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Thu Mar 9 12:31:47 2006 UTC (18 years, 9 months ago) by pam-de
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Initial Release

1 pam-de 1.1 Makefile0000640000076500001440000000156710314237651011406 0ustar mennusers# Fortran flags
2     FC=g77
3     FFLAGS=-fvxt -fno-automatic -Wall -Wno-globals -fbounds-check
4     # C flags
5     CC=gcc
6     CFLAGS=-Wall -O2
7     CFLADJ=-c
8    
9     # used libraries
10     #LIBS=-L/cern/pro/lib -lkernlib -lpacklib -lgraflib -lmathlib -lnsl
11     LIBS= `cernlib kernlib packlib graflib mathlib`
12    
13     template.exe: template-static
14    
15     # this directive links static libraries
16     template-static: template.f trk_level2.f
17     $(FC) $(FFLAGS) template.f -o template.exe $(TRK_GRND)/lib/libtrk.a $(LIBS)
18    
19     # the next directive link dinamyc library (.so)
20     # NB! in order to link dynamically it must be added the library path to
21     # LD_LIBRARY_PATH (in the ./bashrc)
22     template-dynamic: template.f trk_level2.f
23     $(FC) $(FFLAGS) -o template.exe template.f $(LIBS) -L$(TRK_GRND)/lib -ltrk
24    
25     toftrack: toftrack.f trk_level2.f
26     $(FC) $(FFLAGS) toftrack.f -o toftrack.exe $(TRK_GRND)/lib/libtrk.a $(LIBS)
27    
28     clean:
29     rm -f *.o
30     rm -f *.exe
31     rm -f *~
32    
33     README0000664000076500001440000001724410314477647010646 0ustar mennusers
34     1) The ToF software uses the Tracking software V2.00
35     It is assumed that you have created all the directories and the compiling
36     of the three executables "level0.exe", "level1.exe" and "level2.exe"
37     was succesful.
38    
39     2) Copy the file toftrack.tar to the "utilities/template" directory (where
40     the program template.f is located), untar the file toftrack.tar.
41    
42     The following files will be extracted:
43     Makefile (the old Makefile will be overwritten)
44     run-test.sh
45     tofcalib.rz
46     toftrack.f
47     common_tof.f
48     tofroutine.f
49     trk_level2.f (the old trk_level2.f was not correct)
50     common_tofroutine.f
51    
52     3)Create the executable toftrack.exe doing
53     # make toftrack
54    
55     4) The "level*.exe" programs in your working directory were run by doing
56    
57     #./run-test.sh some_filename.txt level0/1/2 &
58    
59     Copy the new "run-test.sh" from the template directory to the working
60     directory. Copy toftrack.exe to the working directory
61     After you have done step 5 (see below) you can run the toftrack software
62     analogue to the command for the level0/1/2 software:
63    
64     #./run-test.sh some_filename.txt toftrack &
65    
66     In the file good_files.tar.gz there is a list of good files from the Roma
67     tests.
68    
69     5) Untar the file tofcalib.tar in your rz-data directory (where the level2
70     and tof rz-files are located). This will create a standard "tofcalib.rz"
71     file plus the calibration files for the Roma data
72     "DW_******_***_tofcalib.rz"
73    
74    
75     ---------------------------------------------------------------------------
76    
77     "tracktof" will read the appropriate level2, tof, and tofcalib file. If
78     there is no tofcalib file for this data run, the standard calibration is
79     used (There will be a message saying "Could not find.... Will use the
80     standard calibration")
81    
82    
83     "tracktof" will create a new rz file DW_******_**_toftrack.rz" combining
84     the level2 data, the (raw) tof data, plus the variables calculated in the
85     tofroutine.
86    
87     The structure looks like this:
88    
89    
90     ******************************************************************
91     * Ntuple ID = 2 Entries = 1185 TOF
92     ******************************************************************
93     * Var numb * Type * Packing * Range * Block * Name *
94     ******************************************************************
95     * 1 * L*4 * 1 * * EVENT * GOOD
96     * 2 * I*4 * * * EVENT * NEV_TRK
97     * 1 * I*4 * * * CPU * PKT_TYPE
98     * 2 * I*4 * * * CPU * PKT_NUM
99     * 3 * I*4 * * * CPU * OBT
100     * 4 * I*4 * * * CPU * WHICH_CALIB
101     * 1 * I*4 * * * TOF * TDCID(12)
102     * 2 * I*4 * * * TOF * EVCOUNT(12)
103     * 3 * I*4 * * * TOF * TDCMASK(12)
104     * 4 * I*4 * * * TOF * ADC(4,12)
105     * 5 * I*4 * * * TOF * TDC(4,12)
106     * 6 * I*4 * * * TOF * TEMP1(12)
107     * 7 * I*4 * * * TOF * TEMP2(12)
108     * 8 * R*4 * * * TOF * BETA(5)
109     * 9 * R*4 * * * TOF * XTOF(3)
110     * 10 * R*4 * * * TOF * YTOF(3)
111     * 11 * R*4 * * * TOF * ADC_C(4,12)
112     * 12 * I*4 * * * TOF * IFLAG(6)
113     * 13 * I*4 * * * TOF * JFLAG(6)
114     * 14 * R*4 * * * TOF * XOUT(3)
115     * 15 * R*4 * * * TOF * YOUT(3)
116     * 1 * I*4 * * * TRIGGER * TRIG_EVCOUNT
117     * 2 * I*4 * * * TRIGGER * PMTPL(3)
118     * 3 * I*4 * * * TRIGGER * TRIGRATE(6)
119     * 4 * I*4 * * * TRIGGER * DLTIME(2)
120     * 5 * I*4 * * * TRIGGER * S4CALCOUNT(2)
121     * 6 * I*4 * * * TRIGGER * PMTCOUNT1(24)
122     * 7 * I*4 * * * TRIGGER * PMTCOUNT2(24)
123     * 8 * I*4 * * * TRIGGER * PATTERNBUSY(3)
124     * 9 * I*4 * * * TRIGGER * PATTERNTRIG(6)
125     * 10 * I*4 * * * TRIGGER * TRIGCONF
126     * 1 * I*4 * * [0,50] * TRACKS * NTRK
127     * 2 * U*4 * 6 * [0,50] * TRACKS * IMAGE(NTRK)
128     * 3 * R*4 * * * TRACKS * XM(6,NTRK)
129     * 4 * R*4 * * * TRACKS * YM(6,NTRK)
130     * 5 * R*4 * * * TRACKS * ZM(6,NTRK)
131     * 6 * R*4 * * * TRACKS * RESX(6,NTRK)
132     * 7 * R*4 * * * TRACKS * RESY(6,NTRK)
133     * 8 * R*4 * * * TRACKS * AL(5,NTRK)
134     * 9 * R*4 * * * TRACKS * COVAL(5,5,NTRK)
135     * 10 * R*4 * * * TRACKS * CHI2(NTRK)
136     * 11 * U*4 * 1 * [0,1] * TRACKS * XGOOD(6,NTRK)
137     * 12 * U*4 * 1 * [0,1] * TRACKS * YGOOD(6,NTRK)
138     * 13 * R*4 * * * TRACKS * XV(6,NTRK)
139     * 14 * R*4 * * * TRACKS * YV(6,NTRK)
140     * 15 * R*4 * * * TRACKS * ZV(6,NTRK)
141     * 16 * R*4 * * * TRACKS * AXV(6,NTRK)
142     * 17 * R*4 * * * TRACKS * AYV(6,NTRK)
143     * 18 * R*4 * * * TRACKS * DEDXP(6,NTRK)
144     * 1 * I*4 * * * SINGLETS * NCLSX(6)
145     * 2 * I*4 * * * SINGLETS * NCLSY(6)
146     ******************************************************************
147     * Block * Entries * Unpacked * Packed * Packing Factor *
148     ******************************************************************
149     * EVENT * 1185 * 8 * 5 * 1.600 *
150     * CPU * 1185 * 16 * 16 * 1.000 *
151     * TOF * 1185 * 932 * 932 * 1.000 *
152     * TRIGGER * 1185 * 288 * 288 * 1.000 *
153     * TRACKS * 1185 * 22004 * Var. * Variable *
154     * SINGLETS * 1185 * 48 * 48 * 1.000 *
155     * Total * --- * 23296 * Var. * Variable *
156     ******************************************************************
157     * Blocks = 6 Variables = 51 Max. Columns = 5824 *
158     ******************************************************************
159    
160    
161    
162     The variables calculated in "TOFROUTINE" are the last ones in the block
163     "TOF":
164    
165    
166     BETA(5): four values (1-4) for beta from S11-S31, S12-S32, S21-S31
167     and S22-S32.
168     if there is no valid signal beta is set to "100".
169     if there are four values for beta, the weighted mean is
170     calculated and put into beta(5). So it is possible for
171     the user to calculate his own mean value by using the
172     single values.
173    
174     XTOF(3): The x-position in the 3 different layers using the ToF
175     timing (So, for the x-coordinate we use S12, S21,S32).
176     If we cannot find a valid timing the value is set to "1000"
177    
178     YTOF(3): The same for y-position using S11, S22,S31
179    
180     ADC_C(4,12): normalized ADC values, the value in the middle of the
181     paddle is set to "1", using the (sometimes poor) attenuation
182     fit curves. The ADC_C matrix is analog to the ADC matrix
183     for the raw data, so one can use the same channel map.
