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Li51/1

LESSON 151 - Astrology 4

DIRECT METHOD OF HOROSCOPE CALCULATION TO CALCULATE THE SIGNS ON THE CUSPS STEP A 1. 2. 3. 4.

Example Write Write Write Write

down BIRTH date down BIRTH' place down LATITUDE of birth place down LONGITUDE of birth place

e .g . 21/6/82 HASTINGS, 39 0 SOUTH 40' 176° EAST 52'

Step Al G6eum_ Obtained from the person or subject the chart is being calculated for . e .g . Date of birth, inception or happening . Step A2 The town, city or area of birth, inception, or happening occurred, again obtained by the person or subject . Step A3 The Geographical Latitude of birth place obtained from a map . Step A4 The Geographical Longitude of birth place obtained from a map .

w

STEP B I. 2. 3.

Hours Mins Secs Write down BIRTH TIME as given Write down ZONE STANDARD Write Summer (or double) time*

01 12

04 00

00 00

a .m ./teal.,* E-/,H+*

Greenwich Mean Time (G .M .T .) 04 00 -a m ./p .m .* 01 GMT date 20/6/82 e.rm../p .m .* Step 81 CL6a' c Birth time or exact time of happening or birth or subject in concern . 4.

I 1 I 1

Step 82 ZONE STANDARD is the standard longitude time zone each country operates under from Greenwich, England . e .g . Greenwich England is 00 degrees longitude, every 15 degrees of longitude west of Greenwich is PLUS one hour of time, thus 30 degrees West Long . would be 2 hours behind Greenwich . Now, for East of Greenwich, every 15 degrees would be minus one hour of time so 30 degrees East Long . would be 2 hours ahead of Greenwich . So in our example, N .Z . being in the 12 hour standard time zone East of Greenwich, we MINUS 12 hours from the LOCAL BIRTH TIME . Step 83 If the birth took place during summer, or double time (daylight saving) allowance must be made by subtracting the appropriate time that was added to the zone clocks . Step 84 The result of the calculations being the birth time as it would have been at Greenwich meantime, (GMT) . Because the result was the product of subtracting in this example, 1 .04p .m . GMT would be the day before the birth date LOCAL time, therefore GMT birth is 1 .04p .m . on 20/6/82 GMT date .

L151/ 2 2 time used in the following the calculation of planetary is also used in This result calculations . . positions which will be explained later This final result

1 1 f 1 I

Hours Mins Secs

STEP C 1. 2.

05 Write in SIDEREAL TIME *noon/midnight GMT Write to INTERVAL ne/From, *noon/fit 01

53

29

04

00

06

57

29

RESULT 3. 4. 5. 6.

8. 9.

1

of birth time is the

Write in the Acceleration on INTERVAL (Step C2) 10 seconds per hour

10

Which equals SIDEREAL TIME at Greenwich at birth Write in LONGITUDE TIME EQUIVALENT Add 12 hours for the Southern Hemisphere ^ •) births (rw% sac assa=~ 9--

+

LOCAL SIDEREAL TIME AT BIRTH Subtract 24 hours if necessary

-

RESULT Carry over seconds to minutes, mins to hours if necessary

FINAL LOCAL SIDEREAL TIME in this example

is

a.sa .-/p .m .+ *

06 11

57 47

39 00 E+/yl!

12

00

00

29 24

104 00

39 .00

= 05

104

39

= 06

-44

39,

06

44

39

Step Cl - O. ovut . Is obtained from an EPHEMERIS . Locate the year of birth and the pages of the month , of birth, then locate the "GMT date" as explained in Step 84 . Under the column named 'Sidereal Time' you will find the hours, minutes and seconds alongside the GMT date . See Table (i)(A' .

f

There may be times when you will use a midnight ephemeris . The same procedure is adopted . Step C2 This is the time difference between the GMT and NOON as shown in our e xample . 1 .04p .m . i s 1 hour and four minutes past the noon which the ST (Sidereal time) was taken from, so this is added .

1 t 1 I

Please make special note : If using a midnight ephemeris, the probable If a MN Ephemeris was used in this ST used would be from Midnight (MN) . example, midnight of the 21st is 00 :00 :00 hours 21st, not 24 :00 :00 hours - 2400 hours, therefore the GMT is subtracted, 1 .04p .m . on the 20th being within the 12 hour zone, and before t he . S T of MN 21st . BUT take You must care not to subtract the actual 1 hour and four minutes . subtract the DIFFERENCE between 1 .04p .m . 20th and MN 21st . In this case the answer w uld be 10 h urs and 56 minutes .' Of c urse if the GMT was 1 .04 a .m . 21st there w uld nly have been lhr 4mins difference between the MN and GMT time, s this figure w uld be used . The F r F r F r F r

rule is :n n ephemeris, if GMT is a .m . subtract the difference . n n ephemeris, if GMT is p .m . add the .difference . MN ephemeris, if GMT is a .m . add the difference . MN ephemeris, if GMT is p .m . subtract the difference .

so

am

00

00

00

am

wo

Own

401

0*

vi ar 9 0 v 0 8

21 22 23 24 25

0

0

0 Lon .

0 Dec .

JUNE, 1982

RAPHAEL'S 13ec

) L

4 38 3410n40 22N 12=44 3NI OS I I3wl 19¢ 1 1 2S3 3 S 111126 7 1 4 42 31 11 37 31 22 1125 1S Its 4 9 3 IS 13 39 3811 3 4 46 2 12 34 S 22 1 71434 4 1313 3 15 23 44 1115 2 4 50 2 13 32 2 22 2 19 42 55 4 34 21 14 29 22 32 1 43 3 3 2 17 14 5 7 41 3 18 35 2 3 19 S1 4 5419 33 34 20 S5 4 58 1715 27 1 22 3 13 38 5 2 1416 24 3922 45 23 28 11 1 3 21 4 4 51 11122 15 22 2 22 9 3 22 4( 5 6 1 17 22 71116 2 N3 22 41 4 4813 22 1 S 10 18 19 22 22 5 19 4 5 S3122 3 4 4 24 39 S 14 319 16 4 23 1 0=55 121 3 21 4 41 6=52 5 20 33 20 14 12 S2 4(2 3(19 2( 18 S3 18 4 S 21 5 21 11 24 23 25 0 3 3 3 16 2 4 3 1)1 9 1 14 42 8 43 23 1 7)(22 44 1 12 4 4 3213 40 31 10 38 3 25 S322 23 6 2 23 1 20 3 2 8 2 4 2 26 31 5 6 5 29 5 33 4 24 3 21 3r 6 35S 113S 31 4 2 9r47 34 0S S7 4 2 23 29 3 4 N18 5 37 43 25 0 3 23 21 16 33 12 1 N 6 5 4 1 7 d 38 4 9 31 3 41 3 25 57 5 23 23 0 u 30 5 12 4 1 22 13 14 21 5 45 3 26 SS 1523 2414 53 1 16 31 4 1 7 n 7 4(18 25 S2 3323 2 29 38 1 23 2 14a40 33 20 2 4 1 22 IS 31 21 1 2~ Q~ 49 S S7 2 29D47 23 2 ISI 4 7=27 1 22 41 6 1 2 Oao44 23 23 2 1S® 1 4 22 33 2 22 21 1 N 4 7Q23 2120 6 5 1 1 41 3 23 2 OR 1 3 1 31 3 5 21 56 3 17 1 6 9 1 5 2 38 55 23 2 14 43 S . 2 4 3 S 6np 3 1713 12 6 13 1 3 36 1 23 2 29 3 1 3 47

•

IONI ION) t0 S 11 21 11 4 12 12 2 12 5 113 1 13 3 7 213 3 I4 1 17 18 22 4 1 17 1 1 5 1 14 21 15 5 17 1 1 5 IS 411 16 1 15 17 2 16 21 9 17 4 1 5416 4 16 5 21 3 5917 1 5117 17 17 3 23 3 4 18 IS t8 ( 4 17 53 t8 18 2 2 3 2918 44 1 4518 27 18 43 1 2 3 1019 16 19 - 1 4118 59 19NI 19 .34 1 2 4919 31 3719 29 2S3820N 9 1S3 19N44 FIRST QUARTER-June 28 . S6.

