Proof ORBITAL_INTEGRATION #229 (#389)

* Proof FIXED_FIXED_CONSTANT_POOL (#207)

* wip(p1338/1354: DONE): Proof ORBITAL_INTEGRATION #229

* wip(p1354/1354: DONE): Proof ORBITAL_INTEGRATION #229

Comanche055/ORBITAL_INTEGRATION.agc

@@ -42,15 +42,15 @@
 KEPPREP		LXA,2	SETPD
 			PBODY
 			0
-		DLOAD*	SQRT		# SQRT(MU) (+18 OR +15)		0D	PL 2D
+		DLOAD*	SQRT		# SQRT(MU) (+18 OR +15) 0D		PL 2D
 			MUEARTH,2
 		PDVL	UNIT		#					PL 8D
 			RCV
-		PDDL	NORM		# NORM R (+29 OR +27 - N1)	2D	PL 4D
+		PDDL	NORM		# NORM R (+29 OR +27 - N1) 2D		PL 4D
 			36D
 			X1
 		PDVL
-		DOT	PDDL		# F*SQRT(MU) (+7 OR +5) 	4D	PL 6D
+		DOT	PDDL		# F*SQRT(MU)(+7 OR +5) 4D	PL 6D
 			VCV
 			TAU.		# (+28)
 		DSU	NORM
@@ -59,25 +59,25 @@ KEPPREP		LXA,2	SETPD
 		SR1
 		DDV	PDDL
 			2D
-		DMP	PUSH		# FS (+6 +N1-N2) 		6D	PL 8D
+		DMP	PUSH		# FS(+6 +N1-N2) 6D		PL 8D
 			4D
-		DSQ	PDDL		# (FS)SQ (+12 +2(N1-N2))	8D	PL 10D
+		DSQ	PDDL		# (FS)SQ(+12 +2(N1-N2)) 8D	PL 10D
 			4D
-		DSQ	PDDL*		# SSQ/MU (-2 OR +2(N1-N2))	10D	PL 12D
+		DSQ	PDDL*		# SSQ/MU(-2OR +2(N1-N2)) 10D		PL 12D
 			MUEARTH,2
 		SR3	SR4
-		PDVL	VSQ		# PREALIGN MU (+43 OR +37) 	12D	PL 14D
+		PDVL	VSQ		# PREALIGN MU (+43 OR +37) 12D	PL 14D
 			VCV
-		DMP	BDSU		#					PL 12D
+		DMP	BDSU		#				PL 12D
 			36D
-		DDV	DMP		#					PL 10D
+		DDV	DMP		#				PL 10D
-			2D		# -(1/R-ALPHA) (+12 +3N1-2N2)
+			2D		# -(1/R-ALPHA)(+12 +3N1-2N2)
 		DMP	SL*
 			DP2/3
-			0 	-3,1	# 10L(1/R-ALPHA) (+13 +2(N1-N2))
+			0 	-3,1	# 10L(1/R-ALPHA)(+13 +2(N1-N2))
-		XSU,1	DAD		# 2(FS)SQ - ETCETERA			PL 8D
+		XSU,1	DAD		# 2(FS)SQ - ETCETERA	PL 8D
 			S1		# X1 = N2-N1
-		SL*	DSU		# -FS+2(FS)SQ ETC (+6 +N1-N2)		PL 6D
+		SL*	DSU		# -FS+2(FS)SQ ETC (+6 +N1-N2)	PL 6D
 			8D,1
 		DMP	DMP
 			0D
@@ -85,8 +85,8 @@ KEPPREP		LXA,2	SETPD
 		SL*	SL*
 # Page 1335
 			8D,1
-			0,1		# S(-FS(1-2FS)-1/6...) (+17 OR +16)
+			0,1		# S(-FS(1-2FS)-1/6...)(+17 OR +16)
-		DAD	PDDL		#					PL 6D
+		DAD	PDDL		#				PL 6D
 			XKEP
 		DMP	SL*		# S(+17 OR +16)
 			0D
@@ -325,7 +325,6 @@ INT-ABRT	EXIT
 # THE OBLATE ROUTINE COMPUTES THE ACCELERATION DUE TO OBLATENESS.  IT USES THE UNIT OF THE VEHICLE
 # POSITION VECTOR FOUND IN ALPHAV AND THE DISTANCE TO THE CENTER IN ALPHAM.  THIS IS ADDED TO THE SUM OF THE
 # DISTURBING ACCELERATIONS IN FV AND THE PROPER DIFEQ STAGE IS CALLED VIA X1.
-
 OBLATE		LXA,2	DLOAD
 			PBODY
 			ALPHAM
@@ -349,7 +348,7 @@ OBLATE		LXA,2	DLOAD
 		VAD	VXM
 			ZUNIT
 			MMATRIX
-		UNIT			# PROBABLY UNNECESSARY.
+		UNIT			# POSSIBLY UNNECESSARY
 COMTERM		STORE	UZ
 		DLOAD	DMPR
 			COSPHI/2
@@ -378,7 +377,7 @@ COMTERM		STORE	UZ
 		DMP*
 			J4REQ/J3,2
 		DDV	DAD		#              -3
-			ALPHAM		# (((P5/256)B 2  /R+P4/32)  /R+P3/8)ALPHAV
+			ALPHAM		# (((P5/256)B 2 /R+P4/32)  /R+P3/8)ALPHAV
 			4		#            4             3
 		DMPR*	DDV
 			2J3RE/J2,2
@@ -390,9 +389,9 @@ COMTERM		STORE	UZ
 		DMP*	SR1
 			J4REQ/J3,2
 		DDV	DAD
-			ALPHAM
+			ALPHAM		#			-3
 		DMPR*	SR3
-			2J3RE/J2,2
+			2J3RE/J2,2	#	3	4
 		DDV	DAD
 			ALPHAM
 		VXSC	VSL1
@@ -423,7 +422,7 @@ COMTERM		STORE	UZ
 			QUALITY1
 QUALITY3	DSQ			# J22 TERM X R**4 IN 2D.  SCALED B61
 					# AS VECTOR.
-		PUSH	DMP		# STORE COSPHI**2 SCALED B2 IN 8D.
+		PUSH	DMP		# STORE COSPHI**2 SCALED B2 IN 8D
 # Page 1343
 			5/8		# 5 SCALED B3
 		PDDL	SR2		# PUT 5 COSPHI**2, D5, IN 8D. GET
@@ -450,14 +449,14 @@ QUALITY3	DSQ			# J22 TERM X R**4 IN 2D.  SCALED B61
 			5/8		# 5 B3 ANSWER B5
 		SL1	DAD		# FROM 12D FOR Z COMPONENT (SL1 GIVES 10
 					# INSTEAD OF 5 FOR COEFFICIENT)
-		PDDL	NORM		# BACK INTO 12D FOR Z COMPONENT
+		PDDL	NORM		# BACK INTO 12D FOR Z COMPONENT.
 			ALPHAM		# SCALED B27 FOR MOON
 			X2
 		PUSH	SLOAD		# STORE IN 14D, DESTROYING URPV
 					# X COMPONENT
 			E32C31RM
 		DDV	VXSC		# IF X2 = 0, DIVISION GIVES B53, VXSC
-					# out of 8D B5 GIVES B58
+					# OUT OF 8D B5 GIVES B58
 		VSL*	VAD		# SHIFT MAKES B61, FOR ADDITION OF
 					# VECTOR IN 2D
 			0	-3,2
@@ -471,7 +470,7 @@ QUALITY3	DSQ			# J22 TERM X R**4 IN 2D.  SCALED B61
 					# ALONE.
 			PBODY
 			RP-TO-R
-		VAD	BOV		# OVERFLOW INDICATOR RESET IN *RP-TO-R*
+		VAD	BOV		# OVERFLOW INDICATOR RESET IN "RP-TO-R"
 			FV
 			GOBAQUE
 		STORE	FV
@@ -617,6 +616,7 @@ ORIGCHNG	STQ	CALL
 # THE RECTIFY SUBROUTINE IS CALLED BY THE INTEGRATION PROGRAM AND OCCASIONALLY BY THE MEASUREMENT INCORPORATION
 # ROUTINES TO ESTABLISH A NEW CONIC.
 
