inputs for ',inps[i]
	inputs=inputs+buildinput(inps[i],7,10,7) # weekly averages
    print 'Built inputs'
    #outputs = []
    #ccc_ref = vutils.findpath(g2,'//ccc/ec///%s/'%fpart)[0]
    #outputs.append(vutils.interpolate(DataReference.create(ccc_ref,tw).getData(),'1day'))
    mi = MultiIterator(inputs)
    import jarray
    ninps = len(inputs)
    input = jarray.zeros(ninps,'f')
    output = jarray.zeros(1,'f')
    ann = fnet_cccec()
    ndata = len(inputs[0])
    for input_no in range(31+28+31+1):
	mi.advance()
    outdata = jarray.zeros(ndata,'f')
    fh = open('junk.out','w',15000)
    while input_no < ndata:
	el = mi.getElement()
	i=0
	while i < ninps:
	    input[i] = el.getY(i)
	    i=i+1
	ann.engine(input,output,0)
	fh.write('Input #: %d\n'%input_no)
	i=0
	while i < ninps:
	    fh.write('%13.6f'%input[i])
	    if i%5 == 4: fh.write('\n')
	    i = i+1
	fh.write('\nOutput #: %d\n'%input_no)
	fh.write('%13.6f\n'%output[0])
	outdata[input_no] = output[0]
	mi.advance()
	input_no=input_no+1
    fh.close()
Exemple #4
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def _test3():
    from ANN import fnet_cccec
    fpart = 'dxc-op'
    g1 = vutils.opendss('anninputs.dss')
    g2 = vutils.opendss('annoutputs.dss')
    g1.filterBy(fpart)
    g2.filterBy(fpart)
    refs = g1[:]
    tw = vutils.timewindow('01oct1975 0000 - 01sep1991 0000')
    #tw = vutils.timewindow('01oct1975 0000 - 01oct1976 0000')
    inps = []
    for i in range(len(refs)):
	inps.append(vutils.interpolate(DataReference.create(refs[i],tw).getData(),'1day'))
    inputs = []
    for i in range(len(inps)):
	print 'Building inputs for ',inps[i]
	inputs=inputs+buildinput(inps[i],7,10,7) # weekly averages
    print 'Built inputs'
    outputs = []
    ccc_ref = vutils.findpath(g2,'//ccc/ec///%s/'%fpart)[0]
    outputs.append(vutils.interpolate(DataReference.create(ccc_ref,tw).getData(),'1day'))
    mi = MultiIterator(inputs)
    import jarray
    ninps = len(inputs)
    input = jarray.zeros(ninps,'f')
    output = jarray.zeros(1,'f')
    ann = fnet_cccec()
    ndata = len(inputs[0])
    for input_no in range(365):
	mi.advance()
    outdata = jarray.zeros(ndata,'f')
    while input_no < ndata:
	el = mi.getElement()
	i=0
	while i < ninps:
	    input[i] = el.getY(i)
	    i=i+1
	ann.engine(input,output,0)
	outdata[input_no] = output[0]
	mi.advance()
	input_no=input_no+1
    #
    stime = inputs[0].getStartTime()
    ti = inputs[0].getTimeInterval()
    rtsout = vutils.RegularTimeSeries('/ann/ccc_out/ec///annutils/',str(stime),\
				      str(ti),outdata)
    vutils.plot(rtsout,outputs[0])
    rtsout = (rtsout-0.140516)/0.000396563
    vutils.writedss('annout.dss','/ann/ccc_out/ec///annutils/',rtsout)
Exemple #5
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def dump2text(outfile, rtsarray, filter=Constants.DEFAULT_FLAG_FILTER):
    """
    """
    xfilter = CompositeFilter([filter, NaNFilter()])
    mi = MultiIterator(rtsarray)
    fh = open(outfile, 'w')
    for i in range(len(rtsarray)):
        fh.write('%s\n' % rtsarray[i].getName())
    while not mi.atEnd():
        #
        el = mi.getElement()
        fh.write(element2text(el, xfilter))
        #
        mi.advance()
    fh.close()
Exemple #6
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def dump_patterns(inputs,outputs,outfile,calibration_percentage=0.75,skip = 365,append=0,
		  fast_write=0):
    '''
    dump_patterns(inputs,outputs,outfile,calibration_percentage=0.75,append=0):
    dumps the patterns to the given outfile.
    outfile.cal which contains calibration% of the points
    outfile.ver which contains validation% = 100 - calibration% of the points
    append=1 appends to the previous .cal and .ver files if they exist
    '''
    bufsize=15000
    #fast_write=0
    prev_no_patterns = [0,0]
    if append:
	cfh = open(outfile+'.cal','r+',bufsize)
	vfh = open(outfile+'.ver','r+',bufsize)
	id = 0
	for fh in [cfh,vfh]:
	    while 1:
		line = string.strip(fh.readline())
		if string.find(line,'No. of patterns') >=0:
		    prev_no_patterns[id] = int(line[string.find(line,':')+1:])
		if string.find(line,'Input pattern')>=0: break
	    fh.seek(0)
	    id = id + 1
    else:
	if fast_write:
	    cfh = PrintStream(BufferedOutputStream(FileOutputStream(outfile+'.cal')))
	    vfh = PrintStream(BufferedOutputStream(FileOutputStream(outfile+'.ver')))
	else:
	    cfh = open(outfile+'.cal','w',bufsize)
	    vfh = open(outfile+'.ver','w',bufsize)
    #
    #if append:
    #	print 'Prev # of patterns = %s'%prev_no_patterns
    npatterns = len(inputs[0]) - skip # skip beginning
    #print 'Time Window of inputs[0] %s'%str(inputs[0].getTimeWindow())
    #print npatterns,len(inputs[0]),skip
    ncalibs = calibration_percentage*npatterns
    ninputs = len(inputs)
    noutputs = len(outputs)
    #print 'Ncalibs: %d & Nverse: %d'%(ncalibs,npatterns-ncalibs)
    if append or not fast_write:
	cfh.write('''SNNS pattern definition file V3.2
generated at date                : %s
No. of patterns                  : %d
No. of input units               : %d
No. of output units              : %d