Y

ON3 0 3 0 2 0 2 0 2 0 1( 0 1 0 0 ON ,

OS 3 0 3 OS 1 1 1 2 1 3 1 41 1 5 1 3 2 1 2 8 2 3 2 2 2 S5 2 4 3 15 3 3 3 3 2 3 5 3 4 OS 0 1 1 4 2 0 4 4 4 0 11 S 2 4SSI OS12 SS14 36m . a .m . (6° = 13)

1 1 1 1 1 1 1 1 1 1 1

N22 21 21 2 2 1 1 1 1 1 17 1 1 IS 1 IS 1 14 INI

IOS 42 10 10 37 10 35 10 33 10 32 10 10 29 10 28 10 27 10 27 10 27 10 27 10 27 10 28 IOS28

on"

4w

0 .0

oft

FULL Moow-June 6, 3h . 59m . p .m. (1S' 1 37')

NEW Mot*w-June 21, Ilk. 52m . a.m. (29' n 41') 12 I D Slderea MW Time

am

1

EPIIEMERIS) ff

I. Lon

e

d Lon . Lon

21 Lon

Il u 10 113

JUNE, 1982 1 If '$ Lon Lon . Lon .

1 tJ 53 2=S 10$27153 1 112 1344 3 2 3 10 2 4 12 3 21 1 1 1 5 41 9 31 5 2 3 3 1 1 15 4 1 5 6 31 3 52 1 1 13 3 1 13 3 8 3 7 41 4 IS 3 8 8 S1 4 2 1 7 4 10 1 4 4 0 3 15 3 2 11 1 4 5 0 5 3 3 7 12 21 3 1 0 S . 15 3 _ I3 3i -5-3 - 0 IS 3 6 6 4 14 4 5 5 0 4 15 3 6 3 15 52 6 14 0 4 1S 31 6D3817 6' 3 0 4 15 31 6 4218 1 6 5 0 1$ 6 3 19 2 7 1 0 3 IS 3, 7 20 3 7 3 0 3 13 .r a 7 221 447 0 313 7 4 22 5 8 2 0 3 1 3 D3 + 8 1 24 8 4 0 31 15 8 4 .21 1' 9 0 3 IS 9 23 26 2 9 2 0 2 IS 31 10 27 3 9 S1 0 2 1S 31 10 4 28 4810 1 0 2 1 5 3 11 3 29 5' 10 3 0 2 15 3 0 2 , 15 3 2 12 3 l111 11 13 2 2 21 11 2 0 2 1S 3 2 14 31 3 3 II 54 0D2 . 13 3 2' 15 3 4 4312 1 0 2 IS 3 16a4 . SnS 12-4 Out 27 1S=3 r Saturn M Lat . Dec . . 12N39 2 39 2 38 2 38 2 37 11231 1 2 36 1 2 36 1 2 35 1 2 35 21 34 2 2 34 2 2 33 2 2 33 2 2 32 3 2N32

Uranus

3S45 3 44 3 43 3 43 3 42 342 3 42 3 42 1 3 43 3 43 3 44 ' 3 45 3 4( 3 47 3 48' 3S 49' N LAST

L

Lon

Lunar Aspects

13

'

24-2 A 0211 261 2141 2611 24 11240 0 d 2 12 26 24 2 L 2 26 124 .22 ~t 2 72S 5 24 21 V 24 2,1 2 4 L 2 223 3 24 1 d" 2 1 25 5 24 1 ~t 1 5 2S 5 24 1 L 1 1 5 23 5124 1 9 V 5 23 ' 24 1 /_ 1 25 4 24 1 • 4 :125 4(24 1 Q 4(2S 4 24 1 1 4 .25 4 24 1 4123 4124 1 3' 25 4 24 1 A d 32S 324 I1 1. Q 3 25 3 24 11 Y 3223 3 24 1 Q 1 3 24 1 d d d 12 2S 32 24 1 1 2 25 24 St 1 1 2 23 2 24 L Q 1 2 25 2 24 r 1 2 25 2 24 O ~1 L 1t ' 1 1 25 2 24 t * U >< 1 1 .25 2 24 0 A d d 1 1 25 2124 Q L +' d AQ 11 1 2511 124d u L

Nc tune

Pluto Lat . Dec .

Mutual As

Is

• *,qfj :~ ra.+Ir ++~ too* 20S291H1922S 417N2 6N4 417 2 6 4 20 271 1922 417 2 6 4 20 261 1922 20 251 1922 417 2 6 4 ;; 0 . ' i . 20 241 1922 417 2 6 4 317 2. 6 4 20 23i-1-9 22 317 2 6 4 ;', .rA~.p~_a1A 20 221 1922 317 21 6 4 20 211 1922 ,', •; Co M., u ~ ~ y,+ a, at'. 1, 5" 3 17 2 6 4 20 201 1922 317 1 6 4 20 •201 1922 117 1 6 4 20 191 1922 20 181 1922 317 1 6 4 20 171 1922 317 1 6 4 317 1 6 42 20 11 1922 317 16 41 20 1 1 1922 20S 151 N1922S 317NI 6N4' QUARTER-JUne 14 . 6h. 6m. p .m . (23' )( 21 ')

L151/4

r if the GMT is bef re the ST subtract the difference, if the GMT is after the ST, add the difference .

A I f t

Step C3 F r every h ur subtracted sec nds per h ur is als initially .

r added fr m/t the ST e .g . Step C2, ten subtracted r added, whatever t k place

e .g . 4 h urs and 30 minutes = 45 sec nds 4 h urs = 40 sec nds (10 sec nds per h ur) 30 minutes = 5 sec nds (half f 1 h ur = half

f 10 sec nds) .

Step C4 Which equals ST at Greenwich at birth . S we n w have the exact ST if birth had happened at Greenwich . Next is t c nvert this back t l cal time . Step C5 L ngitude time equivalent is btained fr m Step A4, 176° East 52' . T f c nvert this t time, each degree f l ngitude equals f ur minutes man time . S : 176° 52' x 4' = 11 h urs 47 minutes . Step C6 Self explanat ry . Step C7 The result being l cal ST at birth . Once the calculati ns g t the exact GMT ST at birth then the necessary calculati ns c uld be made t btain the LOCAL ST at birth .

1 t 1 t

Step C8 There are nly 24 h urs in a day s any calculati n 24 h urs and has 24 h urs subtracted t get the final calculati n .

Step C9 Sec nds and minutes w rk n the N . 60 ; each 60 sec nds aut matically bec me 1 minute and each 60 minutes aut matically bec mes 1 h ur .

STEP 0

Example

1. 2.

Carry f rward y ur final ST result 06 :44 :39 Carry f rward y ur Latitude fr m Step A3 39° SOUTH 40'

3.

Using

the "Tables

f H uses"

pen up

at the page f r latitude 39 0 40'

( r latitude nearest) . 4.

I

ver

L cate in the "Sidereal Time" C lumn y ur SI result (See Table (i)(b) . Y u will find the ST nearest y ur ST using ur example, is 6 :43 :31 . This will be the figure y u will w rk fr m . N te als the difference between : 06 :44 :39 06 :43 :31 in the event

= 00 :01 :08 f wanting m re accurate results .

- .-

--

Table (i)(b)

-_-- _-

"Raphael's Tables o f Houses for Northern Latitudes" W. Foulsham & Co Ltd, England.

-

5

5.

Follow your f i n g e r along t h e l i n e from 06:43:31 numbers w i l l read: 10/13/13/8.42/6/6.

and t h e

following

Now look a t t h e headings above t h e columns, then run your eye down each column and see i f a z o d i a c s i g n changes b e f o r e your ST, then form your new l i n e f o r t h e headings. ST

10

Change a t 6:13:5 Change a t 6:17:26 Result #Now Convert t o Southern hem., e.g. a l l s i g n s a r e changed t o t h e i r opposite signs Place i n degrees a s noted along your ST l i n e

s

Y

12

Ascen

9 -

2

a

r?y, Jv

rVm

X

n/

n/ .

