diff options
Diffstat (limited to 'benchmarks/dcn20.dat')
| -rw-r--r-- | benchmarks/dcn20.dat | 639 |
1 files changed, 639 insertions, 0 deletions
diff --git a/benchmarks/dcn20.dat b/benchmarks/dcn20.dat new file mode 100644 index 0000000..98db17a --- /dev/null +++ b/benchmarks/dcn20.dat @@ -0,0 +1,639 @@ +BEGIN NEW DATA CASE
+C BENCHMARK DCNEW-20
+C This data was received from Dr. Hiroshi Okamoto of Tokyo Electric Power Co.
+C (TEPCO) in Japan. This was by E-mail from <okamoto@rd.tepco.co.jp> on
+C 25 March 1997 as described in a story of the April, 1997, newsletter.
+C This data serves to compare the old Type-59 S.M. with the new Type-58 as
+C provided to ATP by TEPCO.
+C INF 1-GEN SYSTEM FOR SYNCHRONOUS MACHINE MODEL
+C DATA SET 'L0000530.SOU.EMTP2(GE2GC1)'
+C The time step size of 95 usec is especially chosen to illustrate stability
+C problems of the Type-59 S.M. (MACH 1 of the plot). The new Type-58 S.M.
+C (MACH 2 of the plot) is perfectly stable through the 100 msec shown, but
+C the old Type-59 clearly is beginning to diverge at the end of the plot. If
+C dT is increased from 95 to just 100 usec, the old Type-59 becomes a bomb.
+C On the other hand, if dT is decreased from 95 to 90 usec, the old Type-59
+C becomes almost indistinguishable from the new Type-58 over the short time
+C span considered. But increase T-max to find later trouble. The original
+C data had dT = 10 usec and T-max = 1.0 sec. Consider increasing IPLOT
+C in such a case, and maybe using TPPLOT on a saved .PL4 file. If
+C IPLOT is not increased, the result is a 20.401-Mbyte disk file.
+C Answers change 10 February 1999 following the massive changes from
+C TEPCO (Tokyo Electric Power Company) in Japan. See April newsletter.
+ .000095 .100 60. 60.
+ 1 1 1 1 -1
+ 5 5 20 20 100 100
+ 1GA IA 8.707 197.6 3.308
+ 2GB IB 5.704 65.29 -.061 8.591 196.8 3.384
+ 3GC IC 5.466 47.29 -.171 5.704 65.29 -.061 8.707 197.6 3.308
+ 1GAA IAA 8.707 197.6 3.308
+ 2GBB IBB 5.704 65.29 -.061 8.591 196.8 3.384
+ 3GCC ICC 5.466 47.29 -.171 5.704 65.29 -.061 8.707 197.6 3.308
+BLANK ENDING OF BRANCH CARDS
+BLANK ENDING SWITCH CARD
+14IA 408241.76 60.0 0.0 -1.0
+14IB 408241.76 60.0 -120.0 -1.0
+14IC 408241.76 60.0 +120.0 -1.0
+14IAA 408241.76 60.0 0.0 -1.0
+14IBB 408241.76 60.0 -120.0 -1.0
+14ICC 408241.76 60.0 +120.0 -1.0
+59GA 408248.29 60.0 1.0 -1.0
+59GB
+59GC
+ 2 2 10 1000. 500.0 800.0
+BLANK CARD
+ 1.097 0.847 0.847 1. 0.847 1.007
+ 0.767 0.507 0.0 0.66 0.0 1.0
+ 0.005 0.000392 0.027 0.034 0.0
+ 1 1.0 10.3677 1101.16 EU_MG
+ 2 0.0 17.2795 EU_MS
+BLANK CARD
+ 11
+ 21
+ 31
+ 41
+ 51
+BLANK CARD
+ FINISH
+C --------- End old Type-59 S.M. data; begin new Type-58 S.M. data:
+58GAA 408248.29 60.0 1.0 -1.0
+58GBB
+58GCC
+ 2 2 10 1000. 500.0 800.0
+BLANK CARD
+ 1.097 0.847 0.847 1. 0.847 1.007
+ 0.767 0.507 0.0 0.66 0.0 1.0
+ 0.005 0.000392 0.027 0.034 0.0
+ 1 1.0 10.3677 1101.16
+ 2 0.0 17.2795
+BLANK CARD
+ 11
+ 21
+ 31
+ 41
+ 51
+BLANK CARD
+ FINISH
+BLANK card ending source cards
+C GCC -210263.4133669 408248.29 -22.86029096659 50.481419449425 .102784436273E8 -21472.85033321
+C 349937.08475555 121.0000000 45.008674792217 116.9264047 732007.00771024 -105731.5844176
+C ICC -204120.88 408241.76 21.675662657966 50.626515259414 -.10299916478E8
+C 353547.73504567 120.0000000 -45.75160866734 -64.6498883 -837738.5921279
+C Total network loss P-loss by summing injections = 2.470730685868E+04
+ GA GB GC IA IB IC { Old Type-59 S.M.
+ GAA GBB GCC IAA IBB ICC { New Type-58 S.M.
