<span style="color:#444444;font-family:Tahoma, "font-size:14px;background-color:#FFFFFF;">ATP新手,点plotxy后出现The selected file contains no bytes,view LIS file如下,求大神解答 7 L) I4 ]# o( _, z C% ~Alternative Transients Program (ATP), GNU Linux or DOS. All rights reserved by Can/Am user group of Portland, Oregon, USA. ) F' y) c; n1 C- Y, U' L4 a# w# u( k Date (dd-mth-yy) and time of day (hh.mm.ss) = 02-May-19 23:52:54 Name of disk plot file is jjj1.pl4 T1 {5 |# G' e! MConsult the 860-page ATP Rule Book of the Can/Am EMTP User Group in Portland, Oregon, USA. Source code date is 19 September 2003.: c* Y8 b6 s$ t$ X
Total size of LABCOM tables = 9872109 INTEGER words. 31 VARDIM List Sizes follow: 6002 10K 192K 900 420K 1200 15K2 t8 z7 Y; V" P6 B5 U
120K 2250 3800 720 1200 72800 510 90K 800 90 254 120K 100K 3K 15K 192K 120 30K 160K 600 210K 300 19 200 3 n& ?# E' m& S+ r: m1 ~& e/ Z--------------------------------------------------+--------------------------------------------------------------------------------" i" l! X9 s; I( b& n3 g1 A
Descriptive interpretation of input data cards. | Input data card images are shown below, all 80 columns, character by character9 `7 [% y; Y' Q7 `- s$ p
0 1 2 3 4 5 6 7 8 J% s. Q& h. T) x/ R ?
012345678901234567890123456789012345678901234567890123456789012345678901234567890 ' R+ `" G. q0 Y) @& g) k6 _--------------------------------------------------+--------------------------------------------------------------------------------0 s* i1 v5 F; R1 v/ f0 M
Comment card. KOMPAR > 0. |C data:JJJ1.ATP- M |5 W4 ]& C p& W
Marker card preceding new EMTP data case. |BEGIN NEW DATA CASE( Q, h* D, W" F ]
Comment card. KOMPAR > 0. |C --------------------------------------------------------5 {, O3 \/ ?& b
Comment card. KOMPAR > 0. |C Generated by ATPDRAW 五月, 星期四 2, 2019 1 H- R" W9 i9 z# U B' o+ L5 cComment card. KOMPAR > 0. |C A Bonneville Power Administration program% I0 D) O. T0 u s1 I7 r
Comment card. KOMPAR > 0. |C by H. K. H鴌dalen at SEfAS/NTNU - NORWAY 1994-20156 O3 | F: o; O' Z; }
Comment card. KOMPAR > 0. |C --------------------------------------------------------# Z4 s; |; C( ?/ i1 q6 t% I
Comment card. KOMPAR > 0. |C dT >< Tmax >< Xopt >< Copt ><Epsiln> ' ]0 _$ [+ P9 u( n$ u9 YMisc. data. 1.000E-09 1.000E-03 0.000E+00 | 1.E-9 .001* a9 S+ Y. I6 R
Misc. data. 500 1 1 1 1 0 0 1 0 0 | 500 1 1 1 1 0 0 1 04 D7 b0 u! j# e1 ]: \" k: O& ~
Comment card. KOMPAR > 0. |C 1 2 3 4 5 6 7 8: y# H" u6 w7 m9 a1 s- V
Comment card. KOMPAR > 0. |C 345678901234567890123456789012345678901234567890123456789012345678901234567890 9 |! N" j, J- C/ v X* Z0 AComment card. KOMPAR > 0. |C < n1 >< n2 ><ref1><ref2>< R >< L >< C > % W/ D! B" p$ J' O+ _5 T* SComment card. KOMPAR > 0. |C < n1 >< n2 ><ref1><ref2>< R >< A >< B ><Leng><><>0/ I3 R5 j s: q0 p" R. D
Series R-L-C. 0.000E+00 0.000E+00 2.500E-04 | XX0001 250. 04 V! U! Y! q5 `+ x6 ]2 ~4 d# `- n i
4.000E+00 6.000E+01 3.000E+08 6.000E+01 1.667E-06|-1XX0001XX0003 4. 60. 3.E8 500. 1 0 04 D5 y2 r g+ i) Z