T

8

=

8.42

6

6

.

10

13

13

-

# only i f c a l c u l a t i o n s have been made f o r a Southern L a t i t u d e b i r t h .

norH,n

b&p\nutc

%.-a

-7

-'*%\.n\ rrr-\+.

N w , t h e 10 a t t h e t o p of t h e column means t h e 1 0 t h house (10th c u s p ) , t h e 11

(11th c u s p ) , t h e 1 2 ( 1 2 t h c u s p ) , t h e Ascen is t h e ascendant which is t h e 1st cusp, t h e 2 (2nd c u s p ) , t h e 3 ( t h e 3rd cusp). 6.

Follow your e y e s down t h e columns and you w i l l s e e t h e r e s u l t s are:1 0 t h cusp is 10° 'V? 1 1 t h cusp is 1 3 O 1 2 t h cusp is 1 3 O # Ascen is 80T42 2nd cusp is 6O 8 3rd cusp is 6O

STEP E Carry forward Step 06 f o r u s e i n t h i s s t e p . On your horoscope wheel p l a c e t h e s e s i g n s and t h e i r degrees onto t h e cusps o f t h e houses which they have been a l o t t e d t o . See diagram I Sau A c v m x

T h e n ~ f o l l o w i n n a t u r a l progression around t h e wheel t h e o t h e r s i g n s o f t h e zodiac along with t h e degrees o f t h e s i g n s o p p o s i t e them. I t is important t h a t t h e s i g n s o p p o s i t e each o t h e r a r e t h e ones o r d i n a r i l y o p p o s i t e i n n a t u r a l progression; f o r t h e c a s e o f i n t e r c e p t e d houses see diagram IIX

BlRTH CHART

PROGRESSED DATA

D

M

Y

Noon poddons on

Rog .

Corr8q-d

Noon

1B-

-

O ma m-

Firm

-l.d

Air

De&lamm-

Water-

Fall

NAME

No. 2

- 7710 **HOUSES'Chn. DIRECT METHOD

t

aaea

u

(1)

No. Deaagned by M.E.HONE.

PROGRESSED DATA

kog. Noon

-Triplicities:-

Ph

O m dgn-

Air

W a r . ?

Pa

0u+drupliuUties :C a r d i n a l, . -nA Fixad Suawdwt-

BY DIRECT

-OD I n l Y 1

Sd. oar rr G Y T .

l a a r ~ rW l m O M ru p.m. +

hhm..c*rr~rumI

Ud. Ur,

a1 Gt-rrL

as bmb

L.IOll.4. . q ~ l v a k l t 4.e LOCAL sm.m

NAME

No. 2

- fh. " H O W Chrr DfRECT METHOD

-

W-

e AT arm

No. D a g n e d by M.E.HONE.

T.

TO CALCULATE THE PLANETARY POSITIONS

(Note: 1 . 0 4 ~.m.

Using 'Tables o f D i u r n a l Planetary Motion',published by American Federation o f Astrologers, Arizona. Carry forward GMT o f b i r t h e.g. i n t h e example used t h e GMT was

There a r e two types o f t a b l e s t o use. TABLE

The format i n each a r e t h e same.

1: (For t h e c a l c u l a t i o n of t h e Sun's p o s i t i o n ONLY)

STEP 1 Open up your date. Note Ift h e time date before date you w i l

ephemeris again a t t h e b i r t h date and month, l o c a t e t h e GMT whether t h e GMT b i r t h time i s b e f o r e o r a f t e r t h e GMT date. i s b e f o r e 12 noon o f t h e date,you w i l l be working w i t h t h e t h e GMT date, i f t h e GMT b i r t h t i m e i s a f t e r 12 noon GMT l be working w i t h t h e date a f t e r t h e GMT date.

Our example f o l l o w s :

Refer t o example page of ephemeris, t a b l e

GMT b i r t h time and d a t e was 1.04p.m. 20/6/82. hour motion between 20/6/82 and 21/6/82.,

( 5 )(a)

LC\-.

We want t o know t h e sunk 24

From t h e ephemeris, t h e Sun column shows on 21 June 1982 t h a t t h e Sun i s i n ZL 29O 47' 07" and on 20th June 1982 Sun i s i n 28O 49' 50" With t h i s p a r t i c u l a r example, t o s u b t r a c t t h e 20th from t h e 21st we w i l l have t o c a r r y some hours and minutes over. Example 0

- 2828 a 10649

Then we s u b t r a c t

.-

1

Result being d i f f e r e n c e and t h e distance t h e sun t r a v e l l e d i n 24 hours from noon 20th t o noon 21st.

00

57

I'

67 50 17

6;)

Now l o o k up i n Table &) bc\or. . t h e column which heads t h e numbers 57' 17". Apparently t h e r e i s n ' t one so we go t o t h e nearest number (57 * 101@). Now remember t h e GMT b i r t h t i m e on t h e 20th was 1 h r and 4 mins so t a k i n g t h e Four minutes go t o t h e ' 4 ' under t h e heading "Time 0 Hours Minw then Follow t h e rank over u n t i l you a r e under t h e 57' 18" column. The answer w i l l be 0'1OW. Then under t h e column "hoursN go t o t h e 1 hour time of b i r t h then across t o 57' 18" and you w i l l have 2' 23". ~ d these d together

"Raphael's Astronomical Ephemeris of Planets' Places for 1982", W. Foulsham &

I

I

The 0 Hours

* ,

Mln

TABLE l RATE DF 24-HOUR MOTION

:

TABLE l F 24-HOUR YO1 ION 0 Hours 57 06

i5?

4?

8

1 51 1 53 1 55 158 200

7 8 9 10

2 02 2 05 2 07 2 10 2 12

1

6 11 12 13 14 15 16 17 18 19 20 21

n

23 24 25 28 27 28 29

30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45

2 14 2 17 2 19 222 2 24

Add t h e r e s u l t ( 2 ' 33") t o t h e Sun's p o s i t i o n b e f o r e t h e time o f b i r t h . I n t h i s case i t i s t h e p o s i t i o n on t h e 20th. 2 8 O Z 49' 50''

0

Carry mins and secs over

28O

52' 23"

Now check down t h e sun column i n t h e ephemeris f o r t h e zodiac s i g n t h e sun i s i n on t h e GMT day.Our example shows: .

0 28O x

Therefore the answer i s i.e.

5 2 ' 23"

t h e sun i s 28 degrees Gemini, 52 minutes and 93 seconds.

a 2E0

52' 23" w i l l be t r a n s f e r e d t o your horoscope.

TABLE I1 ( f o r a l l o t h e r p l a n e t s ) Same method as for Table I. Carry forward 1.04p.m. For t h e Moon:-

~ and (ii>(d)) (see t a b l (ii)(c)

=on 21st 29O 51 ' 30' Carry over Sec D o n 20th 14O x 40' 33" inu us Result, motion o f moon i n 24 hours Looking up heading i n Table I1 of 15

Carry Over

29O

-=15O 14

* 50 ' 90 '' 40 33 1012/"

11'

40' 29"

Add t o the 20th Moon p o s i t i o n e.g. remember t h e moon has moved from noon 20th so t h e motion must be added t o get the p o s i t i o n a t b i r t h .

14'-

+

=

40' 33" 40' 29"

14O %8O1

62"

15O Jl2 21' 02" This f i g u r e i s transfered t o t h e horoscope.

which equals

For Mercury:-

hours.

(see Table i i i and t a b l e i v )

On l o o k i n g down t h e Mercury column you w i l l see an 8 and a D. Mercury had gone Retrograde i n motion then D i r e c t i n motion befo-re t h e GMT date, t h e r e f o r e t h e p l a n e t motion would be d i r e c t and the c a l c u l a t i o n made as above.

$ on

20th 24hr motion being

- 8'

O0

14' 32'

"Raphael's Astronomical Ephemeris o f Planets1 Places for 1982", W. Foulsham & Co, England.

156

TABLE ll RATE-OF24-HOUR MOTION 1?13'.1

1?1?.

