BEGIN NEW DATA CASE C BENCHMARK DC-27 C Test of "CABLE CONSTANTS", 1st for an underground cable, then for an C overhead line. For the cable, two of the phases have both cores and C sheaths, whereas the 3rd has only the core. A homogeneous earth model is C assumed. Both modal and phase-domain output is illustrated. C DIAGNOSTIC 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 9 C 2 August 2002, add plot of cable cross-section on the screen: C $DEPOSIT, KROSEC=1, { Use SPY DEPOSIT to change this variable of STARTUP CABLE CONSTANTS 2 -1 3 0 1 1 1 2 2 1 25.4E-3 45.6E-3 50.8E-3 55.9E-3 6.8912E-8 1. 1. 3.52 6.8662E-7 1. 1. 3.3 25.4E-3 45.6E-3 50.8E-3 55.9E-3 6.8912E-8 1. 1. 3.52 6.8662E-7 1. 1. 3.3 25.4E-3 45.6E-3 6.8912E-8 1. 1. 3.52 0.75 0.0 0.75 0.3 0.75 0.15 20.0 1000.0 C Impedance matrix [ Z ] in [ohm/m] follows : C 1.0871342E-03 9.7123603E-04 9.7126618E-04 9.7295525E-04 9.7123603E-04 C 1.0433822E-02 7.2285319E-03 8.0995634E-03 9.5255505E-03 7.2285319E-03 C Admittance matrix [ Y ] in [mho/m] follows : C 0.0000000E+00 0.0000000E+00 0.0000000E+00 0.0000000E+00 0.0000000E+00 C 2.1027008E-06 0.0000000E+00 0.0000000E+00 -2.1027006E-06 0.0000000E+00 C Transpose of the current transformation matrix [Ti] follows. This is the inve C 0.0019301 0.0019301 0.0795508 0.4608603 0.4608604 C 94.5057220 94.5057220 1.0795423 -0.4399059 -0.4399060 C Voltage transformation matrix [Tv]. This gives the mapping from modal to phas C 0.9983159 0.9985634 0.1872344 1.0000001 0.9999997 C 1.3742625 11.7389965 -128.8459167 -0.0000002 0.0000385 C Characteristic impedance matrix [Zc] in phase variables, in [ohm]: C 46.5745659 11.1852903 15.2132778 24.9359932 11.2755394 C -4.8109016 -1.6719475 -2.0647478 -0.4119074 -1.1299886 C Modal Propagation Modal impedance Modal C Mode attenuation velocity real imaginary susceptance C [ db/km ] [ m/sec ] [ ohms / meter ] [mho/meter] C 1 2.81088E-01 1.34059E+07 1.188315E-03 8.349145E-03 2.617198E-05 C 2 1.38270E-01 3.78950E+07 2.186609E-04 1.137942E-03 2.394342E-05 C 3 3.73454E-02 8.94327E+07 3.196348E-04 2.227090E-03 2.201588E-06 C 4 1.05997E-01 1.34007E+08 3.100181E-04 4.750426E-04 4.128194E-06 C 5 1.10538E-01 1.35064E+08 3.239154E-04 4.686100E-04 4.072995E-06 BLANK card ending frequency cards C $DEPOSIT, KROSEC=0, { Use SPY DEPOSIT to cancel the change at start of subcase C Begin 2nd subcase, for overhead line. This is untransposed, with one C conductor per phase. This is a single 3-phase circuit with two ground C wires. The 3-layer ("Nakagawa") stratified earth model is assumed. 1 0 1 99 1 3 2 4 1 8.74E-3 1.974E-3 6.18E-3 0. 0.4 6.78E-3 3.78E-8 1. 5.36E-8 1. 25. 12.5 0. 25. 12.5 14. 25. 12.5 28. 35. 17.5 3. 35. 17.5 25. 200. 1.E+05 80000. .5 2.5 200. 1000. 