1923 lines
46 KiB
Plaintext
1923 lines
46 KiB
Plaintext
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# Copyright: Public domain.
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# Filename: CONIC_SUBROUTINES.agc
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# Purpose: Part of the source code for Colossus 2A, AKA Comanche 055.
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# It is part of the source code for the Command Module's (CM)
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# Apollo Guidance Computer (AGC), for Apollo 11.
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# Assembler: yaYUL
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# Contact: Ron Burkey <info@sandroid.org>.
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# Website: www.ibiblio.org/apollo.
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# Pages: 1262-1308
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# Mod history: 2009-05-08 RSB Adapted from the Colossus249/ file of the
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# same name, using Comanche055 page images.
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# 2009-05-20 RSB Corrected: Fixed four interpreter
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# instructions.
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#
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# This source code has been transcribed or otherwise adapted from digitized
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# images of a hardcopy from the MIT Museum. The digitization was performed
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# by Paul Fjeld, and arranged for by Deborah Douglas of the Museum. Many
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# thanks to both. The images (with suitable reduction in storage size and
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# consequent reduction in image quality as well) are available online at
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# www.ibiblio.org/apollo. If for some reason you find that the images are
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# illegible, contact me at info@sandroid.org about getting access to the
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# (much) higher-quality images which Paul actually created.
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#
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# Notations on the hardcopy document read, in part:
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#
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# Assemble revision 055 of AGC program Comanche by NASA
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# 2021113-051. 10:28 APR. 1, 1969
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#
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# This AGC program shall also be referred to as
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# Colossus 2A
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# Page 1262
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# PROGRAM DESCRIPTION -- ENTIRE CONIC SUBROUTINE LOG SECTION DATE -- 1 SEPTEMBER 1967
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# MOD NO. -- 0 LOG SECTION -- CONIC SUBROUTINES
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# MOD BY KRAUSE ASSEMBLY -- COLOSSUS REVISION 88
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#
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# FUNCTIONAL DESCRIPTION --
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# THE FOLLOWING SET OF SUBROUTINES SOLVE VARIOUS PROBLEMS INVOLVING THE TRAJECTORY PRODUCED BY A CENTRAL
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# INVERSE-SQUARE FORCE ACTING ON A POINT MASS, AS OUTLINED IN THE CMC AND LGC LUNAR LANDING MISSION GSOP, SECTION
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# 5.5.1.2. A GENERAL USAGE POINT-OF-VIEW WAS TAKEN IN FORMULATING, MECHANIZING, AND SCALING THE SUBROUTINES,
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# RATHER THAN OPTIMIZING EACH FOR A PARTICULAR USE. THEREFORE, MULTIPLE USAGE CAN BE MADE OF THE SUBROUTINES
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# INVOLVING ANY REALISTIC SET OF CONSTRAINTS. IT SHOULD BE NOTED THAT ONLY ONE SET OF CODING IS USED, WHETHER THE
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# EARTH, MOON, OR ANY OTHER CELESTIAL BODY IS SPECIFIED AS THE CENTRAL BODY OF THE PROBLEM, PROVIDED ONE OBSERVES
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# THE INHERENT SCALE CHANGE REQUIRED IN POSITION, VELOCITY, MU, AND TIME, AS OUTLINES IN MISSION PROGRAMMING
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# DEFINITION MEMO NO. 10. THIS CAN BE ACCOMPLISHED BY SIMPLY ADDING TO THE MUTABLE AND INITIALIZING THE SUBROUTINES
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# APPROPRIATELY.
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#
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# DUE TO THE UNIFORMITY OF THE EQUATIONS INVOLVED, CODING WAS MINIMIZED BY TREATING INDIVIDUAL EQUATIONS AND
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# BLOCKS OF EQUATIONS AS SUBROUTINES OF LOWER RANK WHENEVER POSSIBLE. AS A RESULT, THREE BY-PRODUCTS SUBROUTINES,
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# DIRECTLY USABLE AS INDEPENDENT SUBROUTINES, WERE GENERATED.
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#
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# RESTRICTIONS --
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# THE ONLY LIMITATION IN THE SCOPE OF THE PROBLEM WHICH CAN BE SOLVED BY A PARTICULAR SUBROUTINE IS THE SCALING
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# LIMIT OF EACH PARAMETER AS SPECIFIED IN THE GSOP. THESE SCALING LIMITS WERE CHOSEN SO THAT ALL FEASIBLE TRAJECTORIES
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# COULD BE HANDLED.
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#
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# SINCE THE SUBROUTINES (EXCEPT KEPLER) USE COMMON SUBROUTINES OF LOWER RANK WHICH USE ERASABLE OTHER THAN
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# THE PUSHLIST (DUE TO ITS LIMITED SIZE) AND COMMON INTERPRETIVE SWITCHES, THE CONIC SUBROUTINES CANNOT BE ALLOWED
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# TO INTERRUPT EACH OTHER. IT IS UP TO THE USER TO GUARANTEE THIS CONDITION.
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# Page 1263
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# PROGRAM DESCRIPTION -- KEPLER SUBROUTINE DATE -- 11 OCTOBER 1967
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# MOD NO. -- 1 LOG SECTION -- CONIC SUBROUTINES
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# MOD BY KRAUSE ASSEMBLY -- COLOSSUS 103 AND SUNDANCE 222
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# MOD NO. -- 2 (AUGUST 1968) BY ROBERTSON: TO PERMIT BACKDATING BY MORE THAN ONE ORBITAL PERIOD.
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# MOD NO. -- 3 (DEC 1968) BY ROBERTSON: SUPPRESSION OF X-MODULO-ING
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# MOD NO. -- 4 (JAN 1969) BY ROBERTSON: CLEAR OVFIND AT KEPLER ENTRY
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#
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# FUNCTIONAL DESCRIPTION --
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# THIS SUBROUTINE, GIVEN AN INITIAL STATE VECTOR AND THE DESIRED TRANSFER TIME THROUGH WHICH THE STATE IS TO
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# BE UPDATED ALONG A CONIC TRAJECTORY, COMPUTES THE NEW, UPDATED STATE VECTOR. THE TRAJECTORY MAY BE ANY CONIC
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# SECTION -- CIRCULAR, ELLIPTIC, PARABOLIC, HYPERPOLIC, OR RECTILINEAR WITH RESPECT TO THE EARTH OR THE MOON. THE
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# USE OF THE SUBROUTINE CAN BE EXTENDED USING OTHER PRIMARY BODIES BY SIMPLE ADDITIONS TO THE MUTABLE WITHOUT
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# INTRODUCING ANY CODING CHANGES, ACCEPTING THE INHERENT SCALE FACTOR CHANGES IN POSITION AND VELOCITY. AN ITERATION
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# TECHNIQUE IS UTILIZED IN THE COMPUTATION.
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#
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# IF A NEGATIVE TIME-OF-FLIGHT IS INPUT, THE PROGRAM WILL SOLVE FOR THE STATE WHICH WOULD BE PRODUCED BY
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# EXTRAPOLATING THE POSITION BACKWARD IN TIME.
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#
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# IF THE ABSOLUTE VALUE DESIRED TRANSFER TIME EXCEEDS THE ORBITAL PERIOD, THE SUBROUTINE, THROUGH A
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# MODULAR TECHNIQUE, WILL COMPUTE THE STATE CORRESPONDING TO THE DESIRED TIME AS USUAL.
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#
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# THE RESTRICTIONS ARE --
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# 1. (PREVIOUS RESTRICTION ON THE NEGATIVE DESIRED TRANSFER TIME IS NOW DELETED.)
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# 2. THE PARAMETERS IN THE PROBLEM CANNOT EXCEED THEIR SCALING LIMITS AS SPECIFIED IN THE GSOP. IF
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# ANY OF THESE LIMITS ARE EXCEEDED, THE RESULTING SOLUTION WILL BE MEANINGLESS.
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#
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# THE NUMBER OF ITERATIONS AND, THEREFORE, THE COMPUTATION SPEED IS DEPENDENT ON THE ACCURACY OF THE
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# GUESS, XKFPNEW. THE AGC COMPUTATION TIME IS APPROXIMATELY .061 SECONDS FOR INITIALIZATION, .065 SECONDS FOR THE
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# FINAL COMPUTATIONS, PLUS .083 SECONDS FOR EACH ITERATION.
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#
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# REFERENCES --
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# R-479, MISSION PROGRAMMING DEFINITION MEMO NO. 10, LUNAR LANDING MISSION GSOP, SECTION 5.5, SGA
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# MEMO 67-4.
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#
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# INPUT -- ERASABLE INITIALIZATION REQUIRED
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# SCALE FACTOR
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# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
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# -------- -------------- -----------------------
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# RRECT +29 FOR EARTH DP INITIAL POSITION VECTOR IN METERS
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# +27 FOR MOON
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# Page 1264
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# VRECT +7 FOR EARTH DP INITIAL VELOCITY VECTOR IN METERS/CENTISECOND
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# +5 FOR MOON
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# X1 (38D) NONE INDEX REGISTER SET TO -2D OR -10D ACCORDING TO WHETHER THE EARTH OR MOON,
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# RESPECTIVELY, IS THE CENTRAL BODY
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# TAU +28 DESIRED TRANSFER TIME IN CENTISECONDS (DP)
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# MAY BE POS OR NEG AND ABSOLUTE VALUE MAY BE GREATER OR LESS THAN ONE ORBITAL PERIOD.
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# XKEPNEW +17 FOR EARTH DP GUESS OF ROOT X OF KEPLERS EQN IN SQRT(METERS).SIGN SHOULD AGREE WTIH THAT OF TAU.
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# +16 FOR MOON AND ABS VALUE SHOULD BE LESS THAN THAT CORRESPONDING TO A PERIOD, VIZ, 2PI SQRT(SEMI-
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# MAJOR AXIS), FOR SPEED OF CONVERGENCE, BUT IF EITHER CONDITION FAILS, XKEPNEW IS RESET
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# BY KEPLER TO A POOR BUT VALID GUESS.
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# TC +28 DP PREV. VALUE OF TIME IN CENTISECS. MUST BE LESS THAN ONE ORBITAL PERIOD.
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# XPREV +17 FOR EARTH PRVIOUS VALUE OF X IN SQRT(METERS). MUST BE LESS THAN AN X CORRESPONDING TO ONE
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# +16 FOR MOON ORBITAL PERIOD, VIZ, 2PI SQRT(SEMI-MAJOR AXIS)
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#
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# SUBROUTINES CALLED --
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# DELTIME
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#
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# CALLING SEQUENCE AND NORMAL EXIT MODES --
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# KEPRTN-2 GOTO # MUST BE IN INTERPRETIVE MODE BUT OVFIND ARBITRARY.
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# KEPRTN-1 KEPLER # RETURNS WITH XPREV IN MPAC. PL IS AT 0.
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# KEPRTN ... # CONTINUE
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#
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# KEPLER MUST NOT BE CALLED DIRECTLY SINCE AN INTERRUPTION OF IT WOULD DESTROY THE ERASABLES IT NEEDS TO COMPLETE
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# THE INTERRUPTED JOB. THEREFORE THE USER MUST CALL CSMCONIC OR LEMCONIC WHICH GUARANTEES NO INTERRUPTS AND WHICH
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# ALSO CALLS KEPPREP TO COMPUTE A GUESS OF XKEPNEW.
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#
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# ABORT EXIT MODE --
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# NONE
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#
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# OUTPUT --
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# SCALE FACTOR
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# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
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# -------- -------------- -----------------------
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# RCV +29 FOR EARTH DP TERMINAL POSITION VECTOR IN METERS
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# +27 FOR MOON
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# VCV +7 FOR EARTH DP TERMINAL VELOCITY VECTOR IN METERS/CENTISEC
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# +5 FOR MOON
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# TC +28 DP TRANSFER TIME IN CENTISECS TO WHICH KEPLER CONVERGED. ALWAYS LESS THAN ONE PERIOD.
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# XPREV +17 FOR EARTH DP VALUE OF X IN SQRT(METERS) TO WHICH KEPLER CONVERGED. ALWAYS LESS THAN THE X
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# +16 FOR MOON CORRESPONDING TO ONE PERIOD.
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# Page 1265
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# FOR OTHER OUTPUT WHICH MAY BE OF USE, SEE DEBRIS.