1 2

038 118 4

& 6 7 8 S 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35

348 426 604 542 620 858 735 813 851 029 1007 1045 1123 1201 1239 13 17 1355 1433 15 11 1540 1627 1705 17 43 1821 1859 lQ37 2015 2053 21 31 2209

030 116 164 232 310 348 428 504 642 820 658 736 814 852 930

1008 1046 1124 1202 1240 13 18 1366 1434 15 12 1550 1628 1708 17 44 18 22 1900 19 38 2016 20 54 21 32 2210

036 118 154 232 310 348 426 504 642 620 858 736 816 853 931 1009 1047 1126 1203 1241 13 10 1357 1435 15 13 1551 1629 1707 17 45 18 23 1901 10 39 2017 2055 21 33 2211

lr14' 1 . 038 116 154 232 310 348 427 505 643 621 659 737 815 863 031 1009 1047 1125 1204 1242 1320 1358 1436 1514 1552 1630 1708 1746 1824 1902 1041 2019 2057 2135 2213

1?1,6'.

1?1,5'.

030 1 16 154 232 311 349 427 505 543 621 659 737 816 854 032 1010 1048 1128 1204 1242 1321 1359 1437 15 15 1563 1631 1709 17 48 1826 1004 19 42 2020 20 58 21 36 2214

030 1 18 154 233 311 349 427 505 543 622 700 738 816 854 932 1011 10 49 1127 1205 1243 1321 1400 1438 15 I6 1554 1632 17 10 17 49 18 27 1905 1043 2021 20 59 21 38 2216

1?!7'. 0% 1 16 155 233 311 349 428 506 544 822 700 738 817 855 933 1011 1050 1128 1206 1244 1322 14 01 1439 1517 1555 1633 17 12 1750 1828 1906 19 44 2023 21 01 21 39 2217

Tlme 0 Hours Mln. 46 47 48 49 50

51 52 53 54 55 58

57 58

59 60

TABLE ll RATE OF 24-HOUR MOTION



L151/15 In the table 32' column for 4' 32' column for lhr

0' 05" 1' 20" 1' 25" which is added to the Mercury position on 20th 14' 01' 25"

Mercury position at 1 .04 p .m . GMT

.l5' 25"

For Venus : 25° t5 16' 5° 24° 10 ll'

from 1° 11' column

0' 11" + 2' 57" '2' 6;2

240 8 5' 00" + 3' 09" 24°

I



6

3' 09"

8' 09"

For Mars :9°=,a= S ' ' -8 0 42' 0° 23'

from 0° 23' column 8 0 „Owh2 t 00" + 1' 01"

8° X3 9

0' 04" + 0' 57" 1' 01"

1"

For Jupiter :- Note Jupiter goes Retrograde (8:) before the 20th and 21st and turns direct after these dates, therefore. Jupiter is still considered & . In this event the last calculation is subtracted . This method is used with 20th 21st

0° My 31' - 0° 30' 1'

note less figure subtracted from greater .

No figure in 4' rank of 1' column . 2" in 1 hr rank and 1' column .

on the 20th Jupiter is 31' into scorpio . 60" (lmin) will have to be carried over to the seconds column to subtract the 2" from the tables . 20th minus

I

8

00

30' 60" 02" M030 1 58"

If there had been no apparent motion between the 20th and 21st retrograde figures, the figures in the ephemeris would be copied straight onto the horoscope and considered Retrograde Stationary (8S) .

~r

w

rr NEW M

W

S' real Time I.

21 22 23 24 25

Ma

JUNE, 1982

D

11 12 13 14 IS

r

M. S .

0 L n . '

EPHEMERISI

(RAPHAEL'S

0 Dec.

V

) L

• • •

) D

•

4 38 3410n40 22N 12-44 SNI OS I415=1 19= I I 2S) 11$ 7 1 4 42 3111 37 31 22 1123 15 3 5 111126 4 9 321S 413 39 38 11 38 4 46 2712 34 5 22 1 711134 4 4 50 2 13 32 2422 2 19 42 55 1313 3 15 23 44 1113 2 4 54 21 14 29 22 32 1 43 3 3 2 17 14 5 7 41 3 18 35 4 58 1715 27 14 22 3 13 38 2 3 19 51 14 5 19 33 34 20 3 S 2 1416 24 3 22 4 5 28 111 3721 4 14 51 11122 1 22 2 22 71116 2 N34 22 4114 4 13 9 3 22 3 6 1 17 22 18 19 22 22 5 19 4 ' 5 S3122 3 14 4 24 59 22 1 S 10 1 0=55 1 1 35 21 14 41 6=52 5 20 35 3 14 319 16 43 23 5 18 20 14 4 23 512 52 4 2 3 19 2 14 3818 55 I8 4 5 21 5 21 I l 24 23 25 0 3 3 3 16 2 14 35 1 x 9 3 14 42 5 25 53 22 8 4123 12 7H22 44 1 12 4 14 32 13 40 31 10 38 5 29 23 6 2 23 1 20 3 2 5 8 2314 2 26 31 5 6 5 33 4 24 3 21 3 18 3T 6 35S II 3S3114 25 9''47 34 OS S7 14 22 23 29 3 4N18 5 37 43 25 0 3 23 21 16 35 125 1 1 N 6 3 14 1 7 u 38 47 9 31 S 41 3 25 57 57 23 2 0 u 30 345 12 14 1 22 13 14 21 3 4S 3626 53 IS 23 2414 53 1 5 49 32 27 52 33 23 2 29 38 1 3 3 16 31 14 1 7 u 7 4( 18 25 2 14 1 22 13 31 21 1 S 33 2 8 49 23 2( 14u40 332 3220 5 57 2529u47 721 2 29 51 3 IS 1422 1314 7 a27 1 22 41 3 22 33 24 22 23 6 1 2 0ae44 23 23 2 l 5w 13 N 22 4514 711.25 2120 6 5 1 1 41 3 23 2 011 1 371 3121 3814 6 9 1 2 38 5323 2514 43 532 4 19 3 13 37 21 56 3717 6 13 12 3 36 1 23 2 29 3 1 3 4 13 21 13 5 6118 3 1713 12

p

21 23 25 27 291 3

1 N2 10S 42 12110 1 21 10 37 1 2 10 35 1 2 10 33 1 1 10 3 1 1 10 3 10 2 1 1 1 I8 10 28 I 17 10 27 1 1 10 27 3 4 1 1 10 27 10 27 4 1 1 1 4 2 1 1 5 10 27 4S51 1 14 10 28 INI 10S2

ON3 OS 3 OS4 0 0 5 0 2 1 1 0 2 1 2 1 1 1 32 0 2 1 41 1 5 0 1 1 5 0 13 2 1 2 2 0 2 3 2 4 0 2 5 ON 3 1 33 25 3 3 OS 0 0 8 0 11 0S12

3 57 4 1 4 4' 5 2 SS14

56m . a .m . (6' = 13)

L n

13

JUNE, 1982 d

4

M L n

21

L n

I

'V

L

L n . L n . L n

L n

L n

h

0

Lunar Aspects '

24-2 l_ 211 261 d 2 41 2611 24 112 YL 2 24 2 Y 2 1 26 d Y Y 2 26 1 24 .2 * 2 25 5 24 21 L 2 25 5 24 2 d 3 2 25 3 24 1 Q 4 A Y 2 25 5 24 1 0 4 11 1 5 25 5 24 1 A * Y 1 5 25 5124 170 L 1 5 24 1 il 1 5 25 4 24 1 *' 0 0 1 4 25 4 24 1 l7 0 1 4 25 4 24 1∎ A * 1 4 25 4 24 1 L Y 1 4125 41 24 1 d Q Y 1 325 424 1 d d 0 1 3 25 3 24 11 ~~;4 I= d ~~ iii Lii 5 ~~UIRLi RL= LQ Q qw I F1 w 3 A -t!ff~ ∎ Q 2 5 3 2 s' Y A L O 10 27 3 9 51 0 2 I S 31 1 2 25 3 24 * Q 10 4 28 4 10 1 0 2 1 3 32 1 2 25 2 24 A ~' 11 3 29 5 10 3 0 2 IS 3 1 2225 2 24 ∎ YLY 4 0 2 IS 33 1 2 25 2 24 2 12 34 Inl 11 A Y *OY 13 2 2 2111 2 0 2 IS 3 1 1 25 2424 A 80 d d 2 14 31 3 3 11 5 OD2 IS 3 1 1 25 2 24 Q L* d 2 IS 3 4 4 12 1' 0 2,15 3 1 1 2$ 2124 A Y L Q d 16a S u S 12-4 011)2 15=3 111 25119241182 1 42 1 1 1 14 1 1 1 1 0 5 0 5 0 53 5 3 0 5 5 5 0 41 6 14 0 4 6 3 0 42 6 54 0 4 7 1 0 38 7 3 0 3 7 S 0 34 8 2 0 12

Il u 10113 10 9 3 8 5 8 3 8 7 4 7 2 7 6 5 6 42 6 38 6 D38 6 42 6 52 7 5 7 2 7

2=5 3 3 21 3 3 3 52

5-4 5114 5 41 5 4 5 3 3 3 3 3 3 3 5 34 5 3 5 32 5 3 5 31 5 31 5 3 5 3 5 5 3 SDI

r

Saturn L t . D c.