+C First 12 output variables are electric-network voltage differences (upper voltage minus lower voltage);
+C Next 38 output variables pertain to Type-59 S.M. components (names are generated internally);
+C Step Time GA GB GC IA IB IC GAA GBB GCC IAA
+C
+C IBB ICC MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1
+C ID IQ I0 IF IKD IG IKQ IA
+C MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1
+C IB IC EFD MFORCE MANG TQ GEN ANG 1 ANG 2 VEL 1 VEL 2
+C
+C MACH 1 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2
+C TOR 1 ID IQ I0 IF IKD IG IKQ IA IB
+C
+C MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2
+C IC EFD MFORCE MANG TQ GEN ANG 1 ANG 2 VEL 1 VEL 2 TOR 1
+C 0 0.0 408186.112 -197922.7 -210263.41 408241.76 -204120.88 -204120.88 408186.112 -197922.7 -210263.41 408241.76
+C -204120.88 -204120.88 -4.4130942 60.5639838 .772660912 800.402708 .852074217 .742801855 0.0 49.9984321
+C -25.799853 -22.860291 -682.86299 799.860885 .015912194 .401972289 18.4574189 18.4411968 0.0 .14211E-13
+C .422856651 49.9984321 -25.799853 -22.860291 800.402835 .852298612 .742428139 0.0 -4.4130942 60.5639838
+C .772660912 -682.86299 799.861233 .015911908 .401972457 18.4574189 18.4411968 0.0 0.0 .422856651
+C 1 .95E-4 407893.672 -185217.11 -222679.75 407979.972 -191330.68 -216649.29 408111.529 -185307.24 -222807.51 407979.972
+C -191330.68 -216649.29 -4.2041412 60.3879406 .714862646 800.379672 .811106299 .781017269 0.0 49.7613998
+C -24.063847 -24.459374 -682.86299 799.86747 .015896025 .400786124 18.4574189 18.4411968 .216E-10 .2802E-5
+C .422856453 49.8095208 -24.085131 -24.485985 800.380399 .812262842 .788588762 0.0 -4.2091863 60.3524392
+C .714993055 -682.86299 799.867602 .015892687 .400551293 18.4574189 18.4411968 .21714E-10 .281731E-5 .422856451
+C 2 .19E-3 406867.982 -172041.84 -234825.96 407194.942 -178295.09 -228899.85 406998.315 -172084.21 -234913.87 407194.942
+C -178295.09 -228899.85 -3.9507996 60.1570077 .659527672 800.35128 .762038113 .831454902 0.0 49.4294498
+C -22.260505 -26.026609 -682.86299 799.875576 .015875056 .39923208 18.4574189 18.4411968 .131024E-9 .57827E-5
+C .422855844 49.4707826 -22.278391 -26.047605 800.352354 .763726476 .854919597 0.0 -3.95874 60.0504313
+C .660942841 -682.86299 799.875528 .015865594 .398526145 18.4574189 18.4411968 .132076E-9 .585937E-5 .422855836
+BLANK card ending output requests
+C 1053 .100035 415280.068 -197293.88 -217987.68 408206.223 -199438.29 -208767.93 408235.937 -193516.73 -214722.13 408206.223
+C -199438.29 -208767.93 -4.1350245 61.3028263 .690403958 800.370438 .799733436 .56388449 0.0 50.7259147
+C -25.427344 -24.102756 -682.86299 799.871164 .015965431 .406847425 18.457757 18.4415815 .573744E-4 .395066E-4
+C .421640989 50.3438664 -25.04608 -24.297981 800.350146 .676467979 .59869684 0.0 -3.6952162 61.1409442
+C .577238085 -682.86299 799.876422 .015950332 .405730061 18.4577388 18.4415591 .556036E-4 .380861E-4 .421750163
+C Variabl max: 415280.068 412229.576 411850.366 408241.76 408240.005 408241.321 408635.133 408471.267 408253.524 408241.76
+C 408240.005 408241.321 5.12456969 68.4279518 1.78316215 800.48001 1.02182904 1.18160057 0.0 51.7606628
+C 54.6088512 52.6553712 -682.86299 800.203141 .016566167 .453784705 18.457757 18.4415815 .108985E-3 .154242E-3
+C .424309833 50.8562508 53.8835515 52.2481039 800.498224 1.00871794 1.15996876 0.0 4.8599028 67.7090154
+C 1.87680621 -682.86299 800.19173 .01650918 .44903137 18.4577388 18.4415591 .101535E-3 .149203E-3 .424182575
+C Times of max: .100035 .088635 .09424 0.0 .02223 .011115 .083315 .038855 .044365 0.0
+C .02223 .011115 .08702 .097185 .09709 .01577 .01577 .001425 0.0 .09975
+C .088825 .09443 0.0 .08702 .097185 .097185 .100035 .100035 .046265 .08702
+C .06783 .09975 .08873 .01121 .01577 .01577 .00133 0.0 .00361 .013585
+C .0969 0.0 .00361 .013585 .013585 .100035 .100035 .046455 .086925 .06783
+ 193.01 0.0 .1 .30 .50MACH 1TQ GENMACH 2TQ GEN
+BLANK card ending plot cards
+BEGIN NEW DATA CASE
+C 2nd of 3 subcases was added 18 February 1999. The data came from TEPCO,
+C but has been modified to minimize the computational burden. As should be
+C described in the April, 1999, newsletter, NEW LOAD FLOW is illustrated.