184    
185     IFLAG(6): 6 values for the six layers:
186     "0" if no hit in this layer
187     "-1" if more than one hit
188     otherwise the number of the hitted paddle ("hit" = good
189     TDC values on both sides)
190    
191     JFLAG(6): 6 values for the six layers: coded value to see which
192     strips have valid hits:
193     for i=1 to (number of strips) do
194     if (paddle "i" = hit) then jflag = jflag + 2**(i-1)
195    
196    
197    
198    
199     common_tof.f0000664000076500001440000000125410314004226012242 0ustar mennusers integer tdcid(12),evcount(12)
200     integer tdcmask(12),adc(4,12),tdc(4,12)
201     integer temp1(12),temp2(12)
202     COMMON / tofvar /tdcid,evcount,tdcmask,adc,tdc,temp1,temp2
203    
204     integer*4 trig_evcount
205     integer pmtpl(3), trigrate(6), dltime(2), s4calcount(2)
206     integer pmtcount1(24), pmtcount2(24)
207     integer*4 patternbusy(3)
208     integer patterntrig(6), trigconf
209     COMMON / trig / trig_evcount, pmtpl, trigrate, dltime,
210     & s4calcount, pmtcount1, pmtcount2,
211     & patternbusy, patterntrig, trigconf
212    
213    
214     parameter (ntp_tof=17)
215     parameter (ntp_tofcalib=60)
216    
217     logical good
218     integer nev_trk
219     common / event_tof /good,nev_trk
220     common_tofroutine.f0000664000076500001440000001107510314004226013652 0ustar mennusers* DATA ZTOF/55.,25.,-23/
221     *
222     * TOF data
223     * first index : 1 = A, 2 = B
224     * second index : 1.. number of paddle
225     * third index : 1 = TDC, 2 = ADC
226    
227     c INTEGER tof11(2,8,2),tof12(2,6,2)
228     c INTEGER tof21(2,2,2),tof22(2,2,2)
229     c INTEGER tof31(2,3,2),tof32(2,3,2)
230     REAL tof11(2,8,2),tof12(2,6,2)
231     REAL tof21(2,2,2),tof22(2,2,2)
232     REAL tof31(2,3,2),tof32(2,3,2)
233    
234     c Normalized ADC value
235     REAL adc_c(4,12)
236    
237     c k1 constans for calculation of beta
238     REAL k1_s11s31(24),k1_s12s32(18),k1_S21S31(6),k1_S22S32(6)
239    
240     c middle y (or x) position of the upper and middle ToF-Paddle
241     c to calculate theta-angle without track information
242     REAL tof11_x(8), tof21_y(2), tof31_x(3)
243     REAL tof12_y(6), tof22_x(2), tof32_y(3)
244    
245     c relation of time differences in a tof paddle and the location of the
246     c passage of the particle
247     c first index : 1... number of paddle
248     c second index : 1 = offset, 2 = slope
249     REAL y_coor_lin11(8,2),x_coor_lin12(6,2)
250     REAL x_coor_lin21(2,2),y_coor_lin22(2,2)
251     REAL y_coor_lin31(3,2),x_coor_lin32(3,2)
252    
253     c ADC(x) - correction
254     c first index : 1 = left, 2 = right
255     c second index : 1..8 number of paddle
256     c third index: parameter as follows
257     c left: xkorr=par(1)*exp(-x/par(2))
258     c right:xkorr=par(1)*exp(x/par(2))
259     c then:adc(x,right/left)=adc(x,right/left)/xkorr
260     c normalize to x=0 (middle of paddle)
261     REAL adcx11(2,8,2),adcx12(2,6,2)
262     REAL adcx21(2,2,2),adcx22(2,2,2)
263     REAL adcx31(2,3,2),adcx32(2,3,2)
264    
265    
266     c Time Walk - correction
267     c first index : 1 = left, 2 = right
268     c second index : 1..8 number of paddle
269     REAL tw11(2,8),tw12(2,6)
270     REAL tw21(2,2),tw22(2,2)
271     REAL tw31(2,3),tw32(2,3)
272    
273    
274     c value for status of each PM-data
275     c first index : 1 = left, 2 = right
276     c second index : 1... number of paddle
277     INTEGER tof11_event(2,8),tof12_event(2,6)
278     INTEGER tof21_event(2,2),tof22_event(2,2)
279     INTEGER tof31_event(2,3),tof32_event(2,3)
280    
281     C----
282    
283     INTEGER left,right,top,bot,mid,itdc,iadc
284     INTEGER tdc_ev, adc_ev, none_ev, none_find
285     INTEGER offset, slope
286     INTEGER tof11_i,tof21_i,tof31_i,tof11_j,tof21_j,tof31_j
287     INTEGER tof12_i,tof22_i,tof32_i,tof12_j,tof22_j,tof32_j
288     * REAL adcoff(4,2,52),a,b
289     c REAL delta_x12,delta_y12,delta_x23,delta_y23,delta_x13,delta_y13
290     REAL xtofpos(3),ytofpos(3)
291     REAL xkorr, secure
292     INTEGER i, j, ihelp
293     LOGICAL check
294     REAL theta12,theta13,theta23
295    
296     REAL beta_a(5)
297    
298     INTEGER tof_i_flag(6),tof_j_flag(6)
299    
300    
301     DATA TOFfst / 0/
302    
303     PARAMETER (tofarm23 = 45.)
304     PARAMETER (tofarm13 = 81.)
305     PARAMETER (c2_13=108.) ! = 2.*tofarm13*0.01/(3.E08*50.E-12)
306     PARAMETER (c2_23=60.) ! = 2.*tofarm23*0.01/(3.E08*50.E-12)
307    
308    
309     * S11 8 paddles 33.0 x 5.1 cm
310     * S12 6 paddles 40.8 x 5.5 cm
311     * S21 2 paddles 18.0 x 7.5 cm
312     * S22 2 paddles 15.0 x 9.0 cm
313     * S31 3 paddles 15.0 x 6.0 cm
314     * S32 3 paddles 18.0 x 5.0 cm
315    
316     DATA tof11_x/ -17.85,-12.75,-7.65,-2.55,2.55,7.65,12.75,17.85/
317     DATA tof12_y/ -13.75,-8.25,-2.75,2.75,8.25,13.75/
318     DATA tof21_y/ -3.75,3.75/
319     DATA tof22_x/ -4.5,4.5/
320     DATA tof31_x/ -6.0,0.,6.0/
321     DATA tof32_y/ -5.0,0.0,5.0/
322    
323     integer ch11a(8),hb11a(8),ch11b(8),hb11b(8)
324     integer ch12a(6),hb12a(6),ch12b(6),hb12b(6)
325     integer ch21a(2),hb21a(2),ch21b(2),hb21b(2)
326     integer ch22a(2),hb22a(2),ch22b(2),hb22b(2)
327     integer ch31a(3),hb31a(3),ch31b(3),hb31b(3)
328     integer ch32a(3),hb32a(3),ch32b(3),hb32b(3)
329    
330    
331     data ch11a / 4, 4, 4, 4, 1, 1, 2, 2/
332     data hb11a / 1, 3, 5, 7, 10, 12, 2, 4/
333     data ch11b / 2, 2, 2, 2, 1, 1, 1, 1/
334     data hb11b / 6, 8, 12, 10, 8, 6, 4, 2/
335    
336     data ch12a / 3, 3, 3, 3, 3, 3/
337     data hb12a / 2, 4, 6, 8, 10, 12/
338     data ch12b / 4, 4, 4, 4, 4, 4/
339     data hb12b / 12, 10, 8, 6, 4, 2/
340    
341     data ch21a / 1, 1/
342     data hb21a / 1, 5/
343     data ch21b / 2, 1/
344     data hb21b / 9, 7/
345    
346     data ch22a / 1, 1/
347     data hb22a / 3, 9/
348     data ch22b / 2, 1/
349     data hb22b / 11, 11/
350    
351     data ch31a / 2, 3, 3/
352     data hb31a / 7, 9, 11/
353     data ch31b / 2, 2, 2/
354     data hb31b / 5, 3, 1/
355    
356     data ch32a / 3, 3, 4/
357     data hb32a / 1, 5, 9/
358     data ch32b / 3, 3, 4/
359     data hb32b / 3, 7, 11/
360    
361     common / tofcalc /k1_s11s31,k1_s12s32,k1_S21S31,
362     & k1_S22S32,beta_a,
363     & adcx11,adcx12,adcx21,adcx22,adcx31,adcx32,
364     & tw11,tw12,tw21,tw22,tw31,tw32,
365     & y_coor_lin11,x_coor_lin12,x_coor_lin21,
366     & y_coor_lin22,y_coor_lin31,x_coor_lin32,
367     & xtofpos,ytofpos,adc_c,tof_i_flag,tof_j_flag
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375     xÓ÷YáòNÎÿýþÕÿVE óÿ@ {8Ý@·LÁSaÁSaÁ¯-<ümÂÕ;Jü·ÖÔûÿ*óÿ ÷nN¿Áé78ž.ïdÿ{ý¿û¿zýMèÿ {8ü:¸‹rÿ׿©ÿ—Z›Ÿÿk•ý?!pýGÐÇ¥—þe\ú—qéŸÓ
376     ê[ŠcTðÂþCÂÅ9Lü¯m;ÿËXÿ Á0§Á§Üÿ¿ºè“û_ÔÿZj™õ¿@¸þˆÞèÿÅ­`WeE+ ® ÊÊSÞ(\½CÌÿ[ºEèçsÿ?»{·‰<Üé•q§WÆ^y»Ókö×&‚ ‚ ‚ þ#¾A¥´àÈrun-test.sh0000751000076500001440000001003310314240675012052 0ustar mennusers#################################################################
377     # Shell script to run the tracker reduction programs
378     #################################################################
379     #
380     #
381     #
382     #----------------------------------------------------------------
383     #local variables:
384     rawdata_dir='raw-data/'
385     rzdata_dir='rz-test/'
386    
387     if [ -n "$1" -a -n "$2" ] ;then
388    
389     lines=$(grep -n -c $ $1)
390     list=`more $1`
391    
392     #################################################################
393     # ------------------------- LEVEL0 ------------------------------
394     #
395     # This part of the script creates the input to level0.exe and run it,
396     # starting from a txt list of file IDs (format: YYMMDD_XXX).
397     #
398     # Tipical input of level0.exe is as follows:
399     # ../level0.exe << EOF
400     # 5 # N. of downlink to process
401     # raw-data/ # raw-data directory
402     # 050323_011 # 1^ file id
403     # 050324_001 # 2^
404     # 050324_002 # ....
405     # 050324_003 #
406     # 050324_004 #
407     # rz-test/ # output rz directory
408     # 100000 # maximum number of events to be processed
409     # EOF
410     #################################################################
411     if [ $2 = 'level0' ]; then
412     echo $lines > input
413     echo $rawdata_dir >> input
414     for dnlk in $list
415     do
416     echo $dnlk >> input
417     done
418     echo $rzdata_dir >> input
419     echo '100000' >> input
420     ./level0.exe < input > $1-level0
421     # rm -f input
422    
423     #################################################################
424     # ------------------------- LEVEL1 ------------------------------
425     #
426     # This script creates the input to level1.exe and run it
427     # starting from a txt list of file IDs (format: YYMMDD_XXX).
428     #
429     # Tipical input of level1.exe is as follows:
430     # ../level1.exe << EOF
431     # raw-data/ # raw-data directory
432     # 050323_011 # file id
433     # rz-test/ # input/output rz directory
434     # 100000 # maximum number of events to be processed
435     # EOF
436     #################################################################
437     elif [ $2 = 'level1' ]; then
438     if [ -f $1-level1 ];then
439     rm $1-level1
440     fi
441     touch $1-level1
442     for dnlk in $list
443     do
444     ./level1.exe >> $1-level1 <<EOF
445     $rzdata_dir
446     $dnlk
447     100000
448     EOF
449     done
450     #################################################################
451     # ------------------------- LEVEL2 ------------------------------
452     #
453     # This script creates the input to level2.exe and run it
454     # starting from a txt list of file IDs (format: YYMMDD_XXX).
