def main(): """ NAME gokent.py DESCRIPTION calculates Kent parameters from dec inc data INPUT FORMAT takes dec/inc as first two columns in space delimited file SYNTAX gokent.py [options] OPTIONS -h prints help message and quits -i for interactive filename entry -f FILE, specify filename -F FILE, specifies output file name < filename for reading from standard input OUTPUT mean dec, mean inc, Eta, Deta, Ieta, Zeta, Zdec, Zinc, N """ if len(sys.argv) > 0: if '-h' in sys.argv: # check if help is needed print main.__doc__ sys.exit() # graceful quit if '-f' in sys.argv: ind=sys.argv.index('-f') file=sys.argv[ind+1] f=open(file,'rU') data=f.readlines() elif '-i' in sys.argv: # ask for filename file=raw_input("Enter file name with dec, inc data: ") f=open(file,'rU') data=f.readlines() else: # data=sys.stdin.readlines() # read in data from standard input ofile = "" if '-F' in sys.argv: ind = sys.argv.index('-F') ofile= sys.argv[ind+1] out = open(ofile, 'w + a') DIs= [] # set up list for dec inc data for line in data: # read in the data from standard input if '\t' in line: rec=line.split('\t') # split each line on space to get records else: rec=line.split() # split each line on space to get records DIs.append((float(rec[0]),float(rec[1]))) # kpars=pmag.dokent(DIs,len(DIs)) output = '%7.1f %7.1f %7.1f %7.1f %7.1f %7.1f %7.1f %7.1f %i' % (kpars["dec"],kpars["inc"],kpars["Eta"],kpars["Edec"],kpars["Einc"],kpars["Zeta"],kpars["Zdec"],kpars["Zinc"],kpars["n"]) if ofile == "": print output else: out.write(output+'\n')
def main(): """ NAME eqarea_magic.py DESCRIPTION makes equal area projections from declination/inclination data SYNTAX eqarea_magic.py [command line options] INPUT takes magic formatted sites, samples, specimens, or measurements OPTIONS -h prints help message and quits -f FILE: specify input magic format file from magic, default='sites.txt' supported types=[measurements, specimens, samples, sites] -fsp FILE: specify specimen file name, (required if you want to plot measurements by sample) default='specimens.txt' -fsa FILE: specify sample file name, (required if you want to plot specimens by site) default='samples.txt' -fsi FILE: specify site file name, default='sites.txt' -obj OBJ: specify level of plot [all, sit, sam, spc], default is all -crd [s,g,t]: specify coordinate system, [s]pecimen, [g]eographic, [t]ilt adjusted default is geographic, unspecified assumed geographic -fmt [svg,png,jpg] format for output plots -ell [F,K,B,Be,Bv] plot Fisher, Kent, Bingham, Bootstrap ellipses or Boostrap eigenvectors -c plot as colour contour -sav save plot and quit quietly NOTE all: entire file; sit: site; sam: sample; spc: specimen """ # initialize some default variables FIG = {} # plot dictionary FIG['eqarea'] = 1 # eqarea is figure 1 plotE = 0 plt = 0 # default to not plotting verbose = pmagplotlib.verbose # extract arguments from sys.argv if '-h' in sys.argv: print(main.__doc__) sys.exit() dir_path = pmag.get_named_arg_from_sys("-WD", default_val=".") pmagplotlib.plot_init(FIG['eqarea'],5,5) in_file = pmag.get_named_arg_from_sys("-f", default_val="sites.txt") in_file = pmag.resolve_file_name(in_file, dir_path) if "-WD" not in sys.argv: dir_path = os.path.split(in_file)[0] #full_in_file = os.path.join(dir_path, in_file) plot_by = pmag.get_named_arg_from_sys("-obj", default_val="all").lower() spec_file = pmag.get_named_arg_from_sys("-fsp", default_val="specimens.txt") samp_file = pmag.get_named_arg_from_sys("-fsa", default_val="samples.txt") site_file = pmag.get_named_arg_from_sys("-fsi", default_val="sites.txt") if plot_by == 'all': plot_key = 'all' elif plot_by == 'sit': plot_key = 'site' elif plot_by == 'sam': plot_key = 'sample' elif plot_by == 'spc': plot_key = 'specimen' else: plot_by = 'all' plot_key = 'all' if '-c' in sys.argv: contour = 1 else: contour = 0 if '-sav' in sys.argv: plt = 1 verbose = 0 if '-ell' in sys.argv: plotE = 1 ind = sys.argv.index('-ell') ell_type = sys.argv[ind+1] ell_type = pmag.get_named_arg_from_sys("-ell", "F") dist = ell_type.upper() # if dist type is unrecognized, use Fisher if dist not in ['F', 'K', 'B', 'BE', 'BV']: dist = 'F' if dist == "BV": FIG['bdirs'] = 2 pmagplotlib.plot_init(FIG['bdirs'],5,5) crd = pmag.get_named_arg_from_sys("-crd", default_val="g") if crd == "s": coord = "-1" elif crd == "t": coord = "100" else: coord = "0" fmt = pmag.get_named_arg_from_sys("-fmt", "svg") dec_key = 'dir_dec' inc_key = 'dir_inc' tilt_key = 'dir_tilt_correction' #Dir_type_keys=['','site_direction_type','sample_direction_type','specimen_direction_type'] # fnames = {"specimens": spec_file, "samples": samp_file, 'sites': site_file} contribution = nb.Contribution(dir_path, custom_filenames=fnames, single_file=in_file) try: contribution.propagate_location_to_samples() contribution.propagate_location_to_specimens() contribution.propagate_location_to_measurements() except KeyError as ex: pass # the object that contains the DataFrame + useful helper methods: table_name = list(contribution.tables.keys())[0] data_container = contribution.tables[table_name] # the actual DataFrame: data = data_container.df if plot_key != "all" and plot_key not in data.columns: print("-E- You can't plot by {} with the data provided".format(plot_key)) return # add tilt key into DataFrame columns if it isn't there already if tilt_key not in data.columns: data.loc[:, tilt_key] = None if verbose: print(len(data), ' records read from ', in_file) # find desired dec,inc data: dir_type_key = '' # # get plotlist if not plotting all records # plotlist=[] if plot_key != "all": # return all where plot_key is not blank if plot_key not in data.columns: print('Can\'t plot by "{}". That header is not in infile: {}'.format(plot_key, in_file)) return plots = data[data[plot_key].notnull()] plotlist = plots[plot_key].unique() # grab unique values else: plotlist.append('All') for plot in plotlist: if verbose: print(plot) if plot == 'All': # plot everything at once plot_data = data else: # pull out only partial data plot_data = data[data[plot_key] == plot] DIblock = [] GCblock = [] # SLblock, SPblock = [], [] title = plot mode = 1 k = 0 if dec_key not in plot_data.columns: print("-W- No dec/inc data") continue # get all records where dec & inc values exist plot_data = plot_data[plot_data[dec_key].notnull() & plot_data[inc_key].notnull()] if plot_data.empty: continue # this sorting out is done in get_di_bock #if coord == '0': # geographic, use records with no tilt key (or tilt_key 0) # cond1 = plot_data[tilt_key].fillna('') == coord # cond2 = plot_data[tilt_key].isnull() # plot_data = plot_data[cond1 | cond2] #else: # not geographic coordinates, use only records with correct tilt_key # plot_data = plot_data[plot_data[tilt_key] == coord] # get metadata for naming the plot file locations = data_container.get_name('location', df_slice=plot_data) site = data_container.get_name('site', df_slice=plot_data) sample = data_container.get_name('sample', df_slice=plot_data) specimen = data_container.get_name('specimen', df_slice=plot_data) # make sure method_codes is in plot_data if 'method_codes' not in plot_data.columns: plot_data['method_codes'] = '' # get data blocks DIblock = data_container.get_di_block(df_slice=plot_data, tilt_corr=coord, excl=['DE-BFP']) #SLblock = [[ind, row['method_codes']] for ind, row in plot_data.iterrows()] # get great circles great_circle_data = data_container.get_records_for_code('DE-BFP', incl=True, use_slice=True, sli=plot_data) if len(great_circle_data) > 0: gc_cond = great_circle_data[tilt_key] == coord GCblock = [[float(row[dec_key]), float(row[inc_key])] for ind, row in great_circle_data[gc_cond].iterrows()] #SPblock = [[ind, row['method_codes']] for ind, row in great_circle_data[gc_cond].iterrows()] if len(DIblock) > 0: if contour == 0: pmagplotlib.plotEQ(FIG['eqarea'], DIblock, title) else: pmagplotlib.plotEQcont(FIG['eqarea'], DIblock) else: pmagplotlib.plotNET(FIG['eqarea']) if len(GCblock)>0: for rec in GCblock: pmagplotlib.plotC(FIG['eqarea'], rec, 90., 'g') if len(DIblock) == 0 and len(GCblock) == 0: if verbose: print("no records for plotting") continue #sys.exit() if plotE == 1: ppars = pmag.doprinc(DIblock) # get principal directions nDIs, rDIs, npars, rpars = [], [], [], [] for rec in DIblock: angle=pmag.angle([rec[0],rec[1]],[ppars['dec'],ppars['inc']]) if angle>90.: rDIs.append(rec) else: nDIs.append(rec) if dist=='B': # do on whole dataset etitle="Bingham confidence ellipse" bpars=pmag.dobingham(DIblock) for key in list(bpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(bpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(bpars[key])) npars.append(bpars['dec']) npars.append(bpars['inc']) npars.append(bpars['Zeta']) npars.append(bpars['Zdec']) npars.append(bpars['Zinc']) npars.append(bpars['Eta']) npars.append(bpars['Edec']) npars.append(bpars['Einc']) if dist=='F': etitle="Fisher confidence cone" if len(nDIs)>2: fpars=pmag.fisher_mean(nDIs) for key in list(fpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(fpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(fpars[key])) mode+=1 npars.append(fpars['dec']) npars.append(fpars['inc']) npars.append(fpars['alpha95']) # Beta npars.append(fpars['dec']) isign=old_div(abs(fpars['inc']),fpars['inc']) npars.append(fpars['inc']-isign*90.) #Beta inc npars.append(fpars['alpha95']) # gamma npars.append(fpars['dec']+90.) # Beta dec npars.append(0.) #Beta inc if len(rDIs)>2: fpars=pmag.fisher_mean(rDIs) if verbose: print("mode ",mode) for key in list(fpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(fpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(fpars[key])) mode+=1 rpars.append(fpars['dec']) rpars.append(fpars['inc']) rpars.append(fpars['alpha95']) # Beta rpars.append(fpars['dec']) isign=old_div(abs(fpars['inc']),fpars['inc']) rpars.append(fpars['inc']-isign*90.) #Beta inc rpars.append(fpars['alpha95']) # gamma rpars.append(fpars['dec']+90.) # Beta dec rpars.append(0.) #Beta inc if dist=='K': etitle="Kent confidence ellipse" if len(nDIs)>3: kpars=pmag.dokent(nDIs,len(nDIs)) if verbose: print("mode ",mode) for key in list(kpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(kpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(kpars[key])) mode+=1 npars.append(kpars['dec']) npars.append(kpars['inc']) npars.append(kpars['Zeta']) npars.append(kpars['Zdec']) npars.append(kpars['Zinc']) npars.append(kpars['Eta']) npars.append(kpars['Edec']) npars.append(kpars['Einc']) if len(rDIs)>3: kpars=pmag.dokent(rDIs,len(rDIs)) if verbose: print("mode ",mode) for key in list(kpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(kpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(kpars[key])) mode+=1 rpars.append(kpars['dec']) rpars.append(kpars['inc']) rpars.append(kpars['Zeta']) rpars.append(kpars['Zdec']) rpars.append(kpars['Zinc']) rpars.append(kpars['Eta']) rpars.append(kpars['Edec']) rpars.append(kpars['Einc']) else: # assume bootstrap if dist=='BE': if len(nDIs)>5: BnDIs=pmag.di_boot(nDIs) Bkpars=pmag.dokent(BnDIs,1.) if verbose: print("mode ",mode) for key in list(Bkpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(Bkpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(Bkpars[key])) mode+=1 npars.append(Bkpars['dec']) npars.append(Bkpars['inc']) npars.append(Bkpars['Zeta']) npars.append(Bkpars['Zdec']) npars.append(Bkpars['Zinc']) npars.append(Bkpars['Eta']) npars.append(Bkpars['Edec']) npars.append(Bkpars['Einc']) if len(rDIs)>5: BrDIs=pmag.di_boot(rDIs) Bkpars=pmag.dokent(BrDIs,1.) if verbose: print("mode ",mode) for key in list(Bkpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(Bkpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(Bkpars[key])) mode+=1 rpars.append(Bkpars['dec']) rpars.append(Bkpars['inc']) rpars.append(Bkpars['Zeta']) rpars.append(Bkpars['Zdec']) rpars.append(Bkpars['Zinc']) rpars.append(Bkpars['Eta']) rpars.append(Bkpars['Edec']) rpars.append(Bkpars['Einc']) etitle="Bootstrapped confidence ellipse" elif dist=='BV': sym={'lower':['o','c'],'upper':['o','g'],'size':3,'edgecolor':'face'} if len(nDIs)>5: BnDIs=pmag.di_boot(nDIs) pmagplotlib.plotEQsym(FIG['bdirs'],BnDIs,'Bootstrapped Eigenvectors', sym) if len(rDIs)>5: BrDIs=pmag.di_boot(rDIs) if len(nDIs)>5: # plot on existing plots pmagplotlib.plotDIsym(FIG['bdirs'],BrDIs,sym) else: pmagplotlib.plotEQ(FIG['bdirs'],BrDIs,'Bootstrapped Eigenvectors') if dist=='B': if len(nDIs)> 3 or len(rDIs)>3: pmagplotlib.plotCONF(FIG['eqarea'],etitle,[],npars,0) elif len(nDIs)>3 and dist!