+C INF 1-GEN SYSTEM FOR SYNCHRONOUS MACHINE MODEL
+C DATA SET 'L0000530.SOU.EMTP2(GE2GC1)'
+NEW LOAD FLOW { Request for new TEPCO load flow, used if unbalanced
+C The preceding old form of the request is being reactivated 3 June 2001
+C to demonstrate the new warning message. It also reminds developers that
+C the old form continues to be honored (and eventually should be removed).
+C It is recommended that others use CAO instead of NEW as follows:
+C CAO LOAD FLOW { Alternate, preferred form of request beginning 21 March 99
+C 10.E-6 1. 60. 60. ---- original simulation is demanding
+ 40.E-6 .100 60. 60. { Shorter, faster simulation for this use
+ 1 1 1 1 1 -1
+ 5 5 20 20 100 100 500 500
+ 1GA IA 8.707 197.6 3.308
+ 2GB IB 5.704 65.29 -.061 8.591 196.8 3.384
+ 3GC IC 5.466 47.29 -.171 5.704 65.29 -.061 8.707 197.6 3.308
+BLANK ENDING OF BRANCH CARDS
+BLANK ENDING SWITCH CARD
+14IA 408241.76 60.0 0.0 -1.0
+14IB 408241.76 60.0 -120.0 -1.0
+14IC 408241.76 60.0 +120.0 -1.0
+58GA 408248.29 60.0 1.0 -1.0
+58GB
+58GC
+ 2 2 10 1000. 500.0 800.0
+BLANK CARD for Q axis
+ 1.097 0.847 0.847 1. 0.847 1.007
+ 0.767 0.507 0.0 0.66 0.0 1.0
+ 0.005 0.000392 0.027 0.034 0.0
+ 1 1.0 10.3677 1101.16 EU_MG
+ 2 0.0 17.2795 EU_MS
+BLANK CARD
+ 11
+ 21
+ 31
+ 41
+ 51
+BLANK CARD ending S.M. output requests
+ FINISH
+BLANK CARD ending sources
+ GA GB GC 10000000. 0.
+ 1 0.01
+ GA GB GC IA IB IC
+BLANK CARD FOR ENDING OUTPUT REQUEST
+ PRINTER PLOT
+ 144 2. 0.0 20. GA GB GC
+ 194 2. 0.0 20. MACH 1TQ GENMACH 1I0
+BLANK card ending plot cards
+BEGIN NEW DATA CASE
+C 3rd of 3 subcases involving modeling from TEPCO (Tokyo Electric Power Co.)
+C --- data that demonstrated trouble with the Type-58 S.M. model prior to
+C correction of the UTPF on 22 January 2003. Data is from Dr. Eiichi
+C Haginomori of Kyushu Institute of Technology in Kita-Kyushu, Japan.
+C Ending time T-max has been shortened to 5 * dT because the switching
+C that caused trouble has been advanced to the 3rd time step. Following
+C correction, execution no longer hangs during the step following switching.
+NEW LIST SIZES { Overflow of 3 times default without expanded List 19 below:
+ 350 0
+ 0 80 4000
+BLANK
+ 240000 742
+ABSOLUTE TACS DIMENSIONS
+C Expand TACS Table 1 from 57 to 120 on 1 April 2007. Force the data thru.
+C Reduce preceding 8000 of List 19 to 4000 since TACS is not very demanding
+C The effect on case-summary statistics is to reduce 7644 to 3271.
+C 57 256 285 36 85 713 998 171 --- default
+ 120 30 50 40 70 1200 120 115
+C USING TPBIG-96/7 --- DIRECT CONNECTION OF UM AND INVERTER
+C CALCULATED THETAE FROM EL. INFORMATIONS ACTURALLY --- 3*THETAM=THETAE FOR 6P
+C <<< ONE-GEN --- INF BUS SYSTEM WITH FLYWHEEL COMPENSATOR>>>
+C SYNCH. GENERATOR 1200MVA 6P / FLYWHEEL COMPENSATOR 200MVA 6P DOUBLY FED MACH.
+C <<Inc.-SATUR. CHARACTERISTICS IS INTRODUCED>> SYNC. GEN. FIX FLOW CAN NOT
+C A-SYMMETRICAL FAULT CURRENT, UNDER UPPER LIMIT POWER FLOW
+C <<Both PP & QQ OF UM ARE CONTROLLED, Max output, Gen output = 115%>>
+POWER FREQUENCY, 50.