1.0 1.0 1.0 10.0 10.0 10.0 C Resistance [ R ] in [ohm/m] and inductance [ L ] in [henry/m] follows : C 3.6631241E-02 3.3899128E-02 3.0530494E-02 C 1.0974409E-06 2.2856192E-07 1.1843866E-07 C Conductance [ G ] in [mho/m] and capacitance [ C ] in [farad/m] follows : C 0.0000000E+00 0.0000000E+00 0.0000000E+00 C 1.1469370E-11 -1.4910953E-12 -3.6612786E-13 C Transpose of the current transformation matrix [Ti] follows. This is the inve C 0.3508662 0.3422453 0.3508658 C 0.2195983 2.4146881 0.2195537 C Voltage transformation matrix [Tv]. This gives the mapping from modal to phas C 0.9379887 0.9999999 0.4877141 C -1.4748241 0.0000000 -177.8047791 C Characteristic impedance matrix [Zc] in phase variables, in [ohm]: C 312.2572632 53.8941574 24.6474152 C -7.9390864 -7.2640944 -6.5128512 C Modal Propagation Modal impedance Modal C Mode attenuation velocity real imaginary susceptance C [ db/km ] [ m/sec ] [ ohms / meter ] [mho/meter] C 1 1.10051E+00 2.69766E+08 2.544782E-02 3.395038E-01 1.597196E-05 C 2 9.21221E-02 2.93771E+08 3.050453E-03 3.075625E-01 1.487293E-05 C 3 1.39649E-02 2.99027E+08 9.903153E-03 3.568964E-01 1.236180E-05 BLANK card ending frequency cards BLANK card ending "CABLE CONSTANTS" data subcases BEGIN NEW DATA CASE C August, 1994. Prof. Akihiro Ametani has left after 3 weeks of work C at BPA to install his new CABLE PARAMETERS program. There are 18 C standard test cases for this, and these will be split between the C ends of DC-27 and DC-28. Begin with the 6 examples for overhead C lines: 11A, 11G0, 11G1, 11G3, 11Y2, and 11A' (with prime meaning C modification). Then will come 4 pipe-type cable examples. C 1st of 6 overhead line examples: CASE11A.DAT CABLE CONSTANTS CABLE PARAMETERS C KOLW27 KOLS27 E also? MATRIX PRECISION 10 1 { Optimally encode old F-field C 4 December 2003, optional local KOLWID and KOLSEP of optimal encoding C are read from columns 25-40. Variables are local to overlay 27, and are C carried in LABL27. The default values (for default use, see DC-28) are C KOLW27 = 10 and KOLS27 = 2 (column width of 10 including 2 blanks to C separate matrix columns). Here, using KOLS27 = 1 gives one more digit C of precision at the expense of blank column separation. Since matrices C are visually more appealing with 2 blank separator bytes, the default C values will be reset on the following subcase. C Ze C MATRIX OUTPUTS 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 C 22 December 2003, optional preceding definition of KZFL27(16) is added. C This integer vector controls which matrices are to be outputed (to either C LUNIT6 or separate disk files, or both), and what coordinates are to be C used (e.g., a COMPLEX matrix, a matrix of real parts, a matrix of C imaginary parts, a matrix of magnitudes, or a matrix of angles). C Index Cols. Symbol Labeling of matrix in the LUNIT6 file C ---------------------------------------------------------------------- C 1 17-20 P Complex potential coefficient