•

• 2S S IONI 2S I 19N54 I1I 2 {9 •N) 10 5 2 4 19 14 18 3 2 1 1 3 I 18 3 2 811 4 IB 21 12 3 3 18 2 412 2 17' 33 12 52 3 54 li 42 17 3 2 ] 13 1 I3 3 717 24 2 213 5 4 114 4 ~s 4 1417 14 17 13 2 11 4 1 17 13 17 1 1 515 21 13 41 4 1517 18 I 5 16 1 17 2 16 21 4 17 31 1 8 16 4 17 16 S 3 S 17 S 4 1 SI17 I t8 17 3 3 4 IS 1 1 4 i7 8) 18 1 18 2 1 3 2 18 44 4518 27 ~ 1 41 18 59 18 4 3 1 19 16 19 9 19141 19 N3 1 3 2 4 19 51 19 2 2S382ON 9 1S35$9N44 FIRST QUARTER-June 28, Sh.

n-June 6. 3h. 39m. P.m. ($50 1 37')

Fuu. M

n-June 21, Ilk . 52m . a.m. (29' n 47')

12

1 2 3 4 5

-

•

2N3 2 3 2 3 2 3 2 37 2 37 2 3 2 3 2 3 2 3S 212 34 2 2 34 2 2 3 272 33 2 2 32 3'2N32

Uranus

Dec .

•

03 S 4S 3 44 3 43 3 43 3 421 3 42 1 3 42 3 42 3 43 3 4)1 3 44 3 45 1 3 4 .~ 3 47 3 48 ' 3S49'N LAST

Plut Lat . Dec .

NC - une

Lat .

Mutual Aspects

• `ye s •I Dr 6N4 6 4 1 a a. I. 114 -9 6 4 .~ Z , 42 6 4 6 4 0 4 V 6 4 6 4 9 3 6 4 br ~ ,r D. ~r~sw. 6 45 6 4 wE~r7si . 6 44 6 4 6 43 6 42 6 41 6N4' QUARTER-JunC 14 . 6h . 6m . p .m. (23' )( 21 ')

20S281N ;2 S 20 271 22 20 2 1 22 20 251 22 22 20 21 20 231 1 22 20 221 1 22 20 211 1 22 20 2 1 1 22 20 2 1 1 22 22 20 1 ° 1 22 20 181 20 171 22 22 20 161 922 30 16/1 2OSISIN 22S

17N2 417 2 17 2 417 2 417 2 17 2 . 17 2 17 21 17 2 17 1 . 17 1 17 1 17 1 17 1 17 1 17N1

.e



22

23

Time 0 H urs min .

TABLE 11 RATE OF 24-HOUR MOTION 0'29' r

0'30'

r

031'

• . r

0'35' r

f0°32' h.

Time 0 H urs Min.

TABLE II RATE OF 24-HOUR MOTION 0°29' •

1

.

0'30'

0°31'

001 003 004 0 05 0 07

0 01 003 004 006 0 07

008 009 011 012 013

008 010 011 012 0 14

0 08 010 Oil 013 014

009 010 0 12 013 014

51 52 53 54 55

102 103 104 105 106

104 105 106 107 109

106 107 108

014 015 017 018 0 19

015

016 017 018 020 0 21

016 017 019 020 0 22

56 57 58 59 60

108 109

020

015 0 16 018 019 021

1 12

1 10 1 11 112 1 14 1 15

021 0 22 023 024 026

021 0 23 0 24 0 25 0 27

0 0 0 0 0

22 23 25 26 27

0 23 024 025 0 27 0 28

0 23 025 026 0 28 ' 029

0 25 0 27 0 28 029 030

026 027 0 27 0 28 0 29 030 031 030 0 31 0 32

0 28 029 0 31 0 32 033

0 29 030 0 32 0 33 034

030 0 31 0 33 034 035

031 0 32 0 34 035 036

26 27 28 29 30

031 0 33 0 34 0 35 0 36

0 32 0 34 0 35 036 037

0 34 0 35 0 36 0 37 039

035 0 36 0 37 0 39 040

036 0 37 0 39 0 40 041

0 37 0 38 040 041 042

038 0 39 041 042 044

1 12 2 25 3 37 450 6 02

31 32 33 34 35

0 37 0 39 0 40 041 0 42

0 39 040 040 041 0 41 0 43 0 42 0 44 0 44 0 45

0 41 043 0 44 045 0 47

0 43 044 0 45 047 0 48

044 0 45 047 048 049

045 0 47 048 049 051

36 37 38 39 40

0 43 0 44 0 46 0 47 0.48

046 045 0 46 0 47 047 049 050 048 050 052

5i . 052 0 51 0 53 0 55 0 53 055 057 0 57 058

41 42 43 44 45

0 49 051 0 52 0 53 0 54

0 51 0 53 052 054 056 0 54 0 55 0 57 0 58 0 56

058 0 59 1 01 102 1 04

001 002 004 005 006

0 01 002 004 005 • 006

0 01 003 004 0 05 0 06

0 01 003

6 7 8 9 10

0 07 008 010 011 012

0 07 009 0 10 011 012

008 009 0 10 012 013

11 12 13 14 15

013 014 017 018

014 015 016 017 0 19

16 17 18 19 20

019 021 0 22 0 23 0 24

020 0 21 022 024 025

21 22 23 24 25

016

016 017 019

0'33'

0'34' •

0 01 0 03 004 008 0 07

1 2 3 0 5

0°32'

I

r

0'35' •

I

r

48 47 48 49 50

056 0 57 058 0 59 100

0 57 0 59 100 101 102

0 59 101 102 103 105

101 103 104 105 1 07

103 105 108 107 1 09

105 107 108 109 III

107 109

108 109

I t

1 12 1 14

1 15 1 16 1 17 1 19 120

1 10 III

III 1 12

1 11 1 13

1 13

1 14 1 16

1 12 1 14 1 15 1 16 1 17

1 15 i18 I la 1 19 120

1 17 118 120 121 1 22

1 15 230 3 45 500 6 15

1 17 235 3 52 . 510 6 27

40 400 520 6 40

2 45

715 8 27 940 1062 1205

730 8 45 1000 Ills 1230

7 45 902 1020 1137 1265

1317 14.30 1542 1655 1807

1345 1500 1615 1730 1845

t

1920 2032 21 45 22 57 24 10

1 01 103 104 106

2522 2635 27 47 2900

110 1 11

1 15 1 16

I la It

1 10 III 1 13

121 1 23 1 24 1 25

122 123 125 126 127

4 07 530 6 52

1 25 2 50 415 5 40 7 05

127 2 55 4 22 550 7 17

800 920 1040 1200 1320

8 15 9 37 1100 1222 1345

830 9 55 1120 1245 1410

14 12 1530 16 47 1805 1922

1440 1800 1720 1840 2000

1507 1630 1752 1915 2037

1535 1700 18 25 1950 21 15

1602 1730 18 57 2025 2152

2000 21 15 2230 2345 2500

2040 2157 2315 2432 2550

2120 2240 2400 2520 2640

2200 2322 24 45 2607 2730

2240 2405 2530 2655 2820

2320 2447 2615 2742 2910

26 15 2730 2846 3000

2707 2825 2942 3100

2800 2920 3040 3200

2852 3015 31 37 3300

2945 31 10 3235 3400

3037 3205 3332 3500

H urs 122

$45

1012 1140 1307 1435



35

34 ' TABLE 11 RATE OF 24-HOUR MOTION

Time 0 H urs .», Min .

