SUBROUTINE PLOTU(X,N) C C PURPOSE--THIS SUBROUTINE PRODUCES THE FOLLOWING 4 PLOTS-- C ALL ON THE SAME PRINTER PAGE-- C 1) DATA PLOT--X(I) VERSUS I C 2) AUTOREGRESSION PLOT--X(I) VERSUS X(I-1) C 3) HISTOGRAM C 4) NORMAL PROBABILITY PLOT C IN ADDITION, LOCATION, SCALE, AND AUTOCORRELATION C SUMMARY STATISTICS ARE PRINTED OUT AUTOMATICALLY C ON THE SAME PAGE. C THESE PLOTS GIVE THE DATA ANALYST A QUICK C FIRST-PASS CHECK AT SOME OF C THE UNDERLYING ASSUMPTIONS TYPICALLY MADE-- C CONSTANT LOCATION, CONSTANT SCALE, NO OUTLIERS, C UNAUTOCORRELATED DATA, SYMMETRY, NORMALITY. C INPUT ARGUMENTS--X = THE SINGLE PRECISION VECTOR OF C (UNSORTED) OBSERVATIONS. C N = THE INTEGER NUMBER OF OBSERVATIONS C IN THE VECTOR X. C OUTPUT--4 PLOTS (ALL ON THE SAME PRINTER PAGE)-- C 1) DATA PLOT--X(I) VERSUS I C 2) AUTOREGRESSION PLOT--X(I) VERSUS X(I-1) C 3) HISTOGRAM C 4) NORMAL PROBABILITY PLOT C PLUS LOCATION, SCALE, AND C AUTOCORRELATION SUMMARY STATISTICS. C PRINTING--YES C RESTRICTIONS--THE MINIMUM ALLOWABLE VALUE OF N C FOR THIS SUBROUTINE IS 2. C --THE MAXIMUM ALLOWABLE VALUE OF N C FOR THIS SUBROUTINE IS 7500. C OTHER DATAPAC SUBROUTINES NEEDED--SORT, UNIMED, NORPPF. C FORTRAN LIBRARY SUBROUTINES NEEDED--SQRT. C MODE OF INTERNAL OPERATIONS--SINGLE PRECISION C LANGUAGE--ANSI FORTRAN. C REFERENCES--FILLIBEN, 'SOME USEFUL COMPUTERIZED TECHNIQUES C FOR DATA ANALYSIS', (UNPUBLISHED MANUSCRIPT C AVAILABLE FROM AUTHOR), 1975. C --HAHN AND SHAPIRO, STATISTICAL METHODS IN ENGINEERING, C 1967, PAGES 260-308. C --FILLIBEN, 'THE PROBABILITY PLOT CORRELATION COEFFICIENT C TEST FOR NORMALITY', TECHNOMETRICS, 1975, PAGES 111-117. C WRITTEN BY--JAMES J. FILLIBEN C STATISTICAL ENGINEERING LABORATORY (205.03) C NATIONAL BUREAU OF STANDARDS C WASHINGTON, D. C. 20234 C PHONE--301-921-2315 C ORIGINAL VERSION--NOVEMBER 1974. C UPDATED --JANUARY 1975. C UPDATED --NOVEMBER 1975. C UPDATED --FEBRUARY 1976. C UPDATED --MAY 1976. C UPDATED --FEBRUARY 1977. C C--------------------------------------------------------------------- C