C 2 21-24 Pt Transposed potential coefficient C 3 25-28 Ze Earth impedance ZE, in ohm/m C 4 29-32 Zc Conductor internal impedance ZC, in ohm/m C 5 33-36 Zs Space impedance ZS, in ohm/m C 6 37-40 Presently unused (reserved for later use) C 7 41-44 Zt Total impedance [Zc], in ohm/m C 8 45-48 Yt Total admittance [Yc], in mho/m C 9 49-52 Zph Characteristic impedance matrix [Zc] in phase variables, in [ohm] C 10 53-56 Ti The current transformation matrix [Ti] follows. ... C 11 57-60 Tv Voltage transformation matrix [Tv]. ... C ---------------------------------------------------------------------- C 12 61-64 Comp Complex matrix, with each cell a complex pair C 13 65-68 Real Only the real part of the complex matrix C 14 69-72 Imag Only the imaginary part of the complex matrix C 15 73-76 Mag Only the magnitudes of the complex elements C 16 77-80 Angle Only the angles in degrees of the complex elements 1 0 2 0 1 1 0 0 0 1 0 0 3 0 1 0 79.9916E-631.7050E-3 23.7025E-5 1.0 1 0 1 0 19.6350E-615.7080E-3 90.5019E-5 1.0 11.35 11.35 -0.65 11.35 11.35 0.00 11.35 11.35 0.65 12.35 12.35 0.00 50. 4.0E06 C Total impedance [Zc] C 3.81674E-01 3.64103E-01 3.63346E-01 3.49908E-01 C 4.26910E+01 1.82546E+01 1.47757E+01 1.54036E+01 C C Total admittance [Yc] C 0.00000E+00 0.00000E+00 0.00000E+00 0.00000E+00 C 2.18090E-04 -6.35291E-05 -3.38427E-05 -3.80217E-05 C C Characteristic impedance matrix [Zc] in phase variables, in [ohm]: C 506.78659 215.40545 173.91332 181.49599 C -2.25771 -2.15298 -2.14844 -2.06889 C C Modal transformation matrices follow. These are complex, with the real part displayed above the imaginary part. C Transpose of the current transformation matrix [Ti] follows. This is the inverse of the voltage transformation matrix. C By definition, [Ti] gives the mapping from modal to phase variables: i-phase = [Ti] * i-mode C 0.27659 -0.26181 -0.34850 -0.50000 C 0.00030 0.00062 -0.00015 0.00000 C C Voltage transformation matrix [Tv]. This gives the mapping from modal to phase variables: v-phase = [Tv] * v-mode C 1.00000 -0.29619 -0.41855 -1.00000 C 0.00038 0.00155 -0.00035 0.00000 C C MODE ATTENUATION VELOCITY IMPEDANCE (OHM/M) ADMITTANCE (S/M) C NO. (DB/KM) (M/MIC.S) REAL IMAG. REAL IMAG. C 1 5.74605E+00 297.25 3.68397E-01 2.35412E+01 0.00000E+00 3.03655E-04 C 2 3.60799E-01 299.64 2.43100E-02 2.45439E+01 0.00000E+00 2.86632E-04 C 3 2.70957E-01 299.68 1.29042E-02 1.73460E+01 0.00000E+00 4.05472E-04 C 4 2.39123E-01 299.69 9.16390E-03 1.39576E+01 0.00000E+00 5.03865E-04 BLANK card ending frequency cards within CABLE PARAMETERS C 27 December 2003, changes to MAIN27 made it possible to stack subcases C within CABLE PARAMETERS. To demonstrate this, the following exit and C re-entry (4 non-comment data cards) will be commented out. The answer C is unchanged. Although not recommended, such stacking does now work. C BLANK card ending CABLE CONSTANTS data subcases C BEGIN NEW DATA CASE C CABLE CONSTANTS C CABLE PARAMETERS C KOLW27 KOLS27 E also? MATRIX PRECISION 10 2 { Optimally encode old F-field C 4 December 2003, optional local KOLWID and KOLSEP of optimal encoding C are read from columns 25-40. Values 10 and 2 above serve to restore the C default values. These replace values 10 and 1 of the preceding subcase. 