455     #
456     # Tipical input of level1.exe is as follows:
457     # ../level2.exe << EOF
458     # raw-data/ # raw-data directory
459     # 050323_011 # file id
460     # rz-test/ # input/output rz directory
461     # 100000 # maximum number of events to be processed
462     # F # (debug flag)
463     # EOF
464     #################################################################
465     elif [ $2 = 'level2' ]; then
466     if [ -f $1-level2 ];then
467     rm $1-level2
468     fi
469     touch $1-level2
470     for dnlk in $list
471     do
472     ./level2.exe >> $1-level2 <<EOF
473     $rzdata_dir
474     $dnlk
475     100000
476     COG2
477     F
478     EOF
479     done
480     #################################################################
481     # --------------------- TOFTRACK -----------------------------
482     #
483     # This script creates the input to tofsoft.exe and run it
484     # starting from a txt list of file IDs (format: YYMMDD_XXX).
485     #
486     # Typical input of toftrack.exe is as follows:
487     # ../toftrack.exe << EOF
488     # raw-data/ # raw-data directory
489     # 050323_011 # file id
490     # rz-test/ # input/output rz directory
491     # 100000 # maximum number of events to be processed
492     # F # (debug flag)
493     # EOF
494     #################################################################
495     elif [ $2 = 'toftrack' ]; then
496     if [ -f $1-toftrack ];then
497     rm $1-toftrack
498     fi
499     touch $1-toftrack
500     for dnlk in $list
501     do
502     ./toftrack.exe <<EOF
503     $rzdata_dir
504     $dnlk
505     1
506     100000
507     EOF
508     done
509     fi
510     else
511     echo ""
512     echo "USAGE:"
513     echo "./run-test.sh downlink-list-file-name level0/1/2/tofsoft"
514     echo "( ex: ./run-test.sh 050323.txt level0 & )"
515     echo "( ex: ./run-test.sh 050323.txt level1 & )"
516     echo "( ex: ./run-test.sh 050323.txt level2 & )"
517     echo "( ex: ./run-test.sh 050323.txt toftrack & )"
518     echo ""
519     fi
520    
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548     Pä PãHNAM€"   -ü¤R ( Qˆ Q‡HNAM€"  -ü¤Ztofroutine.f0000664000076500001440000006721310321442276012320 0ustar mennusers SUBROUTINE TOFROUTINE(XOUT,YOUT,ALPHA)
549    
550     C------------------------------------------------
551     C W. Menn
552     C
553     C Version 1.00 August 2005
554     C Version 1.01 7-oct-2005
555     C changed initialization values of xtofpos and ytofpos to "100."
556     C if the calculated values are unphysical (> +/- 100), then they
557     C are set to "101." to avoid problems in the attenuation calculation
558     C------------------------------------------------
559    
560    
561     include 'common_tofroutine.f'
562     include 'common_tof.f'
563    
564     c =======================================
565     c variables for tracking routine
566     c =======================================
567     parameter(NPOINT_MAX=100)
568     REAL XOUT(NPOINT_MAX),YOUT(NPOINT_MAX)
569     REAL ALPHA(5)
570    
571    
572     * ******************************************************************
573     * eventcounter
574     c write(*,*) '--- in beta.f ----'
575    
576    
577     * amplitude has to be 'secure' higher than pedestal for an adc event
578     secure = 2.
579    
580     xtop = 1000.0
581     xmid = 1000.0
582     xbot = 1000.0
583    
584     offset = 1
585     slope = 2
586     top = 1
587     mid = 2
588     bot = 3
589     left = 1
590     right = 2
591     none_ev = 0
592     none_find = 0
593     tdc_ev = 1
594     adc_ev = 1
595     itdc = 1
596     iadc = 2
597    
598     do i=1,5
599     beta_a(i) = 1000.
600     enddo
601    
602     do i=1,4
603     do j=1,12
604     adc_c(i,j) = 1000.
605     enddo
606     enddo
607    
608    
609     c the calibration files are read in the main program from xxx_tofcalib.rz
610    
611     IF (TOFfst.EQ.0) THEN
612     TOFfst = 1
613    
614     write(*,*) 'Calibration Data'
615     write(*,*) 'K1 data '
616     write(*,*) 'S11-S31'
617     DO i = 1,24
618     write(*,*) i,k1_S11S31(i)
619     ENDDO
620    
621     write(*,*) 'S12-S32'
622     DO i = 1,18
623     write (*,*) i,k1_S12S32(i)
624     ENDDO
625    
626     write(*,*) 'S21-S31'
627     DO i = 1,6
628     write(*,*) i,k1_S21S31(i)
629     ENDDO
630    
631     write(*,*) 'S22-S32'
632     DO i = 1,6
633     write (*,*) i,k1_S22S32(i)
634     ENDDO
635    
636    
637     C--- use TDC-difference to calculate incident point
638    
639     write(*,*) 'X-Y-Lin Coordinates'
640     DO i = 1, 8
641     write(*,*) i,y_coor_lin11(i,1),y_coor_lin11(i,2)
642     ENDDO
643     DO i = 1, 6
644     write(*,*) i,x_coor_lin12(i,1),x_coor_lin12(i,2)
645     ENDDO
646     DO i = 1, 2
647     write(*,*) i,x_coor_lin21(i,1),x_coor_lin21(i,2)
648     ENDDO
649     DO i = 1, 2
650     write(*,*) i,y_coor_lin22(i,1),y_coor_lin22(i,2)
651     ENDDO
652     DO i = 1, 3
653     write(*,*) i,y_coor_lin31(i,1),y_coor_lin31(i,2)
654     ENDDO
655     DO i = 1, 3
656     write(*,*) i,x_coor_lin32(i,1),x_coor_lin32(i,2)
657     ENDDO
658    
659     c---------- Time Walk
660    
661     write(*,*) 'Time Walk'
662     DO i = 1,8
663     write(*,*) i,tw11(left,i), tw11(right,i)
664     ENDDO
665     DO i = 1,6
666     write(*,*) i,tw12(left,i), tw12(right,i)
667     ENDDO
668     DO i = 1,2
669     write(*,*) i,tw21(left,i), tw21(right,i)
670     ENDDO
671     DO i = 1,2
672     write(*,*) i,tw22(left,i), tw22(right,i)
673     ENDDO
674     DO i = 1,3
675     write(*,*) i,tw31(left,i), tw31(right,i)
676     ENDDO
677     DO i = 1,3
678     write(*,*) i,tw32(left,i), tw32(right,i)
679     ENDDO
680    
681     c---------- ADC map
682     c read ADC correction file
683    
684     write(*,*) 'ADC Map'
685     write(*,*) 'ADC Map 1'
686     DO i = 1,8
687     write(*,*) (adcx11(left,i,j),j=1,2)
688     write(*,*) (adcx11(right,i,j),j=1,2)
689     ENDDO
690     DO i = 1,6
691     write(*,*) (adcx12(left,i,j),j=1,2)
692     write(*,*) (adcx12(right,i,j),j=1,2)
693     ENDDO
694    
695     write(*,*) 'ADC map 2'
696     DO i = 1,2
697     write(*,*) (adcx21(left,i,j),j=1,2)
698     write(*,*) (adcx21(right,i,j),j=1,2)
699     ENDDO
700     DO i = 1,2
701     write(*,*) (adcx22(left,i,j),j=1,2)
702     write(*,*) (adcx22(right,i,j),j=1,2)
703     ENDDO
704    
705     write(*,*) 'ADC map 3'
706     DO i = 1,3
707     write(*,*) (adcx31(left,i,j),j=1,2)
708     write(*,*) (adcx31(right,i,j),j=1,2)
709     ENDDO
710     DO i = 1,3
711     write(*,*) (adcx32(left,i,j),j=1,2)
712     write(*,*) (adcx32(right,i,j),j=1,2)
713     ENDDO
714    
715     ENDIF
716     c end of reading parameter files
717    
718     c------------------------- get ToF data --------------------------------
719    
720     c put the adc and tdc values from ntuple into tofxx(i,j,k) variables
721    
722     do j=1,8
723     tof11(1,j,2) = adc(ch11a(j),hb11a(j))
724     tof11(2,j,2) = adc(ch11b(j),hb11b(j))
725     tof11(1,j,1) = tdc(ch11a(j),hb11a(j))
726     tof11(2,j,1) = tdc(ch11b(j),hb11b(j))
727     c write(*,*) j,adc(ch11a(j),hb11a(j)),adc(ch11b(j),hb11b(j))
728     enddo
729    
730     do j=1,6
731     tof12(1,j,2) = adc(ch12a(j),hb12a(j))
732     tof12(2,j,2) = adc(ch12b(j),hb12b(j))
733     tof12(1,j,1) = tdc(ch12a(j),hb12a(j))
734     tof12(2,j,1) = tdc(ch12b(j),hb12b(j))
735     enddo
736    
737     do j=1,2
738     tof21(1,j,2) = adc(ch21a(j),hb21a(j))
739     tof21(2,j,2) = adc(ch21b(j),hb21b(j))
740     tof21(1,j,1) = tdc(ch21a(j),hb21a(j))
741     tof21(2,j,1) = tdc(ch21b(j),hb21b(j))
742     enddo
743    
744     do j=1,2
745     tof22(1,j,2) = adc(ch22a(j),hb22a(j))
746     tof22(2,j,2) = adc(ch22b(j),hb22b(j))
747     tof22(1,j,1) = tdc(ch22a(j),hb22a(j))
748     tof22(2,j,1) = tdc(ch22b(j),hb22b(j))
749     enddo
750    
751     do j=1,3
752     tof31(1,j,2) = adc(ch31a(j),hb31a(j))
753     tof31(2,j,2) = adc(ch31b(j),hb31b(j))
754     tof31(1,j,1) = tdc(ch31a(j),hb31a(j))
755     tof31(2,j,1) = tdc(ch31b(j),hb31b(j))
756     enddo
757    
758     do j=1,3
759     tof32(1,j,2) = adc(ch32a(j),hb32a(j))
760     tof32(2,j,2) = adc(ch32b(j),hb32b(j))
761     tof32(1,j,1) = tdc(ch32a(j),hb32a(j))
762     tof32(2,j,1) = tdc(ch32b(j),hb32b(j))
763     enddo
764    
765     C----------------------------------------------------------------------
766    
767     DO i = 1,8
768     if (abs(tof11(1,i,itdc)).gt.10000.) tof11(1,i,itdc)= 10000.
769     if (abs(tof11(2,i,itdc)).gt.10000.) tof11(2,i,itdc)= 10000.
770     if (abs(tof11(1,i,iadc)).gt.10000.) tof11(1,i,iadc)= 10000.
771     if (abs(tof11(2,i,iadc)).gt.10000.) tof11(2,i,iadc)= 10000.
772     ENDDO
773    
774     DO i = 1,6
775     if (abs(tof12(1,i,itdc)).gt.10000.) tof12(1,i,itdc)= 10000.
776     if (abs(tof12(2,i,itdc)).gt.10000.) tof12(2,i,itdc)= 10000.
777     if (abs(tof12(1,i,iadc)).gt.10000.) tof12(1,i,iadc)= 10000.