1e.12' I e 003 008

0 03 006 0 09 012 015

0 03 006 009 012 015

6 7 8 9 10 11 12 13 14 15 16 17 18 19 20

018 021 0 24 0 27 0 30

018 021 0 24 0 27 030 0 33 036 039 0 42 045 0 48 051 0 54 0 57 100

0 18 021 0 24 0 27 030

21 22 23 24 25

1 02 1 05 108 III 1 14

26 27 28 29 30

1 17 120 123 1 26 129

31 32 33 34 35 36 37 38 39 40

1 32 1 35 138 1 41 1 44 1 46 1 49 1 52 1 55 1 58 201 2 04 2 07 2 10 2 13

1 2 2 5

b

4 0

1'13' e I r

41 42 43 44 45

033 0 35 0 38 041 0 44 0 47 050 0 53 056 0 59

1 03 106 109 112 1 15 1 18 1 21 124 127 1 30

0 33 036 040 0 43 048 0 49 052 0 55 0 58 101 1 04 107 110 113 1 16 1 19 1 22 125 128 131

1 33 1 36 139 1 42 1 45 148 150 154 1 57 200

1 34 1 37 140 1 43 1 46

2 03 206 209 2 12 215

2 05 208 211 214 217

149 1 52 156 1 59 202

1'14' map 0 03 0 06 0 09 012 015 018 022 0 25 0 28 031 0 34 037 040 0 43 046 0 49 052 0 55 0 59 1 02

1'15' *g

1e.16' I r

1'17' O / O

TABLE II RATE OF 24-HOUR MOTION

Time 0 H urs Min.

1. 12' e I e

1143' e I r

1. e 14' nr

220 2 23 228 229 2 32 2 35 238 241 2 44 2 48 250 2 53 258 2 59 3 02

2 22 2 25 2 28 231 2 34

2 2 2 2 2

24 27 30 33 38

228 229 2 32 2 35 2 38

2 37 2 40 2 43 2 46 250

2 2 2 2 2

39 42 46 49 52

253 2 65 2 59 302 3 05

2 55 2 58 301 304 3 07

241 2 45 2 48 251 254 2 57 300 3 04 3 07 3 10

0 03 006 0 09 0i2 016

0 03 006 0 09 0 13 016

0 03 006 010 013 018

46 47 48 49 5

2 2 2 2 2

16 19 22 25 28

2 18 221 2 24 2 27 2 30

0 19 022 0 25 0 28 031

019 0 23 0 28 0 29 0 32

51 52 53 54 55 58 57 58 59 60

2 2 2 2 2

31 34 37 40 43

233 2 36 2 39 2 42 2 45

2 2 2 2 2

46 48 52 54 57

2 48 251 2 54 2 57 300

1 05 1 08 111 114 1 17 120 1 23 126 129 1 32

106 109 112 115

1 36 1 39 142 1 45 1 48 151 1 53 157 200 203 206 2 09 213 2 16 219

1 37 1 40 143 1 46 1 49 152 I SS 159 2 02 205

019 0 22 0 25 0 28 0 32 0 35 0 38 0 41 0 44 0 47 0 51 0 54 0 57 100 103 106 110 113 1 16 119 1 22 1 25 1 29 132 1 35 138 141 1 44 148 1 51 1 54 1 56 200 2 03 2 07

2 08 211 214 217 221

210 213 2 16 2 19 2 22

0 34 037 041 0 44 047 050 053 0 56 0 59 1 02

lie 1 21 1 24 128 131 134

0 0 0 0 0

35 38 42 45 48

1 .15' s &

1 .18' O / I

1 .17' e I r 2 28 231 2 34 2 37 2 40 2 44 2 47 2 50 2 53 2 57 300 303 306 3 09 312

0 51 0 55 0 58 . 101 1 04 107 111 114 1 17 120 1 23 1 27 130 133 136 1 39 143 1 46 149 1 52 1 55 ISO 2 02 2 05 208 212 215 2 18 221 2 24

I

2 3 4 5 8

7

5L 55 8 52 11 50 14 47 1745 2042 2340 2637 2935

8 9 10 11 12 13 14 15 16 17 18 19 20

4720 50 17 53 15 56 12 5910

21 22 23 24

10207 1 05 05 10802 11100

3232 3530 3827 41 25 4422

300 600 900 1200 1500 1800 2100 2400 2700 3000 3300 3600. 3900 4200 4500 4800 5100 5400 5700 10000 10300 10600 10900 11200

302 6 05 9 07 1210 15 12 18 15 2117 2420 2722 3095 3327 3630 3932 4235 4537

305 610 915 1220 1626 1830 2135 2440 2745 3050

4840 5142 54 45 5747 10050

3365 3700 4005 4310 4615 4920 5225 5530 6835 10140

10352 10665 1 09 57 11300

104 45 10750 1 10 55 11400

3 07 815 9 22 1230 1537 1845 21 52 2500 2807 31 15 3422 3730 4037 4345 4652 5000 5307 5615 5922 10230 10536 10845 11152 11500

310 620 930 1240 1550 1900 2210 2520 2830 31 40 3450 3800 41 10 4420 4730

3 12 6 25 9 37 1250 1602 1915 2227 2540 2662 3205 35 17 3830 41 42 4455 4807

5040 5350 5700 10010 10320 10630 10940 11250 1 1600

5120 6432 57 45 10057 10410 10722 1 10 35 1 13 47 11700



TABLE I1 RATE OF 24-HOUR MOTION 0°28'

0'27' O

2

k 8 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45

001 002 003 004 005

001 0 02

005 0 07 0 07 008 009. 010 011 012 013 014

006 0 07 008 0 09 010

004

Oil 011 0 12 013 014

0 28 0 29 030 031 0 32 0 33 0 33 0 34 0 35 0 37

015 016 017 0 18 019 0 20 021 022 0 23 0 24 0 25 0 26 0 27 0 28 029 030 031 0 32 0 33 0 34 0 34 0 35 0 36 0 37 0 38

0 38 038 0 39 0 40 041

0 39 0 40 041 0 42 0 43

015 0 16 0 16 017 018 019 020 021 0 22 0 23 0 0 0 0 0

24 25 26 27 27

001 002 003 004 005 006 0 07 008 009 010 Oil 0 12 013 014 0 15 0 16 017 018 019 020

M

•

001 002 003 004 005 006 0 07 008 009 010

001 0 02 003 004 005 006 008 009 010 011

001 0 02 003 004 006 0 07 008 009 010 011

011 0 12 014 015 0 16

012 013 014 015 016

012 013 015 016 017

017 018 019 00 021

017 Ol8 019 021 022 023 0 24 025 0 26 027 028 029 030 031 032 0 34 0 35 036 037 038 0 39 0 40 041• 042 043

018 019 020 021 022 024 0 25 026 0 27 028 029 030 032 033 034 0 35 036 0 37 038 039 0 40 0 42 043 044 045

044 045 0 47 0 48 049

046 047 0 48 0 49 051

021 0 22 023 0 24 025

022 0 23 024 0 25 026

026 027 028 029 030 0 31 0 32 0 33 034 035 036 0 37 038 039 040

027 028 029 030 031 0 32 0 33 0 34 035 036 0 37 0 39 040 041 042 043 044 0 45 0 46 047