='BV': pmagplotlib.plotCONF(FIG['eqarea'],etitle,[],npars,0) if len(rDIs)>3: pmagplotlib.plotCONF(FIG['eqarea'],etitle,[],rpars,0) elif len(rDIs)>3 and dist!='BV': pmagplotlib.plotCONF(FIG['eqarea'],etitle,[],rpars,0) for key in list(FIG.keys()): files = {} filename = pmag.get_named_arg_from_sys('-fname') if filename: # use provided filename filename+= '.' + fmt elif pmagplotlib.isServer: # use server plot naming convention filename='LO:_'+locations+'_SI:_'+site+'_SA:_'+sample+'_SP:_'+specimen+'_CO:_'+crd+'_TY:_'+key+'_.'+fmt elif plot_key == 'all': filename = 'all' if 'location' in plot_data.columns: locs = plot_data['location'].unique() loc_string = "_".join([loc.replace(' ', '_') for loc in locs]) filename += "_" + loc_string filename += "_" + crd + "_" + key filename += ".{}".format(fmt) else: # use more readable naming convention filename = '' # fix this if plot_by is location , for example use_names = {'location': [locations], 'site': [locations, site], 'sample': [locations, site, sample], 'specimen': [locations, site, sample, specimen]} use = use_names[plot_key] use.extend([crd, key]) for item in use: #[locations, site, sample, specimen, crd, key]: if item: item = item.replace(' ', '_') filename += item + '_' if filename.endswith('_'): filename = filename[:-1] filename += ".{}".format(fmt) files[key]=filename if pmagplotlib.isServer: black = '#000000' purple = '#800080' titles={} titles['eq']='Equal Area Plot' FIG = pmagplotlib.addBorders(FIG,titles,black,purple) pmagplotlib.saveP(FIG,files) if plt: pmagplotlib.saveP(FIG,files) continue if verbose: pmagplotlib.drawFIGS(FIG) ans=input(" S[a]ve to save plot, [q]uit, Return to continue: ") if ans == "q": sys.exit() if ans == "a": pmagplotlib.saveP(FIG,files) continue
def main(): """ NAME eqarea_ell.py DESCRIPTION makes equal area projections from declination/inclination data and plot ellipses SYNTAX eqarea_ell.py -h [command line options] INPUT takes space delimited Dec/Inc data OPTIONS -h prints help message and quits -f FILE -fmt [svg,png,jpg] format for output plots -sav saves figures and quits -ell [F,K,B,Be,Bv] plot Fisher, Kent, Bingham, Bootstrap ellipses or Boostrap eigenvectors """ FIG={} # plot dictionary FIG['eq']=1 # eqarea is figure 1 fmt,dist,mode,plot='svg','F',1,0 sym={'lower':['o','r'],'upper':['o','w'],'size':10} plotE=0 if '-h' in sys.argv: print(main.__doc__) sys.exit() if not set_env.IS_WIN: pmagplotlib.plot_init(FIG['eq'],5,5) if '-sav' in sys.argv:plot=1 if '-f' in sys.argv: ind=sys.argv.index("-f") title=sys.argv[ind+1] data=numpy.loadtxt(title).transpose() if '-ell' in sys.argv: plotE=1 ind=sys.argv.index('-ell') ell_type=sys.argv[ind+1] if ell_type=='F':dist='F' if ell_type=='K':dist='K' if ell_type=='B':dist='B' if ell_type=='Be':dist='BE' if ell_type=='Bv': dist='BV' FIG['bdirs']=2 pmagplotlib.plot_init(FIG['bdirs'],5,5) if '-fmt' in sys.argv: ind=sys.argv.index("-fmt") fmt=sys.argv[ind+1] DIblock=numpy.array([data[0],data[1]]).transpose() if len(DIblock)>0: pmagplotlib.plot_eq_sym(FIG['eq'],DIblock,title,sym) #if plot==0:pmagplotlib.draw_figs(FIG) else: print("no data to plot") sys.exit() if plotE==1: ppars=pmag.doprinc(DIblock) # get principal directions nDIs,rDIs,npars,rpars=[],[],[],[] for rec in DIblock: angle=pmag.angle([rec[0],rec[1]],[ppars['dec'],ppars['inc']]) if angle>90.: rDIs.append(rec) else: nDIs.append(rec) if dist=='B': # do on whole dataset etitle="Bingham confidence ellipse" bpars=pmag.dobingham(DIblock) for key in list(bpars.keys()): if key!='n' and pmagplotlib.verbose:print(" ",key, '%7.1f'%(bpars[key])) if key=='n' and pmagplotlib.verbose:print(" ",key, ' %i'%(bpars[key])) npars.append(bpars['dec']) npars.append(bpars['inc']) npars.append(bpars['Zeta']) npars.append(bpars['Zdec']) npars.append(bpars['Zinc']) npars.append(bpars['Eta']) npars.append(bpars['Edec']) npars.append(bpars['Einc']) if dist=='F': etitle="Fisher confidence cone" if len(nDIs)>3: fpars=pmag.fisher_mean(nDIs) for key in list(fpars.keys()): if key!='n' and pmagplotlib.verbose:print(" ",key, '%7.1f'%(fpars[key])) if key=='n' and pmagplotlib.verbose:print(" ",key, ' %i'%(fpars[key])) mode+=1 npars.append(fpars['dec']) npars.append(fpars['inc']) npars.append(fpars['alpha95']) # Beta npars.append(fpars['dec']) isign=abs(fpars['inc']) / fpars['inc'] npars.append(fpars['inc']-isign*90.) #Beta inc npars.append(fpars['alpha95']) # gamma npars.append(fpars['dec']+90.) # Beta dec npars.append(0.) #Beta inc if len(rDIs)>3: fpars=pmag.fisher_mean(rDIs) if pmagplotlib.verbose:print("mode ",mode) for key in list(fpars.keys()): if key!='n' and pmagplotlib.verbose:print(" ",key, '%7.1f'%(fpars[key])) if key=='n' and pmagplotlib.verbose:print(" ",key, ' %i'%(fpars[key])) mode+=1 rpars.append(fpars['dec']) rpars.append(fpars['inc']) rpars.append(fpars['alpha95']) # Beta rpars.append(fpars['dec']) isign=abs(fpars['inc']) / fpars['inc'] rpars.append(fpars['inc']-isign*90.) #Beta inc rpars.append(fpars['alpha95']) # gamma rpars.append(fpars['dec']+90.) # Beta dec rpars.append(0.) #Beta inc if dist=='K': etitle="Kent confidence ellipse" if len(nDIs)>3: kpars=pmag.dokent(nDIs,len(nDIs)) if pmagplotlib.verbose:print("mode ",mode) for key in list(kpars.keys()): if key!='n' and pmagplotlib.verbose:print(" ",key, '%7.1f'%(kpars[key])) if key=='n' and pmagplotlib.verbose:print(" ",key, ' %i'%(kpars[key])) mode+=1 npars.append(kpars['dec']) npars.append(kpars['inc']) npars.append(kpars['Zeta']) npars.append(kpars['Zdec']) npars.append(kpars['Zinc']) npars.append(kpars['Eta']) npars.append(kpars['Edec']) npars.append(kpars['Einc']) if len(rDIs)>3: kpars=pmag.dokent(rDIs,len(rDIs)) if pmagplotlib.verbose:print("mode ",mode) for key in list(kpars.keys()): if key!='n' and pmagplotlib.verbose:print(" ",key, '%7.1f'%(kpars[key])) if key=='n' and pmagplotlib.verbose:print(" ",key, ' %i'%(kpars[key])) mode+=1 rpars.append(kpars['dec']) rpars.append(kpars['inc']) rpars.append(kpars['Zeta']) rpars.append(kpars['Zdec']) rpars.append(kpars['Zinc']) rpars.append(kpars['Eta']) rpars.append(kpars['Edec']) rpars.append(kpars['Einc']) else: # assume bootstrap if len(nDIs)<10 and len(rDIs)<10: print('too few data points for bootstrap') sys.exit() if dist=='BE': print('Be patient for bootstrap...') if len(nDIs)>=10: BnDIs=pmag.di_boot(nDIs) Bkpars=pmag.dokent(BnDIs,1.) if pmagplotlib.verbose:print("mode ",mode) for key in list(Bkpars.keys()): if key!='n' and pmagplotlib.verbose:print(" ",key, '%7.1f'%(Bkpars[key])) if key=='n' and pmagplotlib.verbose:print(" ",key, ' %i'%(Bkpars[key])) mode+=1 npars.append(Bkpars['dec']) npars.append(Bkpars['inc']) npars.append(Bkpars['Zeta']) npars.append(Bkpars['Zdec']) npars.append(Bkpars['Zinc']) npars.append(Bkpars['Eta']) npars.append(Bkpars['Edec']) npars.append(Bkpars['Einc']) if len(rDIs)>=10: BrDIs=pmag.di_boot(rDIs) Bkpars=pmag.dokent(BrDIs,1.) if pmagplotlib.verbose:print("mode ",mode) for key in list(Bkpars.keys()): if key!='n' and pmagplotlib.verbose:print(" ",key, '%7.1f'%(Bkpars[key])) if key=='n' and pmagplotlib.verbose:print(" ",key, ' %i'%(Bkpars[key])) mode+=1 rpars.append(Bkpars['dec']) rpars.append(Bkpars['inc']) rpars.append(Bkpars['Zeta']) rpars.append(Bkpars['Zdec']) rpars.append(Bkpars['Zinc']) rpars.append(Bkpars['Eta']) rpars.append(Bkpars['Edec']) rpars.append(Bkpars['Einc']) etitle="Bootstrapped confidence ellipse" elif dist=='BV': print('Be patient for bootstrap...') vsym={'lower':['+','k'],'upper':['x','k'],'size':5} if len(nDIs)>5: BnDIs=pmag.di_boot(nDIs) pmagplotlib.plot_eq_sym(FIG['bdirs'],BnDIs,'Bootstrapped Eigenvectors',vsym) if len(rDIs)>5: BrDIs=pmag.di_boot(rDIs) if len(nDIs)>5: # plot on existing plots pmagplotlib.plot_di_sym(FIG['bdirs'],BrDIs,vsym) else: pmagplotlib.plot_eq(FIG['bdirs'],BrDIs,'Bootstrapped Eigenvectors',vsym) if dist=='B': if len(nDIs)> 3 or len(rDIs)>3: pmagplotlib.plot_conf(FIG['eq'],etitle,[],npars,0) elif len(nDIs)>3 and dist!='BV': pmagplotlib.plot_conf(FIG['eq'],etitle,[],npars,0) if len(rDIs)>3: pmagplotlib.plot_conf(FIG['eq'],etitle,[],rpars,0) elif len(rDIs)>3 and dist!='BV': pmagplotlib.plot_conf(FIG['eq'],etitle,[],rpars,0) #if plot==0:pmagplotlib.draw_figs(FIG) if plot==0:pmagplotlib.draw_figs(FIG) # files={} for key in list(FIG.keys()): files[key]=title+'_'+key+'.'+fmt if pmagplotlib.isServer: black = '#000000' purple = '#800080' titles={} titles['eq']='Equal Area Plot' FIG = pmagplotlib.add_borders(FIG,titles,black,purple) pmagplotlib.save_plots(FIG,files) elif plot==0: ans=input(" S[a]ve to save plot, [q]uit, Return to continue: ") if ans=="q": sys.exit() if ans=="a": pmagplotlib.save_plots(FIG,files) else: pmagplotlib.save_plots(FIG,files)
def main(): """ NAME plotdi_e.py DESCRIPTION plots equal area projection from dec inc data and cones of confidence (Fisher, kent or Bingham or bootstrap). INPUT FORMAT takes dec/inc as first two columns in space delimited file SYNTAX plotdi_e.py [command line options] OPTIONS -h prints help message and quits -i for interactive parameter entry -f FILE, sets input filename on command line -Fish plots unit vector mean direction, alpha95 -Bing plots Principal direction, Bingham confidence ellipse -Kent plots unit vector mean direction, confidence ellipse -Boot E plots unit vector mean direction, bootstrapped confidence ellipse -Boot V plots unit vector mean direction, distribution of bootstrapped means """ dist = 'F' # default distribution is Fisherian mode = 1 EQ = {'eq': 1} if len(sys.argv) > 0: if '-h' in sys.argv: # check if help is needed print main.__doc__ sys.exit() # graceful quit if '-i' in sys.argv: # ask for filename file = raw_input("Enter file name with dec, inc data: ") dist = raw_input( "Enter desired distrubution: [Fish]er, [Bing]ham, [Kent] [Boot] [default is Fisher]: " ) if dist == "": dist = "F" if dist == "Boot": type = raw_input( " Ellipses or distribution of vectors? [E]/V ") if type == "" or type == "E": dist = "BE" else: dist = "BE" else: # if '-f' in sys.argv: ind = sys.argv.index('-f') file = sys.argv[ind + 1] else: print 'you must specify a file name' print main.__doc__ sys.exit() if '-Bing' in sys.argv: dist = 'B' if '-Kent' in sys.argv: dist = 'K' if '-Boot' in sys.argv: ind = sys.argv.index('-Boot') type = sys.argv[ind + 1] if type == 'E': dist = 'BE' elif type == 'V': dist = 'BV' EQ['bdirs'] = 2 pmagplotlib.plot_init(EQ['bdirs'], 5, 5) else: print main.