778     if (abs(tof12(2,i,iadc)).gt.10000.) tof12(2,i,iadc)= 10000.
779     ENDDO
780    
781    
782     DO i = 1,2
783     if (abs(tof21(1,i,itdc)).gt.10000.) tof21(1,i,itdc)= 10000.
784     if (abs(tof21(2,i,itdc)).gt.10000.) tof21(2,i,itdc)= 10000.
785     if (abs(tof21(1,i,iadc)).gt.10000.) tof21(1,i,iadc)= 10000.
786     if (abs(tof21(2,i,iadc)).gt.10000.) tof21(2,i,iadc)= 10000.
787     ENDDO
788    
789     DO i = 1,2
790     if (abs(tof22(1,i,itdc)).gt.10000.) tof22(1,i,itdc)= 10000.
791     if (abs(tof22(2,i,itdc)).gt.10000.) tof22(2,i,itdc)= 10000.
792     if (abs(tof22(1,i,iadc)).gt.10000.) tof22(1,i,iadc)= 10000.
793     if (abs(tof22(2,i,iadc)).gt.10000.) tof22(2,i,iadc)= 10000.
794     ENDDO
795    
796     DO i = 1,3
797     if (abs(tof31(1,i,itdc)).gt.10000.) tof31(1,i,itdc)= 10000.
798     if (abs(tof31(2,i,itdc)).gt.10000.) tof31(2,i,itdc)= 10000.
799     if (abs(tof31(1,i,iadc)).gt.10000.) tof31(1,i,iadc)= 10000.
800     if (abs(tof31(2,i,iadc)).gt.10000.) tof31(2,i,iadc)= 10000.
801     ENDDO
802    
803     DO i = 1,3
804     if (abs(tof32(1,i,itdc)).gt.10000.) tof32(1,i,itdc)= 10000.
805     if (abs(tof32(2,i,itdc)).gt.10000.) tof32(2,i,itdc)= 10000.
806     if (abs(tof32(1,i,iadc)).gt.10000.) tof32(1,i,iadc)= 10000.
807     if (abs(tof32(2,i,iadc)).gt.10000.) tof32(2,i,iadc)= 10000.
808     ENDDO
809    
810     C----------------------------------------------------------------
811     C------------ Check Paddles for hits -----------------------
812     C----------------------------------------------------------------
813    
814     C upper tof S11
815     DO i = 1,8
816     DO j = 1,2
817     tof11_event(j,i) = none_ev
818     IF ((tof11(j,i,itdc).LT.2000).AND.(tof11(j,i,itdc).GT.100))
819     + tof11_event(j,i) = tof11_event(j,i) + tdc_ev
820     IF ((tof11(j,i,iadc).GT.secure).AND.
821     + (tof11(j,i,iadc).LT.4095))
822     + tof11_event(j,i) = tof11_event(j,i) + adc_ev
823     ENDDO
824     ENDDO
825    
826     c find single paddle in upper tof with tdc and adc signal
827     tof11_i = none_find
828     tof11_j = none_find
829     check = .TRUE.
830     DO i = 1, 8
831     IF ((tof11_event(left,i).GE.1).AND.(tof11_event(right,i).GE.1))
832     + THEN
833     c check if an other paddle has also an event - then set flag
834     tof11_j = tof11_j + 2**(i-1)
835     IF (check.EQV..TRUE.) THEN
836     IF (tof11_i.EQ.none_find) THEN
837     tof11_i = i
838     ELSE
839     tof11_i = -1
840     check = .FALSE.
841     ENDIF
842     ENDIF
843     ENDIF
844     ENDDO
845    
846    
847     C upper tof S12
848     DO i = 1,6
849     DO j = 1,2
850     tof12_event(j,i) = none_ev
851     IF ((tof12(j,i,itdc).LT.2000).AND.(tof12(j,i,itdc).GT.100))
852     + tof12_event(j,i) = tof12_event(j,i) + tdc_ev
853     IF ((tof12(j,i,iadc).GT.secure).AND.
854     + (tof12(j,i,iadc).LT.4095))
855     + tof12_event(j,i) = tof12_event(j,i) + adc_ev
856     ENDDO
857     ENDDO
858    
859     c find single paddle in upper tof with tdc and adc signal
860     tof12_i = none_find
861     tof12_j = none_find
862     check = .TRUE.
863     DO i = 1, 6
864     IF ((tof12_event(left,i).GE.1).AND.(tof12_event(right,i).GE.1))
865     + THEN
866     c check if an other paddle has also an event - then set flag
867     tof12_j = tof12_j + 2**(i-1)
868     IF (check.EQV..TRUE.) THEN
869     IF (tof12_i.EQ.none_find) THEN
870     tof12_i = i
871     ELSE
872     tof12_i = -1
873     check = .FALSE.
874     ENDIF
875     ENDIF
876     ENDIF
877     ENDDO
878    
879    
880     C middle tof S21
881     DO i = 1,2
882     DO j = 1,2
883     tof21_event(j,i) = none_ev
884     IF ((tof21(j,i,itdc).LT.2000).AND.(tof21(j,i,itdc).GT.100))
885     + tof21_event(j,i) = tof21_event(j,i) + tdc_ev
886     IF ((tof21(j,i,iadc).GT.secure).AND.
887     + (tof21(j,i,iadc).LT.4095))
888     + tof21_event(j,i) = tof21_event(j,i) + adc_ev
889     ENDDO
890     ENDDO
891    
892     c find single paddle in upper tof with tdc and adc signal
893     tof21_i = none_find
894     tof21_j = none_find
895     check = .TRUE.
896     DO i = 1, 2
897     IF ((tof21_event(left,i).GE.1).AND.(tof21_event(right,i).GE.1))
898     + THEN
899     c check if an other paddle has also an event - then set flag
900     tof21_j = tof21_j + 2**(i-1)
901     IF (check.EQV..TRUE.) THEN
902     IF (tof21_i.EQ.none_find) THEN
903     tof21_i = i
904     ELSE
905     tof21_i = -1
906     check = .FALSE.
907     ENDIF
908     ENDIF
909     ENDIF
910     ENDDO
911    
912     C middle tof S22
913     DO i = 1,2
914     DO j = 1,2
915     tof22_event(j,i) = none_ev
916     IF ((tof22(j,i,itdc).LT.2000).AND.(tof22(j,i,itdc).GT.100))
917     + tof22_event(j,i) = tof22_event(j,i) + tdc_ev
918     IF ((tof22(j,i,iadc).GT.secure).AND.
919     + (tof22(j,i,iadc).LT.4095))
920     + tof22_event(j,i) = tof22_event(j,i) + adc_ev
921     ENDDO
922     ENDDO
923    
924     c find single paddle in upper tof with tdc and adc signal
925     tof22_i = none_find
926     tof22_j = none_find
927     check = .TRUE.
928     DO i = 1, 2
929     IF ((tof22_event(left,i).GE.1).AND.(tof22_event(right,i).GE.1))
930     + THEN
931     c check if an other paddle has also an event - then set flag
932     tof22_j = tof22_j + 2**(i-1)
933     IF (check.EQV..TRUE.) THEN
934     IF (tof22_i.EQ.none_find) THEN
935     tof22_i = i
936     ELSE
937     tof22_i = -1
938     check = .FALSE.
939     ENDIF
940     ENDIF
941     ENDIF
942     ENDDO
943    
944    
945     C bottom tof S31
946     DO i = 1,3
947     DO j = 1,2
948     tof31_event(j,i) = none_ev
949     IF ((tof31(j,i,itdc).LT.2000).AND.(tof31(j,i,itdc).GT.100))
950     + tof31_event(j,i) = tof31_event(j,i) + tdc_ev
951     IF ((tof31(j,i,iadc).GT.secure).AND.
952     + (tof31(j,i,iadc).LT.4095))
953     + tof31_event(j,i) = tof31_event(j,i) + adc_ev
954     ENDDO
955     ENDDO
956    
957     c find single paddle in upper tof with tdc and adc signal
958     tof31_i = none_find
959     tof31_j = none_find
960     check = .TRUE.
961     DO i = 1, 3
962     IF ((tof31_event(left,i).GE.1).AND.(tof31_event(right,i).GE.1))
963     + THEN
964     c check if an other paddle has also an event - then set flag
965     tof31_j = tof31_j + 2**(i-1)
966     IF (check.EQV..TRUE.) THEN
967     IF (tof31_i.EQ.none_find) THEN
968     tof31_i = i
969     ELSE
970     tof31_i = -1
971     check = .FALSE.
972     ENDIF
973     ENDIF
974     ENDIF
975     ENDDO
976    
977     C bottom tof S32
978     DO i = 1,3
979     DO j = 1,2
980     tof32_event(j,i) = none_ev
981     IF ((tof32(j,i,itdc).LT.2000).AND.(tof32(j,i,itdc).GT.100))
982     + tof32_event(j,i) = tof32_event(j,i) + tdc_ev
983     IF ((tof32(j,i,iadc).GT.secure).AND.
984     + (tof32(j,i,iadc).LT.4095))
985     + tof32_event(j,i) = tof32_event(j,i) + adc_ev
986     ENDDO
987     ENDDO
988    
989     c find single paddle in upper tof with tdc and adc signal
990     tof32_i = none_find
991     tof32_j = none_find
992     check = .TRUE.
993     DO i = 1, 3
994     IF ((tof32_event(left,i).GE.1).AND.(tof32_event(right,i).GE.1))
995     + THEN
996     c check if an other paddle has also an event - then set flag
997     tof32_j = tof32_j + 2**(i-1)
998     IF (check.EQV..TRUE.) THEN
999     IF (tof32_i.EQ.none_find) THEN
1000     tof32_i = i
1001     ELSE
1002     tof32_i = -1
1003     check = .FALSE.