CHARACTER*4 IGRAPH CHARACTER*4 BLANK,HYPHEN,ALPHAI,ALPHAX CHARACTER*4 ALPHAM,ALPHAA,ALPHAD,ALPHAN,EQUAL C DIMENSION X(1) DIMENSION X2(7500),Y2(7500) DIMENSION YLABLE(45,4) DIMENSION XMIN(4),XMAX(4),XMID(4),X25(4),X75(4) DIMENSION ITAXIS(4),IBAXIS(4),ILAXIS(4),IRAXIS(4) COMMON /BLOCK1/ IGRAPH(55,130) COMMON /BLOCK2/ WS(15000) CCCCC COMMON IGRAPH(45,110) EQUIVALENCE (X2(1),WS(1)),(Y2(1),WS(7501)) C DATA BLANK,HYPHEN,ALPHAI,ALPHAX/' ','-','I','X'/ DATA ALPHAM,ALPHAA,ALPHAD,ALPHAN,EQUAL/'M','A','D','N','='/ DATA ITAXIS(1),IBAXIS(1),ILAXIS(1),IRAXIS(1)/ 1,19,5,49/ DATA ITAXIS(2),IBAXIS(2),ILAXIS(2),IRAXIS(2)/ 1,19,54,98/ DATA ITAXIS(3),IBAXIS(3),ILAXIS(3),IRAXIS(3)/27,45,5,49/ DATA ITAXIS(4),IBAXIS(4),ILAXIS(4),IRAXIS(4)/ 27,45,54,98/ C IPR=6 ILOWER=2 IUPPER=7500 C C CHECK THE INPUT ARGUMENTS FOR ERRORS C WRITE(IPR,998) IF(N.LT.ILOWER.OR.N.GT.IUPPER)GOTO50 HOLD=X(1) DO60I=2,N IF(X(I).NE.HOLD)GOTO90 60 CONTINUE WRITE(IPR, 9)HOLD RETURN 50 WRITE(IPR,17)ILOWER,IUPPER WRITE(IPR,47)N RETURN 90 CONTINUE 9 FORMAT(1H , '***** FATAL ERROR--THE FIRST INPUT ARGUMENT (A VEC 1TOR) TO THE PLOTU SUBROUTINE HAS ALL ELEMENTS = ',E15.8, 1' *****') 17 FORMAT(1H , '***** FATAL ERROR--THE SECOND INPUT ARGUMENT TO THE 1 PLOTU SUBROUTINE IS OUTSIDE THE ALLOWABLE (',I1,',',I6, ') INTER 1VAL *****') 47 FORMAT(1H , '***** THE VALUE OF THE ARGUMENT IS ',I8 ,' *****') C C-----START POINT----------------------------------------------------- C C PRODUCE THE FIRST PLOT (UPPER LEFT)--X(I) VERSUS I C C DETERMINE THE VERTICAL AXIS VECTOR Y2, THE HORIZONTAL C AXIS VECTOR X2, AND THE PLOT SAMPLE SIZE N2 FOR THIS C PARTICUAR PLOT. C N2=N DO100I=1,N2 Y2(I)=X(I) X2(I)=I 100 CONTINUE C IPLOT=1 GOTO5000 C C********************************************************************* C C PRODUCE THE SECOND PLOT (UPPER RIGHT)--X(I) VERSUS X(I-1) C C DETERMINE THE VERTICAL AXIS VECTOR Y2, THE HORIZONTAL C AXIS VECTOR X2, AND THE PLOT SAMPLE SIZE N2 FOR THIS C PARTICULAR PLOT. C 2000 N2=N-1 DO1100I=1,N2 