+UM TO TACS
+ .000200 .001 { Just 5 steps. Original data had Tmax = 3.0 and IPLOT = 10
+ 1 1 1 3
+TACS HYBRID
+C INPUTTING VALUES
+92IE3 {UM SECONDARY CURRENT PHASE A --- UM TO TACS PARAMETERS
+92IE1 {DITTO B
+92IE2 {DITTO C
+92IPA {UM PRIMARY CURRENT PHASE A
+92IPB {DITTO B
+92IPC {DITTO C
+90G1RX {UM PRIMARY SIDE TERMINAL VOLTAGE PHASE R
+90G1SX {DITTO S
+90G1TX {DITTO T
+C MEASURING DELTA F OF THE HIGH-VOLTAGE BUS
+90B271R {HIGH VOLTAGE BUS VOLTAGE
+90B271S {HIGH VOLTAGE BUS VOLTAGE
+90B271T {HIGH VOLTAGE BUS VOLTAGE
+C INVERTER CONTROLLING
+91VAP { phase-A current }
+91VBP { phase-B current }
+91VCP { phase-C current }
+93VDA { Leg-A top switch status }
+93VDB { Leg-B top switch status }
+93VDC { Leg-C top switch status }
+C CONSTANTS
+11X0 1.6642 -1. {UM PARAMETER
+11X1 .08635 -1. {DITTO
+11PP1 -600000. -1. {OUTPUT CONST.
+11PP2 -2.5E08 .44 {DITTO
+11QQ1 -1000000. -1. {DITTO
+11QQ2 -2.5E08 .44 {DITTO
+C BUS VOLTAGE FREQUENCY METER
+98BUSV = B271R - .5 *(B271S + B271T)
+ 1VOLT +BUSV
+1.
+1. .005
+98FREQ 50+VOLT 50. 500.
+88DELFR1 = (FREQ - 50.)/ .5
+ DELFR +DELFR1 -1. 1.
+ 2DELFZ +DELFR
+1.
+1. .06 .0009
+C COMMAND CALCULATION --- FIRSTLY UM PRIMARY SIDE VECTORS
+ VRSQ +G1RX -1. 1.
+98SIG 59+VRSQ
+99IN1 = 100 * PI * DELTAT
+98TH0 65+IN1 SIG
+98PP = PP1 + (PP2 * DELFZ) {ACTIVE POWER CONTROLLING
+98QQ = QQ1 + (QQ2 * DELFZ) {REACTIVE POWER CONTROLLING
+99V1PS =SQRT((G1RX * G1RX) + ((G1SX - G1TX) * (G1SX - G1TX)/3.))
+ 1V1P +V1PS
+1.
+1. .002
+98I1P =2 * SQRT((PP * PP) + (QQ * QQ)) / V1P
+98TH11 =ATAN(QQ / PP)
+98TH12 =TH11 + PI
+98TH1 60+TH12 +TH11 +TH11 0.0 PP
+98I1 =I1P * SIN(TH0 + TH1)
+98XXX =COS(TH1) / (V1P/(X1*I1P) - SIN(TH1))
+98TH2 =ATAN(XXX)
+98E1P =X1 * I1P * COS(TH1)/SIN(TH2)
+98I0P =E1P / X0
+98I0 =I0P * SIN(TH0 + TH2 - (PI/2))
+98I21 =I1 + I0
+C CALCULATION CORRESPONDING TO POSITION SENCER
+C PRIMARY SIDE VIEW OF THE SECONDARY CURRENT
+98V1 = 0.5 * (G1RX - G1SX - G1TX)
+98JV1 = (G1TX - G1SX) / 1.7320508
+98I11 = 0.5 * (IPA - IPB - IPC)
+98JI11 = (IPC - IPB) / 1.7320508
+98I21A = (I11 * (1. + (X1/X0))) - (JV1/X0)
+98JI21A = (V1/X0) + (JI11 * (1. + X1/X0))
+98THI210 = -(ATAN(JI21A/I21A))
+98THI211 = THI210 + PI
+98THI21A60+THI211 +THI210 +THI210 0.0 I21A
+C SECONDARY SIDE VIEW OF THE SECONDARY INJECTING CURRENT
+C IN UM, IE3, IE1, IE2 ARE Ia, Ib, Ic OF RESPECTIVE OUTGOING CURRENT, THEN:
+98I22 = 0.5 * (IE1 + IE2 - IE3)
+98JI22 = (IE1 - IE2) / 1.7320508
+98THI220 = -(ATAN(JI22/I22))
+98THI221 = THI220 + PI
+98THI22 60+THI221 +THI220 +THI220 0.0 I22
+C CALCULATION OF THETAE
+98THETAE = THI21A- THI22 {BASED ON UM POSITION IN EMTP}
+C SECONDARY SIDE CURRENTS --- FOR COMMANDING
+98I2A1 =I1P * SIN(TH0 + TH1 - THETAE)
+98I2A0 =I0P * SIN(TH0 + TH2 - (0.5*PI) - THETAE)
+88S2AS =I2A1 + I2A0
+98I2B1 =I1P * SIN(TH0 + TH1 - (0.66667*PI) - THETAE)
+98I2B0 =I0P * SIN(TH0 + TH2 - (1.16667*PI) - THETAE)
+88S2BS =I2B1 + I2B0
+98I2C1 =I1P * SIN(TH0 + TH1 + (0.66667*PI) - THETAE)
+98I2C0 =I0P * SIN(TH0 + TH2 + (0.16667*PI) - THETAE)
+88S2CS =I2C1 + I2C0
+ 1S2AIN +S2AS
+1.