1 0 2 0 1 0 0 0 0 0 0 0 3 0 1 0 5.046E-3 0.0 1.896E-8 1.0 1 0 1 0 2.50E-3 0.0 1.777E-8 1.0 11.35 11.35 -0.65 11.35 11.35 0.00 11.35 11.35 0.65 12.35 12.35 0.00 50. 4.0E06 C MODE ATTENUATION VELOCITY IMPEDANCE (OHM/M) ADMITTANCE (S/M) C NO. (DB/KM) (M/MIC.S) REAL IMAG. REAL IMAG. C 1 5.74605E+00 297.25 3.68397E-01 2.35412E+01 0.00000E+00 3.03655E-04 C 2 3.60799E-01 299.64 2.43100E-02 2.45439E+01 0.00000E+00 2.86632E-04 C 3 2.70957E-01 299.68 1.29042E-02 1.73460E+01 0.00000E+00 4.05472E-04 C 4 2.39123E-01 299.69 9.16391E-03 1.39576E+01 0.00000E+00 5.03865E-04 BLANK card ending frequency cards within CABLE PARAMETERS BLANK card ending CABLE CONSTANTS data subcases BEGIN NEW DATA CASE C 3rd of 6 overhead line examples: CASE11G1.DAT CABLE CONSTANTS CABLE PARAMETERS 1 0 2 0 1 0 0 0 1 0 0 0 3 0 1 0 5.046E-3 0.0 1.896E-8 1.0 1 0 1 0 2.50E-3 0.0 1.777E-8 1.0 11.35 11.35 -0.65 11.35 11.35 0.00 11.35 11.35 0.65 12.35 12.35 0.00 50. 4.0E06 C MODE ATTENUATION VELOCITY IMPEDANCE (OHM/M) ADMITTANCE (S/M) C NO. (DB/KM) (M/MIC.S) REAL IMAG. REAL IMAG. C 1 3.17679E+00 298.37 1.79566E-01 2.06778E+01 0.00000E+00 3.43133E-04 C 2 2.70975E-01 299.68 1.30187E-02 1.74987E+01 0.00000E+00 4.01933E-04 C 3 2.39123E-01 299.69 9.16391E-03 1.39576E+01 0.00000E+00 5.03865E-04 BLANK card ending frequency cards within CABLE PARAMETERS BLANK card ending CABLE CONSTANTS data subcases BEGIN NEW DATA CASE C 4th of 6 overhead line examples: CASE11G3.DAT CABLE CONSTANTS CABLE PARAMETERS 1 0 2 0 1 0 0 0 3 0 0 0 3 0 1 0 5.046E-3 0.0 1.896E-8 1.0 1 0 1 0 2.50E-3 0.0 1.777E-8 1.0 11.35 11.35 -0.65 11.35 11.35 0.00 11.35 11.35 0.65 12.35 12.35 0.00 50. 4.0E06 C MODE ATTENUATION VELOCITY IMPEDANCE (OHM/M) ADMITTANCE (S/M) CHARACT. IMP. (OHM) CHARACT. ADMIT. (S) C NO. (DB/KM) (M/MIC.S) REAL IMAG. REAL IMAG. REAL IMAG. REAL IMAG. C 1 8.29798E-01 299.42 7.35361E-02 3.23051E+01 0.00000E+00 2.18090E-04 384.874 -0.438 2.59825E-03 2.95720E-06 BLANK card ending frequency cards within CABLE PARAMETERS BLANK card ending CABLE CONSTANTS data subcases BEGIN NEW DATA CASE C 5th of 6 overhead line examples: CASE11Y2.DAT CABLE CONSTANTS CABLE PARAMETERS 1 0 2 0 1 0 0 0 0 0 2 0 3 0 1 0 5.046E-3 0.0 1.896E-8 1.0 1.E-15 0.0 1.E-15 0.0 1.E-15 0.0 1 0 1 0 2.50E-3 0.0 1.777E-8 1.0 8.333E-4 0.0 11.35 11.35 -0.65 11.35 11.35 0.00 11.35 11.35 0.65 12.35 12.35 0.00 50. 