__doc__ sys.exit() pmagplotlib.plot_init(EQ['eq'], 5, 5) # # get to work f = open(file, 'r') data = f.readlines() # DIs = [] # set up list for dec inc data DiRecs = [] pars = [] nDIs, rDIs, npars, rpars = [], [], [], [] mode = 1 for line in data: # read in the data from standard input DiRec = {} rec = line.split() # split each line on space to get records DIs.append((float(rec[0]), float(rec[1]), 1.)) DiRec['dec'] = rec[0] DiRec['inc'] = rec[1] DiRec['direction_type'] = 'l' DiRecs.append(DiRec) # split into two modes ppars = pmag.doprinc(DIs) # get principal directions for rec in DIs: angle = pmag.angle([rec[0], rec[1]], [ppars['dec'], ppars['inc']]) if angle > 90.: rDIs.append(rec) else: nDIs.append(rec) if dist == 'B': # do on whole dataset title = "Bingham confidence ellipse" bpars = pmag.dobingham(DIs) for key in bpars.keys(): if key != 'n': print " ", key, '%7.1f' % (bpars[key]) if key == 'n': print " ", key, ' %i' % (bpars[key]) npars.append(bpars['dec']) npars.append(bpars['inc']) npars.append(bpars['Zeta']) npars.append(bpars['Zdec']) npars.append(bpars['Zinc']) npars.append(bpars['Eta']) npars.append(bpars['Edec']) npars.append(bpars['Einc']) if dist == 'F': title = "Fisher confidence cone" if len(nDIs) > 3: fpars = pmag.fisher_mean(nDIs) print "mode ", mode for key in fpars.keys(): if key != 'n': print " ", key, '%7.1f' % (fpars[key]) if key == 'n': print " ", key, ' %i' % (fpars[key]) mode += 1 npars.append(fpars['dec']) npars.append(fpars['inc']) npars.append(fpars['alpha95']) # Beta npars.append(fpars['dec']) isign = abs(fpars['inc']) / fpars['inc'] npars.append(fpars['inc'] - isign * 90.) #Beta inc npars.append(fpars['alpha95']) # gamma npars.append(fpars['dec'] + 90.) # Beta dec npars.append(0.) #Beta inc if len(rDIs) > 3: fpars = pmag.fisher_mean(rDIs) print "mode ", mode for key in fpars.keys(): if key != 'n': print " ", key, '%7.1f' % (fpars[key]) if key == 'n': print " ", key, ' %i' % (fpars[key]) mode += 1 rpars.append(fpars['dec']) rpars.append(fpars['inc']) rpars.append(fpars['alpha95']) # Beta rpars.append(fpars['dec']) isign = abs(fpars['inc']) / fpars['inc'] rpars.append(fpars['inc'] - isign * 90.) #Beta inc rpars.append(fpars['alpha95']) # gamma rpars.append(fpars['dec'] + 90.) # Beta dec rpars.append(0.) #Beta inc if dist == 'K': title = "Kent confidence ellipse" if len(nDIs) > 3: kpars = pmag.dokent(nDIs, len(nDIs)) print "mode ", mode for key in kpars.keys(): if key != 'n': print " ", key, '%7.1f' % (kpars[key]) if key == 'n': print " ", key, ' %i' % (kpars[key]) mode += 1 npars.append(kpars['dec']) npars.append(kpars['inc']) npars.append(kpars['Zeta']) npars.append(kpars['Zdec']) npars.append(kpars['Zinc']) npars.append(kpars['Eta']) npars.append(kpars['Edec']) npars.append(kpars['Einc']) if len(rDIs) > 3: kpars = pmag.dokent(rDIs, len(rDIs)) print "mode ", mode for key in kpars.keys(): if key != 'n': print " ", key, '%7.1f' % (kpars[key]) if key == 'n': print " ", key, ' %i' % (kpars[key]) mode += 1 rpars.append(kpars['dec']) rpars.append(kpars['inc']) rpars.append(kpars['Zeta']) rpars.append(kpars['Zdec']) rpars.append(kpars['Zinc']) rpars.append(kpars['Eta']) rpars.append(kpars['Edec']) rpars.append(kpars['Einc']) else: # assume bootstrap if dist == 'BE': if len(nDIs) > 5: BnDIs = pmag.di_boot(nDIs) Bkpars = pmag.dokent(BnDIs, 1.) print "mode ", mode for key in Bkpars.keys(): if key != 'n': print " ", key, '%7.1f' % (Bkpars[key]) if key == 'n': print " ", key, ' %i' % (Bkpars[key]) mode += 1 npars.append(Bkpars['dec']) npars.append(Bkpars['inc']) npars.append(Bkpars['Zeta']) npars.append(Bkpars['Zdec']) npars.append(Bkpars['Zinc']) npars.append(Bkpars['Eta']) npars.append(Bkpars['Edec']) npars.append(Bkpars['Einc']) if len(rDIs) > 5: BrDIs = pmag.di_boot(rDIs) Bkpars = pmag.dokent(BrDIs, 1.) print "mode ", mode for key in Bkpars.keys(): if key != 'n': print " ", key, '%7.1f' % (Bkpars[key]) if key == 'n': print " ", key, ' %i' % (Bkpars[key]) mode += 1 rpars.append(Bkpars['dec']) rpars.append(Bkpars['inc']) rpars.append(Bkpars['Zeta']) rpars.append(Bkpars['Zdec']) rpars.append(Bkpars['Zinc']) rpars.append(Bkpars['Eta']) rpars.append(Bkpars['Edec']) rpars.append(Bkpars['Einc']) title = "Bootstrapped confidence ellipse" elif dist == 'BV': if len(nDIs) > 5: pmagplotlib.plotEQ(EQ['eq'], nDIs, 'Data') BnDIs = pmag.di_boot(nDIs) pmagplotlib.plotEQ(EQ['bdirs'], BnDIs, 'Bootstrapped Eigenvectors') if len(rDIs) > 5: BrDIs = pmag.di_boot(rDIs) if len(nDIs) > 5: # plot on existing plots pmagplotlib.plotDI(EQ['eq'], rDIs) pmagplotlib.plotDI(EQ['bdirs'], BrDIs) else: pmagplotlib.plotEQ(EQ['eq'], rDIs, 'Data') pmagplotlib.plotEQ(EQ['bdirs'], BrDIs, 'Bootstrapped Eigenvectors') pmagplotlib.drawFIGS(EQ) ans = raw_input('s[a]ve, [q]uit ') if ans == 'q': sys.exit() if ans == 'a': files = {} for key in EQ.keys(): files[key] = 'BE_' + key + '.svg' pmagplotlib.saveP(EQ, files) sys.exit() if len(nDIs) > 5: pmagplotlib.plotCONF(EQ['eq'], title, DiRecs, npars, 1) if len(rDIs) > 5 and dist != 'B': pmagplotlib.plotCONF(EQ['eq'], title, [], rpars, 0) elif len(rDIs) > 5 and dist != 'B': pmagplotlib.plotCONF(EQ['eq'], title, DiRecs, rpars, 1) pmagplotlib.drawFIGS(EQ) ans = raw_input('s[a]ve, [q]uit ') if ans == 'q': sys.exit() if ans == 'a': files = {} for key in EQ.keys(): files[key] = key + '.svg' pmagplotlib.saveP(EQ, files)
def main(): """ NAME eqarea_magic.py DESCRIPTION makes equal area projections from declination/inclination data SYNTAX eqarea_magic.py [command line options] INPUT takes magic formatted sites, samples, specimens, or measurements OPTIONS -h prints help message and quits -f FILE: specify input magic format file from magic, default='sites.txt' supported types=[measurements, specimens, samples, sites] -fsp FILE: specify specimen file name, (required if you want to plot measurements by sample) default='specimens.txt' -fsa FILE: specify sample file name, (required if you want to plot specimens by site) default='samples.txt' -fsi FILE: specify site file name, default='sites.txt' -obj OBJ: specify level of plot [all, sit, sam, spc], default is all -crd [s,g,t]: specify coordinate system, [s]pecimen, [g]eographic, [t]ilt adjusted default is geographic, unspecified assumed geographic -fmt [svg,png,jpg] format for output plots -ell [F,K,B,Be,Bv] plot Fisher, Kent, Bingham, Bootstrap ellipses or Boostrap eigenvectors -c plot as colour contour -sav save plot and quit quietly NOTE all: entire file; sit: site; sam: sample; spc: specimen """ # initialize some default variables FIG = {} # plot dictionary FIG['eqarea'] = 1 # eqarea is figure 1 plotE = 0 plt = 0 # default to not plotting verbose = pmagplotlib.verbose # extract arguments from sys.argv if '-h' in sys.argv: print(main.__doc__) sys.exit() dir_path = pmag.get_named_arg_from_sys("-WD", default_val=os.getcwd()) pmagplotlib.plot_init(FIG['eqarea'],5,5) in_file = pmag.get_named_arg_from_sys("-f", default_val="sites.txt") full_in_file = os.path.join(dir_path, in_file) plot_by = pmag.get_named_arg_from_sys("-obj", default_val="all").lower() spec_file = pmag.get_named_arg_from_sys("-fsp", default_val="specimens.txt") samp_file = pmag.get_named_arg_from_sys("-fsa", default_val="samples.txt") site_file = pmag.get_named_arg_from_sys("-fsi", default_val="sites.txt") if plot_by == 'all': plot_key = 'all' elif plot_by == 'sit': plot_key = 'site' elif plot_by == 'sam': plot_key = 'sample' elif plot_by == 'spc': plot_key = 'specimen' else: plot_key = 'all' if '-c' in sys.argv: contour = 1 else: contour = 0 if '-sav' in sys.argv: plt = 1 verbose = 0 if '-ell' in sys.argv: plotE = 1 ind = sys.argv.index('-ell') ell_type = sys.argv[ind+1] ell_type = pmag.get_named_arg_from_sys("-ell", "F") dist = ell_type.upper() # if dist type is unrecognized, use Fisher if dist not in ['F', 'K', 'B', 'BE', 'BV']: dist = 'F' if dist == "BV": FIG['bdirs'] = 2 pmagplotlib.plot_init(FIG['bdirs'],5,5) crd = pmag.get_named_arg_from_sys("-crd", default_val="g") if crd == "s": coord = "-1" elif crd == "t": coord = "100" else: coord = "0" fmt = pmag.get_named_arg_from_sys("-fmt", "svg") dec_key = 'dir_dec' inc_key = 'dir_inc' tilt_key = 'dir_tilt_correction' #Dir_type_keys=['','site_direction_type','sample_direction_type','specimen_direction_type'] # fnames = {"specimens": spec_file, "samples": samp_file, 'sites': site_file} contribution = nb.Contribution(dir_path, custom_filenames=fnames, single_file=in_file) # the object that contains the DataFrame + useful helper methods: table_name = list(contribution.tables.keys())[0] data_container = contribution.tables[table_name] # the actual DataFrame: data = data_container.df # uses sample infile to add temporary site_name # column to the specimen table data_container = contribution.tables[table_name] data = data_container.df if (plot_key != "all") and (plot_key not in data.columns): contribution.propagate_location_to_measurements() contribution.propagate_location_to_specimens() # add tilt key into DataFrame columns if it isn't there already if tilt_key not in data.columns: data.loc[:, tilt_key] = None if verbose: print(len(data), ' records read from ', in_file) # find desired dec,inc data: dir_type_key = '' # # get plotlist if not plotting all records # plotlist=[] if plot_key != "all": # return all where plot_key is not blank if plot_key not in data.columns: print('Can\'t plot by "{}". That header is not in infile: {}'.format(plot_key, in_file)) return plots = data[data[plot_key].notnull()] plotlist = plots[plot_key].unique() # grab unique values else: plotlist.append('All') for plot in plotlist: if verbose: print(plot) if plot == 'All': # plot everything at once plot_data = data else: # pull out only partial data plot_data = data[data[plot_key] == plot] DIblock = [] GCblock = [] # SLblock, SPblock = [], [] title = plot mode = 1 k = 0 if dec_key not in plot_data.columns: print("-W- No dec/inc data") continue # get all records where dec & inc values exist plot_data = plot_data[plot_data[dec_key].notnull() & plot_data[inc_key].notnull()] if plot_data.empty: continue # this sorting out is done in get_di_bock #if coord == '0': # geographic, use records with no tilt key (or tilt_key 0) # cond1 = plot_data[tilt_key].fillna('') == coord # cond2 = plot_data[tilt_key].isnull() # plot_data = plot_data[cond1 | cond2] #else: # not geographic coordinates, use only records with correct tilt_key # plot_data = plot_data[plot_data[tilt_key] == coord] # get metadata for naming the plot file locations = data_container.get_name('location', df_slice=plot_data) site = data_container.get_name('site', df_slice=plot_data) sample = data_container.get_name('sample', df_slice=plot_data) specimen = data_container.get_name('specimen', df_slice=plot_data) # make sure method_codes is in plot_data if 'method_codes' not in plot_data.columns: plot_data['method_codes'] = '' # get data blocks DIblock = data_container.get_di_block(df_slice=plot_data, tilt_corr=coord, excl=['DE-BFP']) #SLblock = [[ind, row['method_codes']] for ind, row in plot_data.iterrows()] # get great circles great_circle_data = data_container.get_records_for_code('DE-BFP', incl=True, use_slice=True, sli=plot_data) if len(great_circle_data) > 0: gc_cond = great_circle_data[tilt_key] == coord GCblock = [[float(row[dec_key]), float(row[inc_key])] for ind, row in great_circle_data[gc_cond].iterrows()] #SPblock = [[ind, row['method_codes']] for ind, row in great_circle_data[gc_cond].iterrows()] if len(DIblock) > 0: if contour == 0: pmagplotlib.plotEQ(FIG['eqarea'], DIblock, title) else: pmagplotlib.plotEQcont(FIG['eqarea'], DIblock) else: pmagplotlib.plotNET(FIG['eqarea']) if len(GCblock)>0: for rec in GCblock: pmagplotlib.plotC(FIG['eqarea'], rec, 90., 'g') if len(DIblock) == 0 and len(GCblock) == 0: if verbose: print("no records for plotting") continue #sys.exit() if