041 042 0 43 0 44 045

/

I

O

001 002 0 03 0 05 006 0 07 008 009 010 0 12 0 13 014 015 018 017 019 020 021 0 22 0 23 0 24 0 26 0 27 0 28 029 030 031 0 33 0 34 0 35 036 0 37 0 38 0 40 041 0 42 0 43 0 44 0 46 0 47 0 48 0 49 0 50 051 0 52

i

Time 0 H urs Min . 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

TABLE I1 RATE OF 24-HOUR MOTION 0°22' 0.23' 0'24' 0-250'28' O

/

O

0 42 0 43 0 44 0 45 0 46 0 47 0 48 0 49 0 49 050 051 0 52 0 53 0 54

ass

I

0 0 0 0 0

O

44 45 46 47 48

I

M

0 49 050 051 0 52 0 53

0 46 0 47 0 48 0 49 0 50 051 0 52 0 53 0 54 0 55

054 0 55 056 0 57 0 57

058 0 57 0 58 0 59 100

O

I

•

048 0 49 050 051 0 52 063 0 54 0 55 0 58 0 57 058 0 59 100 1 01 1 02

•

I

M

0°27' •

I

M

0'28' •

I

M

0 50 051 0 52 0 53 064

0 52 0 53 0 54 0 55 056

0 54

ass 056 0 57 0 58 100

0 57 0 58 100 101 102

0 56 0 57 0 58 100 1 01 102 103 104

101 1 02 103 104 105

103 104 1 05 108 1 07

105 108 108 109 1 10

105 210 3 15 420 5 25 630 735 8 40 9 45 1050

107 215 3 22 430 5 37 6 45 7 52 900 1007 11 15

1 10 2 20 330 4 40 550 700 810 920 1030 11 40

11 55 1300 1405 1510 16 15

1250 1400 15 10 1620 17 30 18 40 1950 2100 2210 2320 2430 25 40 26 50 2800

ass

Hi V

11 12 13 14 15 16 17 18 19 20

055 150 2 45 3 40 4 35 530 6 25 720 8 15 910 1005 1100 11 55 12 50 1345 14 40 1535 1630 17 25 18 20

21 22 23 24

1915 2010 21 05 2200

2 3 4 5 6 7 8 9 10

5 45 642 7 40 8 37 9 35

800 700 800 900 1000

1032 11 30 1227 1325 14 22

1100 1200 1300 1400 1500

102 205 3 07 410 5 12 815 7 17 8 20 9 22 1025 11 27 1230 1332 14 35 15 37 1640 17 42 18 45 1947 2050

1720 18 25 1930 2035 21 40

1222 1330 14 37 15 45 1652 1800 1907 2015 21 22 2230

21 52 2255 2357 2500

22 45 2350 24 55 2600

2337 24 45 2552 2700

II



TABLE 11 ' RATE OF 24-HOUR MOTION

0'02' • t

CA

6 7 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45

•

0°03' e 1

0 01 0 01 001 001 001 001 001 001 001 001 001 001 001 001 001 001 001 001 002 001 0 02 001 001 002 0 02 001 001 002 001 002 002 001 002 001 0 02 001 0 02 001 0 02 001 002 001 0 03 001 0 03 001 001 0 03 003 001 003 001 003 001 003 002 003 0 02 0 03 0 02 0 02 0 03 003 0 02 0 03 0 02 0 04 002 0 02 0 04 0 04 0 02

0'04' •

•

001 0 01 0 01 0 01 001 001 001 001 0 02 002 002 002 002 002 0 02 0 02 003 003 003 003 003 003 003 0 03 004 004 004 004 004 004 004 004 005 005 0 05 0 05 0 05 005 0 05 0 05 006

.

0'05' •

•

0 01 001 0 01 0 01 0 01 001 002 002 002 002 002 002 003 003 003 003 003 003 004 004 004 004 004 004 0 05 005 0 05 0 05 0 05 0 05 006 006 006 006 006 006 0 07 0 07 0 07 0 07 0 07 0 07

I »

0'08•

0°07'

0 01 001 001 0 01 001 001 0 01 0 01 002 0 01 002 0 02 002 002 002 002 002 003 003 002 003 003 003 003 004 003 004 003 004 004 004 004 005 004 005 0 04 0 05 004 005 0 05 005 006 006 005 006 005 006 005 0 07 006 006 007 006 0 07 007 006 008 006 006 0 07 008 0 07 0 08 007 009 007 009 007 008 009 009 008 009 008 010 0 08 0 09 010 0 09 0 10 011 0 09 011 0 09 011 0 09

001 0 01 001 001 002 002 002 003 003 003 003 004 004 004 005 005 0 05 005 006 006 006 007 007 007 008 008 008 008 009 009 009 010 010 010 010 011 011 Oil 012 012 0 12 013 013 013

TABLE 11 RATE OF 24-HOUR MOTION

Time 0 H urs Min.

46 47 48 49 50 51 52 63 54 55 56 57 58 59 60

0'0'2' •

.

I

0'03'

e I »

0°04' •

I

•

O'05' e I »

0 O6'

0'07' »

002 002 002 0 02 002 002 002 0 02 0 02 002 002 0 02 002 0 02 002

004 • 006 004 006 004 006 004 006 004 006 004 006 004 006 004 0 07 004 0 07 0 05 0 07 005 0 07 005 0 07 005 0 07 005 0 07 0 05 0 07

006 008 008 008 008 008 009 0 09 0 09 009 009 0 09 010 010 010

010 010 010 010 010 011 011 Oil 011 Oil 012 0 12 012 012 012

011 012 0 12 012 012 013 0 13 013 013 0 14 014 014 014 015 0 15

013 014 014 014 015 015 015 015 016 0 16 018 017 017 0 17 0 17

0 07 0 10 012 015 017 0'20 0 22 0 25 0 27 030 0 32 0 35 0 37 0 40 0 42 0 45 0 47 0 50 0 52 0 55 0 57 100

005 010 015 020 0 25 030 0 35 0 40 0 45 050 0 55 100 1 05 1 10 1 15 1 20 1 25 130 1 35 1 40 1 45 150 1 55 200

010 0 20 030 040 050 100 1 10 1 20 130 140 150 200 2 10 220 230 2 40 250 300 3 10 320 330 3 40 350 400

012 0 25 0 37 050 102 1 16 1 27 1 40 1 52 2 05 2 17 230 2 42 2 55 3 07 3 20 3 32 3 45 3 57 4 10 4 22 4 35 4 47 500

015 030 0 45 100 1 15 130 1 45 200 215 230 2 45 300 315 330 3 45 400 4 15 430 4 45 500 5 15 530 5 45 600

0 17 0 35 0 52 110 127 1 45 2 02 220 2 37 2 55 312 3 30 3 47 4 05 4 22 4 40 4 57 515 5 32 550 6 07 6 25 8 42 700

0 07 015 022 030 0 37 0 45 0 52 100 1 07 1 15 122 130 1 37 1 45 1 52 200 2 07 2 15 2 22 230 2 37 2 45 2 52 300

ti



L151/ 2 1 N te Saturn g es Direct (D) bef re the dates we are w rking F r Saturn :Y u willsee fr m, theref re calculati ns are as f r the n n % planets . difference f m ti n between the 20th and 21st . th ugh that there is n Saturn is Stati nary alth ugh direct . N calculati n takes place in this case nt the h r sc pe, Saturn being and the figures are calculated straight c nsidered Stati nary Direct (SD) .

t

SDlS°-'^-30'

F r Uranus :-

Uranus is Retr grade .

f,O32' r,030 '

2 ' fr m tables

3 ! .' 60" V31%05 59

1

F r Neptune :-

-

35' 25° 25° . ' 33' 2'

fr m tables

- 25°-0 34'

69"

'.'& 25 0 ,034'

55"

5"

F rPlut :Plut

is Retr grade Stati nary . Result is

e

RS

24°--^-10'

STEP F Transfering the planets t

the h r sc pe .

