BEGIN NEW DATA CASE C BENCHMARK DC-40 C This present data case restarts the "STATISTICS" (Monte Carlo) simulation C of DC-24, which ran only 3 energizations. When this 2nd half finishes, C 6 will have been completed, to be compared with "M39." answers of DC-24. C Yet answers differ due to different random number generator and use of the C seed (now, initialization only occurs once). As for the disk file that is C connected to UNIT=2 immediately below, note that it is disconnected 3 C lines later, and dumxx.BIN is reconnected. This is to protect DC24clik.BIN C from a stray write. .... Finally, be careful of OPMC C Beware of PARALLEL.LIS entry for same USERID that might modify NENERG! $OPEN, UNIT=22 FILE=dc24clik.bin STATUS=OLD FORM=C-like ! { Hold case START AGAIN { Request for awakening of hibernating solution 9999 { Terminate modifications (none, here) to switching times diagnostic 9 $CLOSE, UNIT=22 STATUS=UNKNOWN { Disconnect dc24clik.bin on 22 to prevent damage $OPEN, UNIT=22 FILE=dc24at40.ext STATUS=OLD FORM=UNFORMATTED RECL=16000 ! LOAD MORE SHOTS { Load the separate extrema produced by 3 shots made in DC-24 $CLOSE, UNIT=22 STATUS=UNKNOWN { Disconnect dc24at40.ext on 22 to prevent damage $OPEN, UNIT=22 STATUS=SCRATCH FILE=dumxx.bin ! { Reconnect dummy .BIN on LUNIT2 MISCELLANEOUS DATA CARDS 100.E-6 20.E-3 60. 1 1 1 1 1 0 0 6 C ISW ITEST IDIST IMAX IDICE KSTOUT KNTRPT NSEED 1 1 0 0 1 { KSTOUT is blank, not 0! } 1 C GENA GENC ENDA B1 ASW10 C Reference angle A1 C1 A10 BSW1 C C GENB ENDA C B1 A10 C The following is DIAGNOSTIC from "RANDNZ" usage of overlay 12. Not a C normal case output, this is useful in case switching times are incorrect: C "RFUNL1/RANDNZ". KNT = 4. SY, D6, SEEDRN, D18 (result) follow .... C 0.439822971502571000E+02 0.446592684878350000E+14 C 0.198544027000000000E+09 0.046227133600041 C "RFUNL1/RANDNZ". KNT = 4. SY, D6, SEEDRN, D18 (result) follow .... C 0.000000000000000000E+00 0.137132374008640000E+14 C 0.370179203200000000E+10 0.861890621483326 C "RFUNL1/RANDNZ". KNT = 4. SY, D6, SEEDRN, D18 (result) follow .... C 0.000000000000000000E+00 0.255679073858209000E+15 C 0.396569462500000000E+10 0.923335232073441 C "RFUNL1/RANDNZ". KNT = 4. SY, D6, SEEDRN, D18 (result) follow .... C 0.000000000000000000E+00 0.273906562054126000E+15 C 0.361268631800000000E+10 0.841144080739468 C "RFUNL1/RANDNZ". KNT = 4. SY, D6, SEEDRN, D18 (result) follow .... C 0.000000000000000000E+00 0.249524631297943000E+15 C 0.421126952700000000E+10 0.980512594571337 C Random switching times for energization number 4 : C 1 2.1466476E-03 2 4.4995694E-03 3 8.0648931E-03 C 0.0 125.9695623 -58.920794 52.58141134 370.8688937 -424.516718 C 1.249136867 -1.87200012 C Times of maxima : .0023 .0114 .0094 .0049 .0078 C .0049 .0171 C diagnostic 9 TIME STEP LOOP { Transfer control to overlay 16 for a resumption of simulation C "RFUNL1/RANDNZ". KNT = 5. SY, D6, SEEDRN, D18 (result) follow .... C 0.439822971502571000E+02 0.290868174960364000E+15 C 0.104773356000000000E+09 0.024394447915256 C "RFUNL1/RANDNZ". KNT = 5. SY, D6, SEEDRN, D18 (result) follow .... C 0.000000000000000000E+00 0.723659092556500000E+13 C 0.386599910100000000E+10 0.900123059051111 C "RFUNL1/RANDNZ". KNT = 5. SY, D6, SEEDRN, D18 (result) follow .... C 0.000000000000000000E+00 0.267020691906970000E+15 C 0.257511465000000000E+10 