IP1=I+1 Y2(I)=X(IP1) X2(I)=X(I) 1100 CONTINUE C IPLOT=2 GOTO5000 C C********************************************************************* C C PRODUCE THE THIRD PLOT (LOWER LEFT)-A HISTOGRAM C 3000 N2=41 INC=3 C C COMPUTE THE SAMPLE MEAN AND SAMPLE STANDARD DEVIATION C AN=N SUM=0.0 DO3100I=1,N SUM=SUM+X(I) 3100 CONTINUE XMEAN=SUM/AN SUM=0.0 DO 3200I=1,N SUM=SUM+(X(I)-XMEAN)**2 3200 CONTINUE S=SQRT(SUM/(AN-1.0)) C C FORM THE FREQUENCY TABLE (Y2) WHICH CORRESPONDS TO A HISTOGRAM C WITH 41 CLASSES AND A CLASS WIDTH OF THREE TENTHS OF A SAMPLE STANDARD C DEVIATION. C DO3300I=1,41 Y2(I)=0.0 3300 CONTINUE C NUMOUT=0 DO3400I=1,N Z=(X(I)-XMEAN)/S IF(-6.0.LE.Z.AND.Z.LE.6.0)GOTO3450 NUMOUT=NUMOUT+1 GOTO3400 3450 CONTINUE MT=((Z+6.0)/0.3)+1.5 Y2(MT)=Y2(MT)+1.0 3400 CONTINUE C DO3800I=1,41 AI=I X2(I)=XMEAN+((AI-21.0)*0.3)*S 3800 CONTINUE C NUMCLA=41 CWIDSD=0.3 CWIDTH=CWIDSD*S C IPLOT=3 GOTO5000 C C********************************************************************* C C PRODUCE THE FOURTH PLOT (LOWER RIGHT)--A NORMAL PROBABILITY PLOT C C DETERMINE THE VERTICAL AXIS VECTOR Y2, THE HORIZONTAL C AXIS VECTOR X2, AND THE PLOT SAMPLE SIZE N2 FOR THIS C PARTICUAR PLOT. C 4000 N2=N CALL SORT(X,N,Y2) CALL UNIMED(N,X2) DO4100I=1,N CALL NORPPF(X2(I),X2(I)) 4100 CONTINUE C IPLOT=4 GOTO5000 C C C********************************************************************* C C OPERATE ON A PARTICULAR PLOT C 5000 ITAX=ITAXIS(IPLOT) IBAX=IBAXIS(IPLOT) ILAX=ILAXIS(IPLOT) IRAX=IRAXIS(IPLOT) C ITAXP2=ITAX+2 IBAXM2=IBAX-2 ILAXP2=ILAX+2 IRAXM2=IRAX-2 ILAXM4=ILAX-4 ILAXM3=ILAX-3 ILAXM2=ILAX-2 ILAXM1=ILAX-1 IYMID=(ITAXP2+IBAXM2)/2 IXMID=(ILAXP2+IRAXM2)/2 HEIGHT=IBAXM2-ITAXP2 WIDTH=IRAXM2-ILAXP2 C C BLANK OUT THE GRAPH C DO300I=ITAX,IBAX DO350J=ILAXM4,IRAX IGRAPH(I,J)=BLANK 350 CONTINUE 300 CONTINUE C C PRODUCE THE Y AXIS C DO400I=ITAXP2,IBAXM2 IGRAPH(I,ILAX)=ALPHAI IGRAPH(I,IRAX)=ALPHAI 400 CONTINUE IYDEL=(IBAXM2-ITAXP2)/2 DO450I=ITAXP2,IBAXM2,IYDEL IGRAPH(I,ILAX)=HYPHEN IGRAPH(I,IRAX)=HYPHEN 450 CONTINUE