Series R-L-C. 0.000E+00 1.000E-01 0.000E+00 | XX0002XX0001 100. 0; ^: ]8 D2 V7 v K# _0 @ u0 z. f0 O
4.000E+00 6.000E+01 3.000E+08 6.000E+01 1.667E-06|-1XX0004XX0005 4. 60. 3.E8 500. 1 0 02 `2 K4 r3 W+ p5 P$ `; N
4.000E+00 6.000E+01 3.000E+08 6.000E+01 1.667E-06|-1XX0006XX0007 4. 60. 3.E8 500. 1 0 04 c; n- O r( D6 ]) r' q& g
Series R-L-C. 2.000E+00 5.000E-07 0.000E+00 | XX0003XX0008 2. .0005 0 - r- }8 N8 w" e 4.000E+00 6.000E+01 3.000E+08 6.000E+01 1.667E-06|-1XX0007XX0009 4. 60. 3.E8 500. 1 0 0 : d/ _+ O: V3 N- s N3 | 4.000E+00 6.000E+01 3.000E+08 6.000E+01 1.667E-06|-1XX0006XX0004 4. 60. 3.E8 500. 1 0 0 # j3 V8 C5 s( }5 a 4.000E+00 6.000E+01 3.000E+08 6.000E+01 1.667E-06|-1XX0010XX0006 4. 60. 3.E8 500. 1 0 0 9 s3 r" Q3 k5 ISeries R-L-C. 0.000E+00 0.000E+00 2.500E-04 | XX0004 250. 0 " c$ w: h+ o* b" s( K. x, l. a" h+ _Series R-L-C. 0.000E+00 0.000E+00 2.000E-03 | XX0005 2.E3 0# {. W9 x- A& U& [# V
Series R-L-C. 0.000E+00 1.000E-01 0.000E+00 | XX0005XX0011 100. 0 D% C3 x9 Y! J5 o
Blank card ending branches. IBR, NTOT = 12 12 |BLANK BRANCH W9 I# @" Z( g. h4 K7 u! UComment card. KOMPAR > 0. |C < n 1>< n 2>< Tclose ><Top/Tde >< Ie ><Vf/CLOP >< type > " R% F) ~9 u/ YSwitch. 1.00E-04 1.00E+03 0.00E+00 0.00E+00 | XX0008XX0007 .0001 1.E3 03 E- z. b" `* k3 |- |. W
Blank card ending switches. KSWTCH = 1. |BLANK SWITCH, {/ E& U; t+ \+ z3 }
Comment card. KOMPAR > 0. |C < n 1><>< Ampl. >< Freq. ><Phase/T0>< A1 >< T1 >< TSTART >< TSTOP >& d8 K2 C. }' F9 H
Source. -2.20E+05 5.00E+01 0.00E+00 -1.00E+00 |14XX0002 0 -2.2E5 50. -1. 1. : C0 j: V- X) _; F @+ {3 @0 p# XSource. 2.20E+05 5.00E+01 0.00E+00 -1.00E+00 |14XX0011 0 2.2E5 50. -1. 1. 7 Q! |8 n! u) z0 e: i1 ZBlank card ends electric sources. KCONST = 2 |BLANK SOURCE0 y' e ]# W7 w; a
" K- B& u) ^+ T+ t# Z
List of input elements that are connected to each node. Only the physical connections of multi-phase lines are shown (capacitive 6 b% r; L0 K# o5 @4 D; Iand inductive coupling are ignored). Repeated entries indicate parallel connections. Switches are included, although sources 3 e F; ]. `+ B: J; @ P* q(including rotating machinery) are omitted -- except that U.M. usage produces extra, internally-defined nodes "UMXXXX"./ Z3 ?* S* Y1 o
--------------+------------------------------ ! n' `; B* z ?1 M$ r) fFrom bus name | Names of all adjacent busses. / G) `( @, x6 a0 z--------------+------------------------------0 D) W# k9 S: b5 C4 X9 c
XX0001 |TERRA *XX0003*XX0002*. @$ b! a7 \0 K5 t9 {
XX0003 |XX0001*XX0008* . D* r y2 I F+ | XX0002 |XX0001*" i: h' x' p3 T* e% T' Y
XX0004 |TERRA *XX0005*XX0006* 9 e3 I0 E6 n) X H XX0005 |TERRA *XX0004*XX0011*/ r) ~. F5 s. X2 d3 @
XX0006 |XX0004*XX0007*XX0010* 5 T% Q/ v! A+ u& k/ c3 w XX0007 |XX0006*XX0008*XX0009* ) o( q" a0 E( A XX0008 |XX0003*XX0007*/ ?1 i9 o5 ?- y" V/ ~
XX0009 |XX0007*& B: @6 K& v5 s2 R2 S. W; P l4 g
XX0010 |XX0006*1 Q, U9 T" h8 J/ p7 r% m3 X& z
XX0011 |XX0005*: Q; ]" S2 F! s