1004     ENDIF
1005     ENDIF
1006     ENDIF
1007     ENDDO
1008    
1009     do i=1,6
1010     tof_i_flag(i)=0
1011     tof_j_flag(i)=0
1012     enddo
1013    
1014     tof_i_flag(1)=tof11_i
1015     tof_i_flag(2)=tof12_i
1016     tof_i_flag(3)=tof21_i
1017     tof_i_flag(4)=tof22_i
1018     tof_i_flag(5)=tof31_i
1019     tof_i_flag(6)=tof32_i
1020    
1021     tof_j_flag(1)=tof11_j
1022     tof_j_flag(2)=tof12_j
1023     tof_j_flag(3)=tof21_j
1024     tof_j_flag(4)=tof22_j
1025     tof_j_flag(5)=tof31_j
1026     tof_j_flag(6)=tof32_j
1027    
1028     C--------------------------------------------------------------------
1029     C-------------------- Time walk correction -------------------------
1030     C--------------------------------------------------------------------
1031    
1032     IF (tof11_i.GT.none_find) THEN
1033     tof11(left,tof11_i,itdc) = tof11(left,tof11_i,itdc) +
1034     + tw11(left,tof11_i)/sqrt(tof11(left,tof11_i,iadc))
1035     tof11(right,tof11_i,itdc) = tof11(right,tof11_i,itdc) +
1036     + tw11(right,tof11_i)/sqrt(tof11(right,tof11_i,iadc))
1037     ENDIF
1038    
1039    
1040     IF (tof12_i.GT.none_find) THEN
1041     tof12(left,tof12_i,itdc) = tof12(left,tof12_i,itdc) +
1042     + tw12(left,tof12_i)/sqrt(tof12(left,tof12_i,iadc))
1043     tof12(right,tof12_i,itdc) = tof12(right,tof12_i,itdc) +
1044     + tw12(right,tof12_i)/sqrt(tof12(right,tof12_i,iadc))
1045     ENDIF
1046    
1047     IF (tof21_i.GT.none_find) THEN
1048     tof21(left,tof21_i,itdc) = tof21(left,tof21_i,itdc) +
1049     + tw21(left,tof21_i)/sqrt(tof21(left,tof21_i,iadc))
1050     tof21(right,tof21_i,itdc) = tof21(right,tof21_i,itdc) +
1051     + tw21(right,tof21_i)/sqrt(tof21(right,tof21_i,iadc))
1052     ENDIF
1053     IF (tof22_i.GT.none_find) THEN
1054     tof22(left,tof22_i,itdc) = tof22(left,tof22_i,itdc) +
1055     + tw22(left,tof22_i)/sqrt(tof22(left,tof22_i,iadc))
1056     tof22(right,tof22_i,itdc) = tof22(right,tof22_i,itdc) +
1057     + tw22(right,tof22_i)/sqrt(tof22(right,tof22_i,iadc))
1058     ENDIF
1059    
1060     IF (tof31_i.GT.none_find) THEN
1061     tof31(left,tof31_i,itdc) = tof31(left,tof31_i,itdc) +
1062     + tw31(left,tof31_i)/sqrt(tof31(left,tof31_i,iadc))
1063     tof31(right,tof31_i,itdc) = tof31(right,tof31_i,itdc) +
1064     + tw31(right,tof31_i)/sqrt(tof31(right,tof31_i,iadc))
1065     ENDIF
1066    
1067     IF (tof32_i.GT.none_find) THEN
1068     tof32(left,tof32_i,itdc) = tof32(left,tof32_i,itdc) +
1069     + tw32(left,tof32_i)/sqrt(tof32(left,tof32_i,iadc))
1070     tof32(right,tof32_i,itdc) = tof32(right,tof32_i,itdc) +
1071     + tw32(right,tof32_i)/sqrt(tof32(right,tof32_i,iadc))
1072     ENDIF
1073    
1074    
1075     C------------------------------------------------------------------
1076     C--- calculate track position in paddle using timing difference
1077     C------------------------------------------------------------------
1078    
1079     do i=1,3
1080     xtofpos(i)=100.
1081     ytofpos(i)=100.
1082     enddo
1083     C----------------------------- S1 --------------------------------
1084    
1085     IF (tof11_i.GT.none_find) THEN
1086     ytofpos(1) = ((tof11(1,tof11_i,itdc)-tof11(2,tof11_i,itdc))/2.
1087     + - y_coor_lin11(tof11_i,offset))/y_coor_lin11(tof11_i,slope)
1088     endif
1089    
1090     IF (tof12_i.GT.none_find) THEN
1091     xtofpos(1) = ((tof12(1,tof12_i,itdc)-tof12(2,tof12_i,itdc))/2.
1092     + - x_coor_lin12(tof12_i,offset))/x_coor_lin12(tof12_i,slope)
1093     endif
1094    
1095    
1096     C----------------------------- S2 --------------------------------
1097    
1098     IF (tof21_i.GT.none_find) THEN
1099     xtofpos(2) = ((tof21(1,tof21_i,itdc)-tof21(2,tof21_i,itdc))/2.
1100     + - x_coor_lin21(tof21_i,offset))/x_coor_lin21(tof21_i,slope)
1101     endif
1102    
1103     IF (tof22_i.GT.none_find) THEN
1104     ytofpos(2) = ((tof22(1,tof22_i,itdc)-tof22(2,tof22_i,itdc))/2.
1105     + - y_coor_lin22(tof22_i,offset))/y_coor_lin22(tof22_i,slope)
1106     endif
1107    
1108    
1109     C----------------------------- S3 --------------------------------
1110    
1111     IF (tof31_i.GT.none_find) THEN
1112     ytofpos(3) = ((tof31(1,tof31_i,itdc)-tof31(2,tof31_i,itdc))/2.
1113     + - y_coor_lin31(tof31_i,offset))/y_coor_lin31(tof31_i,slope)
1114     c write(*,*) '31',tof31(1,tof31_i,itdc),tof31(2,tof31_i,itdc),
1115     c + y_coor_lin31(tof31_i,offset),y_coor_lin31(tof31_i,slope),
1116     c + ytofpos(3)
1117     endif
1118    
1119     IF (tof32_i.GT.none_find) THEN
1120     xtofpos(3) = ((tof32(1,tof32_i,itdc)-tof32(2,tof32_i,itdc))/2.
1121     + - x_coor_lin32(tof32_i,offset))/x_coor_lin32(tof32_i,slope)
1122     c write(*,*) '32',tof32(1,tof32_i,itdc),tof32(2,tof32_i,itdc),
1123     c + x_coor_lin32(tof32_i,offset),x_coor_lin32(tof32_i,slope),
1124     c + xtofpos(3)
1125     endif
1126    
1127    
1128     do i=1,3
1129     if (abs(xtofpos(i)).gt.100.) then
1130     xtofpos(i)=101.
1131     endif
1132     if (abs(ytofpos(i)).gt.100.) then
1133     ytofpos(i)=101.
1134     endif
1135     enddo
1136    
1137    
1138     C----------------------------------------------------------------------
1139     C-------------------- Corrections on ADC-data -------------------------
1140     C--------------------- zenith angle theta ---------------------------
1141     C----------------------------------------------------------------------
1142    
1143     C if we have a good track use tracking information
1144    
1145     dx=0.
1146     dy=0.
1147     dr=0.
1148     theta13 = 0.
1149    
1150     if (xout(1).lt.100.) then
1151     dx = xout(1)-xout(3)
1152     dy = yout(1)-yout(3)
1153     dr = sqrt(dx*dx+dy*dy)
1154     theta13 = atan(dr/tofarm13)
1155     else
1156     IF ((tof12_i.GT.none_find).AND.(tof32_i.GT.none_find))
1157     & dx = xtofpos(1) - xtofpos(3)
1158     IF ((tof11_i.GT.none_find).AND.(tof31_i.GT.none_find))
1159     & dy = ytofpos(1) - ytofpos(3)
1160     dr = sqrt(dx*dx+dy*dy)
1161     theta13 = atan(dr/tofarm13)
1162     endif
1163    
1164    
1165     C----------------------------------------------------------------------
1166     C------------------ angle and ADC(x) correction
1167     C----------------------------------------------------------------------
1168     C----------------------------- S1 --------------------------------
1169    
1170     yhelp=1000.
1171     if (yout(1).lt.100.) then
1172     yhelp=yout(1)
1173     else
1174     yhelp=ytofpos(1)
1175     endif
1176    
1177    
1178     IF (tof11_i.GT.none_find.AND.yhelp.lt.100) THEN
1179    
1180     i = tof11_i
1181     xdummy=tof11(left,i,iadc)
1182     tof11(left,i,iadc) = tof11(left,i,iadc)*cos(theta13)
1183     if (tof11(left,i,iadc).lt.1000) then
1184     xkorr=adcx11(left,i,1)*exp(-yhelp/adcx11(left,i,2))
1185     xkorr0=adcx11(left,i,1)
1186     adc_c(ch11a(i),hb11a(i))=tof11(left,i,iadc)/xkorr
1187     endif
1188    
1189     tof11(right,i,iadc) = tof11(right,i,iadc)*cos(theta13)
1190     if (tof11(right,i,iadc).lt.1000) then
1191     xkorr=adcx11(right,i,1)*exp(yhelp/adcx11(right,i,2))
1192     xkorr0=adcx11(right,i,1)
1193     adc_c(ch11b(i),hb11b(i))=tof11(right,i,iadc)/xkorr
1194     endif
1195     ENDIF
1196    
1197    
1198     xhelp=1000.
1199     if (xout(1).lt.100.) then
1200     xhelp=xout(1)
1201     else
1202     xhelp=xtofpos(1)
1203     endif
1204    
1205    
1206     IF (tof12_i.GT.none_find.AND.xhelp.lt.100) THEN
1207    
1208     i = tof12_i
1209     tof12(left,i,iadc) = tof12(left,i,iadc)*cos(theta13)
1210     if (tof12(left,i,iadc).lt.1000) then
1211     xkorr=adcx12(left,i,1)*exp(-xhelp/adcx12(left,i,2))
1212     xkorr0=adcx12(left,i,1)
1213     adc_c(ch12a(i),hb12a(i))=tof12(left,i,iadc)/xkorr
1214     endif
1215    
1216     tof12(right,i,iadc) = tof12(right,i,iadc)*cos(theta13)
1217     if (tof12(right,i,iadc).lt.1000) then
1218     xkorr=adcx12(right,i,1)*exp(xhelp/adcx12(right,i,2))
1219     xkorr0=adcx12(right,i,1)
1220     adc_c(ch12b(i),hb12b(i))=tof12(right,i,iadc)/xkorr
1221     endif
1222     ENDIF
1223    
1224     C----------------------------- S2 --------------------------------
1225    
1226     xhelp=1000.
1227     if (xout(2).lt.100.) then
1228     xhelp=xout(2)
1229     else
1230     xhelp=xtofpos(2)
1231     endif
1232    
1233     IF (tof21_i.GT.none_find.AND.xhelp.lt.100) THEN
1234    
1235     i = tof21_i
1236     tof21(left,i,iadc) = tof21(left,i,iadc)*cos(theta13)
1237     if (tof21(left,i,iadc).lt.1000) then
1238     xkorr=adcx21(left,i,1)*exp(-xhelp/adcx21(left,i,2))
1239     xkorr0=adcx21(left,i,1)
1240     adc_c(ch21a(i),hb21a(i))=tof21(left,i,iadc)/xkorr
1241     endif
1242    
1243     tof21(right,i,iadc) = tof21(right,i,iadc)*cos(theta13)
1244     if (tof21(right,i,iadc).lt.1000) then
1245     xkorr=adcx21(right,i,1)*exp(xhelp/adcx21(right,i,2))
1246     xkorr0=adcx21(right,i,1)
1247     adc_c(ch21b(i),hb21b(i))=tof21(right,i,iadc)/xkorr
1248     endif
1249     ENDIF
1250    
1251     yhelp=1000.