4.0E06 C MODE ATTENUATION VELOCITY IMPEDANCE (OHM/M) ADMITTANCE (S/M) C NO. (DB/KM) (M/MIC.S) REAL IMAG. REAL IMAG. C 1 1.11101E+03 165.22 3.71110E-01 4.66305E+01 8.33317E-04 1.52015E-04 C 2 3.17749E+00 298.37 1.79366E-01 2.06500E+01 0.00000E+00 3.43588E-04 C 3 2.70975E-01 299.68 1.30187E-02 1.74987E+01 0.00000E+00 4.01933E-04 C 4 2.39123E-01 299.69 9.16391E-03 1.39576E+01 0.00000E+00 5.03865E-04 BLANK card ending frequency cards within CABLE PARAMETERS BLANK card ending CABLE CONSTANTS data subcases BEGIN NEW DATA CASE C 6th of 6 overhead line examples: CASE11A'.DAT CABLE CONSTANTS CABLE PARAMETERS 1 0 1 0 1 0 0 0 0 1 0 0 3 1 1 1 79.9916E-631.7050E-30.0000E+0019.6350E-615.7080E-3 0.0 23.7025E-5 1.090.5019E-5 1. 11.35 11.35 -0.65 11.35 11.35 0.00 11.35 11.35 0.65 12.35 12.35 0.00 50. 4.0E06 C MODE ATTENUATION VELOCITY IMPEDANCE (OHM/M) ADMITTANCE (S/M) C NO. (DB/KM) (M/MIC.S) REAL IMAG. REAL IMAG. C 1 3.17679E+00 298.37 1.79566E-01 2.06778E+01 0.00000E+00 3.43134E-04 C 2 2.70975E-01 299.68 1.30186E-02 1.74987E+01 0.00000E+00 4.01933E-04 C 3 2.39123E-01 299.69 9.16390E-03 1.39576E+01 0.00000E+00 5.03865E-04 BLANK card ending frequency cards within CABLE PARAMETERS BLANK card ending CABLE CONSTANTS data subcases BEGIN NEW DATA CASE C 1st of 4 pipe-type cable examples: CASE3G0.DAT C Results of this case changed on March 2, 2001 after implementing the C correction that Prof. Ametani made on February 17, 2001. C This correction only affects cables having 3 layers of conductors: core, C sheath and armor. CABLE CONSTANTS CABLE PARAMETERS C Beginning 28 September 2002, users are allowed to monitor convergence of C Prof. Ametani's eigenvalue calculation. For high order, this will be seen C automatically. This is important because computation may be slow. But how C large is large? MONMIN is the variable, and the user has control via a C new optional declaration that must (if present) precede miscellaneous data. C In the following, MAXITR = maximum number of iterations for an eigenvalue; C MONMIN = minimum order for the new eigenvalue printout; C ITROUT = frequency of printout within eigenval iteration; C EPSLNA = convergence tolerance for eigenvalue iteration. C This data subcase is of order 10, so is big enough for meaningful printout. C Default values are: 100 50 1 1.E-8 C MAXITR MONMIN ITROUT EPSLNA EIGEN CONTROLS 85 5 1 1.E-8 C 3 -1 3 0 0 0 0 1 0 0 0 0 3 -1 3 0 1 0 0 1 0 0 0 0 1.850 1.860 1.870 1.00E-7 1.0 1. 1. 1.17183738-29.9354891.18391480-38.1912031.32171262-33.629952 3 3 3 11.0E-3 30.60E-3 63.80E-3 65.80E-3 71.00E-3 71.80E-3 76.80E-3 1.8365E-8 1.0 1.0 2.3 1.8365E-8 1.0 1.0 1. 10.00E-8 1.0 1.0 8.0 11.0E-3 30.60E-3 63.80E-3 65.80E-3 71.00E-3 71.80E-3 76.80E-3 1.8365E-8 1.0 1.0 2.3 1.8365E-8 1.0 1.0 1. 10.00E-8 1.0 1.0 8.0 11.0E-3 30.60E-3 63.80E-3 65.80E-3 71.00E-3 71.80E-3 76.80E-3 1.8365E-8 1.0 1.0 2.3 1.8365E-8 1.0 1.0 1. 10.00E-8 1.0 1.0 8.0 20.0 0.0 33. 