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#
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# DEBRIS --
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# PARAMETERS WHICH MAY BE OF USE --
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# SCALE FACTOR
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# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
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# -------- -------------- -----------------------
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# URRECT +1 DP UNIT VECTOR OF INITIAL POSITION
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# R1 +29 FOR EARTH DP MAGNITUDE OF INITIAL POSITION IN METERS
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# +27 FOR MOON
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# ALPHA -22 FOR EARTH DP INVERSE OF SEMI-MAJOR AXIS IN 1/METERS
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# -20 FOR MOON
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# TMODULO +28 DP INTEGRAL NUMBER OF PERIODS IN CENTISECS, WHICH WAS SUBTRACTED FROM TAU. TO PRODUCE A
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# TAU. OF LESS THAN ONE PERIOD.
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#
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# PARAMETERS OF NO USE --
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# DP PARAMETERS -- FPSILENT, DELX, DELT, RCNORM, XMODULO, PLUS PUSHLIST REGISTERS 0 THROUGH 39D.
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# Page 1266
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# PROGRAM DESCRIPTION -- LAMBERT SUBROUTINE DATE -- 1 SEPTEMBER 1967
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# MOD NO. -- 0 LOG SECTION -- CONIC SUBROUTINES
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# MOD BY KRAUSE ASSEMBLY -- COLOSSUS REVISION 88
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#
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# FUNCTIONAL DESCRIPTION --
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# THIS SUBROUTINE CALCULATES THE INITIAL VELOCITY REQUIRED TO TRANSFER A POINT-MASS ALONG A CONIC TRAJECTORY
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# FROM AN INITIAL POSITION TO A TERMINAL POSITION IN A PRESCRIBED TIME INTERVAL. THE RESULTING TRAJECTORY MAY BE
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# A SECTION OF A CIRCLE, ELLIPSE, PARABOLA, OR HYPERBOLA WITH RESPECT TO THE EARTH OR THE MOON. THE USE OF THE
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# SUBROUTINE CAN BE EXTENDED USING OTHER PRIMARY BODIES BY SIMPLE ADDITIONS TO THE MUTABLE WITHOUT INTRODUCING ANY
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# CODING CHANGES, ACCEPTING THE INHERENT SCALE FACTOR CHANGES IN POSITION AND VELOCITY. AN ITERATION TECHNIQUE IS
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# UTILIZED IN THE COMPUTATION.
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#
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# THE RESTRICTIONS ARE: --
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# 1. RECTILINEAR TRAJECTORIES CANNOT BE COMPUTED.
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# 2. AN ACCURACY DEGRADATION OCCURS AS THE COSINE OF THE TRUE ANOMALY DIFFERENCE APPROACHES +1.0.
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# 3. THE ANGLE BETWEEN ANY POSITION VECTOR AND ITS VELOCITY VECTOR MUST BE GREATER THAN 1 DEGREE 47.5 MINUTES
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# AND LESS THAN 178 DEGREES 12.5 MINUTES.
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# 4. NEGATIVE TRANSFER TIME IS AMBIGUOUS AND WILL RESULT IN NO SOLUTION.
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# 5. THE PARAMETERS IN THE PROBLEM MUST NOT EXCEED THEIR SCALING LIMITS SPECIFIED IN THE GSOP. IF THE
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# LIMITS ARE EXCEEDED, THE RESULTING SOLUTION WILL BE MEANINGLESS.
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#
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# THE NUMBER OF ITERATIONS AND, THEREFORE, THE COMPUTATION'S SPEED IS DEPENDENT ON THE ACCURACY OF THE FIRST
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# GUESS OF THE INDEPENDENT VARIABLE, COGA. THE AGC COMPUTATION TIME IS APPROXIMATELY
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# .105 SECONDS FOR INITIALIZATION, .069 SECONDS FOR FINAL COMPUTATIONS, PLUS .205 SECONDS FOR EACH ITERATION.
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#
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# REFERENCES --
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# R-479, MISSION PROGRAMMING DEFINITION MEMO NO. 10, LUNAR LANDING MISSION GSOP -- SECTION 5.5, SGA MEMO 67-8,
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# SGA MEMO 67-4.
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#
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# INPUT -- ERASABLE INITIALIZATION REQUIRED
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# SCALE FACTOR
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# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
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# -------- -------------- -----------------------
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# R1VEC +29 FOR EARTH DP INITIAL POSITION VECTOR IN METERS
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# +27 FOR MOON
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# R2VEC +29 FOR EARTH DP TARGET OR TERMINAL POSITION VECTOR IN METERS
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# +27 FOR MOON
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# TDESIRED +28 DP DESIRED TRANSFER TIME IN CENTISECONDS
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# X1 (38D) NONE INDEX REGISTER SET TO -2D OR -10D ACCORDING TO WHETHER THE EARTH OR MOON,
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# RESPECTIVELY, IS THE CENTRAL BODY
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# GEOMSGN NONE SP +.5 IF DESIRED TRANSFER ANGLE IS LESS THAN 180 DEGREES, -.5 IF GREATER THAN 180 DEG.
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# GUESSW NONE AN INTERPRETER SWITCH TO BE SET IF NO GUESS OF COGA IS AVAILABLE, CLEAR IF A GUESS OF
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# Page 1267
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# COGA IS TO BE USED BY LAMBERT
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# COGA +5 DP GUESS OF COTANGENT OF FLIGHT PATH ANGLE (MEASURED FROM VERTICAL). THIS WILL BE
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# IGNORED IF GUESSW IS SET.
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# NORMSW NONE AN INTERPRETER SWITCH TO BE SET IF UN IS TO BE AN INPUT TO THE SUBROUTINE, CLEAR IF
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# LAMBERT IS TO COMPUTE ITS OWN NORMAL (UN).
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# UN +1 DP UNIT NORMAL TO THE DESIRED ORBIT PLANE IN THE DIRECTION OF THE RESULTING ANGULAR
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# MOMENTUM VECTOR. THIS WILL BE IGNORED IF NORMSW IS CLEAR.
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# VTARGTAG NONE A S.P. TAG TO BE SET TO ZERO IF LAMBERT IS TO COMUTE THE VELOCITY OF R2VEC AS WELL AS
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# AT R1VEC.
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#
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# SUBROUTINES CALLED --
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# GEOM, GETX, DELTIME, ITERATOR, LAMENTER (PART OF NEWSTATE)
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#
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# CALLING SEQUENCE AND NORMAL EXIT MODES --
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# L CALL # MUST BE IN INTERPRETIVE MODE BUT OVFIND ARBITRARY.
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# L+1 LAMBERT # RETURNS WITH PL AT 0 AND WITH VVEC IN MPAC IF VTARGTAG WAS WAS NON-ZERO OR VTARGET
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# # IN MPAC IF VTARGTAG WAS ZERO
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# L+2 BON # CONTINUE IF SOLNSW CLEAR SINCE SOLUTION IS ACCEPTABLE
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# L+3 SOLNSW
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# L+4 LAMABORT
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#
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# IF A LAMBER RESULT IS TO BE A FIRST GUESS FOR THE NEXT LAMBERT CALCULATION, COGA MUST BE PRESERVED AND
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# GUESSW MUST BE CLEAR FOR EACH SUCCEEDING LAMBERT CALL.
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#
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# ABORT EXIT MODES --
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# IF SOLNSW WAS SET UPON EXITING, EITHER LAMBERT WAS ASKED TO COMPUTE A TRANSFER TOO NEAR 0 OR 360 DEG, OR T
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# WAS TOO SMALL TO PRODUCE A REALISTIC TRANSFER BETWEEN R1VEC AND R2FEC. IN EITHER CASE THE FIX MUST BE MADE
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# ACCORDING TO THE NEEDS OF THE PARTICULAR USER. THE ABORT EXIT MODE MAY BE CODED AS ...
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# LAMBERT DLOAD ABS # A MEASURE OF THE PROXIMITY TO 0 OR
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# 1-CHTH # 360 DEGREES.
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# DSU BWM
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# ONEBIT
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# CHANGER2 # CHANGE R2VEC DIRECTION SLIGHTLY.
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# DLOAD DAD
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# TDESIRED
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# SOMETIME
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# STCALL TDESIRED # INCRESE TDESIRED
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# LAMBERT
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#
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# OUTPUT --
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# SCALE FACTOR
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# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
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# Page 1268
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# -------- -------------- -----------------------
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# VVEC +7 FOR EARTH DP INITIAL VELOCITY VECTOR IN METERS/CENTISECOND REQUIRED TO SATISFY THE BOUNDARY VALUE
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# +5 FOR MOON PROBLEM.
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# VTARGET +7 FOR EARTH DP RESULTANT VELOCITY VECTOR AT R2VEC IN METERS/CENTISECOND.
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# +5 FOR MOON
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# SOLNSW NONE INTERPRETER SWITCH WHICH IS SET IF THE SUBROUTINE CANNOT SOLVE THE PROBLEM, CLEAR IF THE
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# SOLUTION EXISTS.
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#
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# FOR OTHER OUTPUT WHICH MAY BE OF USE, SEE DEBRIS.
|
||
|
#
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# DEBRIS --
|
||
|
# PARAMETERS WHICH MAY BE OF USE --
|
||
|
# SCALE FACTOR
|
||
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# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
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||
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# -------- -------------- -----------------------
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# SNTH +1 DP SIN OF ANGLE BETWEEN R1VEC AND R2VEC
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# CSTH +1 DP COSINE OF ANGLE
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# 1-CSTH +2 DP 1-CSTH
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# COGA +5 DP COTAN OF INITIAL REQUIRED FLIGHT PATH ANGLE MEASURED FROM VERTICAL
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# P +4 DP RATIO OF SEMILATUS RECTUM TO INITIAL RADIUS
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# R1A +6 DP RATIO OF INITIAL RADIUS TO SEMI-MAJOR AXIS
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# R1 (32D) +29 FOR EARTH DP INITIAL RADIUS IN METERS
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# +27 FOR MOON
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# UR1 +1 DP UNIT VECTOR OF R1VEC
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# U2 +1 DP UNIT VECTOR OF R2VEC