1252     if (yout(2).lt.100.) then
1253     yhelp=yout(2)
1254     else
1255     yhelp=ytofpos(2)
1256     endif
1257    
1258     IF (tof22_i.GT.none_find.AND.yhelp.lt.100) THEN
1259    
1260     i = tof22_i
1261     tof22(left,i,iadc) = tof22(left,i,iadc)*cos(theta13)
1262     if (tof22(left,i,iadc).lt.1000) then
1263     xkorr=adcx22(left,i,1)*exp(-yhelp/adcx22(left,i,2))
1264     xkorr0=adcx22(left,i,1)
1265     adc_c(ch22a(i),hb22a(i))=tof22(left,i,iadc)/xkorr
1266     endif
1267    
1268     tof22(right,i,iadc) = tof22(right,i,iadc)*cos(theta13)
1269     if (tof22(right,i,iadc).lt.1000) then
1270     xkorr=adcx22(right,i,1)*exp(yhelp/adcx22(right,i,2))
1271     xkorr0=adcx22(right,i,1)
1272     adc_c(ch22b(i),hb22b(i))=tof22(right,i,iadc)/xkorr
1273     endif
1274     ENDIF
1275    
1276     C----------------------------- S3 --------------------------------
1277    
1278     yhelp=1000.
1279     if (yout(3).lt.100.) then
1280     yhelp=yout(3)
1281     else
1282     yhelp=ytofpos(3)
1283     endif
1284    
1285     IF (tof31_i.GT.none_find.AND.yhelp.lt.100) THEN
1286    
1287     i = tof31_i
1288     tof31(left,i,iadc) = tof31(left,i,iadc)*cos(theta13)
1289     if (tof31(left,i,iadc).lt.1000) then
1290     xkorr=adcx31(left,i,1)*exp(-yhelp/adcx31(left,i,2))
1291     xkorr0=adcx31(left,i,1)
1292     adc_c(ch31a(i),hb31a(i))=tof31(left,i,iadc)/xkorr
1293     endif
1294    
1295     tof31(right,i,iadc) = tof31(right,i,iadc)*cos(theta13)
1296     if (tof31(right,i,iadc).lt.1000) then
1297     xkorr=adcx31(right,i,1)*exp(yhelp/adcx31(right,i,2))
1298     xkorr0=adcx31(right,i,1)
1299     adc_c(ch31b(i),hb31b(i))=tof31(right,i,iadc)/xkorr
1300     endif
1301     ENDIF
1302    
1303     xhelp=1000.
1304     if (xout(3).lt.100.) then
1305     xhelp=xout(3)
1306     else
1307     xhelp=xtofpos(3)
1308     endif
1309    
1310     IF (tof32_i.GT.none_find.AND.xhelp.lt.100) THEN
1311    
1312     i = tof32_i
1313     tof32(left,i,iadc) = tof32(left,i,iadc)*cos(theta13)
1314     if (tof32(left,i,iadc).lt.1000) then
1315     xkorr=adcx32(left,i,1)*exp(-xhelp/adcx32(left,i,2))
1316     xkorr0=adcx32(left,i,1)
1317     adc_c(ch32a(i),hb32a(i))=tof32(left,i,iadc)/xkorr
1318     endif
1319    
1320     tof32(right,i,iadc) = tof32(right,i,iadc)*cos(theta13)
1321     if (tof32(right,i,iadc).lt.1000) then
1322     xkorr=adcx32(right,i,1)*exp(xhelp/adcx32(right,i,2))
1323     xkorr0=adcx32(right,i,1)
1324     adc_c(ch32b(i),hb32b(i))=tof32(right,i,iadc)/xkorr
1325     endif
1326     ENDIF
1327    
1328     C-----------------------------------------------------------------------
1329     C---------------------- calculate Beta ------------------------------
1330     C-----------------------------------------------------------------------
1331     C------------------- difference of sums ---------------------------
1332     C
1333     C DS = (t1+t2) - t3+t4)
1334     C DS = c1 + c2/beta*cos(theta)
1335     C c2 = 2d/c gives c2 = 2d/(c*TDCresolution) TDC=50ps/channel
1336     C => c2_23 = 60 for 0.45 m c2_13 = 109 for 0.81 m
1337    
1338     C S11 - S31
1339     IF (tof11_i.GT.none_find.AND.tof31_i.GT.none_find) THEN
1340     xhelp1 = tof11(1,tof11_i,itdc)+tof11(2,tof11_i,itdc)
1341     xhelp2 = tof31(1,tof31_i,itdc)+tof31(2,tof31_i,itdc)
1342     ds = xhelp1-xhelp2
1343     ihelp=(tof11_i-1)*3+tof31_i
1344     c1 = k1_S11S31(ihelp)
1345     beta_a(1) = c2_13/(cos(theta13)*(ds-c1))
1346     ENDIF
1347    
1348     C S12 - S32
1349     IF (tof12_i.GT.none_find.AND.tof32_i.GT.none_find) THEN
1350     xhelp1 = tof12(1,tof12_i,itdc)+tof12(2,tof12_i,itdc)
1351     xhelp2 = tof32(1,tof32_i,itdc)+tof32(2,tof32_i,itdc)
1352     ds = xhelp1-xhelp2
1353     ihelp=(tof12_i-1)*3+tof32_i
1354     c1 = k1_S12S32(ihelp)
1355     beta_a(2) = c2_13/(cos(theta13)*(ds-c1))
1356     ENDIF
1357    
1358    
1359     C S21 - S31
1360     IF (tof21_i.GT.none_find.AND.tof31_i.GT.none_find) THEN
1361     xhelp1 = tof21(1,tof21_i,itdc)+tof21(2,tof21_i,itdc)
1362     xhelp2 = tof31(1,tof31_i,itdc)+tof31(2,tof31_i,itdc)
1363     ds = xhelp1-xhelp2
1364     ihelp=(tof21_i-1)*3+tof31_i
1365     c1 = k1_S21S31(ihelp)
1366     beta_a(3) = c2_23/(cos(theta13)*(ds-c1))
1367     ENDIF
1368    
1369     C S22 - S32
1370     IF (tof22_i.GT.none_find.AND.tof32_i.GT.none_find) THEN
1371     xhelp1 = tof22(1,tof22_i,itdc)+tof22(2,tof22_i,itdc)
1372     xhelp2 = tof32(1,tof32_i,itdc)+tof32(2,tof32_i,itdc)
1373     ds = xhelp1-xhelp2
1374     ihelp=(tof22_i-1)*3+tof32_i
1375     c1 = k1_S22S32(ihelp)
1376     beta_a(4) = c2_23/(cos(theta13)*(ds-c1))
1377     ENDIF
1378    
1379     C-------
1380    
1381     icount=0
1382     sw=0.
1383     sxw=0.
1384     beta_mean=100.
1385    
1386     do i=1,4
1387     if ((beta_a(i).gt.0.4).and.(beta_a(i).lt.1.5)) then
1388     icount= icount+1
1389     if (i.le.2) w_i=1./(0.13**2.)
1390     if (i.ge.3) w_i=1./(0.16**2.)
1391     sxw=sxw + beta_a(i)*w_i
1392     sw =sw + w_i
1393     endif
1394     enddo
1395     if (icount.eq.4) beta_mean=sxw/sw
1396     beta_a(5) = beta_mean
1397    
1398    
1399     c ERROR MESSAGES
1400     100 continue
1401     *
1402     RETURN
1403     END
1404    
1405     toftrack.f0000775000076500001440000004000510321444754011733 0ustar mennusersC------------------------------------------------
1406     PROGRAM TOFTRACK
1407     C------------------------------------------------
1408     C W. Menn
1409     C
1410     C Based on the "template" progran from Elena Vannuccini
1411     C
1412     C Version 1.00 August 2005
1413     C Version 1.01 07-oct-2005: Some bugs found
1414     C - new rz file must be named "***_toftrack.rz'
1415     C - booking of the EVENT and CPU blocks changed according
1416     C to Elena's "book_level2" routine
1417     C
1418     C------------------------------------------------
1419    
1420     include 'trk_level2.f'
1421     include 'common_tofroutine.f'
1422     include 'common_tof.f'
1423    
1424     c----- HBOOK
1425     INTEGER HMEM
1426     parameter (NWPAWC=8500000)
1427     common/PAWC/HMEM(NWPAWC)
1428    
1429     parameter (ntp_level2=22)
1430     parameter (ntp_new=2)
1431    
1432     c------------------------------------------------------------------------
1433     c local variables
1434     c------------------------------------------------------------------------
1435     character*74 data_file !data file name
1436     character*74 tof_file !tofdata file name
1437     character*74 data_dir !data directory
1438     character*74 data_file_level2
1439     character*74 data_file_tof
1440     character*74 data_file_tofcalib
1441     character*74 data_file_new
1442    
1443     parameter (lun_data_level2=72) !data file id number
1444    
1445     c------------------------------------------------------------------
1446     COMMON/QUEST/IQUEST(100)
1447    
1448     C------------------------------------------------------------------
1449     c =======================================
1450     c variables for tracking routine
1451     c =======================================
1452     parameter(NPOINT_MAX=100)
1453     DOUBLE PRECISION ZIN(NPOINT_MAX)
1454     DOUBLE PRECISION XOUT1(NPOINT_MAX),YOUT1(NPOINT_MAX)
1455     REAL XOUT(NPOINT_MAX),YOUT(NPOINT_MAX)
1456     DOUBLE PRECISION AL_P(5)
1457     REAL XFIT(6),YFIT(6),ZFIT(6),ALPHA(5),XGOOD1(6),YGOOD1(6)
1458     c =======================================
1459    
1460     c define TOF Z-coordinates
1461     parameter (NPTOF=3)
1462     REAL ZTOF(NPTOF)
1463     c DATA ZTOF/55.,25.,-23/ !NB!!! from TOP to BOTTOM
1464     DATA ZTOF/53.4,23.9,-23.4/ !Stockholm 29.9.2005
1465    
1466     c------------------------------------------------------------------------
1467     C
1468     CHARACTER*100 name
1469     C
1470    
1471     INTEGER lrec, openntuple
1472     INTEGER istat, ierr, icycle
1473     PARAMETER (lrec=4096)
1474    
1475    
1476     integer patterntrig1(6)
1477     real chi
1478    
1479     character*35 block1,block2
1480    
1481     C-------------------------------------------------------------------------
1482     c
1483     c HBOOK initialization
1484     c
1485     c------------------------------------------------------------------------
1486    
1487     call HLIMIT(NWPAWC)
1488    
1489     C HERE A PATH where you can write!
1490     C
1491     c print *
1492     c print *,'File saved in: ',name
1493     C
1494     C CHANGE here (hbname and hbnt if you want another ntuple id number
1495     C
1496    
1497     111 format(a)
1498     print*,'data dir:'
1499     read(*,111)data_dir
1500     c read(*,*)data_dir
1501     print*,data_dir
1502     print*,'tof file?'