0.599565601442009 C "RFUNL1/RANDNZ". KNT = 5. SY, D6, SEEDRN, D18 (result) follow .... C 0.000000000000000000E+00 0.177860593760851000E+15 C 0.170306619500000000E+10 0.396525998366997 C "RFUNL1/RANDNZ". KNT = 5. SY, D6, SEEDRN, D18 (result) follow .... C 0.000000000000000000E+00 0.117629079022456000E+15 C 0.280968690400000000E+10 0.654181210324168 C Random switching times for energization number 5 : C 1 2.0344905E-03 2 3.8690347E-03 3 6.3961916E-03 C 0.0 131.4745297 -76.1213478 -90.4743742 472.0143285 -556.117151 C 1.594127662 -1.83850686 C Times of maxima : .0022 .0127 .0083 .0139 .0074 C .0044 .0172 C "RFUNL1/RANDNZ". KNT = 6. SY, D6, SEEDRN, D18 (result) follow .... C 0.439822971502571000E+02 0.194062264772377000E+15 C 0.275743720900000000E+10 0.642015880206600 C "RFUNL1/RANDNZ". KNT = 6. SY, D6, SEEDRN, D18 (result) follow .... C 0.000000000000000000E+00 0.190453430588422000E+15 C 0.169578189400000000E+10 0.394829989876598 C "RFUNL1/RANDNZ". KNT = 6. SY, D6, SEEDRN, D18 (result) follow .... C 0.000000000000000000E+00 0.117125959636687000E+15 C 0.220147476700000000E+10 0.512570786988363 C "RFUNL1/RANDNZ". KNT = 6. SY, D6, SEEDRN, D18 (result) follow .... C 0.000000000000000000E+00 0.152053660681924000E+15 C 0.322846893200000000E+10 0.751686499454081 C "RFUNL1/RANDNZ". KNT = 6. SY, D6, SEEDRN, D18 (result) follow .... C 0.000000000000000000E+00 0.222987120664309000E+15 C 0.100859058100000000E+10 0.234830794157460 C Random switching times for energization number 6 : C 1 2.0043546E-03 2 4.3397550E-03 3 5.2772330E-03 C 0.0 131.4745297 -102.270651 45.1085527 370.2365789 -461.601966 C 1.25947653 -1.88310377 C Times of maxima : .0022 .0054 .0094 .0052 .0076 C .02 .017 C 1 ) -------------------------------------------------------------------------- C Statistical distribution of peak voltage for branch "GENA " to "A1 ". C Interval voltage voltage in Frequency Cumulative C number in per unit physical units (density) frequency C 25 1.2500000 0.12500000E+03 0 0 C 26 1.3000000 0.13000000E+03 1 1 C 27 1.3500000 0.13500000E+03 2 3 C 28 1.4000000 0.14000000E+03 1 4 C 29 1.4500000 0.14500000E+03 2 6 C Summary for following request: Mean = 1.35833333E+00 1.34924018E+00 C Variance = 3.66666667E-03 4.10518277E-03 C Standard deviation = 6.05530071E-02 6.40717002E-02 -1 100. GENA A1 -1 GENC C1 ENDA A10 { =2.53418455E-1, Variance = 3.02359400E-3 ASW10 BSW10 CSW10 { Mean=1.49453887E+0, Variance = 6.41172862E-2 C MODTAB AINCR XMAXMX STATISTICS DATA 1 -10. 0.0 ---- Fixed number of 10 boxes -3 B1 BSW1 { Ungroup: Mean=1.07790313E+0, Variance = 1.44614228E-2 STATISTICS DATA 1 .05 0.0 --- Return to p.u. box of 1/20 -2 0. GENB B1 ENDA A10 { =1.11785582E+0, Variance = 1.92038029E-2 STATISTICS DATA 1 -5.0 0.0 ---- Fixed number of 5 boxes -4 0. B1 BSW1 { Ungroup: Mean=1.27016791E+0, Variance = 8.50686724E-2 C 12 ) ------------------------------------------------------------------------- C Statistical distribution of peak energy for branch "B1 " to "BSW1 ". C Interval energy energy in Frequency Cumulative C number in per unit physical units (density) frequency C 5 0.9692791 0.66169358E+00 0 0 C 6 1.1631349 0.79403229E+00 2 2 C 7 1.3569907 0.92637101E+00 2 4 C 8 1.5508465 0.10587097E+01 1 5 C 9 1.7447023 0.11910484E+01 0 5 C 10 1.9385582 0.13233872E+01 1 6 C Distribution parameters for .. data follow. Grouped data