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#
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# PARAMETERS OF NO USE --
|
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|
# DP PARAMETERS -- EPSILONL, CSTH-RHO, TPREV, TERRLAMB, R2, RTNLAMB (SP), PLUS PUSHLIST REGISTER 0 THROUGH 41D
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|
# ADDITIONAL INTERPRETIVE SWITCHES USED -- INFINFLG, 360SW, SLOPESW, ORDERSW
|
||
|
|
||
|
# Page 1269
|
||
|
# PROGRAM DESCRIPTION -- TIME-THETA SUBROUTINE DATE -- 1 SEPTEMBER 1967
|
||
|
# MOD NO. -- 0 LOG SECTION -- CONIC SUBROUTINES
|
||
|
# MOD BY KRAUSE ASSEMBLY -- COLOSSUS REVISION 88
|
||
|
#
|
||
|
# FUNCTIONAL DESCRIPTION --
|
||
|
# THIS SUBROUTINE, GIVEN AN INITIAL STATE VECTOR AND A DESIRED TRUE-ANOMALY-DIFFERENCE THROUGH WHICH THE
|
||
|
# STATE IS TO BE UPDATED ALONG A CONIC TRAJECTORY, CALCULATES THE CORRESPONDING TIME-OF-FLIGHT AND, IN ADDITION,
|
||
|
# PROVIDES THE OPTION OF COMUTING THE NEW UPDATED STATE VECTOR. THE RESULTING TRAJECTORY MAY BE A SECTION OF A
|
||
|
# CIRCLE, ELLIPSE, PARABOLA, OR HYPERBOLA WITH RESPECT TO THE EARTH OR THE MOON. THE USE OF THE SUBROUTINE CAN BE
|
||
|
# EXTENDED USING OTHER PRIMARY BODIES BY SIMPLE ADDITIONS TO THE MUTABLE WTIHOUT INTRODUCING ANY CODING CHANGES,
|
||
|
# ACCEPTING THE INHERENT SCALE FACTOR CHANGES IN POSITION AND VELOCITY.
|
||
|
#
|
||
|
# THE RESTRICTIONS ARE --
|
||
|
# 1. THE ANGLE BETWEEN ANY POSITION VECTOR AND ITS VELOCITY VECTOR MUST BE GREATER THAN 1 DEGREE 47.5 MINUTES
|
||
|
# AND LESS THAN 178 DEGREES 12.5 MINUTES.
|
||
|
# 2. THE PARAMETERS IN THE PROBLEM MUST NOT EXCEED THEIR SCALING LIMITS SPECIFIED IN THE GSCP. IF THE LIMITS
|
||
|
# ARE EXCEEDED, THE RESULTING SOLUTION WILL BE MEANINGLESS.
|
||
|
#
|
||
|
# THE AGC COMPUTATION TIME IS APPROXIMATELY .292 SECONDS.
|
||
|
#
|
||
|
# REFERENCES --
|
||
|
# R-479, MISSION PROGRAMMING DEFINITION MEMO NO. 10, LUNAR LANDING MISSION GSOP-SECTION 5.5, SGA MEMO 67-8.
|
||
|
#
|
||
|
# INPUT -- ERASABLE INITIALIZATION REQUIRED
|
||
|
# SCALE FACTOR
|
||
|
# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
|
||
|
# -------- -------------- -----------------------
|
||
|
# RVEC +29 FOR EARTH DP INITIAL POSITION VECTOR IN METERS
|
||
|
# +27 FOR MOON
|
||
|
# VVEC +7 FOR EARTH DP INITIAL VELOCITY VECTOR IN METERS/CENTISECOND
|
||
|
# +5 FOR MOON
|
||
|
# SNTH +1 ` DP SINE OF THE TRUE-ANOMALY-DIFFERENCE THROUGH WHICH THE STATE IS TO BE UPDATED
|
||
|
# CSTH +1 DP COSINE OF THE ANGLE
|
||
|
# RVSW NONE AN INTERPRETIVE SWITCH TO BE SET IF ONLY TIME IS TO BE AN OUTPUT, CLEAR IF THE NEW STATE
|
||
|
# IS TO BE COMPUTED ALSO.
|
||
|
# X1 (38D) NONE INDEX REGISTER TO BE SET TO -2D OR -10D ACCORDING TO WHETHER THE EARTH OR MOON,
|
||
|
# RESPECTIVELY, IS THE CENTRAL BODY.
|
||
|
#
|
||
|
# SUBROUTINES CALLED --
|
||
|
# Page 1270
|
||
|
# PARAM, GEOM, GETX, DELTIME, NEWSTATE
|
||
|
#
|
||
|
# CALLING SEQUENCE AND NORMAL EXIT MODES --
|
||
|
# IF ONLY TIME IS DESIRED AS OUTPUT --
|
||
|
# L SET CALL # MUST BE IN INTERPRETIVE MODE BUT OVFIND ARBITRARY.
|
||
|
# L+1 RVSW
|
||
|
# L+2 TIMETHET # RETURN WITH PL AT 0 AND T IN MPAC
|
||
|
# L+3 ... # CONTINUE
|
||
|
#
|
||
|
# IF THE UPDATE STATE VECTOR IS DESIRED AS WELL --
|
||
|
# L CLEAR CALL # MUST BE IN INTERPRETIVE MODE BUT OVFIND ARBITRARY.
|
||
|
# L+1 RVSW
|
||
|
# L+2 TIMETHET # RETURNS WITH PL AT 6. THE INITIAL POSITION VECTOR IS IN 0D OF THE PUSHLIST AND
|
||
|
# # THE INITIAL VELOCITY VECTOR IN MPAC.
|
||
|
# L+3 STOVL NEWVVEC
|
||
|
# L+4 STADR
|
||
|
# L+5 STORE NEWRVEC # NEWVVEC AND NEWRVEC ARE SYMBOLIC REPRESENTATIONS OF THE USER'S LOCATIONS.
|
||
|
# L+6 ... # CONTINUE.
|
||
|
#
|
||
|
# ABORT EXIT MODES --
|
||
|
# IF COGAFLAG AND/OR INFINFLG IS SET AT THE EXIT TO TIME-THETA, TIME-THETA WILL TRANSFER TO P00DOO WITH
|
||
|
# AN ALARM CODE (ORIGINALLY 00607), AND NOT RETURN TO THE CALLING PROGRAM. (PCR 692 AND 721).
|
||
|
#
|
||
|
# OUTPUT --
|
||
|
# SCALE FACTOR
|
||
|
# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
|
||
|
# -------- -------------- -----------------------
|
||
|
# T(30D) +28 DP TRANSFER TIME IN CENTISECONDS
|
||
|
# INFINFLG NONE AN INTERPRETIVE SWITCH WHICH IS SET IF THE TRANSFER ANGLE REQUIRES CLOSURE THROUGH
|
||
|
# INFINITY (NO SOLUTION), CLEAR IF A PHYSICAL SOLUTION IS POSSIBLE.
|
||
|
# COGAFLAG NONE AN INTERPRETIVE SWITCH WHICH IS SET IF RESTRICTION 1 HAS BEEN VIOLATED (NO SOLUTION),
|
||
|
# CLEAR IF NOT.
|
||
|
#
|
||
|
# IN ADDITION, IF RVSW IS CLEAR, THE FOLLOWING ARE OUTPUT --
|
||
|
# MPAC - +7 FOR EARTH DP TERMINAL VELOCITY VECTOR IN METERS/CENTISEC.
|
||
|
# MPAC+5 +5 FOR MOON
|
||
|
# 0D - 5D +29 FOR EARTH DP TERMINAL POSITION VECTOR IN METERS (PL AT 6D)
|
||
|
# +27 FOR MOON
|
||
|
#
|
||
|
# FOR OTHER OUTPUT WHICH MAY BE OF USE, SEE DEBRIS.
|
||
|
# Page 1271
|
||
|
#
|
||
|
# DEBRIS --
|
||
|
# PARAMETERS WHICH MAY BE OF USE --
|
||
|
# SCALE FACTOR
|
||
|
# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
|
||
|
# -------- -------------- -----------------------
|
||
|
# R1 (32D) +29 FOR EARTH DP MAGNITUDE OF INITIAL POSITION VECTOR, RVEC, IN METERS
|
||
|
# +27 FOR MOON
|
||
|
# R1A +6 DP RATIO OF R1 TO SEMI-MAJOR AXIS (NEG. FOR HYPERBOLIC TRAJECTORIES)
|
||
|
# P +4 DP RATIO OF SEMILATUS RECTUM TO R1
|
||
|
# COGA +5 DP COTAN OF ANGLE BETWEEN RVEC AND VVEC
|
||
|
# UR1 +1 DP UNIT VECTOR OF RVEC
|
||
|
# U2 +1 DP UNIT VECTOR OF VVEC
|
||
|
# UN +1 DP UNIT VECTOR OF UR1*U2
|
||
|
#
|
||
|
# PARAMETERS OF NO USE --
|
||
|
# SP PARAMETERS -- RTNTT, GEOMSGN, RTNPRM, MAGVEC2=R2 (DP), PLUS PUSHLIST LOCATIONS 0-11D, 14D-21D, 24D-39D, 41D
|
||
|
# ADDITIONAL INTERPRETIVE SWITCHES USED -- NORMSW, 360SW
|
||
|
|
||
|
# Page 1272
|
||
|
# PROGRAM DESCRIPTION -- TIME-RADIUS SUBROUTINE DATE -- 11 OCTOBER 1967
|
||
|
# MOD NO. -1 LOG SECTION -- CONIC SUBROUTINES
|
||
|
# MOD BY KRAUSE ASSEMBLY -- COLOSSUS REVISION 88
|
||
|
#
|
||
|
# FUNCTIONAL DESCRIPTION --
|
||
|
# THIS SUBROUTINE, GIVEN AN INITIAL STATE VECTOR AND A DESIRED RADIUS TO WHICH THE
|
||
|
# STATE IS TO BE UPDATED ALONG A CONIC TRAJECTORY, CALCULATES THE CORRESPONDING TIME-OF-FLIGHT AND, IN ADDITION,
|
||
|
# PROVIDES THE OPTION OF COMPUTING THE NEW UPDATED STATE VECTOR. THE RESULTING TRAJECTORY MAY BE A SECTION OF A
|
||
|
# CIRCLE, ELLIPSE, PARABOLA, OR HYPERBOLA WITH RESPECT TO THE EARTH OR THE MOON. THE USE OF THE SUBROUTINE CAN BE
|
||
|
# EXTENDED USING OTHER PRIMARY BODIES BY SIMMPE ADDITIONS TO THE MUTABLE WITHOUT INTRODUCING ANY CODING CHANGES,
|
||
|
# ACCEPTING THE INHERENT SCALE FACTOR CHANGES IN POSITION AND VELOCITY.
|
||
|
#
|
||
|
# IF THE DESIRED RADIUS IS BEYOND THE RADIUS OF APOCENTER OF THE CONIC OR BELOW THE RADIUS OF PERICENTER,
|
||
|
# APSESW WILL BE SET AND THE SUBROUTINE WILL RETURN THE APOCENTER OR PERICENTER SOLUTION, RESPECTIVELY.
|
||
|
#
|
||
|
# THE RESTRICTIONS ARE --
|
||
|
# 1. THE ANGLE BETWEEN ANY POSITION VECTOR AND ITS VELOCITY VECTOR MUST BE GREATER THAN 1 DEGREE 47.5 MINUTES
|
||
|
# AND LESS THAN 178 DEGREES 12.5 MINUTES.
|
||
|
# 2. THE PARAMETERS IN THE PROBLEM MUST NOT EXCEED THEIR SCALING LIMITS SPECIFIED IN THE GSOP. IF THE LIMITS
|
||
|
# EXCEEDED, THE RESULTING SOLUTION WILL BE MEANINGLESS.
|
||
|
# 3. AN ACCURACY DEGRADATION OCCURS AS THE SENSITIVITIES OF TIME AND UPDATED STATE VECTOR TO CHANGES IN
|
||
|
# RDESIRED INCREASE. THIS WILL OCCUR NEAR EITHER APSIS OF THE CONIC AND WHEN THE CONIC IS NEARLY CIRCULAR. IN
|
||
|
# PARTICULAR, IF THE CONIC IS AN EXACT CIRCLE, THE PROBLEM IS UNDEFINED AND THE SUBROUTINE WILL ABORT.
|
||
|
#
|
||
|
# THE AGC COMPUTATION TIME IS APPROXIMATELY .363 SECONDS.
|
||
|
#
|
||
|
# REFERENCES --
|
||
|
# R-479, MISSION PROGRAMMING DEFINITION MEMO NO. 10, LUNAR LANDING MISSION GSOP-SECTION 5.5, SGA MEMO 67-8.
|
||
|
#
|
||
|
# INPUT -- ERASABLE INITIALIZATION REQUIRED.
|
||
|
# SCALE FACTOR
|
||
|
# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
|
||
|
# -------- -------------- -----------------------
|
||
|
# RVEC +29 FOR EARTH DP INITIAL POSITION VECTOR IN METERS
|
||
|
# +27 FOR MOON
|
||
|
# VVEC +7 FOR EARTH DP INITIAL VELOCITY VECTOR IN METERS/CENTISECOND
|
||
|
# +5 FOR MOON
|
||
|
# RDESIRED +29 FOR EARTH DP TERMINAL RADIAL DISTANCE ON CONIC TRAJECTORY FOR WHICH TRANSFER TIME IS TO BE
|
||
|
# +27 FOR MOON COMPUTED
|
||
|
# SGNRDOT NONE SP TAG SET TO +.5 OR -.5 ACCORDING TO WHETHER THE RADIAL VELOCITY AT RDESIRED IS TO BE
|
||
|
# POSITIVE OR NEGATIVE, RESPECTIVELY. THIS TAG REDUCES THE DOUBLE-VALUED PROBLEM TO A
|
||
|
# Page 1273
|
||
|
# SINGLE-VALUED PROBLEM.
|
||
|
# X1 (38D) NONE INDEX REGISTER TO BE SET TO -2D OR -10D ACCORDING TO WHETHER THE EARTH OR MOON,
|
||
|
# RESPECTIVELY, IS THE CENTRAL BODY.
|
||
|