+1. .005
+ 1S2BIN +S2BS
+1.
+1. .005
+ 1S2CIN +S2CS
+1.
+1. .005
+C --------- SINUSOIDAL REFERENCE CURRENTS
+98IREFA = S2AIN
+98IREFB = S2BIN
+98IREFC = S2CIN
+98DELTAI = 200. { one-half of the difference between the upper and the lower
+C tolerance bands }
+C 98REFPOS = IREFA + DELTAI { POSITIVE REFERENCE BAND FOR PHASE-A }
+C 98REFNEG = IREFA - DELTAI { NEGATIVE REFERENCE BAND FOR PHASE-B }
+C --------- ERROR BETWEEN THE MEASURED AND THE REFERENCE CURRENTS
+98ERRORA = VAP - IREFA
+98ERRORB = VBP - IREFB
+98ERRORC = VCP - IREFC
+C --------- SIGNL = 0 IF THE CURRENT IS WITHIN THE TOLERANCE BANDS
+C = 1 IF THE CURRENT EXCEEDS THE UPPER TOLERANCE BAND
+C =-1 IF THE CURRENT FALLS BELOW THE LOWER TOLERANCE BAND
+98SIGNLA = SIGN( ERRORA ) * ( ABS( ERRORA ) .GT. DELTAI )
+98SIGNLB = SIGN( ERRORB ) * ( ABS( ERRORB ) .GT. DELTAI )
+98SIGNLC = SIGN( ERRORC ) * ( ABS( ERRORC ) .GT. DELTAI )
+C --------- SIGA AND SIGAP CONTROL LEG-A SWITCHES; SIGB AND SIGBP CONTROL LEG-B
+C SIGC AND SIGCP CONTROL LEG-C
+C --------- SIG = NO CHANGE, IF SIGNL = 0
+C = 0 , IF SIGNL = 1
+C = 1 , IF SIGNL =-1
+98SIGA 60+UNITY +VDA +ZERO SIGNLA
+98SIGB 60+UNITY +VDB +ZERO SIGNLB
+98SIGC 60+UNITY +VDC +ZERO SIGNLC
+98SIGAP = .NOT. SIGA
+98SIGBP = .NOT. SIGB
+98SIGCP = .NOT. SIGC
+33THI210THI22 THETAEDELFZ IREFA
+BLANK card ending TACS data
+C POWER SYSTEM CIRCUITS
+C TRANSFORMER FOR UM
+ TRANSFORMER TR1RX 5.00E3
+1.5 205.
+7. 232.
+333. 271.
+3333. 386.
+ 9999
+ 1G1RX G1SX .0001 .01 11.
+ 2B271R NNX .5 90. 158.8
+ TRANSFORMER TR1RX TR1SX
+ 1G1SX G1TX
+ 2B271S NNX
+ TRANSFORMER TR1RX TR1TX
+ 1G1TX G1RX
+ 2B271T NNX
+C AROUND TRANSFORMER PARAMETERS
+ G1RX 100. .5
+ G1SX G1RX
+ G1TX G1RX
+ B271R .2 .02
+ B271S B271R
+ B271T B271R
+ NNX 1.
+C MACHANICAL NETWORK COMPONENTS
+ MG .00366 {1.5%}
+ MG 1.8E11
+ MS MG .10E-3 1
+C UM SECONDARY SIDE PARAMETERS
+ S2A CL2A .001 1
+ S2B CL2B S2A CL2A 1
+ S2C CL2C S2A CL2A 1
+ CL2A 100.
+ CL2B CL2A
+ CL2C CL2A
+C GENERATOR STEP-UP TRANSFORMER
+ TRANSFORMER 1. 747.6 TR1R 60.0E3
+1. 747.6
+4. 971.
+16. 1196.
+1000. 1300.
+ 9999
+ 1B271R 27N1 .2 33. 166.
+ 2G1R G1S .001 .076 24.
+ TRANSFORMER TR1R TR1S
+ 1B271S 27N1
+ 2G1S G1T
+ TRANSFORMER TR1R TR1T
+ 1B271T 27N1
+ 2G1T G1R
+C AROUND TRANSFORMER PARAMETERS
+ 27N1 .5 .005
+ G1R .01 .05
+ G1S G1R
+ G1T G1R
+ B271R G1R
+ B271S G1R
+ B271T G1R
+C LONG TRANSMISSION LINE parameters in English due to bug in TP20
+$VINTAGE, 1
+-1B271R B272R 2.26285E+00 9.55548E+02 1.26663E+05 4.25000E+01 1
+-2B271S B272S 3.10872E-02 2.76280E+02 1.81024E+05 4.25000E+01 1
+-3B271T B272T
+-4L271S L272S
+-5L271T L272T
+-6L271R L272R
+-1B272R B273R 2.26285E+00 9.55548E+02 1.26663E+05 4.50000E+01 1
+-2B272S B273S 3.10872E-02 2.76280E+02 1.81024E+05 4.50000E+01 1
+-3B272T B273T
+-4B272S B273S
+-5B272T B273T
+-6B272R B273R
+$VINTAGE, 0
+ B273R .01 .05
+ B273S B273R
+ B273T B273R
+ B273R SWGR .1 17.5 1
+ B273S SWGS B273R SWGR 1
+ B273T SWGT B273R SWGR 1
+C INVERTER CIRCUITS, WITH 1.5MH
+ VA VAP .001 1.5 3
+ VB VBP VA VAP 3
+ VC VCP VA VAP 3
+C --------- SMALL RESISTANCES ARE ADDED
+ VD VDA 0.001
+ VD VDB VD VDA
+ VD VDC VD VDA
+ VDN VDNA VD VDA
+ VDN VDNB VD VDA
+ VDN VDNC VD VDA
+C ANOTHER HIGH OHMIC RESISTORS
+ VD 90000.