IGRAPH(ITAXP2,ILAXM4)=EQUAL IGRAPH(ITAXP2,ILAXM3)=ALPHAM IGRAPH(ITAXP2,ILAXM2)=ALPHAA IGRAPH(ITAXP2,ILAXM1)=ALPHAX IGRAPH(IYMID,ILAXM4)=EQUAL IGRAPH(IYMID,ILAXM3)=ALPHAM IGRAPH(IYMID,ILAXM2)=ALPHAI IGRAPH(IYMID,ILAXM1)=ALPHAD IGRAPH(IBAXM2,ILAXM4)=EQUAL IGRAPH(IBAXM2,ILAXM3)=ALPHAM IGRAPH(IBAXM2,ILAXM2)=ALPHAI IGRAPH(IBAXM2,ILAXM1)=ALPHAN C C PRODUCE THE X AXIS C DO500J=ILAXP2,IRAXM2 IGRAPH(ITAX,J)=HYPHEN IGRAPH(IBAX,J)=HYPHEN 500 CONTINUE IXDEL=(IRAXM2-ILAXP2)/4 DO550J=ILAXP2,IRAXM2,IXDEL IGRAPH(ITAX,J)=ALPHAI IGRAPH(IBAX,J)=ALPHAI 550 CONTINUE C C DETERMINE THE VALUES TO BE LISTED ON THE LEFT VERTICAL AXIS C YMIN=Y2(1) YMAX=Y2(1) DO600I=1,N2 IF(Y2(I).LT.YMIN)YMIN=Y2(I) IF(Y2(I).GT.YMAX)YMAX=Y2(I) 600 CONTINUE IF(IPLOT.EQ.3)YMIN=1.0 DO650I=ITAXP2,IBAXM2 ANUM=I-ITAXP2 YLABLE(I,IPLOT)=YMAX-(ANUM/HEIGHT)*(YMAX-YMIN) 650 CONTINUE C C DETERMINE XMIN, XMAX, XMID, X25 (=THE 25% POINT), AND C X75 (=THE 75% POINT) C XMIN2=X2(1) XMAX2=X2(1) DO700I=1,N2 IF(X2(I).LT.XMIN2)XMIN2=X2(I) IF(X2(I).GT.XMAX2)XMAX2=X2(I) 700 CONTINUE XMIN(IPLOT)=XMIN2 XMAX(IPLOT)=XMAX2 XMID(IPLOT)=(XMIN2+XMAX2)/2.0 X25(IPLOT)=0.75*XMIN2+0.25*XMAX2 X75(IPLOT)=0.25*XMIN2+0.75*XMAX2 C C DETERMINE THE (X,Y) PLOT POSITIONS C RATIOY=0.0 RATIOX=0.0 IF(YMAX.GT.YMIN)RATIOY=HEIGHT/(YMAX-YMIN) IF(XMAX(IPLOT).GT.XMIN(IPLOT))RATIOX= 1WIDTH/(XMAX(IPLOT)-XMIN(IPLOT)) IF(IPLOT.EQ.3)GOTO750 DO800I=1,N2 MX=RATIOX*(X2(I)-XMIN(IPLOT))+0.5 MX=MX+ILAXP2 MY=RATIOY*(Y2(I)-YMIN)+0.5 MY=IBAXM2-MY IGRAPH(MY,MX)=ALPHAX 800 CONTINUE GOTO850 C 750 DO900I=1,N2 IF(Y2(I).LE.0.5)GOTO900 MX=RATIOX*(X2(I)-XMIN(IPLOT))+0.5 MX=MX+ILAXP2 MY=RATIOY*(Y2(I)-YMIN)+0.5 MY=IBAXM2-MY IGRAPH(MY,MX)=ALPHAX DO950IY=MY,IBAXM2 IGRAPH(IY,MX)=ALPHAX 950 CONTINUE 900 CONTINUE C 850 IF(IPLOT.EQ.1)GOTO2000 IF(IPLOT.EQ.2)GOTO3000 IF(IPLOT.EQ.3)GOTO4000 C C******************************************************************** C C COMPUTE SUMMARY STATISTICS C ZMIN=Y2(1) ZMAX=Y2(N) ZRANGE=ZMAX-ZMIN ZMEAN=XMEAN ZSD=S ZDEVB=ZMEAN-ZMIN ZRDEVB=0.0 IF(ZMEAN.NE.0.0)ZRDEVB=100.0*ZDEVB/ZMEAN