1503     print*,'(without estention: output_YYMMDD_XXX )'
1504     read(*,*)tof_file
1505    
1506     print*,tof_file
1507     print*,' '
1508    
1509     print*,'first event:'
1510     read(*,*) minevent
1511     print*,minevent
1512     c print*,' '
1513    
1514     print*,'number of events to be analysed'
1515     read(*,*) ntotev
1516     print*,ntotev
1517    
1518    
1519     c------------------------------------------------------------------------
1520     c--------------- open ToF rz file
1521     c------------------------------------------------------------------------
1522    
1523     print*,
1524     $ data_dir(1:LNBLNK(data_dir))//tof_file(1:LNBLNK(tof_file))
1525    
1526    
1527     505 format(a,'DW_',a,'_tof.rz')
1528     write(data_file_tof,505)
1529     $ data_dir(1:LNBLNK(data_dir))
1530     $ ,tof_file(1:LNBLNK(tof_file))
1531     print*,'__________ opening TOF rz file __________'
1532     print*,data_file_tof
1533    
1534    
1535     call HROPEN(59,
1536     $ 'EVENT',data_file_tof,'QP',4096,istat) !opens rz
1537    
1538    
1539     if(istat.ne.0) stop
1540     print*,' '
1541     print*,'reading TOF n-tuple...'
1542     call HRIN(ntp_tof,9999,0)
1543     CALL HBNAME(ntp_tof,' ',0,'$CLEAR')
1544     CALL HBNAME(ntp_tof,'EVENT',good,'$SET')
1545     CALL HBNAME(ntp_tof,'TRIGGER',trig_evcount,'$SET')
1546     CALL HBNAME(ntp_tof,'TOF',tdcid,'$SET')
1547     call HPRNTU(ntp_tof)
1548     call HNOENT(ntp_tof,iemax0)
1549     write(*,*) 'Number of events ToF ',iemax0
1550    
1551    
1552     c------------------------------------------------------------------------
1553     c--------------- open ToF calib rz file
1554     c------------------------------------------------------------------------
1555    
1556     print*,
1557     $ data_dir(1:LNBLNK(data_dir))//tof_file(1:LNBLNK(tof_file))
1558    
1559     506 format(a,'DW_',a,'_tofcalib.rz')
1560     write(data_file_tofcalib,506)
1561     $ data_dir(1:LNBLNK(data_dir))
1562     $ ,tof_file(1:LNBLNK(tof_file))
1563     print*,'__________ opening TOF calib rz file __________'
1564     print*,data_file_tofcalib
1565    
1566     CALL HROPEN(59,'TOF K1A',data_file_tofcalib,'QP',4096,istat)
1567    
1568     if (istat.ne.0) then ! check if HROPEN was OK
1569     write(*,*) 'Can''t open correct ToF calibration File !!!'
1570     write(*,*) 'Will use standard file tofcalib.rz !!!'
1571     507 format(a,'tofcalib.rz')
1572     write(data_file_tofcalib,507)
1573     $ data_dir(1:LNBLNK(data_dir))
1574     print*,'__________ opening TOF calib rz file __________'
1575     print*,data_file_tofcalib
1576    
1577     CALL HROPEN(59,'TOF K1A',data_file_tofcalib,'QP',4096,istat)
1578     endif
1579    
1580     print*,' reading TOF CALIB n-tuple...'
1581    
1582     call HRIN(ntp_tofcalib,9999,0)
1583    
1584     call HBNAME(ntp_tofcalib,' ',0,'$CLEAR')
1585    
1586     call HBNAME(ntp_tofcalib,'TOFK1A',k1_s11s31,'$SET')
1587     call HBNAME(ntp_tofcalib,'TOFK1B',k1_s12s32,'$SET')
1588     call HBNAME(ntp_tofcalib,'TOFK1C',k1_s21s31,'$SET')
1589     call HBNAME(ntp_tofcalib,'TOFK1D',k1_s22s32,'$SET')
1590    
1591     call HBNAME(ntp_tofcalib,'TOFLIN11',y_coor_lin11,'$SET')
1592     call HBNAME(ntp_tofcalib,'TOFLIN12',x_coor_lin12,'$SET')
1593     call HBNAME(ntp_tofcalib,'TOFLIN21',x_coor_lin21,'$SET')
1594     call HBNAME(ntp_tofcalib,'TOFLIN22',y_coor_lin22,'$SET')
1595     call HBNAME(ntp_tofcalib,'TOFLIN31',y_coor_lin31,'$SET')
1596     call HBNAME(ntp_tofcalib,'TOFLIN32',x_coor_lin32,'$SET')
1597    
1598     call HBNAME(ntp_tofcalib,'TOFTW11',tw11,'$SET')
1599     call HBNAME(ntp_tofcalib,'TOFTW12',tw12,'$SET')
1600     call HBNAME(ntp_tofcalib,'TOFTW21',tw21,'$SET')
1601     call HBNAME(ntp_tofcalib,'TOFTW22',tw22,'$SET')
1602     call HBNAME(ntp_tofcalib,'TOFTW31',tw31,'$SET')
1603     call HBNAME(ntp_tofcalib,'TOFTW32',tw32,'$SET')
1604    
1605     call HBNAME(ntp_tofcalib,'TOFADC11',adcx11,'$SET')
1606     call HBNAME(ntp_tofcalib,'TOFADC12',adcx12,'$SET')
1607     call HBNAME(ntp_tofcalib,'TOFADC21',adcx21,'$SET')
1608     call HBNAME(ntp_tofcalib,'TOFADC22',adcx22,'$SET')
1609     call HBNAME(ntp_tofcalib,'TOFADC31',adcx31,'$SET')
1610     call HBNAME(ntp_tofcalib,'TOFADC32',adcx32,'$SET')
1611    
1612     call HPRNTU(ntp_tofcalib)
1613    
1614     call HNOENT(ntp_tofcalib,iemax_cal)
1615     c write(*,*) 'Number of Events CALIB ',iemax_cal
1616    
1617     do iev=1,iemax_cal
1618     call HGNT(ntp_tofcalib,iev,ierr) !reads an event
1619     enddo
1620    
1621     call hrout(ntp_tofcalib,icycle,' ')
1622     call hrend('TOF K1A')
1623     close(0)
1624    
1625    
1626    
1627     c------------------------------------------------------------------------
1628     c--------------- open Track Level2 rz file
1629     c------------------------------------------------------------------------
1630    
1631     data_file=tof_file
1632     print*,'data dir:'
1633     c read(*,111)data_dir
1634     print*,data_dir
1635     c print*,'data file?'
1636     c print*,'(without estention: output_YYMMDD_XXX )'
1637     c read(*,*)data_file
1638    
1639     print*,'data_file:'
1640     print*,data_file
1641     print*,' '
1642    
1643     print*,
1644     $ data_dir(1:LNBLNK(data_dir))//data_file(1:LNBLNK(data_file))
1645    
1646     c------------------------------------------------------------------------
1647     504 format(a,'DW_',a,'_level2.rz')
1648     write(data_file_level2,504)
1649     $ data_dir(1:LNBLNK(data_dir))
1650     $ ,data_file(1:LNBLNK(data_file))
1651     print*,'__________ opening LEVEL2 rz file __________'
1652     print*,data_file_level2
1653     print*,'__________ opening LEVEL2 rz file __________'
1654     print*,data_file_level2
1655     IQUEST(10)=65000
1656     call HROPEN(lun_data_level2,
1657     $ 'LEVEL2',data_file_level2,'QP',4096,istat) !opens rz
1658     if(istat.ne.0) goto 19
1659     print*,'reading LEVEL2 n-tuple...'
1660     call HRIN(ntp_level2,9999,0)
1661    
1662     * -----------------------------------------------
1663     CALL HBNAME(ntp_level2,' ',0,'$CLEAR')
1664     CALL HBNAME(ntp_level2,'EVENT',GOOD2,'$SET')
1665     CALL HBNAME(ntp_level2,'CPU',pkt_type,'$SET')
1666     CALL HBNAME(ntp_level2,'TRACKS',ntrk,'$SET')
1667     CALL HBNAME(ntp_level2,'SINGLETS',nclsx,'$SET')
1668     * -----------------------------------------------
1669    
1670     call HPRNTU(ntp_level2)
1671     call HNOENT(ntp_level2,iemax2)
1672    
1673     write(*,*) 'Number of events LEVEL2 ',iemax2
1674     print*,'ok'
1675     print*,' '
1676    
1677    
1678    
1679     c------------------------------------------------------------------------
1680     c read magnetic field map
1681     c------------------------------------------------------------------------
1682     c
1683     c =======================
1684    
1685    
1686     c read magnetic field map
1687     c =======================
1688     c
1689     c------------------------------------------------------------------------
1690     print*,'- read magnetic field map'
1691     print*,' '
1692     call read_B
1693     print*,' '
1694    
1695     c print*,' '
1696     c print*,'- read magnetic field map'
1697     c print*,' '
1698     c call read_B_2maps
1699     c
1700    
1701    
1702     c------------------------------------------------------------------------
1703     c open new RZ file
1704     c------------------------------------------------------------------------
1705    
1706     503 format(a,'DW_',a,'_toftrack.rz')
1707     write(data_file_new,503)
1708     $ data_dir(1:LNBLNK(data_dir))
1709     $ ,data_file(1:LNBLNK(data_file))
1710     print*,'__________ opening NEW rz file __________'
1711     print*,data_file_new
1712    
1713    
1714     call HROPEN(10,'TEST',data_file_new,'NP',4096,istat) !opens rz
1715    
1716     call HBNT(ntp_new,'TOF',' ')
1717    
1718    
1719     c call HBNAME(ntp_new,'EVENT',good,'GOOD:L,NEV_TRK:I')
1720    
1721     call HBNAME(ntp_new,'EVENT',good2,'GOOD2:L,NEV2:I')
1722    
1723    
1724     c call HBNAME(ntp_new,'CPU',pkt_type
1725     c $ ,'PKT_TYPE:I
1726     c $ ,PKT_NUM:I
1727     c $ ,OBT:I
1728     c $ ,WHICH_CALIB:I')
1729    
1730     call HBNAME(ntp_new,'CPU',pkt_type
1731     $ ,'PKT_TYPE:I::[0,50]
1732     $ ,PKT_NUM:I
1733     $ ,OBT:I
1734     $ ,WHICH_CALIB:I::[0,50]')
1735    
1736    
1737    
1738     call HBNAME(ntp_new,'TOF',tdcid
1739     $ ,'TDCID(12):I
1740     $ ,EVCOUNT(12):I
1741     $ ,TDCMASK(12):I
1742     $ ,ADC(4,12):I
1743     $ ,TDC(4,12):I
1744     $ ,TEMP1(12):I
1745     $ ,TEMP2(12):I')
1746    
1747     call HBNAME(ntp_new,'TOF',beta_a,'BETA(5)')
1748     call HBNAME(ntp_new,'TOF',xtofpos,'XTOF(3)')
1749     call HBNAME(ntp_new,'TOF',ytofpos,'YTOF(3)')
1750     call HBNAME(ntp_new,'TOF',adc_c,'ADC_C(4,12)')
1751     call HBNAME(ntp_new,'TOF',tof_i_flag,'IFLAG(6)')
1752     call HBNAME(ntp_new,'TOF',tof_j_flag,'JFLAG(6)')
1753    
1754     call HBNAME(ntp_new,'TOF',xout,'XOUT(3)')