plotE == 1: ppars = pmag.doprinc(DIblock) # get principal directions nDIs, rDIs, npars, rpars = [], [], [], [] for rec in DIblock: angle=pmag.angle([rec[0],rec[1]],[ppars['dec'],ppars['inc']]) if angle>90.: rDIs.append(rec) else: nDIs.append(rec) if dist=='B': # do on whole dataset etitle="Bingham confidence ellipse" bpars=pmag.dobingham(DIblock) for key in list(bpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(bpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(bpars[key])) npars.append(bpars['dec']) npars.append(bpars['inc']) npars.append(bpars['Zeta']) npars.append(bpars['Zdec']) npars.append(bpars['Zinc']) npars.append(bpars['Eta']) npars.append(bpars['Edec']) npars.append(bpars['Einc']) if dist=='F': etitle="Fisher confidence cone" if len(nDIs)>2: fpars=pmag.fisher_mean(nDIs) for key in list(fpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(fpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(fpars[key])) mode+=1 npars.append(fpars['dec']) npars.append(fpars['inc']) npars.append(fpars['alpha95']) # Beta npars.append(fpars['dec']) isign=old_div(abs(fpars['inc']),fpars['inc']) npars.append(fpars['inc']-isign*90.) #Beta inc npars.append(fpars['alpha95']) # gamma npars.append(fpars['dec']+90.) # Beta dec npars.append(0.) #Beta inc if len(rDIs)>2: fpars=pmag.fisher_mean(rDIs) if verbose: print("mode ",mode) for key in list(fpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(fpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(fpars[key])) mode+=1 rpars.append(fpars['dec']) rpars.append(fpars['inc']) rpars.append(fpars['alpha95']) # Beta rpars.append(fpars['dec']) isign=old_div(abs(fpars['inc']),fpars['inc']) rpars.append(fpars['inc']-isign*90.) #Beta inc rpars.append(fpars['alpha95']) # gamma rpars.append(fpars['dec']+90.) # Beta dec rpars.append(0.) #Beta inc if dist=='K': etitle="Kent confidence ellipse" if len(nDIs)>3: kpars=pmag.dokent(nDIs,len(nDIs)) if verbose: print("mode ",mode) for key in list(kpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(kpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(kpars[key])) mode+=1 npars.append(kpars['dec']) npars.append(kpars['inc']) npars.append(kpars['Zeta']) npars.append(kpars['Zdec']) npars.append(kpars['Zinc']) npars.append(kpars['Eta']) npars.append(kpars['Edec']) npars.append(kpars['Einc']) if len(rDIs)>3: kpars=pmag.dokent(rDIs,len(rDIs)) if verbose: print("mode ",mode) for key in list(kpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(kpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(kpars[key])) mode+=1 rpars.append(kpars['dec']) rpars.append(kpars['inc']) rpars.append(kpars['Zeta']) rpars.append(kpars['Zdec']) rpars.append(kpars['Zinc']) rpars.append(kpars['Eta']) rpars.append(kpars['Edec']) rpars.append(kpars['Einc']) else: # assume bootstrap if dist=='BE': if len(nDIs)>5: BnDIs=pmag.di_boot(nDIs) Bkpars=pmag.dokent(BnDIs,1.) if verbose: print("mode ",mode) for key in list(Bkpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(Bkpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(Bkpars[key])) mode+=1 npars.append(Bkpars['dec']) npars.append(Bkpars['inc']) npars.append(Bkpars['Zeta']) npars.append(Bkpars['Zdec']) npars.append(Bkpars['Zinc']) npars.append(Bkpars['Eta']) npars.append(Bkpars['Edec']) npars.append(Bkpars['Einc']) if len(rDIs)>5: BrDIs=pmag.di_boot(rDIs) Bkpars=pmag.dokent(BrDIs,1.) if verbose: print("mode ",mode) for key in list(Bkpars.keys()): if key!='n' and verbose: print(" ",key, '%7.1f'%(Bkpars[key])) if key=='n' and verbose: print(" ",key, ' %i'%(Bkpars[key])) mode+=1 rpars.append(Bkpars['dec']) rpars.append(Bkpars['inc']) rpars.append(Bkpars['Zeta']) rpars.append(Bkpars['Zdec']) rpars.append(Bkpars['Zinc']) rpars.append(Bkpars['Eta']) rpars.append(Bkpars['Edec']) rpars.append(Bkpars['Einc']) etitle="Bootstrapped confidence ellipse" elif dist=='BV': sym={'lower':['o','c'],'upper':['o','g'],'size':3,'edgecolor':'face'} if len(nDIs)>5: BnDIs=pmag.di_boot(nDIs) pmagplotlib.plotEQsym(FIG['bdirs'],BnDIs,'Bootstrapped Eigenvectors', sym) if len(rDIs)>5: BrDIs=pmag.di_boot(rDIs) if len(nDIs)>5: # plot on existing plots pmagplotlib.plotDIsym(FIG['bdirs'],BrDIs,sym) else: pmagplotlib.plotEQ(FIG['bdirs'],BrDIs,'Bootstrapped Eigenvectors') if dist=='B': if len(nDIs)> 3 or len(rDIs)>3: pmagplotlib.plotCONF(FIG['eqarea'],etitle,[],npars,0) elif len(nDIs)>3 and dist!='BV': pmagplotlib.plotCONF(FIG['eqarea'],etitle,[],npars,0) if len(rDIs)>3: pmagplotlib.plotCONF(FIG['eqarea'],etitle,[],rpars,0) elif len(rDIs)>3 and dist!='BV': pmagplotlib.plotCONF(FIG['eqarea'],etitle,[],rpars,0) for key in list(FIG.keys()): files = {} filename = pmag.get_named_arg_from_sys('-fname') if filename: # use provided filename filename+= '.' + fmt elif pmagplotlib.isServer: # use server plot naming convention filename='LO:_'+locations+'_SI:_'+site+'_SA:_'+sample+'_SP:_'+specimen+'_CO:_'+crd+'_TY:_'+key+'_.'+fmt else: # use more readable naming convention filename = '' for item in [locations, site, sample, specimen, crd, key]: if item: item = item.replace(' ', '_') filename += item + '_' if filename.endswith('_'): filename = filename[:-1] filename += ".{}".format(fmt) files[key]=filename if pmagplotlib.isServer: black = '#000000' purple = '#800080' titles={} titles['eq']='Equal Area Plot' FIG = pmagplotlib.addBorders(FIG,titles,black,purple) pmagplotlib.saveP(FIG,files) if plt: pmagplotlib.saveP(FIG,files) continue if verbose: pmagplotlib.drawFIGS(FIG) ans=input(" S[a]ve to save plot, [q]uit, Return to continue: ") if ans == "q": sys.exit() if ans == "a": pmagplotlib.saveP(FIG,files) continue
def main(): """ NAME plotdi_e.py DESCRIPTION plots equal area projection from dec inc data and cones of confidence (Fisher, kent or Bingham or bootstrap). INPUT FORMAT takes dec/inc as first two columns in space delimited file SYNTAX plotdi_e.py [command line options] OPTIONS -h prints help message and quits -i for interactive parameter entry -f FILE, sets input filename on command line -Fish plots unit vector mean direction, alpha95 -Bing plots Principal direction, Bingham confidence ellipse -Kent plots unit vector mean direction, confidence ellipse -Boot E plots unit vector mean direction, bootstrapped confidence ellipse -Boot V plots unit vector mean direction, distribution of bootstrapped means """ dist='F' # default distribution is Fisherian mode=1 EQ={'eq':1} if len(sys.argv) > 0: if '-h' in sys.argv: # check if help is needed print main.__doc__ sys.exit() # graceful quit if '-i' in sys.argv: # ask for filename file=raw_input("Enter file name with dec, inc data: ") dist=raw_input("Enter desired distrubution: [Fish]er, [Bing]ham, [Kent] [Boot] [default is Fisher]: ") if dist=="":dist="F" if dist=="Boot": type=raw_input(" Ellipses or distribution of vectors? [E]/V ") if type=="" or type=="E": dist="BE" else: dist="BE" else: # if '-f' in sys.argv: ind=sys.argv.index('-f') file=sys.argv[ind+1] else: print 'you must specify a file name' print main.__doc__ sys.exit() if '-Bing' in sys.argv:dist='B' if '-Kent' in sys.argv:dist='K' if '-Boot' in sys.argv: ind=sys.argv.index('-Boot') type=sys.argv[ind+1] if type=='E': dist='BE' elif type=='V': dist='BV' EQ['bdirs']=2 pmagplotlib.plot_init(EQ['bdirs'],5,5) else: print main.__doc__ sys.exit() pmagplotlib.plot_init(EQ['eq'],5,5) # # get to work f=open(file,'r') data=f.readlines() # DIs= [] # set up list for dec inc data DiRecs=[] pars=[] nDIs,rDIs,npars,rpars=[],[],[],[] mode =1 for line in data: # read in the data from standard input DiRec={} rec=line.split() # split each line on space to get records DIs.append((float(rec[0]),float(rec[1]),1.)) DiRec['dec']=rec[0] DiRec['inc']=rec[1] DiRec['direction_type']='l' DiRecs.append(DiRec) # split into two modes ppars=pmag.doprinc(DIs) # get principal directions for rec in DIs: angle=pmag.angle([rec[0],rec[1]],[ppars['dec'],ppars['inc']]) if angle>90.: rDIs.append(rec) else: nDIs.append(rec) if dist=='B': # do on whole dataset title="Bingham confidence ellipse" bpars=pmag.dobingham(DIs) for key in bpars.keys(): if key!='n':print " ",key, '%7.1f'%(bpars[key]) if key=='n':print " ",key, ' %i'%(bpars[key]) npars.append(bpars['dec']) npars.append(bpars['inc']) npars.append(bpars['Zeta']) npars.append(bpars['Zdec']) npars.append(bpars['Zinc']) npars.append(bpars['Eta']) npars.append(bpars['Edec']) npars.append(bpars['Einc']) if dist=='F': title="Fisher confidence cone" if len(nDIs)>3: fpars=pmag.fisher_mean(nDIs) print "mode ",mode for key in fpars.keys(): if key!='n':print " ",key, '%7.1f'%(fpars[key]) if key=='n':print " ",key, ' %i'%(fpars[key]) mode+=1 npars.append(fpars['dec']) npars.append(fpars['inc']) npars.append(fpars['alpha95']) # Beta npars.append(fpars['dec']) isign=abs(fpars['inc'])/fpars['inc'] npars.append(fpars['inc']-isign*90.) #Beta inc npars.append(fpars['alpha95']) # gamma npars.append(fpars['dec']+90.) # Beta dec npars.append(0.) #Beta inc if len(rDIs)>3: fpars=pmag.fisher_mean(rDIs) print "mode ",mode for key in fpars.keys(): if key!='n':print " ",key, '%7.1f'%(fpars[key]) if key=='n':print " ",key, ' %i'%(fpars[key]) mode+=1 rpars.append(fpars['dec']) rpars.append(fpars['inc']) rpars.append(fpars['alpha95']) # Beta rpars.append(fpars['dec']) isign=abs(fpars['inc'])/fpars['inc'] rpars.append(fpars['inc']-isign*90.) #Beta inc rpars.append(fpars['alpha95']) # gamma rpars.append(fpars['dec']+90.) # Beta dec rpars.append(0.) #Beta inc if dist=='K': title="Kent confidence ellipse" if len(nDIs)>3: kpars=pmag.dokent(nDIs,len(nDIs)) print "mode ",mode for key in kpars.keys(): if key!='n':print " ",key, '%7.1f'%(kpars[key]) if key=='n':print " ",key, ' %i'%(kpars[key]) mode+=1 npars.append(kpars['dec']) npars.append(kpars['inc']) npars.append(kpars['Zeta']) npars.append(kpars['Zdec']) npars.append(kpars['Zinc']) npars.append(kpars['Eta']) npars.append(kpars['Edec']) npars.append(kpars['Einc']) if len(rDIs)>3: kpars=pmag.dokent(rDIs,len(rDIs)) print "mode ",mode for key in kpars.keys(): if key!='n':print " ",key, '%7.1f'%(kpars[key]) if key=='n':print " ",key, ' %i'%(kpars[key]) mode+=1 rpars.append(kpars['dec']) rpars.append(kpars['inc']) rpars.append(kpars['Zeta']) rpars.append(kpars['Zdec']) rpars.append(kpars['Zinc']) rpars.append(kpars['Eta']) rpars.append(kpars['Edec']) rpars.append(kpars['Einc']) else: # assume bootstrap if dist=='BE': if len(nDIs)>5: BnDIs=pmag.di_boot(nDIs) Bkpars=pmag.dokent(BnDIs,1.) print "mode ",mode for key in Bkpars.keys(): if key!='n':print " ",key, '%7.1f'%(Bkpars[key]) if key=='n':print " ",key, ' %i'%(Bkpars[key]) mode+=1 npars.append(Bkpars['dec']) npars.append(Bkpars['inc']) npars.append(Bkpars['Zeta']) npars.append(Bkpars['Zdec']) npars.append(Bkpars['Zinc']) npars.append(Bkpars['Eta']) npars.append(Bkpars['Edec']) npars.append(Bkpars['Einc']) if len(rDIs)>5: BrDIs=pmag.di_boot(rDIs) Bkpars=pmag.dokent(BrDIs,1.) print "mode ",mode for key in Bkpars.keys(): if key!='n':print " ",key, '%7.1f'%(Bkpars[key]) if key=='n':print " ",key, ' %i'%(Bkpars[key]) mode+=1 rpars.append(Bkpars['dec']) rpars.append(Bkpars['inc']) rpars.append(Bkpars['Zeta']) rpars.append(Bkpars['Zdec']) rpars.append(Bkpars['Zinc']) rpars.append(Bkpars['Eta']) rpars.append(Bkpars['Edec']) rpars.append(Bkpars['Einc']) title="Bootstrapped confidence ellipse" elif dist=='BV': if len(nDIs)>5: pmagplotlib.plotEQ(EQ['eq'],nDIs,'Data') BnDIs=pmag.di_boot(nDIs) pmagplotlib.plotEQ(EQ['bdirs'],BnDIs,'Bootstrapped Eigenvectors') if len(rDIs)>5: BrDIs=pmag.di_boot(rDIs) if len(nDIs)>5: # plot on existing plots pmagplotlib.plotDI(EQ['eq'],rDIs) pmagplotlib.plotDI(EQ['bdirs'],BrDIs) else: pmagplotlib.plotEQ(EQ['eq'],rDIs,'Data') pmagplotlib.plotEQ(EQ['bdirs'],BrDIs,'Bootstrapped Eigenvectors') pmagplotlib.drawFIGS(EQ) ans=raw_input('s[a]ve, [q]uit ') if ans=='q':sys.exit() if ans=='a': files={} for key in EQ.keys(): files[key]='BE_'+key+'.svg' pmagplotlib.saveP(EQ,files) sys.exit() if len(nDIs)>5: pmagplotlib.plotCONF(EQ['eq'],title,DiRecs,npars,1) if len(rDIs)>5 and dist!='B': pmagplotlib.plotCONF(EQ['eq'],title,[],rpars,0) elif len(rDIs)>5 and dist!='B': pmagplotlib.plotCONF(EQ['eq'],title,DiRecs,rpars,1) pmagplotlib.drawFIGS(EQ) ans=raw_input('s[a]ve, [q]uit ') if ans=='q':sys.exit() if ans=='a': files={} for key in EQ.keys(): files[key]=key+'.svg' pmagplotlib.saveP(EQ,files)