IF(ZRDEVB.LT.0.0)ZRDEVB=-ZRDEVB ZDEVA=ZMAX-ZMEAN ZRDEVA=0.0 IF(ZMEAN.NE.0.0)ZRDEVA=100.0*ZDEVA/ZMEAN IF(ZRDEVA.LT.0.0)ZRDEVA=-ZRDEVA C C DETERMINE THE NUMBER OF DISTINCT POINTS C NUMDIS=1 NM1=N-1 DO7200I=1,NM1 IP1=I+1 IF(Y2(I).EQ.Y2(IP1))GOTO7200 NUMDIS=NUMDIS+1 7200 CONTINUE C C COMPUTE THE SAMPLE MEDIAN C NHALF=N/2 IEVODD=N-2*(N/2) IF(IEVODD.EQ.0)GOTO7250 ZMED=Y2(NHALF) GOTO7260 7250 NHALFP=NHALF+1 ZMED=(Y2(NHALF)+Y2(NHALFP))/2.0 7260 CONTINUE C C DETERMINE THE FREQUENCY OF THE SAMPLE MIN AND MAX C NUMMIN=1 NM1=N-1 DO7400I=1,NM1 IP1=I+1 IF(Y2(I).EQ.Y2(IP1))NUMMIN=NUMMIN+1 IF(Y2(I).EQ.Y2(IP1))GOTO7400 GOTO7450 7400 CONTINUE 7450 NUMMAX=1 DO7500I=1,NM1 IREV=N-I+1 NMI=N-I IF(Y2(IREV).EQ.Y2(NMI))NUMMAX=NUMMAX+1 IF(Y2(IREV).EQ.Y2(NMI))GOTO7500 GOTO7550 7500 CONTINUE 7550 CONTINUE PROMIN=NUMMIN PROMIN=100.0*PROMIN/AN PROMAX=NUMMAX PROMAX=100.0*PROMAX/AN C C COMPUTE THE AUTOCORRELATION C ZMEAN1=(AN*ZMEAN-X(N))/(AN-1.0) ZMEAN2=(AN*ZMEAN-X(1))/(AN-1.0) SUM1=0.0 SUM2=0.0 SUM3=0.0 NM1=N-1 DO7600I=1,NM1 IP1=I+1 SUM1=SUM1+(X(I)-ZMEAN1)*(X(IP1)-ZMEAN2) SUM2=SUM2+(X(I)-ZMEAN1)**2 SUM3=SUM3+(X(IP1)-ZMEAN2)**2 7600 CONTINUE SUM23=SUM2*SUM3 ZAUTOC=9999.99 IF(SUM23.GT.0.0)ZAUTOC=SUM1/(SQRT(SUM23)) ZAUTOC=100.0*ZAUTOC C C WRITE EVERYTHING OUT C ITAX=ITAXIS(1) IBAX=IBAXIS(1) ITAXP1=ITAX+1 ITAXP2=ITAX+2 IBAXM1=IBAX-1 IBAXM2=IBAX-2 J1=ILAXIS(1)-4 J2=IRAXIS(1) J3=ILAXIS(2)-4 J4=IRAXIS(2) WRITE(IPR,5104) WRITE(IPR,5105)(IGRAPH(ITAX,J),J=J1,J2),(IGRAPH(ITAX,J),J=J3,J4) WRITE(IPR,5105)(IGRAPH(ITAXP1,J),J=J1,J2),(IGRAPH(ITAXP1,J),J=J3,J 14) DO5100I=ITAXP2,IBAXM2 WRITE(IPR,5110)YLABLE(I,1),(IGRAPH(I,J),J=J1,J2), 1 YLABLE(I,2),(IGRAPH(I,J),J=J3,J4) 5100 CONTINUE WRITE(IPR,5105)(IGRAPH(IBAXM1,J),J=J1,J2),(IGRAPH(IBAXM1,J),J=J3,J 14) WRITE(IPR,5105)(IGRAPH(IBAX,J),J=J1,J2),(IGRAPH(IBAX,J),J=J3,J4) WRITE(IPR,5115)XMIN(1),X25(1),XMID(1),X75(1),XMAX(1), 1 XMIN(2),X25(2),XMID(2),X75(2),XMAX(2) C ISKIPM=2 DO5200I=1,ISKIPM WRITE(IPR,999) 5200 CONTINUE C ITAX=ITAXIS(3) IBAX=IBAXIS(3) ITAXP1=ITAX+1 