1755     call HBNAME(ntp_new,'TOF',yout,'YOUT(3)')
1756    
1757    
1758     call HBNAME(ntp_new,'TRIGGER',trig_evcount
1759     $ ,'TRIG_EVCOUNT:I
1760     $ ,PMTPL(3):I
1761     $ ,TRIGRATE(6):I
1762     $ ,DLTIME(2):I
1763     $ ,S4CALCOUNT(2):I
1764     $ ,PMTCOUNT1(24):I
1765     $ ,PMTCOUNT2(24):I
1766     $ ,PATTERNBUSY(3):I
1767     $ ,PATTERNTRIG(6):I
1768     $ ,TRIGCONF:I')
1769    
1770    
1771     417 format('NTRK:I::[0,',I4,']')
1772     418 format(',IMAGE(NTRK):I::[0,',I4,']')
1773     write(block1,417)NTRKMAX
1774     write(block2,418)NTRKMAX
1775     call HBNAME(ntp_new,'TRACKS',NTRK,
1776     $ block1//
1777     $ block2//'
1778     $ ,XM(6,NTRK):R
1779     $ ,YM(6,NTRK):R
1780     $ ,ZM(6,NTRK):R
1781     $ ,RESX(6,NTRK):R
1782     $ ,RESY(6,NTRK):R
1783     $ ,AL(5,NTRK):R
1784     $ ,COVAL(5,5,NTRK):R
1785     $ ,CHI2(NTRK):R
1786     $ ,XGOOD(6,NTRK):I::[0,1]
1787     $ ,YGOOD(6,NTRK):I::[0,1]
1788     $ ,XV(6,NTRK):R
1789     $ ,YV(6,NTRK):R
1790     $ ,ZV(6,NTRK):R
1791     $ ,AXV(6,NTRK):R
1792     $ ,AYV(6,NTRK):R
1793     $ ,DEDXP(6,NTRK):R
1794     $ ')
1795     call HBNAME(ntp_new,'SINGLETS',nclsx,
1796     $ 'NCLSX(6):I,NCLSY(6):I')
1797    
1798    
1799     call HPRNTU(ntp_new)
1800    
1801     c------------------------------------------------------------------------
1802    
1803     call HCDIR('//LEVEL2',' ')
1804    
1805     c------------------------------------------------------------------------
1806     c start loop on events
1807     c------------------------------------------------------------------------
1808    
1809     maxevent=minevent+ntotev
1810     igoodevent=0
1811    
1812     c do iev = 1,iemax0
1813     do iev = minevent,MIN(iemax0,maxevent) !loop on events
1814     Call Hcdir('//EVENT',' ')
1815     Call Hgnt(ntp_tof,iev,Ierr)
1816    
1817     do i=1,6
1818     patterntrig1(i) = patterntrig(i)
1819     enddo
1820    
1821     * ----------------------------------------------
1822     Call Hcdir('//LEVEL2',' ')
1823     call HGNT(ntp_level2,iev,ierr) !reads an event
1824    
1825     if(ierr.ne.0) goto 21
1826     * ----------------------------------------------
1827    
1828     do i=1,nptof
1829     xout(i)=1000.
1830     yout(i)=1000.
1831     enddo
1832     do i=1,5
1833     ALPHA(i) = 1000.
1834     enddo
1835     do i=1,6
1836     XFIT(i) = 1000.
1837     YFIT(i) = 1000.
1838     ZFIT(i) = 1000.
1839     XGOOD1(i) = 1000.
1840     YGOOD1(i) = 1000.
1841     enddo
1842    
1843     chi = 1000.
1844    
1845     *=======> INSTERT HERE YOUR CODE
1846    
1847     * ---- example ----
1848     * write(*,*) 'GOOD2 ',good2
1849     * if(GOOD2)then
1850     if(NTRK.ne.0)then
1851     print*,'Event ',iev,' # tracks ',ntrk
1852     if(ntrk.eq.1)then
1853    
1854     chi = CHI2(1)
1855     do i=1,5
1856     ALPHA(i) = AL(i,1)
1857     enddo
1858     do i=1,6
1859     XFIT(i) = XV(i,1)
1860     YFIT(i) = YV(i,1)
1861     ZFIT(i) = ZV(i,1)
1862     XGOOD1(i)=XGOOD(i,1)
1863     YGOOD1(i)=YGOOD(i,1)
1864     enddo
1865    
1866     igoodevent = igoodevent+1
1867     * assigned input parameters for track routine
1868     * 1) Z-coordinates where the trajectory is evaluated
1869     do itof=1,NPTOF
1870     ZIN(itof) = ZTOF(itof)
1871     enddo
1872     * 2) track status vector
1873     do i=1,5
1874     AL_P(i) = AL(i,1)
1875     enddo
1876     * -------- *** tracking routine *** --------
1877     call track(NPTOF,ZIN,XOUT1,YOUT1,AL_P,IFAIL)
1878     * ------------------------------------------
1879     do itof=1,NPTOF
1880     XOUT(itof)=XOUT1(itof)
1881     YOUT(itof)=YOUT1(itof)
1882     enddo
1883    
1884     do itof=1,NPTOF
1885     c print*,' ',itof,ZIN(itof),XOUT(itof),YOUT(itof)
1886     enddo
1887     endif
1888     else
1889     print*,'Event ',iev,' *** BAD ***'
1890     endif
1891    
1892    
1893     call tofroutine(xout,yout,alpha)
1894    
1895    
1896     c--------------------- fill new rz file -----------------------------
1897    
1898     call HFNT(2)
1899    
1900     enddo !end loop on events
1901     GOTO 9000 !got to end
1902    
1903     c------------------------------------------------------------------------
1904     c
1905     c data file opening error
1906     c
1907     c------------------------------------------------------------------------
1908     19 continue
1909    
1910     print*,' '
1911     print*,'ERROR OPENING DATA FILE: ',data_file
1912     print*,' '
1913     print*,' '
1914    
1915     goto 9000 !the end
1916    
1917     c------------------------------------------------------------------------
1918     c
1919     c level2 ntuple event reading error
1920     c
1921     c------------------------------------------------------------------------
1922    
1923     21 continue
1924    
1925     print*,' '
1926     print*,'ERROR WHILE READING LEVEL2 NTUPLE, AT EVENT
1927     $ : ',iev
1928     print*,' '
1929     print*,' '
1930    
1931     goto 9000 !the end
1932    
1933     c------------------------------------------------------------------------
1934     c
1935     c closes files and exits
1936     c
1937     c------------------------------------------------------------------------
1938    
1939     9000 continue
1940    
1941     write(*,*) 'Good Events ',igoodevent
1942    
1943    
1944     c--------------------------------------------------------------
1945    
1946     call HCDIR('//EVENT',' ')
1947     CALL HROUT(0,icycle,' ')
1948     call HREND('EVENT')
1949     close(0)
1950    
1951     call HCDIR('//LEVEL2',' ')
1952     call HREND('level2')
1953     close(lun_data_level2)
1954    
1955    
1956     call HPRNTU(2)
1957     call HCDIR('//TEST',' ')
1958     CALL HROUT(0,icycle,' ')
1959     call HREND('TEST')
1960     close(0)
1961    
1962     STOP
1963     END
1964    
1965    
1966     include 'tofroutine.f'
1967    
1968     trk_level2.f0000644000076500001440000000607310314004227012156 0ustar mennusers*************************************************************************
1969     *
1970     * Common level2.f
1971     *
1972     * contains LEVEL2 ntuple variables definitions
1973     *
1974     *
1975     *************************************************************************
1976    
1977     PARAMETER (NTRKMAX=50) !ncloyz_max*ncloxz_max)
1978    
1979     c EVENT block:
1980     * -----------------------------------------------------------
1981     logical good2 !flag to mark good or noise events
1982     integer nev2 !level2 event number
1983     common/level2/good2,nev2
1984    
1985     c CPU block (only for ground data):
1986     * -----------------------------------------------------------
1987     integer pkt_type !CPU packet type identifier. see http://people.roma2.infn.it/~cpu/HB_list.txt
1988     c 0x12 --> calibration board 0
1989     c 0x13 --> calibration board 1
1990     c 0x10 --> event
1991     c 0x30 --> full event for calib special
1992     c 0x83 --> tracker ALARM (control register)
1993     integer pkt_num !CPU packet number
1994     integer obt !CPU on-board time
1995     integer which_calib !calibration file identifier. see DW_DATE_NUM_calib.txt file
1996     common/level2_cpu/pkt_type,pkt_num,obt,which_calib
1997    
1998    
1999     * -----------------------------------------------------------
2000     * Common to store TRACK info
2001     * All the variables have a dimention equal to the number of
2002     * found tracks
2003     * -----------------------------------------------------------
2004     c TRACK PARAMETERS
2005     integer ntrk !# identified tracks
2006     integer image !flag to tag track-images
2007     real al !track state vector
2008     integer xgood !mask of used planes
2009     integer ygood !*
2010     real xm !me asured points
2011     real ym !*
2012     real zm !*
2013     real resx !spatial resolution
2014     real resy !*
2015     real chi2 !chi2
2016     real xv !calculated points
2017     real yv !*
2018     real zv !*
2019     real axv !calculated angles (deg)
2020     real ayv !*
2021     real dedxp
2022     common/level2_tracks/
2023     $ ntrk
2024     $ ,image(NTRKMAX)
2025     $ ,xm(6,NTRKMAX)
2026     $ ,ym(6,NTRKMAX)
2027     $ ,zm(6,NTRKMAX)
2028     $ ,resx(6,NTRKMAX)
2029     $ ,resy(6,NTRKMAX)
2030     $ ,al(5,NTRKMAX)
2031     $ ,chi2(NTRKMAX)
2032     $ ,xgood(6,NTRKMAX)
2033     $ ,ygood(6,NTRKMAX)
2034     $ ,xv(6,NTRKMAX)
2035     $ ,yv(6,NTRKMAX)
2036     $ ,zv(6,NTRKMAX)
2037     $ ,axv(6,NTRKMAX)
2038     $ ,ayv(6,NTRKMAX)
2039     $ ,dedxp(6,NTRKMAX)
2040     * -----------------------------------------------------------
2041     * Common to store SINGLET info
2042     * (clusters not associated with any track)
2043     * -----------------------------------------------------------
2044     integer nclsx !# unassociated clusters per plane X views
2045     integer nclsy ! " " " " Y views
2046     common/level2_singlets/
2047     $ nclsx(6),nclsy(6)
2048    
2049    

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