TERRA |XX0001*XX0004*XX0005* , z. h( ?3 e+ {; a3 g% n8 I. e--------------+------------------------------7 `. B9 I2 Q' Y* U
Pi-equivalent branches of distributed circuits are added to the table of List Size 3 between indices 7 and 12.7 q& u+ f5 a0 s/ R# q- W* G
t; ?& I4 j" @Sinusoidal steady-state phasor solution, branch by branch. All flows are away from a bus, and the real part, magnitude, or "P": A! e/ u6 a- U
is printed above the imaginary part, the angle, or "Q". The first solution frequency = 5.00000000E+01 Hertz.& _1 K4 K- s4 B7 S3 p
Bus K Phasor node voltage Phasor branch current Power flow Power loss ( B# O3 A E" M% O Bus M Rectangular Polar Rectangular Polar P and Q P and Q' i8 B5 y0 N0 r& V
; }7 w H# T n' I% T/ T XX0005 -11739.96572792 11739.969852465 -.3132466566685 7376.5122181602 -34457.13223354 -.643041176E-12& } D/ g+ z: K6 @+ k
-9.840933953513 -179.9519723 7376.5122115091 90.0024331 .433000018187E8 54716345.08468041 [( E) ~ v3 h, D( k6 S
0 H9 t* F2 ^5 t- S+ A* I XX0011 220000. 220000. .31324665666851 7376.5122181602 34457.1322335367 A2 z- d* s+ o* q
0.0 0.0 -7376.512211509 -89.9975669 .811416343266E9& B; N2 j! t* B, f, p: a. I
Total network loss P-loss by summing injections = 3.509876731190E+04 }$ c& v" L$ ^9 M" S- J. n ) e% L% m' k+ e- k) n; I
Output for steady-state phasor switch currents. 5 t" D8 t* n a: Y. ~; q Node-K Node-M I-real I-imag I-magn Degrees Power Reactive; B( D2 Q2 Z% I! o& x
XX0008 XX0007 Open Open Open Open Open Open% e2 \" W b% K; a
1 g* \- t" _* @6 qSolution at nodes with known voltage. Nodes that are shorted together by switches are shown as a group of names, with the printed 7 k# d8 ?8 h% c" Kresult applying to the composite group. The entry "MVA" is SQRT( P**2 + Q**2 ) in units of power, while "P.F." is the9 E U1 ?+ L1 \9 n! b
associated power factor.+ C$ O X; z" L) W( Q$ K
Node Source node voltage Injected source current Injected source power z# Q! B6 I, ~/ D. U1 v; H: t
name Rectangular Polar Rectangular Polar P and Q MVA and P.F.: O- ~9 w3 n: D c& n2 y
* q4 Y' Q0 }& j) j
XX0002 -220000. 220000. -.005833046167 11774.184683562 641.63507836944 .12951603152E10% L6 z# I" N/ m+ G" F7 O
0.0 180.0000000 11774.18468356 90.0000284 .12951603152E10 0.0000005; r2 F4 G' d" r" u! T$ M, C0 T
. {7 r/ U1 W1 s1 B
XX0011 220000. 220000. .31324665666851 7376.5122181602 34457.132233536 .811416343998E9 ( {( a: y2 |6 ^ 0.0 0.0 -7376.512211509 -89.9975669 .811416343266E9 0.00004253 g, K* ~& W) ^) K6 o5 v8 [
. j8 V; p$ L" v3 W) f+ \
' w- x. K* g$ X# c" C8 \------------------------------------------------------------------------------------------------------------------------------------ Z2 z9 Z7 V+ ?, `
ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/( t, d7 r' I/ p/ y0 X; e& Z
ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/5 J& `1 P- U. g* d& k: @$ [# n
------------------------------------------------------------------------------------------------------------------------------------" G' y8 C3 z$ ?; o