+ VDN VD
+ VAPG VD
+ VBPG VD
+ VCPG VD
+ VA VD
+ VB VD
+ VC VD
+C SNUBBER
+ VDA VA 5. 10.
+ VDB VB VDA VA
+ VDC VC VDA VA
+ VA VDNA VDA VA
+ VB VDNB VDA VA
+ VC VDNC VDA VA
+C INVERTER INITIAL DUMMY LOAD
+ VAPGL .003
+ VBPGL VAPGL
+ VCPGL VAPGL
+BLANK card ending branch cards
+C FAULT INITIATION AND CLEARING SWITCHES
+C ---------------- Begin modification for use with T-max = 5 * dT.
+C First, omit the 3 original fault switches to ground:
+C L271R .303 10. 1
+C L271S .299 10. 1
+C L271T .2965 10. 1
+C Only the phase "a" switch is needed. This was the one
+C that caused trouble (a tight loop 1 step after closure).
+C Advance closing time to 2.5 * dT ==> closure on step 3.
+C Without correction to OVER16, execution would hang with
+C the last output on the screen being that for step 3:
+ L271R .000500 10.0 1
+C ---------------- End of modification made 22 January 2003
+ B271R L271R -1. .4
+ B271S L271S -1. .4
+ B271T L271T -1. .4
+ L272R B272R -1. .4
+ L272S B272S -1. .4
+ L272T B272T -1. .4
+C SWITCHES TURN OVER THE INVERTER OUTPUT FROM DUMMY TO UM SECONDARY
+ VAPG VAPGL -1. .201 9.E10 {SHALL BE BEFORE MEASURING SW
+ VBPG VBPGL -1. .201 9.E10
+ VCPG VCPGL -1. .201 9.E10
+ VAPG CL2A .20 10.
+ VBPG CL2B .20 10.
+ VCPG CL2C .20 10.
+C SWITCHES IN THE INVERTER AND AC SIDE CIRCUITS
+ VAP VAPG MEASURING
+ VBP VBPG MEASURING
+ VCP VCPG MEASURING
+C CONNECTED DIODE
+13VDA VA SIGA 1
+13VDB VB SIGB 1
+13VDC VC SIGC 1
+13VDNA VA SIGAP 1
+13VDNB VB SIGBP 1
+13VDNC VC SIGCP 1
+BLANK card ending switch cards
+14SWGR 225000. 50. 0. -1.
+14SWGS 225000. 50. -120. -1.
+14SWGT 225000. 50. 120. -1.
+C <CLASS 1 CARDS>
+14S2A -15600. .005 5. -1. .201
+14S2B -15600. .005 -115. -1. .201
+14S2C -15600. .005 125. -1. .201
+C DC VOLTAGE CAN BE REDUCED TO +/- 700 VOLTS WITHOUT CHANGING OTHERS
+14VD 750. .00001 -1.
+14VDN -750. .00001 -1.
+C MECHANICAL TORQUE (ACTUAL VALUE WILL BE SET BY INITIAL CONDITION)
+14MS -1.0001 .000001 -1.
+C ------ UNIVERSAL MACHINE PARAMETERS
+19 UM
+ 1 {COMPENSATION, SLIP INITIALIZATION IS INTRODUCED}
+BLANK RECORD ENDING GENERAL UNIVERSAL MACHINE SPECIFICATION
+C UM MACHINE-TABLE
+C UM TYPE 4 (DOUBLY FED INDUCTION MACHINE)
+ 4 311MG 3 .1047
+ .0053
+ .0053
+C INITIAL CONDITION ---- ONLY SLIP IS SPECIFIED AS .01%
+.01 MS
+C MOTOR COIL PARAMETERS
+C THE POWER (ARMATURE/STATOR) COILS
+ G1RX 1
+.003 .000275 G1SX 1
+.003 .000275 G1TX 1
+C THE ROTOR COILS
+.003 .000275 CL2B 1
+.003 .000275 CL2C 1
+ CL2A 1
+BLANK ENDING ALL WINDING ROTOR INDUCTION MOTOR DATA
+58G1R 20000. 50. 4.3
+58G1S
+58G1T
+C <CLASS 2 CARDS>
+TOLERANCES {DEFAULT}
+PARAMETER FITTING 1.0
+C <CLASS 3 CARDS>
+ 1 1 61.0 1.0 1200. 24.0 -500. 550. 900.