def main(): """ NAME eqarea_magic.py DESCRIPTION makes equal area projections from declination/inclination data SYNTAX eqarea_magic.py [command line options] INPUT takes magic formatted pmag_results, pmag_sites, pmag_samples or pmag_specimens OPTIONS -h prints help message and quits -f FILE: specify input magic format file from magic,default='pmag_results.txt' supported types=[magic_measurements,pmag_specimens, pmag_samples, pmag_sites, pmag_results, magic_web] -obj OBJ: specify level of plot [all, sit, sam, spc], default is all -crd [s,g,t]: specify coordinate system, [s]pecimen, [g]eographic, [t]ilt adjusted default is geographic, unspecified assumed geographic -fmt [svg,png,jpg] format for output plots -ell [F,K,B,Be,Bv] plot Fisher, Kent, Bingham, Bootstrap ellipses or Boostrap eigenvectors -c plot as colour contour -sav save plot and quit quietly NOTE all: entire file; sit: site; sam: sample; spc: specimen """ FIG = {} # plot dictionary FIG['eqarea'] = 1 # eqarea is figure 1 in_file, plot_key, coord, crd = 'pmag_results.txt', 'all', "0", 'g' plotE, contour = 0, 0 dir_path = '.' fmt = 'svg' verbose = pmagplotlib.verbose if '-h' in sys.argv: print(main.__doc__) sys.exit() if '-WD' in sys.argv: ind = sys.argv.index('-WD') dir_path = sys.argv[ind+1] pmagplotlib.plot_init(FIG['eqarea'], 5, 5) if '-f' in sys.argv: ind = sys.argv.index("-f") in_file = dir_path+"/"+sys.argv[ind+1] if '-obj' in sys.argv: ind = sys.argv.index('-obj') plot_by = sys.argv[ind+1] if plot_by == 'all': plot_key = 'all' if plot_by == 'sit': plot_key = 'er_site_name' if plot_by == 'sam': plot_key = 'er_sample_name' if plot_by == 'spc': plot_key = 'er_specimen_name' if '-c' in sys.argv: contour = 1 plt = 0 if '-sav' in sys.argv: plt = 1 verbose = 0 if '-ell' in sys.argv: plotE = 1 ind = sys.argv.index('-ell') ell_type = sys.argv[ind+1] if ell_type == 'F': dist = 'F' if ell_type == 'K': dist = 'K' if ell_type == 'B': dist = 'B' if ell_type == 'Be': dist = 'BE' if ell_type == 'Bv': dist = 'BV' FIG['bdirs'] = 2 pmagplotlib.plot_init(FIG['bdirs'], 5, 5) if '-crd' in sys.argv: ind = sys.argv.index("-crd") crd = sys.argv[ind+1] if crd == 's': coord = "-1" if crd == 'g': coord = "0" if crd == 't': coord = "100" if '-fmt' in sys.argv: ind = sys.argv.index("-fmt") fmt = sys.argv[ind+1] Dec_keys = ['site_dec', 'sample_dec', 'specimen_dec', 'measurement_dec', 'average_dec', 'none'] Inc_keys = ['site_inc', 'sample_inc', 'specimen_inc', 'measurement_inc', 'average_inc', 'none'] Tilt_keys = ['tilt_correction', 'site_tilt_correction', 'sample_tilt_correction', 'specimen_tilt_correction', 'none'] Dir_type_keys = ['', 'site_direction_type', 'sample_direction_type', 'specimen_direction_type'] Name_keys = ['er_specimen_name', 'er_sample_name', 'er_site_name', 'pmag_result_name'] data, file_type = pmag.magic_read(in_file) if file_type == 'pmag_results' and plot_key != "all": plot_key = plot_key+'s' # need plural for results table if verbose: print(len(data), ' records read from ', in_file) # # # find desired dec,inc data: # dir_type_key = '' # # get plotlist if not plotting all records # plotlist = [] if plot_key != "all": plots = pmag.get_dictitem(data, plot_key, '', 'F') for rec in plots: if rec[plot_key] not in plotlist: plotlist.append(rec[plot_key]) plotlist.sort() else: plotlist.append('All') for plot in plotlist: # if verbose: print plot DIblock = [] GCblock = [] SLblock, SPblock = [], [] title = plot mode = 1 dec_key, inc_key, tilt_key, name_key, k = "", "", "", "", 0 if plot != "All": odata = pmag.get_dictitem(data, plot_key, plot, 'T') else: odata = data # data for this obj for dec_key in Dec_keys: # get all records with this dec_key not blank Decs = pmag.get_dictitem(odata, dec_key, '', 'F') if len(Decs) > 0: break for inc_key in Inc_keys: # get all records with this inc_key not blank Incs = pmag.get_dictitem(Decs, inc_key, '', 'F') if len(Incs) > 0: break for tilt_key in Tilt_keys: if tilt_key in Incs[0].keys(): break # find the tilt_key for these records if tilt_key == 'none': # no tilt key in data, need to fix this with fake data which will be unknown tilt tilt_key = 'tilt_correction' for rec in Incs: rec[tilt_key] = '' # get all records matching specified coordinate system cdata = pmag.get_dictitem(Incs, tilt_key, coord, 'T') if coord == '0': # geographic # get all the blank records - assume geographic udata = pmag.get_dictitem(Incs, tilt_key, '', 'T') if len(cdata) == 0: crd = '' if len(udata) > 0: for d in udata: cdata.append(d) crd = crd+'u' for name_key in Name_keys: # get all records with this name_key not blank Names = pmag.get_dictitem(cdata, name_key, '', 'F') if len(Names) > 0: break for dir_type_key in Dir_type_keys: # get all records with this direction type Dirs = pmag.get_dictitem(cdata, dir_type_key, '', 'F') if len(Dirs) > 0: break if dir_type_key == "": dir_type_key = 'direction_type' locations, site, sample, specimen = "", "", "", "" for rec in cdata: # pick out the data if 'er_location_name' in rec.keys() and rec['er_location_name'] != "" and rec['er_location_name'] not in locations: locations = locations + \ rec['er_location_name'].replace("/", "")+"_" if 'er_location_names' in rec.keys() and rec['er_location_names'] != "": locs = rec['er_location_names'].split(':') for loc in locs: if loc not in locations: locations = locations+loc.replace("/", "")+'_' if plot_key == 'er_site_name' or plot_key == 'er_sample_name' or plot_key == 'er_specimen_name': site = rec['er_site_name'] if plot_key == 'er_sample_name' or plot_key == 'er_specimen_name': sample = rec['er_sample_name'] if plot_key == 'er_specimen_name': specimen = rec['er_specimen_name'] if plot_key == 'er_site_names' or plot_key == 'er_sample_names' or plot_key == 'er_specimen_names': site = rec['er_site_names'] if plot_key == 'er_sample_names' or plot_key == 'er_specimen_names': sample = rec['er_sample_names'] if plot_key == 'er_specimen_names': specimen = rec['er_specimen_names'] if dir_type_key not in rec.keys() or rec[dir_type_key] == "": rec[dir_type_key] = 'l' if 'magic_method_codes' not in rec.keys(): rec['magic_method_codes'] = "" DIblock.append([float(rec[dec_key]), float(rec[inc_key])]) SLblock.append([rec[name_key], rec['magic_method_codes']]) if rec[tilt_key] == coord and rec[dir_type_key] != 'l' and rec[dec_key] != "" and rec[inc_key] != "": GCblock.append([float(rec[dec_key]), float(rec[inc_key])]) SPblock.append([rec[name_key], rec['magic_method_codes']]) if len(DIblock) == 0 and len(GCblock) == 0: if verbose: print("no records for plotting") sys.exit() if verbose: for k in range(len(SLblock)): print('%s %s %7.1f %7.1f' % ( SLblock[k][0], SLblock[k][1], DIblock[k][0], DIblock[k][1])) for k in range(len(SPblock)): print('%s %s %7.1f %7.1f' % ( SPblock[k][0], SPblock[k][1], GCblock[k][0], GCblock[k][1])) if len(DIblock) > 0: if contour == 0: pmagplotlib.plot_eq(FIG['eqarea'], DIblock, title) else: pmagplotlib.plot_eq_cont(FIG['eqarea'], DIblock) else: pmagplotlib.plot_net(FIG['eqarea']) if len(GCblock) > 0: for rec in GCblock: pmagplotlib.plot_circ(FIG['eqarea'], rec, 90., 'g') if plotE == 1: ppars = pmag.doprinc(DIblock) # get principal directions nDIs, rDIs, npars, rpars = [], [], [], [] for rec in DIblock: angle = pmag.angle([rec[0], rec[1]], [ ppars['dec'], ppars['inc']]) if angle > 90.: rDIs.append(rec) else: nDIs.append(rec) if dist == 'B': # do on whole dataset etitle = "Bingham confidence ellipse" bpars = pmag.dobingham(DIblock) for key in bpars.keys(): if key != 'n' and verbose: print(" ", key, '%7.1f' % (bpars[key])) if key == 'n' and verbose: print(" ", key, ' %i' % (bpars[key])) npars.append(bpars['dec']) npars.append(bpars['inc']) npars.append(bpars['Zeta']) npars.append(bpars['Zdec']) npars.append(bpars['Zinc']) npars.append(bpars['Eta']) npars.append(bpars['Edec']) npars.append(bpars['Einc']) if dist == 'F': etitle = "Fisher confidence cone" if len(nDIs) > 2: fpars = pmag.fisher_mean(nDIs) for key in fpars.keys(): if key != 'n' and verbose: print(" ", key, '%7.1f' % (fpars[key])) if key == 'n' and verbose: print(" ", key, ' %i' % (fpars[key])) mode += 1 npars.append(fpars['dec']) npars.append(fpars['inc']) npars.append(fpars['alpha95']) # Beta npars.append(fpars['dec']) isign = abs(fpars['inc'])/fpars['inc'] npars.append(fpars['inc']-isign*90.) # Beta inc npars.append(fpars['alpha95']) # gamma npars.append(fpars['dec']+90.) # Beta dec npars.append(0.) # Beta inc if len(rDIs) > 2: fpars = pmag.fisher_mean(rDIs) if verbose: print("mode ", mode) for key in fpars.keys(): if key != 'n' and verbose: print(" ", key, '%7.1f' % (fpars[key])) if key == 'n' and verbose: print(" ", key, ' %i' % (fpars[key])) mode += 1 rpars.append(fpars['dec']) rpars.append(fpars['inc']) rpars.append(fpars['alpha95']) # Beta rpars.append(fpars['dec']) isign = abs(fpars['inc'])/fpars['inc'] rpars.append(fpars['inc']-isign*90.) # Beta inc rpars.append(fpars['alpha95']) # gamma rpars.append(fpars['dec']+90.) # Beta dec rpars.append(0.) # Beta inc if dist == 'K': etitle = "Kent confidence ellipse" if len(nDIs) > 3: kpars = pmag.dokent(nDIs, len(nDIs)) if verbose: print("mode ", mode) for key in kpars.keys(): if key != 'n' and verbose: print(" ", key, '%7.1f' % (kpars[key])) if key == 'n' and verbose: print(" ", key, ' %i' % (kpars[key])) mode += 1 npars.append(kpars['dec']) npars.append(kpars['inc']) npars.append(kpars['Zeta']) npars.append(kpars['Zdec']) npars.append(kpars['Zinc']) npars.append(kpars['Eta']) npars.append(kpars['Edec']) npars.append(kpars['Einc']) if len(rDIs) > 3: kpars = pmag.dokent(rDIs, len(rDIs)) if verbose: print("mode ", mode) for key in kpars.keys(): if key != 'n' and verbose: print(" ", key, '%7.1f' % (kpars[key])) if key == 'n' and verbose: print(" ", key, ' %i' % (kpars[key])) mode += 1 rpars.append(kpars['dec']) rpars.append(kpars['inc']) rpars.append(kpars['Zeta']) rpars.append(kpars['Zdec']) rpars.append(kpars['Zinc']) rpars.append(kpars['Eta']) rpars.append(kpars['Edec']) rpars.append(kpars['Einc']) else: # assume bootstrap if dist == 'BE': if len(nDIs) > 5: BnDIs = pmag.di_boot(nDIs) Bkpars = pmag.dokent(BnDIs, 1.) if verbose: print("mode ", mode) for key in Bkpars.keys(): if key != 'n' and verbose: print(" ", key, '%7.1f' % (Bkpars[key])) if key == 'n' and verbose: print(" ", key, ' %i' % (Bkpars[key])) mode += 1 npars.append(Bkpars['dec']) npars.append(Bkpars['inc']) npars.append(Bkpars['Zeta']) npars.append(Bkpars['Zdec']) npars.append(Bkpars['Zinc']) npars.append(Bkpars['Eta']) npars.append(Bkpars['Edec']) npars.append(Bkpars['Einc']) if len(rDIs) > 5: BrDIs = pmag.di_boot(rDIs) Bkpars = pmag.dokent(BrDIs, 1.) if verbose: print("mode ", mode) for key in Bkpars.keys(): if key != 'n' and verbose: print(" ", key, '%7.1f' % (Bkpars[key])) if key == 'n' and verbose: print(" ", key, ' %i' % (Bkpars[key])) mode += 1 rpars.append(Bkpars['dec']) rpars.append(Bkpars['inc']) rpars.append(Bkpars['Zeta']) rpars.append(Bkpars['Zdec']) rpars.append(Bkpars['Zinc']) rpars.append(Bkpars['Eta']) rpars.append(Bkpars['Edec']) rpars.append(Bkpars['Einc']) etitle = "Bootstrapped confidence ellipse" elif dist == 'BV': sym = {'lower': ['o', 'c'], 'upper': [ 'o', 'g'], 'size': 3, 'edgecolor': 'face'} if len(nDIs) > 5: BnDIs = pmag.di_boot(nDIs) pmagplotlib.plot_eq_sym( FIG['bdirs'], BnDIs, 'Bootstrapped Eigenvectors', sym) if len(rDIs) > 5: BrDIs = pmag.di_boot(rDIs) if len(nDIs) > 5: # plot on existing plots pmagplotlib.plot_di_sym(FIG['bdirs'], BrDIs, sym) else: pmagplotlib.plot_eq( FIG['bdirs'], BrDIs, 'Bootstrapped Eigenvectors') if dist == 'B': if len(nDIs) > 3 or len(rDIs) > 3: pmagplotlib.plot_conf(FIG['eqarea'], etitle, [], npars, 0) elif len(nDIs) > 3 and dist != 'BV': pmagplotlib.plot_conf(FIG['eqarea'], etitle, [], npars, 0) if len(rDIs) > 3: pmagplotlib.plot_conf(FIG['eqarea'], etitle, [], rpars, 0) elif len(rDIs) > 3 and dist != 'BV': pmagplotlib.plot_conf(FIG['eqarea'], etitle, [], rpars, 0) if verbose: pmagplotlib.draw_figs(FIG) # files = {} locations = locations[:-1] for key in FIG.keys(): if pmagplotlib.isServer: # use server plot naming convention filename = 'LO:_'+locations+'_SI:_'+site+'_SA:_'+sample + \ '_SP:_'+specimen+'_CO:_'+crd+'_TY:_'+key+'_.'