Our w rk with sidereal time gave us the signs degree the cusp c mmences . i

n the h use cusps and what

Take the sun 2803r- 52' 33" Gemini starts the 3rd h use cusp at 6° s it w uld be reas nable t assume 6° f Gemini w uld be in the 2nd h use and the remaining 24° in the 3rd h use . (Each sign having 30° each) . C unt fr m the 6th degree t the 28th degree which is nly 1 degree ff 30 0 Gemini and 2 degrees ff 0° Cancer . (N te the .4th h use cusp is 10° Cancer) . Place the Sun n the 28th degree f Gemini as sh wn in the f ll wing diagram . Keep clear in y ur mind the h use cusps are sign p sts and we place the planets nt the h r sc pe 360° circle in relati n t these signp sts . Als n te a sign c nsists nly f 30° (0°-30°) n m re, n less . Keep clear the distincti n between signs and h use . The h uses are n paper, the signs are pr jected int the heavens . In analysis the tw c me t gether dynamically . We use a degree f a sign t mark the beginning f a h use . The h use begins at its cusp, (signp st) . F r the ther planets repeat the same meth d .



L151/ 2 2 CALCULATION OF THE "PARTS" 6 parts will be dealt with in this lecture .

f

The The The The The The

Part Part Part Part Part Part

f f f f f f

F rtuna 8 Illuminati n ~' Destiny Occultism Vr Fate $ Spirit O,

N te in the f ll wing the signs start fr m 0° s Aries will be 0°-1, that is, 'the first h use BUT numbered 0 . Taurus is 1-2 s is numbered 1 alth ugh Taurus is the sec nd h use . Gemini 2, Cancer 3 and s n. 0

• t + M The ascendan e .g .

n minus the sun Sign °

'r 0 • =2 2 - ' - 2 we see 24 cann t take away 28 s we b rr w 1 extra sign (30°) t 24 and give 12 signs t the 1 remaining sign

9 15 24 28

42 21 63 52

54 13 63 2 28 .52 26 11' _ 026 0 * 11 ' which is 11entered n t the h r sc pe

~' The part f illuminati n is the same degree but part f f rtuna .

pp site sign t

the

i .e . 47,,k6° I10'

t

® MC + Sun - M n (MC is mid-heaven which is the 10th h use cusp using the Placidus System .) e .g .

9

10 28 52 38 52 11 3L_ 2 15 21 9 23 31 _ 023 0 V~31'

• 3L2

I Ascendent + Neptune - Uranus

36ff0

9 41 8 25 34 8 34 75 -08 30 58 0 4 17

•

' 4°

T

17'



L151/ 2 3

Ascendent + Saturn - Sun

t

'' 0 9 41 =6 15 30 6 24 71 a 2 28 52 ------------------54 5 71 28 52 3 26 19

b rr wing

A

Ascendant + Sun - M

Carry

T0 -2 2 2 0 c/ 0

ver

° Cq%

19'

n

+

1

g 2

9 28 37 15 22 23

41 52 93 21 72 12

= c0~ 23°T 12'

THE MOON NODES : These are f und in the Ephemeris in the m nth and day

f GMT . Calculate these

as ne w uld the Retr grade planets . First calculate the N rth N de ( J% ) . The result f the N rth N de is exactly the same f r the S uth N de except the S uth N de is placed

t

in

the

pp site sign .

L151/ 2 4 INTERCEPTED HOUSES There may n t necessarily be a different sign per cusp . e .g . fr m y ur Tables 10

27°

11

2°

12

f H uses a result may be Ascen

11 0 14°48'

The h r sc pe w uld l

3

2

60

29°

k thus :

1

1 t e

1 4th and 10th are intercepted h uses .



L151/2 5 OTHER POINTS Filling in the data t

the left

f y urchart .

The ruling planet is the str ngest planet in the h r sc pe . S me say the r the ascendant is the ruling planet, . but planet ruling the sun sign, the planet in the str ngest and m st influential p siti n . preference is t This is btained thr ugh the analysis f the planetary p siti ns .

1 1

Ruling Planet : Str ngest planet in chart . Rulers H use : The h use the ruling planet is situated . Rising Planet : Planet nearest ascendant . It is c nsidered any planet m re than 60° away fr m the ascendant cann t be c nsidered a rising planet . The am unt f planets, parts, n des, ASC and MC in p sitive P sitive : (masculine) signs . The am unt f planets, parts, n des, ASC and MC in negative Negative : (feminine) signs . TRIPLICITIES : Fire : Am unt f planets, parts, n des, ASC and MC in fire signs . Earth : Same as Fire but in Earth signs . Air : Same as Fire but in Air signs . Water : Same as Fire but in Water signs . QUADRUPLICITIES : Cardinal : Am unt f planets, parts, n des, ASC & MC in Cardinal signs . Fixed : Same as Cardinal but in Fixed signs . Mutable : Same as Cardinal but in Mutable signs . Angular : Am unt f planets, parts, n des, ASC & MC in Angular H uses . Succeedent : Same as Angular but in Succeedent H uses . Cadent : Same as Angular but in Cadent H uses .

t 1

I

MUTUAL RECEPTION : The relati nship between 2 planets l cated in the sign which rules .

ne

r the

ther



L151/ 2 6 . ASPECTS Maj r Aspects : d

4Q 0 d +

t

T GT Y * 0

U 1

C njuncti n Semi Square Sextile Square Trine Opp siti n Grand Cr ss T Square (Cr ss) Grand Trine Y C nfigurati n D uble Sextile D uble Semi Sextile D uble Semi Square

00

45 0 60 0 90° 120° 180° 2x90°, 2x180° 2480 0 , 1x90° t b th 180° 3x120° linking up . 2x60° inc njunct a third . 2x120°, 1x60° 2x60° , 1x30° linking 2x90°, 1x45° linking

Explanati n . pp siti ns each A grand cr ss is f ur planets square each ther, e .g . 2 square, the ther pp siti n . b th f them . The T square is 2 planets in pp siti n and an ther square The GT is 2 planets trine each ther, and th se tw b th trining a third . Y is 2 planets sextile each ther and b th inc njunct an ther . ** is 2 planets trine with a third sextile b th . ther and a third planet semi D uble Semi Sextile is 2 planets sextile each sextile b th . D uble Semi Square is 2 planets square and a third semi square b th . Min r Aspects :

1

Vigintile -- Semi Sextile -+- Semi Quintile Q Quintile Tridecile Q Sesquiquadrate . Bi-Quintile ® Quincunx P Parallel

18° 30° 36° 72° 108° 135° 144° 150°

The degrees are distances between planets . The aspect graph is filled in with the symb ls in the appr priate b x where an aspect is f rmed between 2 planets .



PROGRESSED DATA

D

I

N

M

n p mu ns n

C rresp nd t I

PO PD , Pig

.

I P4

Pa I

Ruling Planet

Ruler's H use

Rising

~

Planet

t

'

Negadve

Triplicities :Fire

Own sign.

Earth, 5

Ealted

Air

Detiiment~

$

Water

..~

Fall •

Ouadruplicities :-

Cardiaal~_ Fixed q 3 t

Mutable

I

Angular sueceedent Cadent __

Mutual Recepti n

1 PLANET

BY DIRECT METHOD

ASPECTS

DEC.

a

O ,

~:

NOTES

h

w

Sun M

E

010

M. (0

T,

4ti

L.uma.

,

n

D, i i

turn, deft

d

i'I (, S-Z

Lew d.

Mercury

Q Venus

*a t3 d -

a

Mars

I

1

airs ew . r. alv.w

•n

Z ne .nerd ,,

I2

s mm. f r d..s l.) am**

-

-

Cry

C M.? C •M.r. d.

Jupiter

O I1-

C

'LD :

6 :`a

r. h

Saturn

OS S'3 2`t

ud• we m m C.M.T.

r

Iwwvv.l •T OIPuOM neem

pra

04-

Ar.a

_ O( 441.111-

~^7

O

AaC Mums n interval . .m p

Neptune

Sid.

r Plut

$

r

,

tir .e ar Cz.sw c a pitta .4gwsal.wr^s

L.p4m

`7

- 6 S7 3q 1(-?

LOCAL SID. TIME AT IIIIITIL Subuact 24 bra . %I w...aurv ~ 24

d° II

M.C.

Q

C-

•

N

. .

N . Z -The "HOUSES" Chart. DIRECT METHOD

/

y.

/c.-4 3y

as W 4 39 Delete rMW .r .ris .et tpwr M•

Designed by M .E.HONE .

a~

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Gc.,S~„MQ \4

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