'''%(time.ctime(time.time()),ncalibs+prev_no_patterns[0],ninputs,noutputs))
	vfh.write('''SNNS pattern definition file V3.2
generated at date                : %s
No. of patterns                  : %d
No. of input units               : %d
No. of output units              : %d

'''%(time.ctime(time.time()),npatterns-ncalibs+prev_no_patterns[1],ninputs,noutputs))
    else:
	cfh.print('''SNNS pattern definition file V3.2
generated at date                : %s
No. of patterns                  : %d
No. of input units               : %d
No. of output units              : %d

'''%(time.ctime(time.time()),ncalibs+prev_no_patterns[0],ninputs,noutputs))
	vfh.print('''SNNS pattern definition file V3.2
generated at date                : %s
No. of patterns                  : %d
No. of input units               : %d
No. of output units              : %d

'''%(time.ctime(time.time()),npatterns-ncalibs+prev_no_patterns[1],ninputs,noutputs))
    #
    #goto end of file
    if append:
	for fh in [cfh,vfh]:
	    if fast_write:
		fh.close()
	    else:
		fh.seek(0,2)
	if fast_write:
	    cfh = PrintStream(BufferedOutputStream(FileOutputStream(outfile+'.cal',1)))
	    vfh = PrintStream(BufferedOutputStream(FileOutputStream(outfile+'.ver',1)))
    #
    i=0
    all = inputs + outputs
    iterator = MultiIterator(all)
    npattern = 1
    nskip = 0
    nprint_intvl = npatterns/10
    nprints = 0
    while not iterator.atEnd():
	if npattern%nprint_intvl == 0:
	    nprints = nprints + 1
	    print 'Done: %d%%'%(nprints*10)
	if nskip < skip:
	    nskip=nskip+1
	    iterator.advance()
	    continue
	if npattern > npatterns: break
	el = iterator.getElement()
	j=0
	#print el
	if npattern <= ncalibs:
	    fh = cfh
	    pattern_no = npattern
	    prev_pattern_no = prev_no_patterns[0]
	else:
	    fh = vfh
	    pattern_no = npattern - ncalibs
	    prev_pattern_no = prev_no_patterns[1]
	if fast_write:
	    fh.println()
	    fh.println('# Input pattern %d:'%(pattern_no+prev_pattern_no))
	else:
	    fh.write('\n# Input pattern %d:\n'%(pattern_no+prev_pattern_no))
	while j < ninputs:
	    if fast_write:
		fh.print('%10.6f'%el.getY(j))
	    else:
		fh.write('%10.6f'%el.getY(j))
	    j=j+1
	if fast_write:
	    fh.println()
	    fh.println('# Output pattern %d:'%(pattern_no+prev_pattern_no))
	else:
	    fh.write('\n# Output pattern %d:\n'%(pattern_no+prev_pattern_no))
	while j < ninputs+noutputs:
	    if fast_write:
		fh.print('%10.6f'%el.getY(j))
	    else:
		fh.write('%10.6f'%el.getY(j))
	    j=j+1
	if fast_write:
	    fh.println()
	else:
	    fh.write('\n')
	npattern = npattern+1
	iterator.advance()
    #
    cfh.close()
    vfh.close()
Exemple #7
0
    function that exists in ANN package. The usual way to do this is to convert
    the SNNS generated "C" network to java using snns2java script. The generated
    java file is put in the ANN directory and compiled using "javac ann_func.java"
    command.

    inputs is the given inputs after being scaled and shifted for memory (Use
    buildinputs function for that)
    '''
    try:
	exec("from ANN import %s"%ann_func) in locals(), globals()
    except AttributeError, err:
	raise '''No function: %s defined
	Please make sure that function exists in the
	$CLASSPATH/ANN directory and is compiled'''%ann_func
    ann_obj = eval('%s()'%ann_func)
    mi = MultiIterator(inputs)
    ninps = len(inputs)
    input = jarray.zeros(ninps,'f')
    output = jarray.zeros(nouts,'f')
    ndata = len(inputs[0])
    #fh=open('%s_junk.data'%ann_func,'w')
    outarray = jarray.zeros(ndata,'f')
    input_no = 0
    nan_filter = NaNFilter()
    nprint_intvl = ndata/10
    nprints=0
    while input_no < ndata:
	if input_no%nprint_intvl == 0:
	    nprints=nprints+1
	    print 'Done: %d%%'%(nprints*10)
	el = mi.getElement()