+ -1.
+.003 .2033 1.048 .640 .299 .640 .214 .278
+6.4 0.0 .033 .04 .214 .01 .1
+C <CLASS 4 CARD FOR MECHANICAL PARAMETERS>
+ 1 1.0 25. 5.
+BLANK {FOR END OF CLASS 4 CARDS}
+ 11
+ 21
+ 31
+ 51
+BLANK {FOR END OF OUTPUT REQUEST}
+C 71VFG1
+C 73TEG1 14
+ FINISH
+BLANK card ending electric network source cards
+C - - INITIAL CONDITIONS
+C 03VA VAP 16200.
+C 03VB VBP -12000.
+C 03VC VCP -4400.
+ B271R B271S B271T G1R G1S G1T G1RX G1SX G1TX CL2A CL2B CL2C
+C First 15 output variables are electric-network voltage differences (upper voltage minus lower voltage);
+C Next 17 output variables are branch currents (flowing from the upper node to the lower node);
+C Next 16 output variables pertain to Type-59 S.M. components (names are generated internally);
+C Next 5 output variables belong to TACS (with "TACS" an internally-added upper name of pair).
+C Final 11 output variables pertain to Type-19 U.M. components (names are generated internally);
+C Step Time VA VB VC B271R B271S B271T G1R G1S G1T G1RX
+C VAP VBP VCP
+C
+C G1SX G1TX CL2A CL2B CL2C L271R VDA VDB VDC VDNA
+C TERRA VA VB VC VA
+C
+C VDNB VDNC MS S2A S2B S2C B273R B273S B273T VA
+C VB VC MG CL2A CL2B CL2C SWGR SWGS SWGT VAP
+C
+C VB VC MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1
+C VBP VCP IA IB IC IF IKD IG IKQ ID
+C
+C MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 TACS TACS
+C IQ I0 EFD MFORCE MANG TQ GEN ANG 1 VEL 1 THI210 THI22
+C
+C TACS TACS TACS UM-1 UM-1 UM-1 UM-1 UM-1 UM-1 UM-1
+C THETAE DELFZ IREFA TQGEN FLUXMD IMD OMEGM THETAM IPA IPB
+C
+C UM-1 UM-1 UM-1 UM-1
+C IPC IE1 IE2 IE3
+C *** Phasor I(0) = 1.7481189E+03 Switch "B271R " to "L271R " closed in the steady-state.
+C *** Phasor I(0) = -4.5243456E+02 Switch "B271S " to "L271S " closed in the steady-state.
+C *** Phasor I(0) = -1.2956844E+03 Switch "B271T " to "L271T " closed in the steady-state.
+C *** Phasor I(0) = 1.7686094E+03 Switch "L272R " to "B272R " closed in the steady-state.
+C *** Phasor I(0) = -5.1164059E+02 Switch "L272S " to "B272S " closed in the steady-state.
+C *** Phasor I(0) = -1.2569688E+03 Switch "L272T " to "B272T " closed in the steady-state.
+C *** Phasor I(0) = 7.8597942E-28 Switch "VAPG " to "VAPGL " closed in the steady-state.
+C *** Phasor I(0) = 7.8597942E-28 Switch "VBPG " to "VBPGL " closed in the steady-state.
+C *** Phasor I(0) = 7.8597942E-28 Switch "VCPG " to "VCPGL " closed in the steady-state.
+C *** Phasor I(0) = 7.8597944E-28 Switch "VAP " to "VAPG " closed in the steady-state.
+C *** Phasor I(0) = 7.8597944E-28 Switch "VBP " to "VBPG " closed in the steady-state.
+C *** Phasor I(0) = 7.8597944E-28 Switch "VCP " to "VCPG " closed in the steady-state.