+fmt else: # use more readable plot naming convention filename = '' for item in [locations, site, sample, specimen, crd, key]: if item: item = item.replace(' ', '_') filename += item + '_' if filename.endswith('_'): filename = filename[:-1] filename += ".{}".format(fmt) files[key] = filename if pmagplotlib.isServer: black = '#000000' purple = '#800080' titles = {} titles['eq'] = 'Equal Area Plot' FIG = pmagplotlib.add_borders(FIG, titles, black, purple) pmagplotlib.save_plots(FIG, files) elif verbose: ans = raw_input( " S[a]ve to save plot, [q]uit, Return to continue: ") if ans == "q": sys.exit() if ans == "a": pmagplotlib.save_plots(FIG, files) if plt: pmagplotlib.save_plots(FIG, files)
def main(): """ NAME eqarea_magic.py DESCRIPTION makes equal area projections from declination/inclination data SYNTAX eqarea_magic.py [command line options] INPUT takes magic formatted pmag_results, pmag_sites, pmag_samples or pmag_specimens OPTIONS -h prints help message and quits -f FILE: specify input magic format file from magic,default='pmag_results.txt' supported types=[magic_measurements,pmag_specimens, pmag_samples, pmag_sites, pmag_results, magic_web] -obj OBJ: specify level of plot [all, sit, sam, spc], default is all -crd [s,g,t]: specify coordinate system, [s]pecimen, [g]eographic, [t]ilt adjusted default is geographic, unspecified assumed geographic -fmt [svg,png,jpg] format for output plots -ell [F,K,B,Be,Bv] plot Fisher, Kent, Bingham, Bootstrap ellipses or Boostrap eigenvectors -c plot as colour contour -sav save plot and quit quietly NOTE all: entire file; sit: site; sam: sample; spc: specimen """ FIG={} # plot dictionary FIG['eqarea']=1 # eqarea is figure 1 in_file,plot_key,coord,crd='pmag_results.txt','all',"0",'g' plotE,contour=0,0 dir_path='.' fmt='svg' verbose=pmagplotlib.verbose if '-h' in sys.argv: print main.__doc__ sys.exit() if '-WD' in sys.argv: ind=sys.argv.index('-WD') dir_path=sys.argv[ind+1] pmagplotlib.plot_init(FIG['eqarea'],5,5) if '-f' in sys.argv: ind=sys.argv.index("-f") in_file=dir_path+"/"+sys.argv[ind+1] if '-obj' in sys.argv: ind=sys.argv.index('-obj') plot_by=sys.argv[ind+1] if plot_by=='all':plot_key='all' if plot_by=='sit':plot_key='er_site_name' if plot_by=='sam':plot_key='er_sample_name' if plot_by=='spc':plot_key='er_specimen_name' if '-c' in sys.argv: contour=1 plt=0 if '-sav' in sys.argv: plt=1 verbose=0 if '-ell' in sys.argv: plotE=1 ind=sys.argv.index('-ell') ell_type=sys.argv[ind+1] if ell_type=='F':dist='F' if ell_type=='K':dist='K' if ell_type=='B':dist='B' if ell_type=='Be':dist='BE' if ell_type=='Bv': dist='BV' FIG['bdirs']=2 pmagplotlib.plot_init(FIG['bdirs'],5,5) if '-crd' in sys.argv: ind=sys.argv.index("-crd") crd=sys.argv[ind+1] if crd=='s':coord="-1" if crd=='g':coord="0" if crd=='t':coord="100" if '-fmt' in sys.argv: ind=sys.argv.index("-fmt") fmt=sys.argv[ind+1] Dec_keys=['site_dec','sample_dec','specimen_dec','measurement_dec','average_dec','none'] Inc_keys=['site_inc','sample_inc','specimen_inc','measurement_inc','average_inc','none'] Tilt_keys=['tilt_correction','site_tilt_correction','sample_tilt_correction','specimen_tilt_correction','none'] Dir_type_keys=['','site_direction_type','sample_direction_type','specimen_direction_type'] Name_keys=['er_specimen_name','er_sample_name','er_site_name','pmag_result_name'] data,file_type=pmag.magic_read(in_file) if file_type=='pmag_results' and plot_key!="all":plot_key=plot_key+'s' # need plural for results table if verbose: print len(data),' records read from ',in_file # # # find desired dec,inc data: # dir_type_key='' # # get plotlist if not plotting all records # plotlist=[] if plot_key!="all": plots=pmag.get_dictitem(data,plot_key,'','F') for rec in plots: if rec[plot_key] not in plotlist: plotlist.append(rec[plot_key]) plotlist.sort() else: plotlist.append('All') for plot in plotlist: #if verbose: print plot DIblock=[] GCblock=[] SLblock,SPblock=[],[] title=plot mode=1 dec_key,inc_key,tilt_key,name_key,k="","","","",0 if plot!="All": odata=pmag.get_dictitem(data,plot_key,plot,'T') else: odata=data # data for this obj for dec_key in Dec_keys: Decs=pmag.get_dictitem(odata,dec_key,'','F') # get all records with this dec_key not blank if len(Decs)>0: break for inc_key in Inc_keys: Incs=pmag.get_dictitem(Decs,inc_key,'','F') # get all records with this inc_key not blank if len(Incs)>0: break for tilt_key in Tilt_keys: if tilt_key in Incs[0].keys(): break # find the tilt_key for these records if tilt_key=='none': # no tilt key in data, need to fix this with fake data which will be unknown tilt tilt_key='tilt_correction' for rec in Incs:rec[tilt_key]='' cdata=pmag.get_dictitem(Incs,tilt_key,coord,'T') # get all records matching specified coordinate system if coord=='0': # geographic udata=pmag.get_dictitem(Incs,tilt_key,'','T') # get all the blank records - assume geographic if len(cdata)==0: crd='' if len(udata)>0: for d in udata:cdata.append(d) crd=crd+'u' for name_key in Name_keys: Names=pmag.get_dictitem(cdata,name_key,'','F') # get all records with this name_key not blank if len(Names)>0: break for dir_type_key in Dir_type_keys: Dirs=pmag.get_dictitem(cdata,dir_type_key,'','F') # get all records with this direction type if len(Dirs)>0: break if dir_type_key=="":dir_type_key='direction_type' locations,site,sample,specimen="","","","" for rec in cdata: # pick out the data if 'er_location_name' in rec.keys() and rec['er_location_name']!="" and rec['er_location_name'] not in locations:locations=locations+rec['er_location_name'].replace("/","")+"_" if 'er_location_names' in rec.keys() and rec['er_location_names']!="": locs=rec['er_location_names'].split(':') for loc in locs: if loc not in locations:locations=locations+loc.replace("/","")+'_' if plot_key=='er_site_name' or plot_key=='er_sample_name' or plot_key=='er_specimen_name': site=rec['er_site_name'] if plot_key=='er_sample_name' or plot_key=='er_specimen_name': sample=rec['er_sample_name'] if plot_key=='er_specimen_name': specimen=rec['er_specimen_name'] if plot_key=='er_site_names' or plot_key=='er_sample_names' or plot_key=='er_specimen_names': site=rec['er_site_names'] if plot_key=='er_sample_names' or plot_key=='er_specimen_names': sample=rec['er_sample_names'] if plot_key=='er_specimen_names': specimen=rec['er_specimen_names'] if dir_type_key not in rec.keys() or rec[dir_type_key]=="":rec[dir_type_key]='l' if 'magic_method_codes' not in rec.keys():rec['magic_method_codes']="" DIblock.append([float(rec[dec_key]),float(rec[inc_key])]) SLblock.append([rec[name_key],rec['magic_method_codes']]) if rec[tilt_key]==coord and rec[dir_type_key]!='l' and rec[dec_key]!="" and rec[inc_key]!="": GCblock.append([float(rec[dec_key]),float(rec[inc_key])]) SPblock.append([rec[name_key],rec['magic_method_codes']]) if len(DIblock)==0 and len(GCblock)==0: if verbose: print "no records for plotting" sys.exit() if verbose: for k in range(len(SLblock)): print '%s %s %7.1f %7.1f'%(SLblock[k][0],SLblock[k][1],DIblock[k][0],DIblock[k][1]) for k in range(len(SPblock)): print '%s %s %7.1f %7.1f'%(SPblock[k][0],SPblock[k][1],GCblock[k][0],GCblock[k][1]) if len(DIblock)>0: if contour==0: pmagplotlib.plotEQ(FIG['eqarea'],DIblock,title) else: pmagplotlib.plotEQcont(FIG['eqarea'],DIblock) else: pmagplotlib.plotNET(FIG['eqarea']) if len(GCblock)>0: for rec in GCblock: pmagplotlib.plotC(FIG['eqarea'],rec,90.,'g') if plotE==1: ppars=pmag.doprinc(DIblock) # get principal directions nDIs,rDIs,npars,rpars=[],[],[],[] for rec in DIblock: angle=pmag.angle([rec[0],rec[1]],[ppars['dec'],ppars['inc']]) if angle>90.: rDIs.append(rec) else: nDIs.append(rec) if dist=='B': # do on whole dataset etitle="Bingham confidence ellipse" bpars=pmag.dobingham(DIblock) for key in bpars.keys(): if key!='n' and verbose:print " ",key, '%7.1f'%(bpars[key]) if key=='n' and verbose:print " ",key, ' %i'%(bpars[key]) npars.append(bpars['dec']) npars.append(bpars['inc']) npars.append(bpars['Zeta']) npars.append(bpars['Zdec']) npars.append(bpars['Zinc']) npars.append(bpars['Eta']) npars.append(bpars['Edec']) npars.append(bpars['Einc']) if dist=='F': etitle="Fisher confidence cone" if len(nDIs)>2: fpars=pmag.fisher_mean(nDIs) for key in fpars.keys(): if key!='n' and verbose:print " ",key, '%7.1f'%(fpars[key]) if key=='n' and verbose:print " ",key, ' %i'%(fpars[key]) mode+=1 npars.append(fpars['dec']) npars.append(fpars['inc']) npars.append(fpars['alpha95']) # Beta npars.append(fpars['dec']) isign=abs(fpars['inc'])/fpars['inc'] npars.append(fpars['inc']-isign*90.) #Beta inc npars.append(fpars['alpha95']) # gamma npars.append(fpars['dec']+90.) # Beta dec npars.append(0.) #Beta inc if len(rDIs)>2: fpars=pmag.fisher_mean(rDIs) if verbose:print "mode ",mode for key in fpars.keys(): if key!='n' and verbose:print " ",key, '%7.1f'%(fpars[key]) if key=='n' and verbose:print " ",key, ' %i'%(fpars[key]) mode+=1 rpars.append(fpars['dec']) rpars.append(fpars['inc']) rpars.append(fpars['alpha95']) # Beta rpars.append(fpars['dec']) isign=abs(fpars['inc'])/fpars['inc'] rpars.append(fpars['inc']-isign*90.) #Beta inc rpars.append(fpars['alpha95']) # gamma rpars.append(fpars['dec']+90.) # Beta dec rpars.append(0.) #Beta inc if dist=='K': etitle="Kent confidence ellipse" if len(nDIs)>3: kpars=pmag.dokent(nDIs,len(nDIs)) if verbose:print "mode ",mode for key in kpars.keys(): if key!='n' and verbose:print " ",key, '%7.1f'%(kpars[key]) if key=='n' and verbose:print " ",key, ' %i'%(kpars[key]) mode+=1 npars.append(kpars['dec']) npars.append(kpars['inc']) npars.append(kpars['Zeta']) npars.append(kpars['Zdec']) npars.append(kpars['Zinc']) npars.append(kpars['Eta']) npars.append(kpars['Edec']) npars.append(kpars['Einc']) if len(rDIs)>3: kpars=pmag.dokent(rDIs,len(rDIs)) if verbose:print "mode ",mode for key in kpars.keys(): if key!='n' and verbose:print " ",key, '%7.1f'%(kpars[key]) if key=='n' and verbose:print " ",key, ' %i'%(kpars[key]) mode+=1 rpars.append(kpars['dec']) rpars.append(kpars['inc']) rpars.append(kpars['Zeta']) rpars.append(kpars['Zdec']) rpars.append(kpars['Zinc']) rpars.append(kpars['Eta']) rpars.append(kpars['Edec']) rpars.append(kpars['Einc']) else: # assume bootstrap if dist=='BE': if len(nDIs)>5: BnDIs=pmag.di_boot(nDIs) Bkpars=pmag.dokent(BnDIs,1.) if verbose:print "mode ",mode for key in Bkpars.keys(): if key!