# RVSW NONE AN INTERPRETIVE SWITCH TO BE SET IF ONLY TIME IS TO BE AN OUTPUT, CLEAR IF THE NEW STATE
|
||
|
# IS TO BE COMPUTED ALSO.
|
||
|
#
|
||
|
# SUBROUTINES CALLED --
|
||
|
# PARAM, GEOM, GETX, DELTIME, NEWSTATE
|
||
|
#
|
||
|
# CALLING SEQUENCE AND NORMAL EXIT MODES --
|
||
|
# IF ONLY TIME IS DESIRED AS OUTPUT --
|
||
|
# L SET CALL # MUST BE IN INTERPRETIVE MODE BUT OVFIND ARBITRARY.
|
||
|
# L+1 RVSW
|
||
|
# L+2 TIMERAD # RETURN WITH PL AT 0 AND T IN MPAC
|
||
|
# L+3 ... # CONTINUE
|
||
|
#
|
||
|
# IF THE UPDATE STATE VECTOR IS DESIRED AS WELL --
|
||
|
# L CLEAR CALL # MUST BE IN INTERPRETIVE MODE BUT OVFIND ARBITRARY.
|
||
|
# L+1 RVSW
|
||
|
# L+2 TIMERAD # RETURNS WITH PL AT 6. THE INITIAL POSITION VECTOR IS IN 0D OF THE PUSHLIST AND
|
||
|
# # THE INITIAL VELOCITY VECTOR IN MPAC.
|
||
|
# L+3 STOVL NEWVVEC
|
||
|
# L+4 STADR
|
||
|
# L+5 STORE NEWRVEC # NEWVVEC AND NEWRVEC ARE SYMBOLIC REPRESENTATIONS OF THE USER'S LOCATIONS.
|
||
|
# L+6 ... # CONTINUE
|
||
|
#
|
||
|
# ABORT EXIT MODES --
|
||
|
# IF SOLNSW AND/OR COGAFLAG AND/OR INFINFLG IS SET AT THE EXIT TO TIME-RADIUS, TIME-RADIUS WILL TRANSFER
|
||
|
# TO P00DOO WITH AN ALARM CODE (ORIGINALLY 00607), AND NOT RETURN TO THE CALLING PROGRAM. (PCR 692 & 721).
|
||
|
#
|
||
|
# OUTPUT --
|
||
|
# SCALE FACTOR
|
||
|
# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
|
||
|
# -------- -------------- -----------------------
|
||
|
# T (30D) +28 DP TRANSFER TIME IN CENTISECONDS.
|
||
|
# INFINFLG NONE AN INTERPRETIVE SWITCH WHICH IS SET IF RDESIRED AND SGNRDOT REQUIRE CLOSURE THROUGH
|
||
|
# INFINITY (NO SOLUTION), CLEAR IF A PHYSICAL SOLUTION IS POSSIBLE.
|
||
|
# COGAFLAG NONE AN INTERPRETIVE SWITCH WHICH IS SET IF RESTRICTION 1 HAS BEEN VIOLATED (NO SOLUTION),
|
||
|
# CLEAR IF NOT.
|
||
|
# APSESW NONE AN INTERPRETIVE SWITCH WHICH IS SET IF RDESIRED WAS GREATER THAN RADIUS OF APOCENTER OR
|
||
|
# Page 1274
|
||
|
# LESS THAN RADIUS OF PERICENTER. THE APOCENTER OR PERICENTER SOLUTION, RESPECTIVELY,
|
||
|
# WILL THEN BE RETURNED. THE SWITCH IS CLEAR IF RDESIRED WAS BETWEEN PERICENTER AND
|
||
|
# APOCENTER.
|
||
|
# SOLNSW NONE AN INTERPRETIVE SWITCH WHICH IS SET IF THE CONIC IS SO CLOSE TO A CIRCLE THAT THE TERMIN
|
||
|
# POINT IS AMBIGUOUS, VIOLATING RESTRICTION 3. IF ECCENTRICITY IS GREATER THAN 2-TO-THE-
|
||
|
# MINUS-18, THE SWITCH IS CLEAR.
|
||
|
#
|
||
|
# IN ADDITION, IF RVSW IS CLEAR, THE FOLLOWING ARE OUTPUT --
|
||
|
# MPAC - +7 FOR EARTH DP TERMINAL VELOCITY VECTOR IN METERS/CENTISEC.
|
||
|
# MPAC+5 +5 FOR MOON
|
||
|
# 0D - 5D +29 FOR EARTH DP TERMINAL POSITION VECTOR IN METERS (PL AT 6D)
|
||
|
# +27 FOR MOON
|
||
|
#
|
||
|
# FOR OTHER OUTPUT WHICH MAY BE OF USE, SEE DEBRIS.
|
||
|
#
|
||
|
# DEBRIS --
|
||
|
# PARAMETERS WHICH MAY BE OF USE --
|
||
|
# SCALE FACTOR
|
||
|
# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
|
||
|
# -------- -------------- -----------------------
|
||
|
# R1 (32D) +29 FOR EARTH DP MAGNITUDE OF INITIAL POSITION VECTOR, RVEC, IN METERS
|
||
|
# +27 FOR MOON
|
||
|
# R1A +6 DP RATIO OF R1 TO SEMI-MAJOR AXIS (NEG. FOR HYPERBOLIC TRAJECTORIES)
|
||
|
# P +4 DP RATIO OF SEMILATUS RECTUM TO R1
|
||
|
# COGA +5 DP COTAN OF ANGLE BETWEEN RVEC AND VVEC
|
||
|
# UR1 +1 DP UNIT VECTOR OF RVEC
|
||
|
# U2 +1 DP UNIT VECTOR OF VVEC
|
||
|
# UN +1 DP UNIT VECTOR OF UR1*U2
|
||
|
# CSTH +1 DP COSINE OF TRUE ANOMALY DIFFERENCE BETWEEN RVEC AND RDESIRED.
|
||
|
# SNTH +1 DP SINE OF TRUE ANOMALY DIFFERENCE.
|
||
|
#
|
||
|
# PARAMETERS OF NO USE --
|
||
|
# SP PARAMETERS -- RTNTT, GEOMSGN, RTNPRM, MAGVEC2*R2 (DP), PLUS PUSHLIST LOCATIONS 0-11D, 14D-21D, 24D-39D, 41D
|
||
|
# ADDITIONAL INTERPRETIVE SWITCHES USED -- NORMSW, 360SW
|
||
|
#
|
||
|
|
||
|
# Page 1275
|
||
|
# PROGRAM DESCRIPTION -- APSIDES SUBROUTINE DATE -- 1 SEPTEMBER 1967
|
||
|
# MOD NO. -- 0 LOG SECTION -- CONIC SUBROUTINES
|
||
|
# MOD BY KRAUSE ASSEMBLY -- COLOSSUS REVISION 88
|
||
|
#
|
||
|
# FUNCTIONAL DESCRIPTION --
|
||
|
# THIS SUBROUTINE, GIVEN AN INITIAL STATE VECTOR, CALCULATES THE RADIUS OF PERICENTER AND OF APOCENTER AND THE
|
||
|
# ECCENTRICITY OF THE RESULTING CONIC TRAJECTORY, WHICH MAY BE A STRAIGHT LINE,
|
||
|
# CIRCLE, ELLIPSE, PARABOLA, OR HYPERBOLA WITH RESPECT TO THE EARTH OR THE MOON. THE USE OF THE SUBROUTINE CAN
|
||
|
# BE EXTENDED USING OTHER PRIMARY BODIES BY SIMPLE ADDITIONS TO THE MUTABLE WITHOUT INTRODUCING ANY CODING CHANGES,
|
||
|
# ACCEPTING THE INHERENT SCALE FACTOR CHANGES IN POSITION AND VELOCITY.
|
||
|
#
|
||
|
# THE RESTRICTIONS ARE --
|
||
|
# 1. IF APOCENTER IS BEYOND THE SCALING OF POSITION, THE SCALE FACTOR LIMIT (536,870,910 METERS WITH RESPECT
|
||
|
# TO THE EARTH OR 134,217,727.5 METERS WITH RESPECT TO THE MOON) WILL BE RETURNED.
|
||
|
# 2. THE PARAMETERS IN THE PROBLEM MUST NOT EXCEED THEIR SCALING LIMITS SPECIFIED IN THE GSOP. IF THE LIMITS
|
||
|
# ARE EXCEEDED, THE RESULTING SOLUTION WILL BE MEANINGLESS.
|
||
|
#
|
||
|
# THE AGC COMPUTATION TIME IS APPROXIMATELY .103 SECONDS.
|
||
|
#
|
||
|
# REFERENCES --
|
||
|
# MISSION PROGRAMMING DEFINITION MEMO NO. 10, LUNAR LANDING MISSION GSOP-SECTION 5.5.
|
||
|
#
|
||
|
# INPUT -- ERASABLE INITIALIZATION REQUIRED
|
||
|
# SCALE FACTOR
|
||
|
# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
|
||
|
# -------- -------------- -----------------------
|
||
|
# RVEC +29 FOR EARTH DP INITIAL POSITION VECTOR IN METERS
|
||
|
# +27 FOR MOON
|
||
|
# VVEC +7 FOR EARTH DP INITIAL VELOCITY VECTOR IN METERS/CENTISECOND
|
||
|
# +5 FOR MOON
|
||
|
# X1 (38D) NONE INDEX REGISTER TO BE SET TO -2D OR -10D ACCORDING TO WHETHER THE EARTH OR MOON,
|
||
|
# RESPECTIVELY, IS THE CENTRAL BODY.
|
||
|
#
|
||
|
# SUBROUTINES CALLED --
|
||
|
# PARAM, GEOM
|
||
|
#
|
||
|
# CALLING SEQUENCE AND NORMAL EXIT MODES --
|
||
|
# Page 1276
|
||
|
# IF ONLY TIME IS DESIRED AS OUTPUT --
|
||
|
# L CALL # MUST BE IN INTERPRETIVE MODE BUT OVFIND ARBITRARY.
|
||
|
# L+1 APSIDES # RETURNS WITH PL AT 0, RADIUS OF APOCENTER IN MPAC AND RADIUS OF PERICENTER IN 0D
|
||
|
# L+2 STODL APOAPSE
|
||
|
# L+3 0D
|
||
|
# L+4 STORE PERIAPSE # APOAPSE AND PERIAPSE ARE SYMBOLIC REPRESENTATIONS OF THE USER'S LOCATIONS
|
||
|
# L+5 ... # CONTINUE
|
||
|
#
|
||
|
# OUTPUT --
|
||
|
# SCALE FACTOR
|
||
|
# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
|
||
|
# -------- -------------- -----------------------
|
||
|
# MPAC +29 FOR EARTH DP RADIUS OF APOCENTER IN METERS
|
||
|
# +27 FOR MOON
|
||
|
# 0D-1D +29 FOR EARTH DP RADIUS OF PERICENTER IN METERS
|
||
|
# +27 FOR MOON
|
||
|
# ECC +3 DP ECCENTRICITY OF CONIC TRAJECTORY
|
||
|
#
|
||
|
# FOR OTHER OUTPUT WHICH MAY BE OF USE, SEE DEBRIS.
|
||
|
#
|
||
|
# DEBRIS --
|
||
|
# PARAMETERS WHICH MAY BE OF USE --
|
||
|
# SCALE FACTOR
|
||
|
# VARIABLE IN POWERS OF 2 DESCRIPTION AND REMARKS
|
||
|
# -------- -------------- -----------------------
|
||
|
# R1 (32D) +29 FOR EARTH DP MAGNITUDE OF INITIAL POSITION VECTOR, RVEC, IN METERS
|
||
|
# +27 FOR MOON
|
||
|
# R1A +6 DP RATIO OF R1 TO SEMI-MAJOR AXIS (NEG. FOR HYPERBOLIC TRAJECTORIES)
|
||
|
# P +4 DP RATIO OF SEMILATUS RECTUM TO R1
|
||
|
# COGA +5 DP COTAN OF ANGLE BETWEEN RVEC AND VVEC
|
||
|
# UR1 +1 DP UNIT VECTOR OF RVEC
|
||
|
# U2 +1 DP UNIT VECTOR OF VVEC
|
||
|
# UN +1 DP UNIT VECTOR OF UR1*U2
|
||
|
# MAGVEC2 +7 FOR EARTH DP MAGNITUDE OF VVEC
|
||
|
# +5 FOR MOON
|
||
|
#
|
||
|
# PARAMETERS OF NO USE --
|
||
|
# SP PARAMETERS -- RTNAPSE, GOMSGN, RTNPRM, PLUS PUSHLIST LOCATIONS 0-5, 10D-11D, 14D-21D, 31D-38D.
|
||
|
# ADDITIONAL INTERPRETIVE SWITCHES USED -- NORMSW
|
||
|
|
||
|
SETLOC CONICS
|
||
|
# Page 1277
|
||
|
BANK
|
||
|
|
||
|
COUNT 12/CONIC
|
||
|
|
||
|
EBANK= UR1
|
||
|
KEPLERN SETPD BOV
|
||
|
0
|
||
|
+1
|
||
|
VLOAD*
|
||
|
MUTABLE,1
|
||
|
STOVL 14D
|
||
|
RRECT
|
||
|
UNIT SSP
|
||
|
ITERCTR
|
||
|
20D
|
||
|
STODL URRECT
|
||
|
36D
|
||
|
STOVL R1
|
||
|
RRECT
|
||
|
DOT SL1R
|
||
|
VRECT
|
||
|
DMP SL1R
|
||
|
1/ROOTMU # 1/ROOTMU (-17 OR -14)
|
||
|
STOVL KEPC1 # C1=R.V/ROOTMU (+17 OR +16)
|
||
|
|
||
|
VRECT
|
||
|
VSQ DMPR
|
||
|
1/MU # 1/MU (-34 OR -28)
|
||
|
DMP SL3
|
||
|
R1
|
||
|
DSU ROUND
|
||
|
D1/64
|
||
|
STORE KEPC2 # C2=RV.V/MU -1 (+6)
|
||
|
|
||
|
BDSU SR1R
|
||
|
D1/64
|
||
|
DDV
|
||
|
R1
|
||
|
STORE ALPHA # ALPHA=(1-C2)/R1 (-22 OR -20)
|
||
|
|
||
|
BPL DLOAD # MAXIMUM X DEPENDS ON TYPE OF CONIC
|
||
|
1REV
|
||
|
-50SC # -50SC (+12)
|
||
|
DDV BOV
|
||
|
ALPHA
|
||
|
STOREMAX
|
||
|
SQRT GOTO
|
||
|
STOREMAX
|
||
|
# Page 1278
|
||
|
1REV SQRT BDDV
|
||
|
2PISC # 2PISC (+6)
|
||
|
BOV
|
||
|
STOREMAX
|
||
|
STOREMAX STORE XMAX
|
||
|
DMP PDDL
|
||
|
1/ROOTMU
|
||
|
ALPHA
|
||
|
NORM PDDL
|
||
|
X1
|
||
|
SL* DDV
|
||
|
0 -6,1
|
||
|
BOV BMN
|
||
|
MODDONE
|
||
|
MODDONE # MPAC=PERIOD
|
||
|
PERIODCH PDDL ABS # 0D=PERIOD
|
||
|
TAU.