+C 0 0.0 -.2259E-29 -.2259E-29 -.2259E-29 208158.64 -21846.037 -186312.6 19943.7027 -8673.1817 -11270.521 9113.64098
+C -5276.1428 -3837.4982 16.8063328 -6.3031915 -10.503141 0.0 0.0 0.0 0.0 0.0
+C 0.0 0.0 152316.004 5578.69031 -2366.6623 -3212.028 3559.62137 -1144.404 -2415.2173 .78598E-27
+C .78598E-27 .78598E-27 41715.1084 -30191.8 -11523.308 1001.80789 .487618E-5 0.0 .20218E-5 -35892.416
+C 38680.9534 .170478E-9 -3332.2787 718.756062 .237235816 11.7236335 39.4571339 .46896E-12 0.0 0.0
+C 0.0 0.0 0.0 123706.91 35.5738008 6712.03789 104.709283 .523598776 938.381553 -554.20525
+C -384.1763 2366.59923 3211.92301 -5578.5222
+C 1 .2E-3 -.1339E-13 -.1339E-13 -.1339E-13 201977.519 -7722.5921 -194254.03 19823.8315 -7579.7442 -12244.087 9151.45131
+C -4804.5629 -4346.8884 23.814177 -7.6609777 -16.153199 0.0 0.0 0.0 0.0 0.0
+C 0.0 0.0 152316.004 5578.68724 -2366.6304 -3212.0569 3505.7501 -925.34683 -2580.4033 -.8926E-15
+C -.8926E-15 -.8926E-15 42307.6898 -28187.048 -14120.641 1001.59093 -2.0122485 0.0 -.8358523 -35874.126
+C 38689.6613 -.1969E-11 -3332.2787 716.646844 .237381679 11.7267018 39.4571339 -.29124E-6 -1.4215961 .087267731
+C -1.5088638 0.0 -62.836554 123698.108 35.5747011 6712.20775 104.709283 .544540632 942.608173 -504.94928
+C -437.6589 2366.55377 3211.89533 -5578.4491
+C 2 .4E-3 -749.75008 -749.75008 -749.75008 194885.42 6602.83234 -201489.52 19598.7968 -6330.0077 -13268.789 9151.94877
+C -4310.2982 -4841.6506 28.6859178 -9.1396133 -19.546304 0.0 0.0 0.0 0.0 -149.97834
+C -149.97834 -149.97834 152316.004 5578.68418 -2366.5985 -3212.0857 3437.41314 -702.48667 -2734.9265 -49.980007
+C -49.980007 -49.980007 42730.2018 -26082.723 -16647.479 1001.36092 -4.0385211 0.0 -1.6446481 -35870.068
+C 38686.6306 -.3212E-11 -3332.2787 714.385728 .237526201 11.7277418 39.4571339 -.97244E-6 -1.3592587 .087272806
+C -1.4465315 0.0 -145.63073 123685.026 35.5770492 6712.65079 104.709283 .565482489 943.011488 -453.49067
+C -489.52082 2366.50709 3211.89023 -5578.3973
+C *** Close switch "L271R " to " " after 6.00000000E-04 sec.
+C 3 .6E-3 -749.41701 -749.41701 750.083142 186906.226 20907.6164 -207813.87 19310.7466 -5217.9361 -14092.81 9111.193
+C -3792.8021 -5318.3909 27.9503294 -12.236022 -15.714307 0.0 0.0 0.0 183.36497 -116.59171
+C -116.59171 0.0 152316.004 5578.68111 -2366.5666 -3212.1145 3356.73113 -477.93728 -2878.7937 -149.91115
+C -149.91115 -49.951141 42979.6997 -23882.395 -19097.305 1001.16741 -5.618633 0.0 -2.210096 -35872.276
+C 38671.8269 .52551E-11 -3332.2787 712.559772 .23763113 11.7257636 39.4571339 -.15646E-5 -1.2963263 .087286091
+C -1.3836124 0.0 -177.30291 123687.716 35.579885 6713.18584 104.709283 .586424345 939.747207 -400.25471
+C -539.4925 2366.44424 3211.95737 -5578.4016
+BLANK card ending names of nodes for node voltage
+ PRINTER PLOT
+C 4 .8E-3 -748.99533 -748.99533 749.838688 0.0 13506.5876 -233952.01 14577.5321 277.974209 -14855.506 5550.20833
+C 194.206101 -5744.4144 -2556.0075 -910.96566 3466.97318 1441.53156 0.0 0.0 -27.703214 -260.88663
+C -260.88663 0.0 152316.004 5578.67804 -2366.5347 -3212.1433 3263.9781 -252.44548 -3011.5318 -249.77866
+C -249.77866 50.0436418 44314.9041 -22892.215 -21422.689 1001.6319 -1.0119264 0.0 -8.8523256 -37619.202
+C 39135.5529 -.705E-11 -3332.2787 702.815796 .238926785 11.9567249 39.4571338 -.23891E-4 -.8024862 .091369899
+C -.8938561 0.0 -215.55492 133220.775 35.2574518 6652.3494 104.709283 .607366202 1023.64204 -438.56934
+C -585.0727 2357.42505 3246.81306 -5604.2381
+C 5 .1E-2 -748.60353 -748.60353 749.387134 0.0 81277.3789 -183207.78 12900.5692 2610.61804 -15511.187 4283.41475
+C 1858.75941 -6142.1742 -4023.6743 -783.70104 4807.37529 2017.68499 0.0 0.0 175.891852 -345.88141
+C -345.88141 0.0 152316.004 5578.67497 -2366.5028 -3212.1722 3157.97507 -25.604427 -3132.3703 -349.57863
+C -349.57863 149.978695 47142.2759 -23517.378 -23624.897 1004.52269 25.8533897 0.0 -15.562683 -41739.361
+C 39892.6407 .51464E-11 -3332.2787 697.874488 .240411365 12.3998762 39.457133 -.1102E-3 -.56146341 .092374845
+C -.65383825 0.0 -274.01893 147358.665 34.4425429 6498.593 104.709283 .628308059 1170.0168 -540.67448
+C -629.34232 2358.66581 3260.24591 -5618.9117
+BLANK card ending batch-mode plot cards
+BEGIN NEW DATA CASE
+BLANK
|