='n' and verbose:print " ",key, '%7.1f'%(Bkpars[key]) if key=='n' and verbose:print " ",key, ' %i'%(Bkpars[key]) mode+=1 npars.append(Bkpars['dec']) npars.append(Bkpars['inc']) npars.append(Bkpars['Zeta']) npars.append(Bkpars['Zdec']) npars.append(Bkpars['Zinc']) npars.append(Bkpars['Eta']) npars.append(Bkpars['Edec']) npars.append(Bkpars['Einc']) if len(rDIs)>5: BrDIs=pmag.di_boot(rDIs) Bkpars=pmag.dokent(BrDIs,1.) if verbose:print "mode ",mode for key in Bkpars.keys(): if key!='n' and verbose:print " ",key, '%7.1f'%(Bkpars[key]) if key=='n' and verbose:print " ",key, ' %i'%(Bkpars[key]) mode+=1 rpars.append(Bkpars['dec']) rpars.append(Bkpars['inc']) rpars.append(Bkpars['Zeta']) rpars.append(Bkpars['Zdec']) rpars.append(Bkpars['Zinc']) rpars.append(Bkpars['Eta']) rpars.append(Bkpars['Edec']) rpars.append(Bkpars['Einc']) etitle="Bootstrapped confidence ellipse" elif dist=='BV': sym={'lower':['o','c'],'upper':['o','g'],'size':3,'edgecolor':'face'} if len(nDIs)>5: BnDIs=pmag.di_boot(nDIs) pmagplotlib.plotEQsym(FIG['bdirs'],BnDIs,'Bootstrapped Eigenvectors', sym) if len(rDIs)>5: BrDIs=pmag.di_boot(rDIs) if len(nDIs)>5: # plot on existing plots pmagplotlib.plotDIsym(FIG['bdirs'],BrDIs,sym) else: pmagplotlib.plotEQ(FIG['bdirs'],BrDIs,'Bootstrapped Eigenvectors') if dist=='B': if len(nDIs)> 3 or len(rDIs)>3: pmagplotlib.plotCONF(FIG['eqarea'],etitle,[],npars,0) elif len(nDIs)>3 and dist!='BV': pmagplotlib.plotCONF(FIG['eqarea'],etitle,[],npars,0) if len(rDIs)>3: pmagplotlib.plotCONF(FIG['eqarea'],etitle,[],rpars,0) elif len(rDIs)>3 and dist!='BV': pmagplotlib.plotCONF(FIG['eqarea'],etitle,[],rpars,0) if verbose:pmagplotlib.drawFIGS(FIG) # files={} locations=locations[:-1] for key in FIG.keys(): filename='LO:_'+locations+'_SI:_'+site+'_SA:_'+sample+'_SP:_'+specimen+'_CO:_'+crd+'_TY:_'+key+'_.'+fmt files[key]=filename if pmagplotlib.isServer: black = '#000000' purple = '#800080' titles={} titles['eq']='Equal Area Plot' FIG = pmagplotlib.addBorders(FIG,titles,black,purple) pmagplotlib.saveP(FIG,files) elif verbose: ans=raw_input(" S[a]ve to save plot, [q]uit, Return to continue: ") if ans=="q": sys.exit() if ans=="a": pmagplotlib.saveP(FIG,files) if plt: pmagplotlib.saveP(FIG,files)
def main(): """ NAME eqarea_ell.py DESCRIPTION makes equal area projections from declination/inclination data and plot ellipses SYNTAX eqarea_ell.py -h [command line options] INPUT takes space delimited Dec/Inc data OPTIONS -h prints help message and quits -f FILE -fmt [svg,png,jpg] format for output plots -sav saves figures and quits -ell [F,K,B,Be,Bv] plot Fisher, Kent, Bingham, Bootstrap ellipses or Boostrap eigenvectors """ FIG = {} # plot dictionary FIG['eq'] = 1 # eqarea is figure 1 fmt, dist, mode, plot = 'svg', 'F', 1, 0 sym = {'lower': ['o', 'r'], 'upper': ['o', 'w'], 'size': 10} plotE = 0 if '-h' in sys.argv: print(main.__doc__) sys.exit() pmagplotlib.plot_init(FIG['eq'], 5, 5) if '-sav' in sys.argv: plot = 1 if '-f' in sys.argv: ind = sys.argv.index("-f") title = sys.argv[ind + 1] data = numpy.loadtxt(title).transpose() if '-ell' in sys.argv: plotE = 1 ind = sys.argv.index('-ell') ell_type = sys.argv[ind + 1] if ell_type == 'F': dist = 'F' if ell_type == 'K': dist = 'K' if ell_type == 'B': dist = 'B' if ell_type == 'Be': dist = 'BE' if ell_type == 'Bv': dist = 'BV' FIG['bdirs'] = 2 pmagplotlib.plot_init(FIG['bdirs'], 5, 5) if '-fmt' in sys.argv: ind = sys.argv.index("-fmt") fmt = sys.argv[ind + 1] DIblock = numpy.array([data[0], data[1]]).transpose() if len(DIblock) > 0: pmagplotlib.plotEQsym(FIG['eq'], DIblock, title, sym) if plot == 0: pmagplotlib.drawFIGS(FIG) else: print("no data to plot") sys.exit() if plotE == 1: ppars = pmag.doprinc(DIblock) # get principal directions nDIs, rDIs, npars, rpars = [], [], [], [] for rec in DIblock: angle = pmag.angle([rec[0], rec[1]], [ppars['dec'], ppars['inc']]) if angle > 90.: rDIs.append(rec) else: nDIs.append(rec) if dist == 'B': # do on whole dataset etitle = "Bingham confidence ellipse" bpars = pmag.dobingham(DIblock) for key in list(bpars.keys()): if key != 'n' and pmagplotlib.verbose: print(" ", key, '%7.1f' % (bpars[key])) if key == 'n' and pmagplotlib.verbose: print(" ", key, ' %i' % (bpars[key])) npars.append(bpars['dec']) npars.append(bpars['inc']) npars.append(bpars['Zeta']) npars.append(bpars['Zdec']) npars.append(bpars['Zinc']) npars.append(bpars['Eta']) npars.append(bpars['Edec']) npars.append(bpars['Einc']) if dist == 'F': etitle = "Fisher confidence cone" if len(nDIs) > 3: fpars = pmag.fisher_mean(nDIs) for key in list(fpars.keys()): if key != 'n' and pmagplotlib.verbose: print(" ", key, '%7.1f' % (fpars[key])) if key == 'n' and pmagplotlib.verbose: print(" ", key, ' %i' % (fpars[key])) mode += 1 npars.append(fpars['dec']) npars.append(fpars['inc']) npars.append(fpars['alpha95']) # Beta npars.append(fpars['dec']) isign = old_div(abs(fpars['inc']), fpars['inc']) npars.append(fpars['inc'] - isign * 90.) #Beta inc npars.append(fpars['alpha95']) # gamma npars.append(fpars['dec'] + 90.) # Beta dec npars.append(0.) #Beta inc if len(rDIs) > 3: fpars = pmag.fisher_mean(rDIs) if pmagplotlib.verbose: print("mode ", mode) for key in list(fpars.keys()): if key != 'n' and pmagplotlib.verbose: print(" ", key, '%7.1f' % (fpars[key])) if key == 'n' and pmagplotlib.verbose: print(" ", key, ' %i' % (fpars[key])) mode += 1 rpars.append(fpars['dec']) rpars.append(fpars['inc']) rpars.append(fpars['alpha95']) # Beta rpars.append(fpars['dec']) isign = old_div(abs(fpars['inc']), fpars['inc']) rpars.append(fpars['inc'] - isign * 90.) #Beta inc rpars.append(fpars['alpha95']) # gamma rpars.append(fpars['dec'] + 90.) # Beta dec rpars.append(0.) #Beta inc if dist == 'K': etitle = "Kent confidence ellipse" if len(nDIs) > 3: kpars = pmag.dokent(nDIs, len(nDIs)) if pmagplotlib.verbose: print("mode ", mode) for key in list(kpars.keys()): if key != 'n' and pmagplotlib.verbose: print(" ", key, '%7.1f' % (kpars[key])) if key == 'n' and pmagplotlib.verbose: print(" ", key, ' %i' % (kpars[key])) mode += 1 npars.append(kpars['dec']) npars.append(kpars['inc']) npars.append(kpars['Zeta']) npars.append(kpars['Zdec']) npars.append(kpars['Zinc']) npars.append(kpars['Eta']) npars.append(kpars['Edec']) npars.append(kpars['Einc']) if len(rDIs) > 3: kpars = pmag.dokent(rDIs, len(rDIs)) if pmagplotlib.verbose: print("mode ", mode) for key in list(kpars.keys()): if key != 'n' and pmagplotlib.verbose: print(" ", key, '%7.1f' % (kpars[key])) if key == 'n' and pmagplotlib.verbose: print(" ", key, ' %i' % (kpars[key])) mode += 1 rpars.append(kpars['dec']) rpars.append(kpars['inc']) rpars.append(kpars['Zeta']) rpars.append(kpars['Zdec']) rpars.append(kpars['Zinc']) rpars.append(kpars['Eta']) rpars.append(kpars['Edec']) rpars.append(kpars['Einc']) else: # assume bootstrap if len(nDIs) < 10 and len(rDIs) < 10: print('too few data points for bootstrap') sys.exit() if dist == 'BE': print('Be patient for bootstrap...') if len(nDIs) >= 10: BnDIs = pmag.di_boot(nDIs) Bkpars = pmag.dokent(BnDIs, 1.) if pmagplotlib.verbose: print("mode ", mode) for key in list(Bkpars.keys()): if key != 'n' and pmagplotlib.verbose: print(" ", key, '%7.1f' % (Bkpars[key])) if key == 'n' and pmagplotlib.verbose: print(" ", key, ' %i' % (Bkpars[key])) mode += 1 npars.append(Bkpars['dec']) npars.append(Bkpars['inc']) npars.append(Bkpars['Zeta']) npars.append(Bkpars['Zdec']) npars.append(Bkpars['Zinc']) npars.append(Bkpars['Eta']) npars.append(Bkpars['Edec']) npars.append(Bkpars['Einc']) if len(rDIs) >= 10: BrDIs = pmag.di_boot(rDIs) Bkpars = pmag.dokent(BrDIs, 1.) if pmagplotlib.verbose: print("mode ", mode) for key in list(Bkpars.keys()): if key != 'n' and pmagplotlib.verbose: print(" ", key, '%7.1f' % (Bkpars[key])) if key == 'n' and pmagplotlib.verbose: print(" ", key, ' %i' % (Bkpars[key])) mode += 1 rpars.append(Bkpars['dec']) rpars.append(Bkpars['inc']) rpars.append(Bkpars['Zeta']) rpars.append(Bkpars['Zdec']) rpars.append(Bkpars['Zinc']) rpars.append(Bkpars['Eta']) rpars.append(Bkpars['Edec']) rpars.append(Bkpars['Einc']) etitle = "Bootstrapped confidence ellipse" elif dist == 'BV': print('Be patient for bootstrap...') vsym = {'lower': ['+', 'k'], 'upper': ['x', 'k'], 'size': 5} if len(nDIs) > 5: BnDIs = pmag.di_boot(nDIs) pmagplotlib.plotEQsym(FIG['bdirs'], BnDIs, 'Bootstrapped Eigenvectors', vsym) if len(rDIs) > 5: BrDIs = pmag.di_boot(rDIs) if len(nDIs) > 5: # plot on existing plots pmagplotlib.plotDIsym(FIG['bdirs'], BrDIs, vsym) else: pmagplotlib.plotEQ(FIG['bdirs'], BrDIs, 'Bootstrapped Eigenvectors', vsym) if dist == 'B': if len(nDIs) > 3 or len(rDIs) > 3: pmagplotlib.plotCONF(FIG['eq'], etitle, [], npars, 0) elif len(nDIs) > 3 and dist != 'BV': pmagplotlib.plotCONF(FIG['eq'], etitle, [], npars, 0) if len(rDIs) > 3: pmagplotlib.plotCONF(FIG['eq'], etitle, [], rpars, 0) elif len(rDIs) > 3 and dist != 'BV': pmagplotlib.plotCONF(FIG['eq'], etitle, [], rpars, 0) if plot == 0: pmagplotlib.drawFIGS(FIG) if plot == 0: pmagplotlib.drawFIGS(FIG) # files = {} for key in list(FIG.keys()): files[key] = title + '_' + key + '.' + fmt if pmagplotlib.isServer: black = '#000000' purple = '#800080' titles = {} titles['eq'] = 'Equal Area Plot' FIG = pmagplotlib.addBorders(FIG, titles, black, purple) pmagplotlib.saveP(FIG, files) elif plot == 0: ans = input(" S[a]ve to save plot, [q]uit, Return to continue: ") if ans == "q": sys.exit() if ans == "a": pmagplotlib.saveP(FIG, files) else: pmagplotlib.saveP(FIG, files)
def main(): """ NAME gokent.py DESCRIPTION calculates Kent parameters from dec inc data INPUT FORMAT takes dec/inc as first two columns in space delimited file SYNTAX gokent.py [options] OPTIONS -h prints help message and quits -i for interactive filename entry -f FILE, specify filename -F FILE, specifies output file name < filename for reading from standard input OUTPUT mean dec, mean inc, Eta, Deta, Ieta, Zeta, Zdec, Zinc, N """ if len(sys.argv) > 0: if '-h' in sys.argv: # check if help is needed print main.__doc__ sys.exit() # graceful quit if '-f' in sys.argv: ind = sys.argv.index('-f') file = sys.argv[ind + 1] f = open(file, 'rU') data = f.readlines() elif '-i' in sys.argv: # ask for filename file = raw_input("Enter file name with dec, inc data: ") f = open(file, 'rU') data = f.readlines() else: # data = sys.stdin.readlines() # read in data from standard input ofile = "" if '-F' in sys.argv: ind = sys.argv.index('-F') ofile = sys.argv[ind + 1] out = open(ofile, 'w + a') DIs = [] # set up list for dec inc data for line in data: # read in the data from standard input if '\t' in line: rec = line.split('\t') # split each line on space to get records else: rec = line.split() # split each line on space to get records DIs.append((float(rec[0]), float(rec[1]))) # kpars = pmag.dokent(DIs, len(DIs)) output = '%7.1f %7.1f %7.1f %7.1f %7.1f %7.1f %7.1f %7.1f %i' % ( kpars["dec"], kpars["inc"], kpars["Eta"], kpars["Edec"], kpars["Einc"], kpars["Zeta"], kpars["Zdec"], kpars["Zinc"], kpars["n"]) if ofile == "": print output else: out.write(output + '\n')