500.0E03 BLANK card ending frequency cards within CABLE PARAMETERS BLANK card ending CABLE CONSTANTS data subcases BEGIN NEW DATA CASE C 2nd of 4 pipe-type cable examples: CASE3G1.DAT C Results of this case changed on March 2, 2001 after implementing the C correction that Prof. Ametani made on February 17, 2001. C This correction only affects cables having 3 layers of conductors: core, C sheath and armor. CABLE CONSTANTS CABLE PARAMETERS C MAXITR MONMIN ITROUT EPSLNA EIGEN CONTROLS -85 -5 -1 -1.E-8 C Default values are: 100 50 1 1.E-8 C 17 January 2004, the preceding is added to illustrate rejection of any bad C value. Here, a minus sign has been added to each parameter. Each will be C rejected, and this means no change. So, MAXITR will remain at value 85, C MONMIN will remain at value 5 (compare with default values of 100 and 50, C respectively). C 3 -1 3 0 0 0 0 1 1 0 0 0 3 -1 3 0 1 0 0 1 1 0 0 0 1.850 1.860 1.870 1.00E-7 1.0 1. 1. 1.17183738-29.9354891.18391480-38.1912031.32171262-33.629952 3 3 3 11.0E-3 30.60E-3 63.80E-3 65.80E-3 71.00E-3 71.80E-3 76.80E-3 1.8365E-8 1.0 1.0 2.3 1.8365E-8 1.0 1.0 1. 10.00E-8 1.0 1.0 8.0 11.0E-3 30.60E-3 63.80E-3 65.80E-3 71.00E-3 71.80E-3 76.80E-3 1.8365E-8 1.0 1.0 2.3 1.8365E-8 1.0 1.0 1. 10.00E-8 1.0 1.0 8.0 11.0E-3 30.60E-3 63.80E-3 65.80E-3 71.00E-3 71.80E-3 76.80E-3 1.8365E-8 1.0 1.0 2.3 1.8365E-8 1.0 1.0 1. 10.00E-8 1.0 1.0 8.0 20.0 0.0 33. 500.0E03 BLANK card ending frequency cards within CABLE PARAMETERS BLANK card ending CABLE CONSTANTS data subcases BEGIN NEW DATA CASE C 3rd of 4 pipe-type cable examples: CASE3G4.DAT CABLE CONSTANTS CABLE PARAMETERS C KOLW27 KOLS27 E also? MATRIX PRECISION 10 2 BOTH { Optimally encode both E & F C About preceding 2 lines, which were added 6 December 2003: KOLW27 and KOLS27 C are unchanged. But added BOTH in 45-48 is the request to have the real part C optimally encoded rather than ordinary E-field encoded. I.e., treat the real C part the same as the imaginary part of the matrix for printed output. C 3 -1 3 0 0 0 0 1 4 0 0 0 3 -1 3 0 1 1 0 1 4 0 0 0 1.850 1.860 1.870 1.00E-7 1.0 1. 1. 1.17183738-29.9354891.18391480-38.1912031.32171262-33.629952 3 3 3 11.0E-3 30.60E-3 63.80E-3 65.80E-3 71.00E-3 71.80E-3 76.80E-3 1.8365E-8 1.0 1.0 2.3 1.8365E-8 1.0 1.0 1. 10.00E-8 1.0 1.0 8.0 11.0E-3 30.60E-3 63.80E-3 65.80E-3 71.00E-3 71.80E-3 76.80E-3 1.8365E-8 1.0 1.0 2.3 1.8365E-8 1.0 1.0 1. 10.00E-8 1.0 1.0 8.0 11.0E-3 30.60E-3 63.80E-3 65.80E-3 71.00E-3 71.80E-3 76.80E-3 1.8365E-8 1.0 1.0 2.3 1.8365E-8 1.0 1.0 1. 10.00E-8 1.0 1.0 8.0 20.0 0.0 33. 