|
||
|
DSU BMN
|
||
|
0D
|
||
|
MODDONE
|
||
|
SIGN
|
||
|
TAU.
|
||
|
STODL TAU.
|
||
|
GOTO
|
||
|
PERIODCH
|
||
|
MODDONE SETPD DLOAD
|
||
|
0
|
||
|
XKEPNEW
|
||
|
STORE X
|
||
|
SIGN BZE
|
||
|
TAU.
|
||
|
BADX
|
||
|
BMN ABS
|
||
|
BADX
|
||
|
DSU BPL
|
||
|
XMAX
|
||
|
BADX
|
||
|
STORBNDS DLOAD BPL
|
||
|
TAU.
|
||
|
STOREMIN
|
||
|
DLOAD DCOMP
|
||
|
XMAX
|
||
|
STODL XMIN
|
||
|
KEPZERO
|
||
|
STCALL XMAX
|
||
|
DXCOMP
|
||
|
STOREMIN DLOAD
|
||
|
KEPZERO
|
||
|
STORE XMIN
|
||
|
DXCOMP DLOAD DMPR
|
||
|
# Page 1279
|
||
|
TAU.
|
||
|
BEE22
|
||
|
ABS
|
||
|
STODL EPSILONT
|
||
|
XPREV
|
||
|
XDIFF BDSU
|
||
|
X
|
||
|
STORE DELX
|
||
|
|
||
|
KEPLOOP DLOAD DSQ
|
||
|
X # X=XKEP
|
||
|
NORM PUSH # 0D=XSQ (+34 OR +32 -N1) PL AT 2
|
||
|
X1
|
||
|
DMP SRR*
|
||
|
ALPHA
|
||
|
0 -6,1
|
||
|
STCALL XI # XI=ALPHA XSQ (+6)
|
||
|
DELTIME
|
||
|
BOV BDSU
|
||
|
TIMEOVFL # UNLIKELY
|
||
|
TAU.
|
||
|
STORE DELT # DELT=DELINDEP
|
||
|
ABS BDSU
|
||
|
EPSILONT
|
||
|
BPL DLOAD
|
||
|
KEPCONVG
|
||
|
T
|
||
|
DSU NORM
|
||
|
TC
|
||
|
X1
|
||
|
PDDL NORM
|
||
|
DELX
|
||
|
X2
|
||
|
XSU,1 DMP
|
||
|
X2
|
||
|
DELT
|
||
|
SLR* DDV
|
||
|
1,1
|
||
|
SR1 PUSH # 0D=TRIAL DELX PL AT 2
|
||
|
BPL DLOAD
|
||
|
POSDELX
|
||
|
X
|
||
|
STORE XMAX # MOVE MAX BOUND IN
|
||
|
BDSU DSU # PL AT 0
|
||
|
XMIN
|
||
|
BOV BPL
|
||
|
NDXCHNGE
|
||
|
NDXCHNGE
|
||
|
DLOAD GOTO
|
||
|
# Page 1280
|
||
|
0D
|
||
|
NEWDELX
|
||
|
|
||
|
NDXCHNGE DLOAD DSU
|
||
|
XMIN
|
||
|
X
|
||
|
DMPR GOTO # TO FORCE MPAC +2 TO ZERO
|
||
|
DP9/10
|
||
|
NEWDELX
|
||
|
|
||
|
POSDELX DLOAD
|
||
|
X
|
||
|
STORE XMIN # MOVE MIN BOUND IN
|
||
|
BDSU DSU # PL AT 0
|
||
|
XMAX
|
||
|
BOV BMN
|
||
|
PDXCHNGE
|
||
|
PDXCHNGE
|
||
|
DLOAD
|
||
|
0D
|
||
|
NEWDELX STORE DELX
|
||
|
BZE DAD
|
||
|
KEPCONVG
|
||
|
X
|
||
|
STODL X
|
||
|
T
|
||
|
STORE TC
|
||
|
BRNCHCTR RTB BHIZ
|
||
|
CHECKCTR
|
||
|
KEPCONVG
|
||
|
GOTO
|
||
|
KEPLOOP # ITERATE
|
||
|
|
||
|
PDXCHNGE DLOAD DSU
|
||
|
XMAX
|
||
|
X
|
||
|
DMPR GOTO # TO FORCE MPAC +2 TO ZERO
|
||
|
DP9/10
|
||
|
NEWDELX
|
||
|
|
||
|
BADX DLOAD SR1
|
||
|
XMAX
|
||
|
SIGN
|
||
|
TAU.
|
||
|
STCALL X
|
||
|
STORBNDS
|
||
|
# Page 1281
|
||
|
TIMEOVFL DLOAD BMN # X WAS TOO BIG
|
||
|
X
|
||
|
NEGTOVFL
|
||
|
STORE XMAX
|
||
|
CMNTOVFL DLOAD SR1
|
||
|
DELX
|
||
|
STORE DELX
|
||
|
BZE BDSU
|
||
|
KEPRTN
|
||
|
X
|
||
|
STODL X
|
||
|
TC
|
||
|
STCALL T
|
||
|
BRNCHCTR
|
||
|
NEGTOVFL STCALL XMIN
|
||
|
CMNTOVFL
|
||
|
KEPCONVG DLOAD SR4R
|
||
|
R1
|
||
|
DSU VXSC
|
||
|
XSQC(XI)
|
||
|
URRECT
|
||
|
VSL1 PDDL # 0D=(R1-XSQC(XI))URRECT (+33 OR +31)
|
||
|
X
|
||
|
DSQ NORM
|
||
|
X1
|
||
|
DMPR DMPR
|
||
|
1/ROOTMU
|
||
|
X
|
||
|
DMP SRR*
|
||
|
S(XI)
|
||
|
0 -7,1
|
||
|
BDSU
|
||
|
T
|
||
|
SL1 VXSC
|
||
|
VRECT
|
||
|
VSL1 VAD
|
||
|
VSL4
|
||
|
STORE RCV # RCV (+29 OR +27)
|
||
|
|
||
|
ABVAL NORM
|
||
|
X2
|
||
|
STODL RCNORM
|
||
|
XI
|
||
|
DMPR DSU
|
||
|
S(XI)
|
||
|
D1/128
|
||
|
DMP SL1R
|
||
|
ROOTMU
|
||
|
DMP SLR*
|
||
|
# Page 1282
|
||
|
X
|
||
|
0 -3,2
|
||
|
DDV VXSC
|
||
|
RCNORM
|
||
|
URRECT
|
||
|
VSL1 PDDL # 0D=URRECT(XI S(XI)-1)X ROOTMU/RCV (+15
|
||
|
XSQC(XI) # OR +13) PL AT 6
|
||
|
SLR* DDV
|
||
|
0 -4,2
|
||
|
RCNORM
|
||
|
BDSU VXSC
|
||
|
D1/256
|
||
|
VRECT
|
||
|
VAD VSL8
|
||
|
STADR # PL AT 0
|
||
|
STODL VCV # VCV (+7 OR +5)
|
||
|
T
|
||
|
STODL TC
|
||
|
X
|
||
|
STCALL XPREV
|
||
|
KEPRTN
|
||
|
|
||
|
# Page 1283
|
||
|
DELTIME EXIT # MPAC=XI (+6), 0D=XSQ (+34 OR +32 -N1)
|
||
|
TC POLY
|
||
|
DEC 8
|
||
|
2DEC .083333334
|
||
|
|
||
|
2DEC -.266666684
|
||
|
|
||
|
2DEC .406349155
|
||
|
|
||
|
2DEC -.361198675
|
||
|
|
||
|
2DEC .210153242
|
||
|
|
||
|
2DEC -.086221951
|
||
|
|
||
|
2DEC .026268812
|
||
|
|
||
|
2DEC -.006163316
|
||
|
|
||
|
2DEC .001177342
|
||
|
|
||
|
2DEC -.000199055
|
||
|
|
||
|
TC INTPRET
|
||
|
STODL S(XI)
|
||
|
XI
|
||
|
EXIT
|
||
|
TC POLY
|
||
|
DEC 8
|
||
|
2DEC .031250001
|
||
|
|
||
|
2DEC -.166666719
|
||
|
|
||
|
2DEC .355555413
|
||
|
|
||
|
2DEC -.406347410
|
||
|
|
||
|
2DEC .288962094
|
||
|
|
||
|
2DEC -.140117894
|
||
|
|
||
|
2DEC .049247387
|
||
|
|
||
|
2DEC -.013081923
|
||
|
|
||
|
2DEC .002806389
|
||
|
|
||
|
2DEC -.000529414
|
||
|
|
||
|
TC INTPRET
|
||
|
# Page 1284
|
||
|
DMP SRR* # PL AT 0
|
||
|
0D
|
||
|
0 -5,1
|
||
|
STORE XSQC(XI) # XSQC(XI) (+33 OR +31)
|
||
|
DMP SL1
|
||
|
KEPC1
|
||
|
RTB PDDL # XCH WITH PL. 0D=C1 XSQ C(XI) (+49 OR +46)
|
||
|
TPMODE # PL AT 0,3
|
||
|
DMP SRR*
|
||
|
S(XI)
|
||
|
0 -5,1
|
||
|
DMP SL1
|
||
|
KEPC2
|
||
|
RTB PDDL # 3D=C2 XSQ S(XI) (+35 OR +33) PL AT 6
|
||
|
TPMODE
|
||
|
R1
|
||
|
SR TAD # PL AT 3
|
||
|
6
|
||
|
NORM DMP # TO PRESERVE SIGNIF.
|
||
|
X1
|
||
|
X
|
||
|
SR* TAD # X(C2 XSQ S(XI) +R1) (+49 OR +46) PL AT 0
|
||
|
0 -3,1
|
||
|
SL4R DMPR
|
||
|
1/ROOTMU
|
||
|
STORE T
|
||
|
RVQ
|
||
|
|
||
|
# Page 1285
|
||
|
ITERATOR BONCLR DLOAD
|
||
|
SLOPESW
|
||
|
FIRSTIME
|
||
|
DEP
|
||
|
DSU NORM
|
||
|
DEPREV
|
||
|
X1
|
||
|
PDDL NORM
|
||
|
DELINDEP
|
||
|
X2
|
||
|
XSU,1 DMP
|
||
|
X2
|
||
|
DELDEP
|
||
|
SLR* DDV # PL UP 2
|
||
|
1,1
|
||
|
SR1 BOFF
|
||
|
ORDERSW
|
||
|
SGNCHECK
|
||
|
ABS SIGN # IN CASE 2ND DERIV. CHANGED SIGN, MUST
|
||
|
DELDEP # DISREGARD IT TO FIND MIN.