+
 RECTIFY		LXA,2	VLOAD
 			PBODY
 			TDELTAV
@@ -640,9 +640,8 @@ MINIRECT	STORE	VRECT
 		RVQ
 
 # Page 1348
-# THE THREE DIFEQ ROUTINES -- DIFEQ+0, DIFEQ+12, DIFEQ+24 -- ARE ENTERED TO PROCESS THE CONTRIBUTIONS AT THE
+# THE THREE DIFEQ ROUTINES - DIFEQ+0, DIFEQ+12, DIFEQ+24 - ARE ENTEREDTO PROCESS THE CONTRIBUTIONS AT THE
 # BEGINNING, MIDDLE, AND END OF THE TIMESTEP, RESPECTIVELY.  THE UPDATING IS DONE BY THE NYSTROM METHOD.
-
 DIFEQ+0		VLOAD	VSR3
 			FV
 		STCALL	PHIV
@@ -782,7 +781,7 @@ DIFEQCOM	DLOAD	DAD		# INCREMENT H AND DIFEQCNT.
 			FBR3
 
 WMATEND		CLEAR	CLEAR
-			DIM0FLAG	# DON'T INTEGRATE W THIS TIME
+			DIM0FLAG	# DONT INTEGRATE W THIS TIME
 			ORBWFLAG	# INVALIDATE W
 		CLEAR
 			RENDWFLG
@@ -797,9 +796,8 @@ WMATEND		CLEAR	CLEAR
 
 # Page 1352
 # ORBITAL ROUTINE FOR EXTRAPOLATION OF THE W MATRIX.  IT COMPUTES THE SECOND DERIVATIVE OF EACH COLUMN POSITION
-# VECTOR OF THE MATRIX AND CALLS THE NYSTROM INTEGRATION ROUTINES TO SOLVE THE DIFFERENTIAL EQUATIONS.  THE PROGRAM
+# VECTOR OF THE MATRIX AND CALLS THE NYSTROM INTEGRATION ROUTINES TO SOLVETHE DIFFERENTIAL EQUATIONS.  THE PROGRAM
-# USES A TABLE OF VEHICLE POSITION VECTORS COMPUTED DURING THE INTEGRATION OF THE VEHICLE'S POSITION AND VELOCITY.
+# USES A TABLE OF VEHICLE POSITION VECTORS COMPUTED DURING THE INTEGRATION OF THE VEHICLES POSITION AND VELOCITY.
-
 DOW..		LXA,2	DLOAD*
 			PBODY
 			MUEARTH,2
@@ -944,6 +942,3 @@ URPV		EQUALS	14D
 COSPHI/2	EQUALS	URPV 	+4
 UZ		EQUALS	20D
 TVEC		EQUALS	26D
-
-
-