Ungrouped data C Mean = 1.32468140E+00 1.27016791E+00 C Variance = 8.51815081E-02 8.50686724E-02 C Standard deviation = 2.91858713E-01 2.91665343E-01 C Switch "A1 " to "ASW1 " C 8.33333377E-03 switch closings per column C Columns C 5 10 15 20 25 30 C +----+----+----+----+----+----+ (Note: all "A" below did line C A * up before left shift, C A * in about column 127). C A * C A * C | * Pull in to col 80 ----> A C | * Pull in to col 80 ----> A C A * C | * Pull in to col 80 ----> A C A * C A * C A * C A * C | 2.0000E-03 * Pull in to col 80 ----> A C A * C | * Pull in to col 80 ----> A C A * C A * C A * C A * C A * C A * C A * C | * Pull in to col 80 ----> A C A * C A * C Time (scale = 1.44337567E-05 Sec/line) BLANK card ending statistical output variable requests BEGIN NEW DATA CASE C ====================================================================== C 2nd of 4 subcases will follow an explanation of how to produce vector C plots of statistical distributions in Apollo window using input of the C preceding solution. See "STATPLOT" as described in Section I-F-1-g C of the rule book. Execute the following in a 2/3-height window with C font F7x13.B and nearly full width: C $ STATPLOT.EXE C Y 5 .9 1.9 C HELP C GO C <<< Pasted data beginning with 1st row of the C <<< statistical tabulation of peak energy for C <<< branch "B1 " to "BSW1 ". This begins C <<< in row 10 and extends through row 20, followed C <<< 4 lines of summary statistics. See Rule Book. C LINE 1.4 0.1 C LINE 1.8 0.1 C LINE 1.0 1.0 C ====================================================================== C On to the 2nd subcase, which will illustrate statistical tabulation C of previously-generated energizations without the addition of any new C solutions. It also illustrates the combination of 2 sets of extrema, C with the 1st coming from the 1st subcase of DC-24 (just as with the C preceding data subcase) and the 2nd coming from the 3rd subcase of C DC-24. This illustrates the use of "LOAD NEXT PART" that announces C or requests concatenation of the 2nd set of extrema. Finally, there C is illustration of the erasure of energizations from each set. Since C both sets of data are really identical, killing one extrema in 1 file C and the remaining 2 in the other, in any combination, will result in C 3 remaining extrema that should tabulate identically to the 3 of DC-24 $OPEN, UNIT=22 FILE=dc24clik.bin STATUS=OLD FORM=C-like ! { Hold case START AGAIN { Request for awakening of hibernating solution 9999 { Terminate modifications (none, here) to switching times diagnostic 9 $CLOSE, UNIT=22 STATUS=UNKNOWN { Disconnect dc24clik.bin on 22 to prevent damage $OPEN, UNIT=22 FILE=dc24at40.ext STATUS=OLD FORM=UNFORMATTED RECL=16000 ! C 345678901234567890 KIL KIL KIL KIL --- Ruler for (20X, 15I4) of next card: LOAD MORE SHOTS 2 { Load extrema of DC-24 minus shot number 2 $CLOSE, UNIT=22 STATUS=UNKNOWN { Disconnect dc24at40.ext on 22 to prevent damage TOGGLE EXTREMA MODE { Change from default UNFORMATTED mode to card images $OPEN, UNIT=22 FILE=dc24ct40.lis STATUS=OLD FORM=FORMATTED ! LOAD MORE SHOTS 1 3 { Load additional history, minus shots 1 & 3 C Following card means next case will have L2FORM = 0 within "REQUES" C whether code is overlaid or not. Otherwise, virtual computers would C have kept L2FORM = 1 whereas overlaid would have reset L2FORM = 0. TOGGLE EXTREMA MODE { Restore the default UNFORMATTED mode of "LOAD MORE SHOTS" $CLOSE, UNIT=22 STATUS=UNKNOWN { Disconnect dc24ct40.lis on 22 to prevent damage $OPEN, UNIT=22 STATUS=SCRATCH FILE=dumxx.bin ! { Reconnect dummy .BIN on LUNIT2 MISCELLANEOUS DATA CARDS 100.E-6 20.E-3 60. 