|
||
|
|
||
|
SGNCHECK PUSH BPL # TRIAL DELINDEP PL DOWN 2
|
||
|
POSDEL
|
||
|
DLOAD BON
|
||
|
INDEP
|
||
|
ORDERSW
|
||
|
MINCHECK
|
||
|
STORE MAX # IF NOT 2ND ORDER, CAN MOVE MAX BOUND IN.
|
||
|
|
||
|
MINCHECK BDSU DSU
|
||
|
MIN
|
||
|
BOV BPL
|
||
|
MODNGDEL
|
||
|
MODNGDEL
|
||
|
GOTO
|
||
|
DELOK
|
||
|
|
||
|
MODNGDEL DLOAD DSU # TRIAL DELINDEP WOULD EXCEED MIN BOUND
|
||
|
MIN
|
||
|
INDEP
|
||
|
DMP GOTO
|
||
|
DP9/10
|
||
|
NEWDEL
|
||
|
|
||
|
FIRSTIME DLOAD DMP
|
||
|
MIN
|
||
|
TWEEKIT # DLOAD TWEEKIT(40D) SENSITIVE TO CHANGE.
|
||
|
PDDL DMP # S2(41D) SHOULDN'T CONTAIN HI ORDER ONES
|
||
|
# Page 1286
|
||
|
MAX
|
||
|
TWEEKIT
|
||
|
DSU
|
||
|
SIGN GOTO
|
||
|
DELDEP
|
||
|
SGNCHECK
|
||
|
|
||
|
POSDEL DLOAD BON
|
||
|
INDEP
|
||
|
ORDERSW
|
||
|
MAXCHECK
|
||
|
STORE MIN # IF NOT 2ND ORDER, CAN MOVE MIN BOUND IN.
|
||
|
|
||
|
MAXCHECK BDSU DSU
|
||
|
MAX
|
||
|
BOV BMN
|
||
|
MODPSDEL
|
||
|
MODPSDEL
|
||
|
DELOK DLOAD
|
||
|
0D
|
||
|
NEWDEL STORE DELINDEP
|
||
|
RVQ
|
||
|
|
||
|
MODPSDEL DLOAD DSU
|
||
|
MAX
|
||
|
INDEP
|
||
|
DMP GOTO
|
||
|
DP9/10
|
||
|
NEWDEL
|
||
|
|
||
|
CHECKCTR CS ONE
|
||
|
INDEX FIXLOC
|
||
|
AD ITERCTR
|
||
|
INDEX FIXLOC
|
||
|
TS ITERCTR
|
||
|
TS MPAC
|
||
|
TC DANZIG
|
||
|
|
||
|
# Page 1287
|
||
|
NEWSTATE DLOAD SR4R
|
||
|
R1
|
||
|
DSU VXSC
|
||
|
XSQC(XI)
|
||
|
UR1
|
||
|
VSL1 PDDL # 0D=(R1-XSQC(XI))UR1 (+33 OR 31) PL AT 6
|
||
|
X
|
||
|
DSQ NORM
|
||
|
X1
|
||
|
DMPR DMPR
|
||
|
1/ROOTMU
|
||
|
X
|
||
|
DMP SRR*
|
||
|
S(XI)
|
||
|
0 -7,1
|
||
|
BDSU
|
||
|
T
|
||
|
SL1 VXSC
|
||
|
VVEC
|
||
|
VSL1 VAD # PL AT 0
|
||
|
VSL4 PUSH
|
||
|
ABVAL
|
||
|
LAMENTER NORM
|
||
|
X1
|
||
|
STODL R2
|
||
|
XI
|
||
|
DMP DSU
|
||
|
S(XI)
|
||
|
D1/128
|
||
|
DMP SL1R
|
||
|
ROOTMU
|
||
|
DMP SLR*
|
||
|
X
|
||
|
0 -3,1
|
||
|
DDV VXSC
|
||
|
R2
|
||
|
UR1
|
||
|
VSL1 PDDL # 6D=V2VEC PART (+15 OR 13) PL AT 12
|
||
|
XSQC(XI)
|
||
|
SLR* DDV
|
||
|
0 -4,1
|
||
|
R2
|
||
|
BDSU
|
||
|
D1/256
|
||
|
VXSC VAD
|
||
|
VVEC # PL AT 6
|
||
|
VSL8 RVQ
|
||
|
|
||
|
# Page 1288
|
||
|
SETLOC CONICS1
|
||
|
BANK
|
||
|
|
||
|
COUNT 04/CONIC
|
||
|
# DO NOT DISTURB THE ORDER OF THESE CDS, OVERLAYS HAVE BEEN MADE.
|
||
|
BEE17 DEC 0 # KEEP WITH D1/8 2DEC 1.0B-17 (0000004000)
|
||
|
D1/8 2DEC 1.0 B-3
|
||
|
|
||
|
D1/128 2DEC 1.0 B-7
|
||
|
|
||
|
D1/64 2DEC 1.0 B-6
|
||
|
|
||
|
D1/4 2DEC 1.0 B-2
|
||
|
|
||
|
D1/16 2DEC 1.0 B-4
|
||
|
|
||
|
D1/32 2DEC 1.0 B-5
|
||
|
|
||
|
D1/1024 2DEC 1.0 B-10
|
||
|
|
||
|
D1/256 2DEC 1.0 B-8
|
||
|
|
||
|
DP9/10 2DEC .9
|
||
|
|
||
|
KEPZERO EQUALS LO6ZEROS
|
||
|
-50SC 2DEC -50.0 B-12
|
||
|
|
||
|
2PISC 2DEC 6.28318530 B-6
|
||
|
|
||
|
BEE19 EQUALS D1/32 -1 # 2DEC 1.0 B-19 (00000 01000)
|
||
|
BEE22 EQUALS D1/256 -1 # 2DEC 1.0 B-22 (00000 00100)
|
||
|
ONEBIT 2DEC 1.0 B-28
|
||
|
|
||
|
COGUPLIM 2DEC .999511597
|
||
|
|
||
|
COGLOLIM 2DEC -.999511597
|
||
|
|
||
|
# Page 1289
|
||
|
SETLOC CONICS
|
||
|
BANK
|
||
|
|
||
|
COUNT 12/CONIC
|
||
|
|
||
|
TIMETHET STQ SETPD # PL AT 0
|
||
|
RTNTT
|
||
|
0
|
||
|
BOV
|
||
|
+1
|
||
|
VLOAD PDVL # SETUP FOR PARAM CALL PL AT 6
|
||
|
RVEC
|
||
|
VVEC
|
||
|
CALL
|
||
|
PARAM
|
||
|
BOV CALL
|
||
|
COGAOVFL # PL AT 0
|
||
|
GETX
|
||
|
COMMNOUT DLOAD BON
|
||
|
XI
|
||
|
INFINFLG
|
||
|
ABTCONIC
|
||
|
CLEAR CALL
|
||
|
COGAFLAG
|
||
|
DELTIME
|
||
|
BON CALL
|
||
|
RVSW
|
||
|
RTNTT
|
||
|
NEWSTATE
|
||
|
GOTO
|
||
|
RTNTT
|
||
|
|
||
|
COGAOVFL SETGO
|
||
|
COGAFLAG
|
||
|
ABTCONIC
|
||
|
BANK 4
|
||
|
SETLOC CONICS1
|
||
|
BANK
|
||
|
COUNT* $$/CONIC
|
||
|
PARAM STQ CLEAR # MPAC=V1VEC, 0D=R1VEC PL AT 6
|
||
|
RTNPRM
|
||
|
NORMSW
|
||
|
CLEAR
|
||
|
COGAFLAG
|
||
|
SSP CALL
|
||
|
GEOMSGN
|
||
|
37777 # GAMMA ALWAYS LESS THAN 180DEG
|
||
|
GEOM # MPAC=SNGA (+1), 0D=CSGA (+1) PL AT 2
|
||
|
STODL 36D # 36D=SIN GAMMA (+1) PL AT 0
|
||
|
# Page 1290
|
||
|
SR DDV
|
||
|
5
|
||
|
|
||
|
36D
|
||
|
STOVL* COGA
|
||
|
MUTABLE,1
|
||
|
STODL 1/MU
|
||
|
MAGVEC2
|
||
|
DSQ NORM
|
||
|
X1
|
||
|
DMPR DMP
|
||
|
1/MU
|
||
|
R1
|
||
|
SRR*
|
||
|
0 -3,1
|
||
|
PUSH BDSU # 0D=R1 V1SQ/MU (+6) PL AT 2
|
||
|
D1/32
|
||
|
STODL R1A # R1A (+6) PL AT 0
|
||
|
|
||
|
DMP NORM
|
||
|
36D
|
||
|
X1
|
||
|
DMP SR*
|
||
|
36D
|
||
|
0 -4,1
|
||
|
STCALL P # P (+4)
|
||
|
RTNPRM
|
||
|
|
||
|
# Page 1291
|
||
|
GEOM UNIT # MPAC=V2VEC, 0D=R1VEC PL AT 6
|
||
|
STODL U2 # U2 (+1)
|
||
|
36D
|
||
|
STOVL MAGVEC2 # PL AT 0
|
||
|
UNIT
|
||
|
STORE UR1 # UR1 (+1)
|
||
|
DOT SL1
|
||
|
U2
|
||
|
PDDL # 0D=CSTH (+1) PL AT 2
|
||
|
36D
|
||
|
STOVL R1 # R1 (+29 OR +27)
|
||
|
UR1
|
||
|
VXV VSL1
|
||
|
U2
|
||
|
BON SIGN
|
||
|
NORMSW
|
||
|
HAVENORM
|
||
|
GEOMSGN
|
||
|
UNIT BOV
|
||
|
COLINEAR
|
||
|
UNITNORM STODL UN # UN (+1)
|
||
|
36D
|
||
|
SIGN RVQ # MPAC=SNTH (+1), 34D=SNTH.SNTH (+2)
|
||
|
GEOMSGN
|
||
|
|
||
|
COLINEAR VSR1 GOTO
|
||
|
UNITNORM
|
||
|
|
||
|
HAVENORM ABVAL SIGN
|
||
|
GEOMSGN
|
||
|
RVQ # MPAC=SNTH (+1), 34D=SNTH.SNTH (+2)
|
||
|
|
||
|
# Page 1292
|
||
|
BANK 12
|
||
|
SETLOC CONICS
|
||
|
BANK
|
||
|
|
||
|
COUNT 12/CONIC
|
||
|
|
||
|
GETX AXT,2 SSP # ASSUMES P (+4) IN MPAC
|
||
|
3
|
||
|
S2
|
||
|
1
|
||
|
CLEAR
|
||
|
360SW
|
||
|
SQRT PDDL # 0D=SQRT(P) PL AT 2
|
||
|
CSTH
|
||
|
SR1 BDSU
|
||
|
D1/4
|
||
|
PDDL SRR # PL AT 4D
|
||
|
SNTH
|
||
|
6
|
||
|
DDV # PL AT 2
|
||
|
BOV
|
||
|
360CHECK
|
||
|
DSU DMP
|
||
|
COGA # PL AT 0
|
||
|
SL2R BOV
|
||
|
360CHECK
|
||
|
WLOOP PUSH DSQ # 0D=W (+5) PL AT 2
|
||
|
TLOAD PDDL # 2D=WSQ (+10) PL AT 5
|
||
|
MPAC
|
||
|
R1A
|
||
|
SR4 TAD # PL AT 2
|
||
|
BMN SQRT
|
||
|
INFINITY
|
||
|
ROUND DAD # PL AT 0D
|
||
|
BOV TIX,2
|
||
|
RESETX2
|
||
|
WLOOP
|
||
|
|
||
|
BDDV BOV
|
||
|