500.0E03 C Characteristic impedance matrix [Zc] in phase variables, in [ohm]: C 33.72483 0.00000 0.00000 4.62992 0.00000 0.00000 C -0.11456 -0.00001 -0.00001 -0.06850 -0.00001 -0.00001 C C MODE ATTENUATION VELOCITY IMPEDANCE (OHM/M) ADMITTANCE (S/M) C NO. (DB/KM) (M/MIC.S) REAL IMAG. REAL IMAG. C 1 2.18897E-01 197.36 1.46645E-03 4.63124E-01 0.00000E+00 5.47097E-04 C 2 2.18897E-01 197.36 1.46645E-03 4.63124E-01 0.00000E+00 5.47097E-04 C 3 2.18897E-01 197.36 1.46645E-03 4.63124E-01 0.00000E+00 5.47097E-04 C 4 1.36719E+00 295.29 1.45751E-03 4.92463E-02 0.00000E+00 2.29785E-03 C 5 1.36719E+00 295.29 1.45751E-03 4.92463E-02 0.00000E+00 2.29785E-03 C 6 1.36719E+00 295.29 1.45751E-03 4.92463E-02 0.00000E+00 2.29785E-03 BLANK card ending frequency cards within CABLE PARAMETERS BLANK card ending CABLE CONSTANTS data subcases BEGIN NEW DATA CASE C 4th of 4 pipe-type cable examples: CASE3NP0.DAT C Results of this case changed on March 2, 2001 after implementing the C correction that Prof. Ametani made on February 17, 2001. C This correction only affects cables having 3 layers of conductors: core, C sheath and armor. CABLE CONSTANTS CABLE PARAMETERS C KOLW27 KOLS27 E also? MATRIX PRECISION 8 1 BOTH { Optimally encode both E & F C About preceding 2 lines, which were added 8 December 2003. This is the same C as the preceding subcase, but with the width minimized as an illustration. C There is no need; this is just an illustration. C 3 0 3 0 0 0 0 0 0 0 0 0 3 0 3 0 1 0 0 0 0 0 0 0 1.850 1.00E-7 1.0 1. 1. 1.17183738-29.9354891.18391480-38.1912031.32171262-33.629952 3 3 3 11.0E-3 30.60E-3 63.80E-3 65.80E-3 71.00E-3 71.80E-3 76.80E-3 1.8365E-8 1.0 1.0 2.3 1.8365E-8 1.0 1.0 1. 10.00E-8 1.0 1.0 8.0 11.0E-3 30.60E-3 63.80E-3 65.80E-3 71.00E-3 71.80E-3 76.80E-3 1.8365E-8 1.0 1.0 2.3 1.8365E-8 1.0 1.0 1. 10.00E-8 1.0 1.0 8.0 11.0E-3 30.60E-3 63.80E-3 65.80E-3 71.00E-3 71.80E-3 76.80E-3 1.8365E-8 1.0 1.0 2.3 1.8365E-8 1.0 1.0 1. 10.00E-8 1.0 1.0 8.0 33. 500.0E03 BLANK card ending frequency cards within CABLE PARAMETERS BLANK card ending CABLE CONSTANTS data subcases BEGIN NEW DATA CASE C Use preceding data of the 1st of 6 overhead line examples ( CASE11A.DAT ) C to illustrate fitting associated with new frequency-dependence of Taku Noda C 1st of 2 NODA SETUP examples that are being added 6 October 1994 C NODA SETUP, 1, { Request Taku Noda's ARMA model fitter. 1 ==> F-scan printout NODA SETUP { Request Taku Noda's ARMA model fitter. No printout of F-scan { Output file name (blank requests use of default TAKUNODA.CCC) 2nd of 2 such lines (any number are allowed). NODA SETUP END { Bound of fitter data; begin CABLE PARAMETERS data CABLE CONSTANTS CABLE PARAMETERS C KOLW27 KOLS27 E also? MATRIX PRECISION 10 2 BOTH { Optimally encode both E & F C The preceding 2 lines were added 8 December 2003. They cancel the narrow C columns of the preceding subcase. This is a return to default values. 1 0 2 0 1 0 0 0 0 1 0 0 3 0 1 0 79.9916E-631.7050E-3 23.7025E-5 1.0 1 0 1 0 19.6350E-615.7080E-3 90.5019E-5 1.0 11.35 11.35 -0.65 11.35 11.35 0.00 11.35 11.35 0.65 12.35 12.35 0.00 50. 10. 5 10 600. 50. 