ITAXP2=ITAX+2 IBAXM1=IBAX-1 IBAXM2=IBAX-2 J1=ILAXIS(3)-4 J2=IRAXIS(3) J3=ILAXIS(4)-4 J4=IRAXIS(4) WRITE(IPR,5304) WRITE(IPR,5105)(IGRAPH(ITAX,J),J=J1,J2),(IGRAPH(ITAX,J),J=J3,J4) WRITE(IPR,5105)(IGRAPH(ITAXP1,J),J=J1,J2),(IGRAPH(ITAXP1,J),J=J3,J 14) DO5300I=ITAXP2,IBAXM2 WRITE(IPR,5110)YLABLE(I,3),(IGRAPH(I,J),J=J1,J2), 1 YLABLE(I,4),(IGRAPH(I,J),J=J3,J4) 5300 CONTINUE WRITE(IPR,5105)(IGRAPH(IBAXM1,J),J=J1,J2),(IGRAPH(IBAXM1,J),J=J3,J 14) WRITE(IPR,5105)(IGRAPH(IBAX,J),J=J1,J2),(IGRAPH(IBAX,J),J=J3,J4) WRITE(IPR,5115)XMIN(3),X25(3),XMID(3),X75(3),XMAX(3), 1 XMIN(4),X25(4),XMID(4),X75(4),XMAX(4) WRITE(IPR,5320) WRITE(IPR,5325)NUMCLA,N,NUMDIS WRITE(IPR,5326)CWIDTH,CWIDSD,ZMIN,NUMMIN,PROMIN WRITE(IPR,5330)NUMOUT,ZMED WRITE(IPR,5331)ZMEAN WRITE(IPR,5332)ZMAX,NUMMAX,PROMAX WRITE(IPR,5334)ZSD,ZRANGE WRITE(IPR,5336)ZDEVB,ZRDEVB WRITE(IPR,5338)ZDEVA,ZRDEVA WRITE(IPR,5340)ZAUTOC C 5104 FORMAT(1H ,20X,12X,'PLOT OF X(I) VERSUS I',41X,'PLOT OF ', 1 'X(I) VERSUS X(I-1)') 5105 FORMAT(1H ,16X,4A1,45A1,16X,4A1,45A1) 5110 FORMAT(1H ,F16.7,4A1,45A1,F16.7,4A1,45A1) 5115 FORMAT(1H ,17X,5F10.4,15X,4F10.4,F9.3) 5304 FORMAT(1H ,38X,'HISTOGRAM',49X,'NORMAL PROBABILITY PLOT') 5320 FORMAT(1H ,20X,' -6 -3 0 3 6') 5325 FORMAT(1H ,20X,'NUMBER OF CLASSES = ',I3,42X, 1'SAMPLE SIZE =',I9,' DISTINCT POINTS =',I6) 5326 FORMAT(1H ,20X,'CLASS WIDTH = ',E14.7,' = ',F3.1, 1 ' STANDARD DEVIATIONS',11X, 1'MINIMUM =',F13.6,' COUNT =',I5,' (',F7.2,'%)') 5330 FORMAT(1H ,16X,I5,' OBSERVATIONS WERE IN EXCESS OF 6 STANDARD', 1 ' DEVIATIONS',11X, 1'MEDIAN =',F14.6) 5331 FORMAT(1H ,20X, 'ABOUT THE SAMPLE MEAN AND SO WERE NOT PRINTED IN 1 HISTOGRAM',7X, 1'MEAN =',F16.6) 5332 FORMAT(1H ,85X, 1'MAXIMUM =',F13.6,' COUNT =',I5,' (',F7.2,'%)') 5334 FORMAT(1H ,85X, 1'ST. DEV. =',F12.6,' RANGE =',F16.6) 5336 FORMAT(1H ,20X,65X,'MAX DEV. BELOW MEAN =',F14.6,' (',F7.2,'%)') 5338 FORMAT(1H ,85X,'MAX DEV. ABOVE MEAN =',F14.6,' (',F7.2,'%)') 5340 FORMAT(1H ,85X,'AUTOCORR. =',F10.2,'%') 998 FORMAT(1H1) 999 FORMAT(1H ) C RETURN END