D1/128
|
||
|
INFINITY
|
||
|
POLYCOEF BMN PUSH # 0D=1/W (+2) OR 16/W (+6) PL AT 2
|
||
|
INFINITY
|
||
|
DSQ
|
||
|
NORM DMP
|
||
|
X1
|
||
|
R1A
|
||
|
SRR* EXIT
|
||
|
0 -10D,1
|
||
|
# Page 1293
|
||
|
TC POLY
|
||
|
DEC 5
|
||
|
2DEC .5
|
||
|
|
||
|
2DEC -.166666770
|
||
|
|
||
|
2DEC .100000392
|
||
|
|
||
|
2DEC -.071401086
|
||
|
|
||
|
2DEC .055503292
|
||
|
|
||
|
2DEC -.047264098
|
||
|
|
||
|
2DEC .040694204
|
||
|
|
||
|
TC INTPRET
|
||
|
DMP SL1R # PL AT 0D
|
||
|
PUSH BON
|
||
|
360SW
|
||
|
TRUE360X
|
||
|
XCOMMON DSQ NORM
|
||
|
X1
|
||
|
DMP SRR*
|
||
|
R1A
|
||
|
0 -12D,1
|
||
|
STODL XI # XI (+6)
|
||
|
|
||
|
R1
|
||
|
SR1 SQRT
|
||
|
ROUND DMP
|
||
|
SL4R # PL AT 0
|
||
|
STORE X # X (+17 OR +16)
|
||
|
|
||
|
DSQ NORM
|
||
|
X1
|
||
|
PDDL DMP # 0D=XSQ (+34 OR +32 -N1) PL AT 2
|
||
|
P
|
||
|
R1
|
||
|
SL3 SQRT
|
||
|
DMP SL3R
|
||
|
COGA
|
||
|
STODL KEPC1
|
||
|
R1A
|
||
|
BDSU CLEAR
|
||
|
D1/64
|
||
|
INFINFLG
|
||
|
STORE KEPC2
|
||
|
# Page 1294
|
||
|
RVQ
|
||
|
|
||
|
RESETX2 AXT,2
|
||
|
3
|
||
|
|
||
|
360CHECK SETPD BPL
|
||
|
0D
|
||
|
INVRSEQN
|
||
|
SET
|
||
|
360SW
|
||
|
|
||
|
INVRSEQN DLOAD SQRT
|
||
|
P
|
||
|
PDDL DMP # 0D=SQRT(P) (+2) PL AT 2
|
||
|
SNTH
|
||
|
COGA
|
||
|
SL1 PDDL # 2D=SNTH COGA (+5) PL AT 4
|
||
|
CSTH
|
||
|
SR4 DAD
|
||
|
D1/32
|
||
|
DSU DMP # PL AT 2,0
|
||
|
NORM BDDV
|
||
|
X1
|
||
|
SNTH
|
||
|
SLR* ABS # NOTE: NEAR 360 CASE TREATED DIFFERENTLY
|
||
|
0 -5,1
|
||
|
PUSH DSQ # 0D=1/W (-1) PL AT 2
|
||
|
STODL 34D
|
||
|
D1/16
|
||
|
1/WLOOP PUSH DSQ # 2D=G (+4) PL AT 4
|
||
|
RTB PDDL # PL AT 7
|
||
|
TPMODE
|
||
|
R1A
|
||
|
DMP SR4
|
||
|
34D
|
||
|
TAD
|
||
|
BMN SQRT # PL AT 4
|
||
|
INFINITY
|
||
|
DAD # PL AT 2
|
||
|
TIX,2 NORM
|
||
|
1/WLOOP
|
||
|
X1
|
||
|
BDDV
|
||
|
SLR* GOTO # PL AT 0
|
||
|
0 -7,1
|
||
|
POLYCOEF
|
||
|
|
||
|
# Page 1295
|
||
|
TRUE360X DLOAD BMN
|
||
|
R1A
|
||
|
INFINITY
|
||
|
SQRT NORM
|
||
|
X1
|
||
|
BDDV SL*
|
||
|
2PISC
|
||
|
0 -3,1
|
||
|
DSU PUSH # 0D=2PI/SQRT(R1A) -X PL AT 0,2
|
||
|
GOTO
|
||
|
XCOMMON
|
||
|
INFINITY SETPD BOV # NO SOLUTION EXISTS SINCE CLOSURE THROUGH
|
||
|
0 # INFINITY IS REQUIRED
|
||
|
OVFLCLR
|
||
|
OVFLCLR SET RVQ
|
||
|
INFINFLG
|
||
|
|
||
|
# Page 1296
|
||
|
LAMBERT STQ SETPD
|
||
|
RTNLAMB
|
||
|
0D
|
||
|
BOV
|
||
|
+1
|
||
|
SSP VLOAD*
|
||
|
ITERCTR
|
||
|
20D
|
||
|
MUTABLE,1
|
||
|
STODL 1/MU
|
||
|
TDESIRED
|
||
|
DMPR
|
||
|
BEE19
|
||
|
STORE EPSILONL
|
||
|
SET VLOAD
|
||
|
SLOPESW
|
||
|
R1VEC
|
||
|
PDVL CALL # 0D=R1VEC (+29 OR +27) PL AT 6
|
||
|
R2VEC # MPAC=R2VEC (+29 OR +27)
|
||
|
GEOM
|
||
|
STODL SNTH # 0D=CSTH (+1) PL AT 2
|
||
|
MAGVEC2
|
||
|
NORM PDDL # PL AT 4
|
||
|
X1
|
||
|
R1
|
||
|
SR1 DDV # PL AT 2
|
||
|
SL* PDDL # DXCH WITH 0D, 0D=R1/R2 (+7) PL AT 0,2
|
||
|
0 -6,1
|
||
|
STADR
|
||
|
STORE CSTH # CSTH (+1)
|
||
|
SR1 BDSU
|
||
|
D1/4
|
||
|
STORE 1-CSTH # 1-CSTH (+2)
|
||
|
|
||
|
ROUND BZE
|
||
|
360LAMB
|
||
|
NORM PDDL # PL AT 4
|
||
|
X1
|
||
|
0D
|
||
|
SR1 DDV # PL AT 2
|
||
|
SL* SQRT
|
||
|
0 -3,1
|
||
|
PDDL SR # 2D=SQRT(2R1/R2(1-CSTH)) (+5) PL AT 4
|
||
|
SNTH
|
||
|
6
|
||
|
DDV DAD # PL AT 2
|
||
|
1-CSTH
|
||
|
STADR
|
||
|
STORE COGAMAX
|
||
|
BOV BMN # IF OVFL, COGAMAX=COGUPLIM
|
||
|
# Page 1297
|
||
|
UPLIM # IF NEG, USE EVEN IF LT COGLOLIM, SINCE
|
||
|
MAXCOGA # THIS WOULD BE RESET IN LAMBLOOP
|
||
|
DSU BMN # IF COGAMAX GT COGUPLIM, COGAMAX=COGUPLIM
|
||
|
COGUPLIM
|
||
|
MAXCOGA # OTHERWISE OK, SO GO TO MAXCOGA
|
||
|
UPLIM DLOAD
|
||
|
COGUPLIM # COGUPLIM=.999511597 = MAX VALUE OF COGA
|
||
|
STORE COGAMAX # NOT CAUSING OVFL IN R1A CALCULATION
|
||
|
MAXCOGA DLOAD
|
||
|
CSTH
|
||
|
SR DSU # PL AT 0
|
||
|
6
|
||
|
STADR
|
||
|
STODL CSTH-RHO
|
||
|
GEOMSGN
|
||
|
BMN DLOAD
|
||
|
LOLIM
|
||
|
CSTH-RHO
|
||
|
SL1 DDV
|
||
|
SNTH
|
||
|
BOV
|
||
|
LOLIM
|
||
|
MINCOGA STORE COGAMIN # COGAMIN (+5)
|
||
|
BON SSP
|
||
|
GUESSW
|
||
|
NOGUESS
|
||
|
TWEEKIT
|
||
|
00001
|
||
|
DLOAD
|
||
|
COGA
|
||
|
|
||
|
LAMBLOOP DMP
|
||
|
SNTH
|
||
|
SR1 DSU
|
||
|
CSTH-RHO
|
||
|
NORM PDDL # 0D=SNTH COGA-(CSTH-RHO) (+7+C(XI)) PL=2
|
||
|
X1
|
||
|
1-CSTH
|
||
|
SL* DDV # 1-CSTH (+2) PL AT 0
|
||
|
0 -9D,1
|
||
|
BMN BZE
|
||
|
NEGP
|
||
|
NEGP
|
||
|
STODL P # P=(1-CSTH)/(SNTH COGA-(CSTH-RHO)) (+4)
|
||
|
COGA
|
||
|
DSQ DAD
|
||
|
D1/1024
|
||
|
NORM DMP
|
||
|
X1
|
||
|
# Page 1298
|
||
|
P
|
||
|
SR* BDSU
|
||
|
0 -8D,1
|
||
|
D1/32
|
||
|
STODL R1A # R1A=2-P(1+COGA COGA) (+6)
|
||
|
|
||
|
P
|
||
|
BOV CALL
|
||
|
HIENERGY
|
||
|
GETX
|
||
|
DLOAD
|
||
|
T
|
||
|
STODL TPREV
|
||
|
XI
|
||
|
BON CALL
|
||
|
INFINFLG
|
||
|
NEGP # HAVE EXCEEDED THEORETICAL BOUNDS
|
||
|
DELTIME
|
||
|
BOV BDSU
|
||
|
BIGTIME
|
||
|
TDESIRED
|
||
|
STORE TERRLAMB
|
||
|
ABS BDSU
|
||
|
EPSILONL
|
||
|
BPL RTB
|
||
|
INITV
|
||
|
CHECKCTR
|
||
|
BHIZ CALL
|
||
|
SUFFCHEK
|
||
|
ITERATOR
|
||
|
DLOAD BZE
|
||
|
MPAC
|
||
|
SUFFCHEK
|
||
|
DAD
|
||
|
COGA
|
||
|
STCALL COGA
|
||
|
LAMBLOOP
|
||
|
|
||
|
NEGP DLOAD BPL # IMPOSSIBLE TRAJECTORY DUE TO INACCURATE
|
||
|
DCOGA # BOUND CALCULATION. TRY NEW COGA.
|
||
|
LOENERGY
|
||
|
|
||
|
HIENERGY SETPD DLOAD # HIGH ENERGY TRAJECTORY RESULTED.
|
||
|
0
|
||
|
COGA # IN OVFL OF P OR R1A, OR XI EXCEEDING 50.
|
||
|
STORE COGAMIN # THIS IS THE NEW BOUND.
|
||
|
COMMONLM DLOAD SR1
|
||
|
DCOGA
|
||
|
# Page 1299
|
||
|
STORE DCOGA # USE DCOGA/2 AS DECREMENT
|
||
|
BZE BDSU
|
||
|
SUFFCHEK
|
||
|
COGA
|
||
|
STCALL COGA
|
||
|
LAMBLOOP
|
||
|
|
||
|
BIGTIME DLOAD
|
||
|
TPREV
|
||
|
STORE T
|
||
|
|
||
|
LOENERGY SETPD DLOAD # LOW ENERGY TRAJECTORY RESULTED
|
||
|
0
|
||
|
COGA # IN OVERFLOW OF TIME.
|
||
|
STCALL COGAMAX # THIS IS THE NEW BOUND.