def main(): """ NAME eqarea_magic.py DESCRIPTION makes equal area projections from declination/inclination data SYNTAX eqarea_magic.py [command line options] INPUT takes magic formatted sites, samples, specimens, or measurements OPTIONS -h prints help message and quits -f FILE: specify input magic format file from magic, default='sites.txt' supported types=[measurements, specimens, samples, sites] -fsp FILE: specify specimen file name, (required if you want to plot measurements by sample) default='specimens.txt' -fsa FILE: specify sample file name, (required if you want to plot specimens by site) default='samples.txt' -fsi FILE: specify site file name, default='sites.txt' -obj OBJ: specify level of plot [all, sit, sam, spc], default is all -crd [s,g,t]: specify coordinate system, [s]pecimen, [g]eographic, [t]ilt adjusted default is geographic, unspecified assumed geographic -fmt [svg,png,jpg] format for output plots -ell [F,K,B,Be,Bv] plot Fisher, Kent, Bingham, Bootstrap ellipses or Boostrap eigenvectors -c plot as colour contour -sav save plot and quit quietly NOTE all: entire file; sit: site; sam: sample; spc: specimen """ # initialize some default variables FIG = {} # plot dictionary FIG["eqarea"] = 1 # eqarea is figure 1 plotE = 0 plt = 0 # default to not plotting verbose = pmagplotlib.verbose # extract arguments from sys.argv if "-h" in sys.argv: print main.__doc__ sys.exit() dir_path = pmag.get_named_arg_from_sys("-WD", default_val=os.getcwd()) pmagplotlib.plot_init(FIG["eqarea"], 5, 5) in_file = pmag.get_named_arg_from_sys("-f", default_val="sites.txt") full_in_file = os.path.join(dir_path, in_file) plot_by = pmag.get_named_arg_from_sys("-obj", default_val="all").lower() spec_file = pmag.get_named_arg_from_sys("-fsp", default_val="specimens.txt") samp_file = pmag.get_named_arg_from_sys("-fsa", default_val="samples.txt") site_file = pmag.get_named_arg_from_sys("-fsi", default_val="sites.txt") if plot_by == "all": plot_key = "all" elif plot_by == "sit": plot_key = "site" elif plot_by == "sam": plot_key = "sample" elif plot_by == "spc": plot_key = "specimen" else: plot_key = "all" if "-c" in sys.argv: contour = 1 else: contour = 0 if "-sav" in sys.argv: plt = 1 verbose = 0 if "-ell" in sys.argv: plotE = 1 ind = sys.argv.index("-ell") ell_type = sys.argv[ind + 1] ell_type = pmag.get_named_arg_from_sys("-ell", "F") dist = ell_type.upper() # if dist type is unrecognized, use Fisher if dist not in ["F", "K", "B", "BE", "BV"]: dist = "F" if dist == "BV": FIG["bdirs"] = 2 pmagplotlib.plot_init(FIG["bdirs"], 5, 5) crd = pmag.get_named_arg_from_sys("-crd", default_val="g") if crd == "s": coord = "-1" elif crd == "t": coord = "100" else: coord = "0" fmt = pmag.get_named_arg_from_sys("-fmt", "svg") dec_key = "dir_dec" inc_key = "dir_inc" tilt_key = "dir_tilt_correction" # Dir_type_keys=['','site_direction_type','sample_direction_type','specimen_direction_type'] # fnames = {"specimens": spec_file, "samples": samp_file, "sites": site_file} contribution = nb.Contribution(dir_path, custom_filenames=fnames, single_file=in_file) # the object that contains the DataFrame + useful helper methods: table_name = contribution.tables.keys()[0] data_container = contribution.tables[table_name] # the actual DataFrame: data = data_container.df # uses sample infile to add temporary site_name # column to the specimen table data_container = contribution.tables[table_name] data = data_container.df if (plot_key != "all") and (plot_key not in data.columns): data = contribution.propagate_name_down(plot_key, table_name) # add tilt key into DataFrame columns if it isn't there already if tilt_key not in data.columns: data.loc[:, tilt_key] = None if verbose: print len(data), " records read from ", in_file # find desired dec,inc data: dir_type_key = "" # # get plotlist if not plotting all records # plotlist = [] if plot_key != "all": # return all where plot_key is not blank if plot_key not in data.columns: print 'Can\'t plot by "{}". That header is not in infile: {}'.format(plot_key, in_file) return plots = data[data[plot_key].notnull()] plotlist = plots[plot_key].unique() # grab unique values else: plotlist.append("All") for plot in plotlist: if verbose: print plot if plot == "All": # plot everything at once plot_data = data else: # pull out only partial data plot_data = data[data[plot_key] == plot] DIblock = [] GCblock = [] # SLblock, SPblock = [], [] title = plot mode = 1 k = 0 if dec_key not in plot_data.columns: print "-W- No dec/inc data" continue # get all records where dec & inc values exist plot_data = plot_data[plot_data[dec_key].notnull() & plot_data[inc_key].notnull()] if plot_data.empty: continue # this sorting out is done in get_di_bock # if coord == '0': # geographic, use records with no tilt key (or tilt_key 0) # cond1 = plot_data[tilt_key].fillna('') == coord # cond2 = plot_data[tilt_key].isnull() # plot_data = plot_data[cond1 | cond2] # else: # not geographic coordinates, use only records with correct tilt_key # plot_data = plot_data[plot_data[tilt_key] == coord] # get metadata for naming the plot file locations = data_container.get_name("location", df_slice=plot_data) site = data_container.get_name("site", df_slice=plot_data) sample = data_container.get_name("sample", df_slice=plot_data) specimen = data_container.get_name("specimen", df_slice=plot_data) # make sure method_codes is in plot_data if "method_codes" not in plot_data.columns: plot_data["method_codes"] = "" # get data blocks DIblock = data_container.get_di_block(df_slice=plot_data, tilt_corr=coord, excl=["DE-BFP"]) # SLblock = [[ind, row['method_codes']] for ind, row in plot_data.iterrows()] # get great circles great_circle_data = data_container.get_records_for_code("DE-BFP", incl=True, use_slice=True, sli=plot_data) if len(great_circle_data) > 0: gc_cond = great_circle_data[tilt_key] == coord GCblock = [[float(row[dec_key]), float(row[inc_key])] for ind, row in great_circle_data[gc_cond].iterrows()] # SPblock = [[ind, row['method_codes']] for ind, row in great_circle_data[gc_cond].iterrows()] if len(DIblock) > 0: if contour == 0: pmagplotlib.plotEQ(FIG["eqarea"], DIblock, title) else: pmagplotlib.plotEQcont(FIG["eqarea"], DIblock) else: pmagplotlib.plotNET(FIG["eqarea"]) if len(GCblock) > 0: for rec in GCblock: pmagplotlib.plotC(FIG["eqarea"], rec, 90.0, "g") if len(DIblock) == 0 and len(GCblock) == 0: if verbose: print "no records for plotting" continue # sys.exit() if plotE == 1: ppars = pmag.doprinc(DIblock) # get principal directions nDIs, rDIs, npars, rpars = [], [], [], [] for rec in DIblock: angle = pmag.angle([rec[0], rec[1]], [ppars["dec"], ppars["inc"]]) if angle > 90.0: rDIs.append(rec) else: nDIs.append(rec) if dist == "B": # do on whole dataset etitle = "Bingham confidence ellipse" bpars = pmag.dobingham(DIblock) for key in bpars.keys(): if key != "n" and verbose: print " ", key, "%7.1f" % (bpars[key]) if key == "n" and verbose: print " ", key, " %i" % (bpars[key]) npars.append(bpars["dec"]) npars.append(bpars["inc"]) npars.append(bpars["Zeta"]) npars.append(bpars["Zdec"]) npars.append(bpars["Zinc"]) npars.append(bpars["Eta"]) npars.append(bpars["Edec"]) npars.append(bpars["Einc"]) if dist == "F": etitle = "Fisher confidence cone" if len(nDIs) > 2: fpars = pmag.fisher_mean(nDIs) for key in fpars.keys(): if key != "n" and verbose: print " ", key, "%7.1f" % (fpars[key]) if key == "n" and verbose: print " ", key, " %i" % (fpars[key]) mode += 1 npars.append(fpars["dec"]) npars.append(fpars["inc"]) npars.append(fpars["alpha95"]) # Beta npars.append(fpars["dec"]) isign = abs(fpars["inc"]) / fpars["inc"] npars.append(fpars["inc"] - isign * 90.0) # Beta inc npars.append(fpars["alpha95"]) # gamma npars.append(fpars["dec"] + 90.0) # Beta dec npars.append(0.0) # Beta inc if len(rDIs) > 2: fpars = pmag.fisher_mean(rDIs) if verbose: print "mode ", mode for key in fpars.keys(): if key != "n" and verbose: print " ", key, "%7.1f" % (fpars[key]) if key == "n" and verbose: print " ", key, " %i" % (fpars[key]) mode += 1 rpars.append(fpars["dec"]) rpars.append(fpars["inc"]) rpars.append(fpars["alpha95"]) # Beta rpars.append(fpars["dec"]) isign = abs(fpars["inc"]) / fpars["inc"] rpars.append(fpars["inc"] - isign * 90.0) # Beta inc rpars.append(fpars["alpha95"]) # gamma rpars.append(fpars["dec"] + 90.0) # Beta dec rpars.append(0.0) # Beta inc if dist == "K": etitle = "Kent confidence ellipse" if len(nDIs) > 3: kpars = pmag.dokent(nDIs, len(nDIs)) if verbose: print "mode ", mode for key in kpars.keys(): if key != "n" and verbose: print " ", key, "%7.1f" % (kpars[key]) if key == "n" and verbose: print " ", key, " %i" % (kpars[key]) mode += 1 npars.append(kpars["dec"]) npars.append(kpars["inc"]) npars.append(kpars["Zeta"]) npars.append(kpars["Zdec"]) npars.append(kpars["Zinc"]) npars.append(kpars["Eta"]) npars.append(kpars["Edec"]) npars.append(kpars["Einc"]) if len(rDIs) > 3: kpars = pmag.dokent(rDIs, len(rDIs)) if verbose: print "mode ", mode for key in kpars.keys(): if key != "n" and verbose: print " ", key, "%7.1f" % (kpars[key]) if key == "n" and verbose: print " ", key, " %i" % (kpars[key]) mode += 1 rpars.append(kpars["dec"]) rpars.append(kpars["inc"]) rpars.append(kpars["Zeta"]) rpars.append(kpars["Zdec"]) rpars.append(kpars["Zinc"]) rpars.append(kpars["Eta"]) rpars.append(kpars["Edec"]) rpars.append(kpars["Einc"]) else: # assume bootstrap if dist == "BE": if len(nDIs) > 5: BnDIs = pmag.di_boot(nDIs) Bkpars = pmag.dokent(BnDIs, 1.0) if verbose: print "mode ", mode for key in Bkpars.keys(): if key != "n" and verbose: print " ", key, "%7.1f" % (Bkpars[key]) if key == "n" and verbose: print " ", key, " %i" % (Bkpars[key]) mode += 1 npars.append(Bkpars["dec"]) npars.append(Bkpars["inc"]) npars.append(Bkpars["Zeta"]) npars.append(Bkpars["Zdec"]) npars.append(Bkpars["Zinc"]) npars.append(Bkpars["Eta"]) npars.append(Bkpars["Edec"]) npars.append(Bkpars["Einc"]) if len(rDIs) > 5: BrDIs = pmag.di_boot(rDIs) Bkpars = pmag.dokent(BrDIs, 1.0) if verbose: print "mode ", mode for key in Bkpars.keys(): if key != "n" and verbose: print " ", key, "%7.1f" % (Bkpars[key]) if key == "n" and verbose: print " ", key, " %i" % (Bkpars[key]) mode += 1 rpars.append(Bkpars["dec"]) rpars.append(Bkpars["inc"]) rpars.append(Bkpars["Zeta"]) rpars.append(Bkpars["Zdec"]) rpars.append(Bkpars["Zinc"]) rpars.append(Bkpars["Eta"]) rpars.append(Bkpars["Edec"]) rpars.append(Bkpars["Einc"]) etitle = "Bootstrapped confidence ellipse" elif dist == "BV": sym = {"lower": ["o", "c"], "upper": ["o", "g"], "size": 3, "edgecolor": "face"} if len(nDIs) > 5: BnDIs = pmag.di_boot(nDIs) pmagplotlib.plotEQsym(FIG["bdirs"], BnDIs, "Bootstrapped Eigenvectors", sym) if len(rDIs) > 5: BrDIs = pmag.di_boot(rDIs) if len(nDIs) > 5: # plot on existing plots pmagplotlib.plotDIsym(FIG["bdirs"], BrDIs, sym) else: pmagplotlib.plotEQ(FIG["bdirs"], BrDIs, "Bootstrapped Eigenvectors") if dist == "B": if len(nDIs) > 3 or len(rDIs) > 3: pmagplotlib.plotCONF(FIG["eqarea"], etitle, [], npars, 0) elif len(nDIs) > 3 and dist != "BV": pmagplotlib.plotCONF(FIG["eqarea"], etitle, [], npars, 0) if len(rDIs) > 3: pmagplotlib.plotCONF(FIG["eqarea"], etitle, [], rpars, 0) elif len(rDIs) > 3 and dist != "BV": pmagplotlib.plotCONF(FIG["eqarea"], etitle, [], rpars, 0) for key in FIG.keys(): files = {} filename = pmag.get_named_arg_from_sys("-fname") if filename: filename += "." + fmt else: filename = ( "LO:_" + locations + "_SI:_" + site + "_SA:_" + sample + "_SP:_" + specimen + "_CO:_" + crd + "_TY:_" + key + "_." + fmt ) files[key] = filename if pmagplotlib.isServer: black = "#000000" purple = "#800080" titles = {} titles["eq"] = "Equal Area Plot" FIG = pmagplotlib.addBorders(FIG, titles, black, purple) pmagplotlib.saveP(FIG, files) if plt: pmagplotlib.saveP(FIG, files) continue if verbose: pmagplotlib.drawFIGS(FIG) ans = raw_input(" S[a]ve to save plot, [q]uit, Return to continue: ") if ans == "q": sys.exit() if ans == "a": pmagplotlib.saveP(FIG, files) continue