1 1 1 1 1 0 0 3 C ISW ITEST IDIST IMAX IDICE KSTOUT KNTRPT NSEED 1 1 0 0 1 { KSTOUT is blank, not 0! } 1 TIME STEP LOOP { Transfer control to overlay 16 for a resumption of simulation C 1 ) -------------------------------------------------------------------------- C Statistical distribution of peak voltage for branch "GENA " to "A1 ". C Interval voltage voltage in Frequency Cumulative C number in per unit physical units (density) frequency C 27 1.3500000 0.13500000E+03 0 0 C 28 1.4000000 0.14000000E+03 1 1 C 29 1.4500000 0.14500000E+03 2 3 C Distribution parameters for .. data follow. Grouped data Ungrouped data C Mean = 1.40833333E+00 1.40208495E+00 C Variance = 8.33333333E-04 8.75092111E-04 C Standard deviation = 2.88675135E-02 2.95819558E-02 -1 100. GENA A1 C &&&&&&&&&&&&& End request and documentation. Begin 3 coupled cards ...... C 2 ) -------------------------------------------------------------------------- C Statistical distribution of peak voltage for branch "GENA " to "A1 ". C Interval voltage voltage in Frequency Cumulative C number in per unit physical units (density) frequency C 9 0.4500000 0.13635000E+03 0 0 C 10 0.5000000 0.15150000E+03 3 3 C Distribution parameters for .. data follow. Grouped data Ungrouped data C Mean = 4.75000000E-01 4.62734306E-01 C Variance = 0.00000000E+00 9.53165933E-05 C Standard deviation = 0.00000000E+00 9.76302173E-03 -1 GENA A1 CONT. C 3 ) -------------------------------------------------------------------------- C Statistical distribution of peak voltage for branch "GENC " to "C1 ". C Interval voltage voltage in Frequency Cumulative C number in per unit physical units (density) frequency C 4 0.2000000 0.60600000E+02 0 0 C 5 0.2500000 0.75750000E+02 2 2 C 6 0.3000000 0.90900000E+02 1 3 C Distribution parameters for .. data follow. Grouped data Ungrouped data C Mean = 2.41666667E-01 2.45766731E-01 C Variance = 8.33333333E-04 2.19347831E-03 C Standard deviation = 2.88675135E-02 4.68345845E-02 -1 GENC C1 CONT. C 4 ) -------------------------------------------------------------------------- C Statistical distribution of peak voltage for branch "ENDA " to "A10 ". C Interval voltage voltage in Frequency Cumulative C number in per unit physical units (density) frequency C 2 0.1000000 0.30300000E+02 0 0 C 3 0.1500000 0.45450000E+02 2 2 C 4 0.2000000 0.60600000E+02 1 3 C Distribution parameters for .. data follow. Grouped data Ungrouped data C Mean = 1.41666667E-01 1.43690600E-01 C Variance = 8.33333333E-04 9.61072666E-04 C Standard deviation = 2.88675135E-02 3.10011720E-02 -1 ENDA A10 C 5 ) -------------------------------------------------------------------------- C SUMMARY SUMMARY SUMMARY SUMMARY SUMMARY SUMMARY SUMMARY SUMMAR C 5 ) -------------------------------------------------------------------------- C A distribution of peak values among all output branches of the last data card C statistical distribution is for the maximum of the peaks at all of these outpu C Interval voltage voltage in Frequency Cumulative C number in per unit physical units (density) frequency C 9 0.4500000 0.13635000E+03 0 0 C 10 0.5000000 0.15150000E+03 3 3 C Distribution parameters for .. data follow. Grouped data Ungrouped data C Mean = 4.75000000E-01 4.62734306E-01 C Variance = 0.00000000E+00 9.53165933E-05 C Standard deviation = 0.00000000E+00 9.76302173E-03 C 3456789012345678901234567890123456789012345678 C MODTAB AINCR XMAXMX STATISTICS DATA 1 0.0 0.0 ---- Only individual -1 GENC C1 { =.245766731, Variance=2.19347831E-3} C ----------- Following is 2nd mini-switch plot, which is the 1st Gaussian : C Switch "B1 " to "BSW1 " C 1.32420007E-02 switch closings per column C Columns C 5 10 15 20 25 30 C +----+----+----+----+----+----+ C X C X C X C X C A* C A * C A * C A * C A * C A * C A * C A * C | 4.0000E-03 * Pulled 3 columns left ---> A C | * Pulled 3 columns left ---> A C A * C A * C A * C | * Pulled 3 columns left ---> A C A * BLANK card ending statistical tabulation requests BEGIN NEW DATA CASE C 3rd of 4 total subcases, which will illustrate statistical tabulation C of previously-generated energizations without the addition of any new C solutions. It is like 2nd, only with a different erasure of 3 shots. C Tabulations are the same. Finally, it illustrates the omission of the C miniature character plots of switch closing times via NO SWITCH PLOTS. $OPEN, UNIT=22 FILE=dc24clik.bin STATUS=OLD FORM=C-like ! { Hold case START AGAIN { Request for awakening of hibernating solution 9999 { Terminate modifications (none, here) to switching times diagnostic 9 $CLOSE, UNIT=22 STATUS=UNKNOWN { Disconnect dc24clik.bin on 22 to prevent damage $OPEN, UNIT=22 FILE=dc24at40.ext STATUS=OLD FORM=UNFORMATTED RECL=16000 ! C 345678901234567890 KIL KIL KIL KIL --- Ruler for (20X, 15I4) of next card: LOAD MORE SHOTS 3 { Load extrema of DC-24 minus shot number 3 $CLOSE, UNIT=22 STATUS=UNKNOWN { Disconnect dc24at40.ext on 22 to prevent damage TOGGLE EXTREMA MODE { Change from default UNFORMATTED mode to card images $OPEN, UNIT=22 FILE=dc24ct40.lis STATUS=OLD FORM=FORMATTED ! LOAD MORE SHOTS 1 2 { Load additional history, minus shots 1 & 2 C Following card means next case will have L2FORM = 0 within "REQUES" C whether code is overlaid or not. Otherwise, virtual computers would C have kept L2FORM = 1 whereas overlaid would have reset L2FORM = 0. TOGGLE EXTREMA MODE { Restore the default UNFORMATTED mode of "LOAD MORE SHOTS" $CLOSE, UNIT=22 STATUS=UNKNOWN { Disconnect dc24ct40.lis on 22 to prevent damage $OPEN, UNIT=22 STATUS=SCRATCH FILE=dumxx.bin ! { Reconnect dummy .BIN on LUNIT2 MISCELLANEOUS DATA CARDS 100.E-6 20.E-3 60. 1 1 1 1 1 0 0 3 C ISW ITEST IDIST IMAX IDICE KSTOUT KNTRPT NSEED 1 1 0 0 1 { KSTOUT is blank, not 0! } 1 TIME STEP LOOP { Transfer control to overlay 16 for a resumption of simulation C 1 ) -------------------------------------------------------------------------- C Statistical distribution of peak voltage for branch "GENA " to "A1 ". C Interval voltage voltage in Frequency Cumulative C number in per unit physical units (density) frequency C 27 1.3500000 0.13500000E+03 0 0 C 28 1.4000000 0.14000000E+03 1 1 C 29 1.4500000 0.14500000E+03 2 3 C Distribution parameters for .. data follow. Grouped data Ungrouped data C Mean = 1.40833333E+00 1.40208495E+00 C Variance = 8.33333333E-04 8.75092111E-04 C Standard deviation = 2.88675135E-02 2.95819558E-02 -1 