|
||
|
COMMONLM
|
||
|
|
||
|
SUFFCHEK DLOAD ABS
|
||
|
TERRLAMB
|
||
|
PDDL DMP
|
||
|
TDESIRED # PL AT 2D
|
||
|
D1/4
|
||
|
DAD DSU # PL AT 0D
|
||
|
ONEBIT
|
||
|
BPL SETGO
|
||
|
INITV
|
||
|
SOLNSW
|
||
|
RTNLAMB
|
||
|
|
||
|
360LAMB SETPD SETGO # LAMBERT CANNOT HANDLE CSTH=1
|
||
|
0
|
||
|
SOLNSW
|
||
|
RTNLAMB
|
||
|
|
||
|
NOGUESS SSP DLOAD
|
||
|
TWEEKIT
|
||
|
20000
|
||
|
COGAMIN
|
||
|
SR1 PDDL # PL AT 2
|
||
|
COGAMAX
|
||
|
SR1 DAD
|
||
|
STADR # PL AT 0
|
||
|
STORE COGA
|
||
|
STCALL DCOGA
|
||
|
LAMBLOOP
|
||
|
# Page 1300
|
||
|
LOLIM DLOAD GOTO
|
||
|
COGLOLIM # COGLOLIM=-.999511597
|
||
|
MINCOGA
|
||
|
|
||
|
INITV DLOAD NORM
|
||
|
R1
|
||
|
X1
|
||
|
PDDL SR1 # PL AT 2
|
||
|
P
|
||
|
DDV # PL AT 0
|
||
|
SL* SQRT
|
||
|
0 -4,1
|
||
|
DMP SL1
|
||
|
ROOTMU
|
||
|
PUSH DMP # 0D=VTAN (+7) PL AT 2
|
||
|
COGA
|
||
|
SL VXSC
|
||
|
5
|
||
|
UR1
|
||
|
PDDL # XCH WITH 0D PL AT 0,6
|
||
|
VXSC VSL1
|
||
|
UN
|
||
|
VXV VAD
|
||
|
UR1 # PL AT 0
|
||
|
VSL1 CLEAR
|
||
|
SOLNSW
|
||
|
STORE VVEC
|
||
|
SLOAD BZE
|
||
|
VTARGTAG
|
||
|
TARGETV
|
||
|
GOTO
|
||
|
RTNLAMB
|
||
|
|
||
|
TARGETV DLOAD CALL
|
||
|
MAGVEC2
|
||
|
LAMENTER
|
||
|
STCALL VTARGET
|
||
|
RTNLAMB
|
||
|
|
||
|
# Page 1301
|
||
|
TIMERAD STQ SETPD # PL AT 0
|
||
|
RTNTR
|
||
|
0
|
||
|
BOV
|
||
|
+1
|
||
|
VLOAD PDVL # PL AT 6
|
||
|
RVEC
|
||
|
VVEC
|
||
|
CALL
|
||
|
PARAM
|
||
|
BOV DLOAD
|
||
|
COGAOVFL # PL AT 0
|
||
|
D1/32
|
||
|
DSU DMP
|
||
|
R1A
|
||
|
P
|
||
|
SQRT DMP
|
||
|
COGA
|
||
|
SL4 VXSC
|
||
|
U2
|
||
|
PDDL DSU # PL AT 6
|
||
|
D1/64
|
||
|
R1A
|
||
|
VXSC VSU # PL AT 0
|
||
|
UR1
|
||
|
VSL4 UNIT
|
||
|
BOV
|
||
|
CIRCULAR
|
||
|
PDDL NORM # 0D=UNIT(ECC) (+3) PL AT 6
|
||
|
RDESIRED # 35D=ECC (+3)
|
||
|
X1
|
||
|
PDDL DMP # PL AT 8
|
||
|
R1
|
||
|
P
|
||
|
SL* DDV # PL AT 6
|
||
|
0,1
|
||
|
DSU DDV
|
||
|
D1/16
|
||
|
36D # 36D=ECC (+3)
|
||
|
STORE COSF
|
||
|
BOV DSQ
|
||
|
BADR2
|
||
|
BDSU BMN
|
||
|
D1/4
|
||
|
BADR2
|
||
|
SQRT SIGN
|
||
|
SGNRDOT
|
||
|
CLEAR
|
||
|
APSESW
|
||
|
|
||
|
# Page 1302
|
||
|
TERMNVEC VXSC VSL1
|
||
|
UN
|
||
|
VXV PDVL # VXCH WITH 0D PL AT 0,6
|
||
|
0D
|
||
|
VXSC VAD # PL AT 0
|
||
|
COSF
|
||
|
VSL1 PUSH # 0D=U2 PL AT 6
|
||
|
|
||
|
DOT DDV # LIMITS RESULT TO POSMAX OR NEGMAX
|
||
|
UR1
|
||
|
DP1/4
|
||
|
SR1 BOV # SCALE BACK DOWN TO NORMAL
|
||
|
+1 # CLEAR OVFIND IF SET
|
||
|
STOVL CSTH # CSTH (+1)
|
||
|
UR1
|
||
|
VXV VSL1
|
||
|
DOT SL1
|
||
|
UN
|
||
|
STODL SNTH # SNTH (+1)
|
||
|
P
|
||
|
CALL
|
||
|
GETX
|
||
|
CLRGO
|
||
|
SOLNSW
|
||
|
COMMNOUT
|
||
|
|
||
|
CIRCULAR SETPD SETGO
|
||
|
0
|
||
|
SOLNSW
|
||
|
ABTCONIC
|
||
|
|
||
|
BADR2 DLOAD SIGN
|
||
|
LODPHALF
|
||
|
COSF
|
||
|
STODL COSF
|
||
|
KEPZERO
|
||
|
SETGO
|
||
|
APSESW
|
||
|
TERMNVEC
|
||
|
|
||
|
# Page 1303
|
||
|
APSIDES STQ SETPD # PL AT 0
|
||
|
RTNAPSE
|
||
|
0D
|
||
|
BOV
|
||
|
+1
|
||
|
VLOAD PDVL # PL AT 6
|
||
|
RVEC
|
||
|
VVEC
|
||
|
CALL
|
||
|
PARAM
|
||
|
BOV # PL AT 0
|
||
|
GETECC
|
||
|
GETECC DMP SL4
|
||
|
R1A
|
||
|
BDSU SQRT
|
||
|
D1/64
|
||
|
STORE ECC
|
||
|
DAD PDDL # PL AT 2
|
||
|
D1/8
|
||
|
R1
|
||
|
DMP SL1
|
||
|
P
|
||
|
DDV # PL AT 0
|
||
|
PDDL NORM # 0D=RP (+29 OR +27) PL AT 2
|
||
|
R1A
|
||
|
X1
|
||
|
PDDL SL* # PL AT 4
|
||
|
R1
|
||
|
0 -5,1
|
||
|
DDV DSU # PL AT 2,0
|
||
|
BOV BMN
|
||
|
INFINAPO
|
||
|
INFINAPO
|
||
|
GOTO
|
||
|
RTNAPSE
|
||
|
INFINAPO DLOAD GOTO # RETURNS WITH APOAPSIS IN MPAC, PERIAPSIS
|
||
|
LDPOSMAX
|
||
|
RTNAPSE # THAT PL IS AT 0.
|
||
|
|
||
|
# Page 1304
|
||
|
ABTCONIC EXIT
|
||
|
TC P00DOO
|
||
|
OCT 00607
|
||
|
|
||
|
# Page 1305
|
||
|
SETLOC CONICS1
|
||
|
BANK
|
||
|
|
||
|
COUNT 04/CONIC
|
||
|
|
||
|
MUTABLE 2DEC* 3.986032 E10 B-36* # MUE
|
||
|
|
||
|
2DEC* .25087606 E-10 B+34* # 1/MUE
|
||
|
|
||
|
2DEC* 1.99650495 E5 B-18* # SQRT(MUE)
|
||
|
|
||
|
2DEC* .50087529 E-5 B+17* # 1/SQRT(MUE)
|
||
|
|
||
|
2DEC 4.902778 E8 B-30 # MUM
|
||
|
|
||
|
2DEC .203966 E-8 B+28 # 1/MUM
|
||
|
|
||
|
2DEC* 2.21422176 E4 B-15* # SQRT(MUM)
|
||
|
|
||
|
2DEC* .45162595 E-4 B+14* # 1/SQRT(MUM)
|
||
|
|
||
|
LDPOSMAX EQUALS LODPMAX # DPPOSMAX IN LOW MEMORY.
|
||
|
|
||
|
# ERASABLE ASSIGNEMENTS
|
||
|
|
||
|
# KEPLER SUBROUTINE
|
||
|
|
||
|
# INPUT --
|
||
|
# RRECT ERASE +5
|
||
|
# VRECT ERASE +5
|
||
|
# TAU. ERASE +1
|
||
|
# XKEP ERASE +1
|
||
|
# TC ERASE +1
|
||
|
# XPREV ERASE +1
|
||
|
1/MU EQUALS 14D
|
||
|
ROOTMU EQUALS 16D
|
||
|
1/ROOTMU EQUALS 18D
|
||
|
|
||
|
# OUTPUT --
|
||
|
# RCV ERASE +5
|
||
|
# VCV ERASE +5
|
||
|
# RC ERASE +1
|
||
|
# XPREV ERASE +1
|
||
|
|
||
|
# DEBRIS --
|
||
|
ALPHA EQUALS 8D
|
||
|
XMAX EQUALS 10D
|
||
|
# Page 1306
|
||
|
XMIN EQUALS 12D
|
||
|
X EQUALS 20D
|
||
|
XI EQUALS 24D
|
||
|
S(XI) EQUALS 26D
|
||
|
XSQC(XI) EQUALS 28D
|
||
|
T EQUALS 30D
|
||
|
R1 EQUALS 32D
|
||
|
KEPC1 EQUALS 34D
|
||
|
KEPC2 EQUALS 36D
|
||
|
|
||
|
# DELX ERASE +1
|
||
|
# DELT ERASE +1
|
||
|
# URRECT ERASE +5
|
||
|
# RCNORM ERASE +1
|
||
|
# XPREV EQUALS XKEP
|
||
|
|
||
|
|
||
|
# LAMBERT SUBROUTINE
|
||
|
#
|
||
|
# INPUT --
|
||
|
# R1VEC ERASE +5
|
||
|
# R2VEC ERASE +5
|
||
|
# TDESIRED ERASE +1
|
||
|
# GEOMSGN ERASE +0
|
||
|
# GUESSW # 0 IF COGA GUESS AVIABLE, 1 IF NOT
|
||
|
# COGA ERASE +1 # INPUT ONLY IF GUESS IS ZERO.
|
||
|
# NORMSW # 0 IF UN TO BE COMPUTED, 1 IF UN INPUT
|
||
|
# UN ERASE +5 # ONLY USED IF NORMSW IS 1
|
||
|
# VTARGTAG ERASE +0
|
||
|
# TWEEKIT EQUALS 40D # ONLY USED IF GUESSW IS 0
|
||
|
|
||
|
# OUTPUT --
|
||
|
# VTARGET ERASE +5 # AVAILABLE ONLY IF VTARGTAG IS ZERO.
|
||
|
# V1VEC EQUALS MPAC
|
||
|
|
||
|
# DEBRIS --
|
||
|
# RTNLAMB ERASE +0
|
||
|
# U2 ERASE +5
|
||
|
# MAGVEC2 ERASE +1
|
||
|
# UR1 ERASE +5
|
||
|
# R1 EQUALS 31D
|
||
|
# UN ERASE +5
|
||
|
# SNTH ERASE +1
|
||
|
# CSTH ERASE +1
|
||
|
# 1-CSTH ERASE +1
|
||
|
# CSTH-RHO ERASE +1
|
||
|
|
||
|
COGAMAX EQUALS 14D # CLOBBERS 1/MU
|
||
|
COGAMIN EQUALS 8D
|
||
|
DCOGA EQUALS 12D
|
||
|
|
||
|
# TWEEKIT EQUALS 40D
|
||
|
# P ERASE +1
|
||
|
# Page 1307
|
||
|
# COGA ERASE +1
|
||
|
# R1A ERASE +1
|
||
|
# X EQUALS 20D
|
||
|
# XSQ EQUALS 22D
|
||
|
# XI EQUALS 24D
|
||
|
# S(XI) EQUALS 26D
|
||
|
# XSQC(XI) EQUALS 28D
|
||
|
# T EQUALS 30D
|
||
|
# KEPC1 EQUALS 34D
|
||
|
# KEPC2 EQUALS 36D
|
||
|
# SLOPSW
|
||
|
# SOLNSW
|
||
|
|
||
|
# OTHERS --
|
||
|
# RVEC EQUALS R1VEC
|
||
|
# VVEC ERASE +5
|
||
|
# COGAFLAG
|
||
|
# RVSW
|
||
|
# INFINFLG
|
||
|
# APSESW
|
||
|
# 360SW
|
||
|
# RTNTT EQUALS RTNLAMB
|
||
|
# ECC ERASE +1
|
||
|
# RTNTR EQUALS RTNLAMB
|
||
|
# RTNAPSE EQUALS RTNLAMB
|
||
|
# R2 EQUALS MAGVEC2
|
||
|
|
||
|
COSF EQUALS 24D
|
||
|
|
||
|
# RTNPRM ERASE +0
|
||
|
# SCNRDOT ERASE +0
|
||
|
# RDESIRED ERASE +1
|
||
|
|
||
|
|
||
|
# ITERATOR SUBROUTINE
|
||
|
|
||
|
# ORDERSW
|
||
|
MAX EQUALS 14D # CLOBBERS 1/MU
|
||
|
MIN EQUALS 8D
|
||
|
|
||
|
# INDEP ERASE +1
|
||
|
|
||
|
DELINDEP EQUALS 12D
|
||
|
ITERCTR EQUALS 22D
|
||
|
DEP EQUALS 30D
|
||
|
|
||
|
# DELDEP ERASE +1
|
||
|
# DEPREV ERASE +1
|
||
|
|
||
|
TWEEKIT EQUALS 40D
|
||
|
|
||
|
|
||
|
# MORE KEPLER
|
||
|
|
||
|
# EPSILONT ERASE +1
|
||
|
|
||
|
# Page 1308
|
||
|
# MORE LAMBERT
|
||
|
|
||
|
# TERRLAMB EQUALS DELDEP
|
||
|
# TPREV EQUALS DEPREV
|
||
|
|
||
|
# EPSILONL EQUALS EPSILONT +2 # DOUBLE PRECISION WORD
|
||
|
|
||
|
|