1.E8 600. BLANK card ending frequency cards within CABLE PARAMETERS BLANK card ending CABLE CONSTANTS data subcases BEGIN NEW DATA CASE C 2nd of 2 NODA SETUP examples that are being added 6 October 1994 C The preceding was for an overhead line. This is for a single-phase C cable (core and sheath). Cable data came from CESI (see DCNEW-6). NODA SETUP { Request Taku Noda's fitter, for which data follows { Output file name (blank requests use of default TAKUNODA.CCC) 2nd of 2 NODA SETUP END { Bound of fitter data; begin CABLE PARAMETERS data CABLE CONSTANTS CABLE PARAMETERS { Transfer to new (August, 1994) cable constants code C MISCELLANEOUS DATA CARD 2 -1 1 0 1 0 0 0 C CARDS INDICATING NUMBER OF CONDUCTORS PER SC COAXIAL CABLE 2 C GEOMETRICAL AND PHYSICAL DATA CARDS .0206 .02865 .06395 .0689 .0775 1.775E-8 1. 1. 3.5 9.1E-8 1. 1. 2.25 C CROSS-SECTION LOCATION CARD 1.05 0. C EARTH RESISTIVITY AND FREQUENCY CARDS 300. 10. 5 10 600. 300. 1.E8 600. BLANK card ending frequency cards of imbedded "LINE PARAMETERS" data case BLANK card ending "CABLE PARAMETERS" data cases BLANK card ending "CABLE CONSTANTS" data cases BEGIN NEW DATA CASE C Final subcase is same as 1st subcase of CABLE PARAMETERS except that C it illustrates omission of preceding CABLE CONSTANTS and following C blank to terminate that otherwise-unused routine. See October, 1997, C newsletter story explaining this improvement. WSM, 13 August 1997 CABLE PARAMETERS { Note there is no preceding CABLE CONSTANTS request 1 0 2 0 1 0 0 0 0 1 0 0 3 0 1 0 79.9916E-631.7050E-3 23.7025E-5 1.0 1 0 1 0 19.6350E-615.7080E-3 90.5019E-5 1.0 11.35 11.35 -0.65 11.35 11.35 0.00 11.35 11.35 0.65 12.35 12.35 0.00 50. 4.0E06 BLANK card ending frequency cards within CABLE PARAMETERS BLANK card ending "CABLE PARAMETERS" data cases BEGIN NEW DATA CASE C This is an example of a system which is a combination of an C overhead line and an underground line. C In October, 1998, Prof. Aki Ametani provided this data case as an C illustration for the calculation of the mutual earth-return C impedance of a system which is a combination of overhead and C underground conductors (lines or cables). A paper, co-authored C by Prof. Ametani, S. Yamaguchi, and N. Nagaoka, titled "Mutual C Impedance between Overhead and Underground Cables" is to be C presented at the 1998 EEUG meeting on November 9-10 C CABLE CONSTANTS CABLE PARAMETERS 1 0 1 0 1 0 0 0 0 0 0 0 C ITY ISYS NPC IEAR KMOD 2 0 1 0 C NP NG KBP KBG .4300E-01 0.00 0.0 0.0 0.0 0.0 C ROUTp RINp ROUTg RINg SEPp SEPg .1690E-07 1.0 C RHOp MUp RHOg MUg 1.00 1.00 0.00 -0.1 -0.1 0.0 C VTOWER1 VMID1 HORIZ1 VTOWER2 VMID2 HORIZ2 100. 10.000 8 1 C RHO FREQ IDEC IPNT BLANK card ending frequency cards within CABLE PARAMETERS BLANK card ending "CABLE PARAMETERS" data cases BLANK card ending "CABLE CONSTANTS" data cases BEGIN NEW DATA CASE BLANK