SUBROUTINE ELIO(RPIANO,NPIANI,QQQQ,NTOT,INDICE) C---------------------------------------------------------------------- C- C- Purpose and Methods : IT FINDS THE NUMBER OF LAYERS (RPIANO) IN WHICH C- THERE IS A DETECTED ENERGY BETWEEN EINF AND ESUP . FOR EXAMPLE IF C- EINF = 2.5 mip AND ESUP = 10 mip WE INDENTIFY PARTICLE WITH A C- CHARACTERISTIC AS ALPHA AT MINIMUM . C- QQQQ IS THE TRUNCATED MEAN OF THE DETECTED ENERGY OF THE BARICENTRA OF THE C- DEFINED LAYERS . C- NTOT GIVES THE NUMBER OF LAYERS WITH DETECTED ENERGY ALONG THE TRACK C- DEFINED BY THE TRACKING SYSTEM . WE SAY THAT IS ALONG THE TRACK IF THE C- CLUSTER IS INSIDE A RADIUS OF 4 STRIPS BY THE POSITION DEFINED BY THE C- TRACKING SYSTEM . C- INDICE IS THE NUMBER OF CLUSTERS BESIDES THAT ALONG THE TRACK THAT ARE C- MORE THAN 4 STRIPS FAR AWAY BY THE TRACK . C- C- Inputs : NPIANI C- Outputs : RPIANO,QQQQ,NTOT,INDICE C- Controls: C- C- Created 9-FEB-1994 MIRKO BOEZIO C- Modified 28-APR-1994 MIRKO BOEZIO . IF ISTRISCIA IS NEGATIVE AND GREATER C- THAN NX THAN NN IS EQUAL 1 . C- Modified 8-JUL-1994 MIRKO BOEZIO . CORRECTED AN ERROR ON THE DEFINITION C- OF ISTRISCIA . C- Modified 14-DEC-1994 MIRKO BOEZIO . THE TRACK IS DEFINED BY THE C- TRACKING SYSTEM THROUGH IBAR AND BAR . C- C---------------------------------------------------------------------- INCLUDE 'INTEST.TXT' REAL LUNGH REAL RPIANO(2) REAL BAR(2,NPLA) REAL NQQ(2*NPLA) REAL RIL(NCHA/2) REAL TG(2) INTEGER IBAR(2,NPLA) INTEGER NTOT(2) COMMON/ANGOLO/BAR,IBAR SAVE /ANGOLO/ COMMON/DOVE/NX,NY,LUNGH SAVE /DOVE/ COMMON/TAGLIOEN/EINF,ESUP,ENER(2) SAVE /TAGLIOEN/ COMMON /SHIFT/ SHIFT SAVE /SHIFT/ COMMON/TANGENTI/TG SAVE /TANGENTI/ RINDEX = 0. C DO K = 1,NCHA/2 RIL(K) = 1000. ENDDO C ENER(1) = 0. ENER(2) = 0. C QQQ = 0. QQQQ = 0. QQX = 0. QQY = 0. NGIR = 0 DO M = 1,2 NTOT(M) = 0 RPIANO(M) = 0. C DO J = 1,NPLA IF (MOD(J,2).EQ.0) THEN SHIFT = -0.5 ELSE SHIFT = 0.5 ENDIF C DO K = 1,NGIR RIL(K) = 1000. ENDDO C IF (M.EQ.1) NQQ(J) = 0. IF (M.EQ.2) NQQ(J+NPLA) = 0. NNN = 0 C NN = IBAR(M,J) IF (NN.LE.0) NN = 1 C NGIR = NCL(M,J) ! number of clusters in layer J of the M View IF (NGIR.EQ.0) GO TO 5 IPP = 0. DO L = 1,NGIR CALL LASTRISCIA(CLUS(M,J,L),IN) RIL(L) = FLOAT(ABS(NN - IN)) IF (RIL(L).GE.5) IPP = 1 ENDDO MM = NCHA/2 C C WE USE THE CLUSTER NEAREST THE TRACK . C LK = LVMIN(RIL,MM) C C CHECK ON THE DISTANCE OF THE CLUSTER FROM THE TRACK . C IF (RIL(LK).GE.5) GO TO 5 IF (IPP.EQ.1) INDICE = INDICE + 1 IF (J.EQ.1) ENER(M) = CLUS(M,J,LK+NCHA/2) ! this is the detected C energy of the cluster in the first layer C NTOT(M) = NTOT(M) + 1 C C CHECK ON THE DETECTED ENERGY OF THE CLUSTER . C IF (CLUS(M,J,LK+NCHA/2).GT.EINF.AND.CLUS(M,J,LK+NCHA/2). & LT.ESUP) THEN IADD = 0 IF (M.EQ.2) IADD = NPLA NQQ(J + IADD) = NQQ(J + IADD) + CLUS(M,J,LK+NCHA/2) NNN = NNN + 1 ENDIF C 5 CONTINUE IADD = 0 IF (M.EQ.2) IADD = NPLA IF (NQQ(J + IADD).LT.EMIN) NQQ(J + IADD) = 10000. IF (NNN.GE.1) RPIANO(M) = RPIANO(M) + 1 C ENDDO ENDDO C RPIATOT = RPIANO(1) + RPIANO(2) IF (RPIATOT.GE.FLOAT(NPIANI)) THEN NPIA = NPIANI ELSE NPIA = INT(ANINT(RPIATOT)) ENDIF QQQ = 0. NDIM = 2 * NPLA DO I = 1,NPIA N = LVMIN(NQQ,NDIM) QQQ = QQQ + NQQ(N) NQQ(N) = 10000. ENDDO IF (NPIA.NE.0) THEN QQQQ = QQQ / FLOAT(NPIA) ! Truncated mean . ENDIF C 400 CONTINUE RETURN END C