100. GENA A1 C Column positioning of "NO SWITCH PLOTS" on blank terminator is arbitrary: BLANK card ending statistical tabulation requests --- NO SWITCH PLOTS --- BEGIN NEW DATA CASE C 4th of 4 total subcases will illustrate the repeated simulation of the C already-solved 2nd energization. By definition, only a single shot C will occur, and by means of KSTOUT = 0 we can look at time-step loop C output just as though there were no "STATISTICS". Such output now C can be followed by plotting (activated on 30 March 1989). Note that C the plot file header was created by the 2nd subcase of DC-24. It is C necessary to connect this since only time-step-loop output is produced C by "START AGAIN" usage such as here. Miscellaneous data parameter C ICAT = 2 will save the ".PL4" plot file, so subsequent, independent C plotting is possible (and is illustrated by the 2nd plot of the first C subcase of DC-54). There is no statistical tabulation for the present C subcase, of course. Variable KNTRPT = 2 repeats the 2nd shot of the C previously-solved 1st subcase of DC-24. The zero (not blank!) KSTOUT C provides desired time-step loop output. $OPEN, UNIT=22 FILE=dc24clik.bin STATUS=OLD FORM=C-like ! { Hold case START AGAIN { Request for awakening of hibernating solution 9999 { Terminate modifications (none, here) to switching times diagnostic 9 $CLOSE, UNIT=22 STATUS=UNKNOWN { Disconnect dc24clik.bin on 22 to prevent damage $OPEN, UNIT=22 FILE=dc24at40.ext STATUS=OLD FORM=UNFORMATTED RECL=16000 ! C 345678901234567890 KIL KIL KIL KIL --- Ruler for (20X, 15I4) of next card: LOAD MORE SHOTS { Load extrema produced by 1st subcase of DC-24 $CLOSE, UNIT=22 STATUS=UNKNOWN { Disconnect dc24at40.ext on 22 to prevent damage $OPEN, UNIT=22 STATUS=SCRATCH FILE=dumxx.bin ! { Reconnect dummy .BIN on LUNIT2 MISCELLANEOUS DATA CARDS 100.E-6 20.E-3 60. 1 1 1 1 1 0 2 3 C Preceding KNTRPT = 3 was changed from former 6 on 23 Sept 1998. C ISW ITEST IDIST IMAX IDICE KSTOUT KNTRPT NSEED 1 1 0 0 1 0 2 1 CHANGE PRINTOUT FREQUENCY 1 1 20 10 $CLOSE, UNIT=4 STATUS=DELETE { Destroy empty date/time plot file of "SYSDEP" $OPEN, UNIT=4 FILE=dc24b40d.pl4 STATUS=OVERLAY ! { C-like uses only header C READ PL4 HEADER { Messes up C-like usage of PL4 C Transfer control to the time-step loop. |TIME STEP LOOP { Transfer C GENA GENC ENDA B1 ASW10 C Reference angle A1 C1 A10 BSW1 C C GENB ENDA C B1 A10 C Random switching times for energization number 2 : C 1 1.8999095E-03 2 4.7979502E-03 3 7.5258324E-03 C 18 .0018 .284217E-13 -.26148E-11 .284217E-12 0.0 0.0 C .192639E-17 .966554E-16 C *** Close switch "A1 " to "ASW1 " after 1.90000000E-03 sec. C 19 .0019 -.28422E-13 .26148E-11 -.28422E-12 0.0 0.0 C .210598E-16 .966554E-16 TIME STEP LOOP { Transfer control to overlay 16 for a resumption of simulation C 200 .02 18.40117142 -5.2655535 13.97952075 79.19748583 128.2703628 C .4457755752 -1.28521406 C Variable max : 141.9164096 61.55446116 25.22399908 371.6253603 334.5616569 C 1.207725131 .5125980517 C Times of max : .002 .0154 .0132 .0059 .0028 C .0058 .0105 C Variable min : -103.914014 -46.8051457 -41.9189588 -288.448852 -318.274018 C -1.09393135 -1.83695142 C Times of min : .0032 .0144 .0139 .0071 .0088 C .0071 .017 PRINTER PLOT 144 1. 0.0 10. ASW10 { Plot limits: (-3.183, 3.346) BLANK card ending batch-mode plot cards BEGIN NEW DATA CASE BLANK