You lose, fella. The EMTP logic has detected an error condition, and is now going to terminate program execution. The following ) K* i4 B* J. j1 U5 x- Z( Cmessage summarizes the circumstances leading to this situation. Where an otherwise-unidentified data card is referred to, or where 1 M k; R3 I; @the "last" card is mentioned, it is the most recently read card of the input data that is meant. The 80-column image of this card ! D) v2 v% u- i- i3 v$ u" Qis generally the last one printed out prior to this termination message. But possibly this last-read card has not yet been+ i' U( r, \' M! U
displayed, so a copy follows: ! k- I! a; p' q& g X5 d( J " XX0001XX0003XX0008XX0007XX0006XX0009XX0005XX0004 "& B1 b9 H. A: x" e! M8 x0 L
KILL code number Overlay number Nearby statement number ; y2 q/ B. P7 G/ Q6 ^ 102 12 1536; B* u! T3 h0 R% s' x _
KILL = 102. The total resistance for one particular mode of a constant-parameter, distributed transmission line is too large.+ p- ~ [ g n8 T' z& [/ o
This is for linear branch number 2 (in order of data input) which connects bus "XX0001" with bus "XX0003". Resistance is to) h( Z" k2 H' Z$ ?# l" _1 Y1 F
be lumped, with half in the middle and a quarter at each end (variable IPUNCH of columns 53-54 is equal to -1). The total modal5 h& U' G2 h+ b' g
resistance of 2.00000000E+03 Ohms is unreasonably large when compared with the surge (characteristic) impedance of : i, [$ m2 y# G7 n" Z6.00000000E+01 Ohms. Program logic can not handle any resistance that exceeds four times the characteristic impedance. For 2 E- |2 w% j8 P6 D1 F! a) wnormal power lines, such values are absurd, anyway, so no sympathy is accorded. : n' G/ R$ F2 W9 q) c( K------------------------------------------------------------------------------------------------------------------------------------; w2 B0 W% ~" e: w @ C& V! H! T* B: h
ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ 6 f6 U" t7 a5 |- c1 f# r* qERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ERROR/ / [: s' F P" Y! T1 H/ H S9 N. L------------------------------------------------------------------------------------------------------------------------------------ . {4 x. U, i9 M0 b , u5 }& V- p+ o/ P6 n
Actual List Sizes for the preceding solution follow. 02-May-19 23:52:54" `; d" ~+ W4 J) f; }! D9 _
Size 1-10: 12 12 12 2 -9999 1 -9999 -9999 0 0* b) v/ I7 p3 X4 _; e n$ ~6 z9 {
Size 11-20: 0 -9999 -9999 -9999 -9999 0 0 0 23 0+ ^# C. r6 {) m' i; H8 n
Size 21-30: 1 -9999 14 -9999 -9999 1 -9999 -9999 -9999 0 7 S a& l) f, x- E" r) kSeconds for overlays 1-5 : 0.016 0.000 0.016 -- (CP: Wait; Real)7 k/ i5 M0 r1 c4 v& E+ \' ?5 n/ u/ h
Seconds for overlays 6-11 : 0.016 0.000 0.016 - G. D; _. ~% t6 V5 N' \$ PSeconds for overlays 12-15 : 0.000 0.000 0.000, \5 G& F2 e' p
Seconds for time-step loop : 0.000 0.000 0.000 ! R: j" X# \: a3 ^% GSeconds after DELTAT-loop : 0.000 0.000 0.000 g" y, W. M, c n, w' i
---------------------------; L1 ?: B7 r6 y$ Z7 m( O2 \
Totals : 0.031 0.000 0.031