Theme 3.2

Nakṣatra Solar zodiac from Vedic times

Dating Maghādi and Śraviṣṭhādi Epochs

Observing the Sun's rhytmns

( ayana, ṛtu, nakṣatra, precession )

view of sunrise	surise location	sunrise (day) count
	north east	1
	true east	92
	south east	183
	true east	274
	north east	367 1 of next cycle

• The sunrise horizon point moves from north east to south east and back to same north east point after 366 sunrises - a solar year.
• The north east to south east journey is called dakṣiṇāyana and the reverse is uttarāyaṇa
• In addition the sun cycles through six ṛtu-s in a year - śiśira, vasanta, grīṣma, varṣā, śarad, hemanta - each of 61 sunrises.
• Specific background stars can be observed just before each sunrise. These stars are called nakṣatra-s , 27 in number.
• Each of the 2 ayana-s and 6 ṛtu-s are associated with specfic nakṣatra-s.
• Over ages this ayana/ṛtu-nakṣatra association changes due to the precession phenomenon.
• This change is used to date the ancient texts.

Nakṣatra solar zodiac

• The Sun completes one circuit in 366 days in clockwise direction
  
  

• The ṛtu-s complete one circuit in ~25,800 years in anticlockwise direction

The Maghādi/dakṣināyaṇa epoch

Brahmāṇḍa Purāṇa BP 21.143-149

• This BP passage defines visuvat to be of equal day and night duration of 15 muhūrtas each - equinox - in the mid of vasanta and śarat ṛtus.

• The passage further states the nakṣatra location at an aṃsa grain for equinoctal sun and moon at spring and autumn equinoxes.

• It turns out the sun and moon locus at each of the equinox are diametrically opposite - at 1/4 kṛttikā and 3/4 viśākhā, indicating the description are of the equinoctial full moon.

Maitrāyaṇīya Āraṇyaka Upaniṣat MAU 6.14

• The year commences in Maghādi (at dakṣiṇāyana).
• A year has 12 parts and each part has 9 amṣa.
• The year's first half , Āgneya,is from Maghādi to Śraviṣṭhārdha and
• The second half , Vāruṇa, is from Sārpādi to Śraviṣṭhārdha in reverse order.

Nidānasūtra NS 5.12

• Sun traverses 13 and an additional 5/9 ahorāṭras in each nakṣatra.
• To cover 27 nakṣatras the sun takes 366 ahorāṭras/days.

From these MAU, NS and BP passages

1. Sun spends 13 and 5/9 days equally with each naḳsatra of 4 amṣa . The sun completes one trip through the 27 nakṣatras in 366 days
2. The sun is at Maghādi at start of dakṣiṇāyana. (Further Mahāsaliaṃ chapter of Vṛddagārgīya Jyotiṣa (VGJ) states Maghā to be the first among the solar nakṣatras.)
3. The equality of the 27 nakṣatras and the start of sequence at at Maghā help allocate the day numbers to each nakṣatra sector.
4. The BP verses specify the spring and autumnal equinoctial full moons at 1/4 Kṛttikā and 3/4 Viśākhā nakṣatras. This information enables us to date the verses.
5. We mark the Kṛttikā and Viśākhā sectors such that equinoxes are at ¼ kṛttikā and ¾ viśākhā.
6. We collect the visible Kṛttikā(η Tau) and Viśākhā(α Lib) longitudes adjusted for precession from 2400BCE to 0BCE.
7. We programatically collect all full moon longitudes that occur near the equinoxes from 2400BCE to 0BCE, using astropy library. There are about 7 such events each century for each equinox. The equinoctial full moons are marked in the chart that follows.

A tech note - Collecting full moons programatically

The Astropy library, that uses Meeus algos, is used to collect the full moon longitudes programmatically.

1. Start at an ancient date - 2400-03-21 BCE
2. Computed the full moon longitude for the date
3. If sun and moon longitudes are within 180°+
   -- a FM found, collect it
   -- step up the date by 28 days and repeat
4. If not nudge the date by difference of sun and moon longitudes
5. Repeat 2 onwards till 0 BCE

Meeus, J., Astronomical Algorithms, 2nd ed, p337, p357

is Julian Day number of Full Moon

Computing the information of BP

• Get full moon timeseries from 2400BCE to 800BCE. There are about 1237 FM per century - the top chart
  
  
  
• The series is then filtered for Equinoctial Full Moons - the mid chart
  
  
  
  
  
• The series is further filtered for EFM near kṛttikā and viśākhā - the bottom chart
• The yellow region shows the epoch when the visible kṛttikā and viśākhā are contained in their respective sectors - 2000BCE to 1600BCE

Inferring the BP epoch

Nakṣatra Chart 1700BCE - Maghādi epoch

• The equinoctial full moons of BP
  • ¼ kṛttikā sector
  • ¾ viśākhā sector
  • SE-AE axis of the chart
• aligns with maghādi of MAU
  • when maghādi (SS 1) is at
    • start of dakṣiṇāyana
• around 1700 BCE

The Śraviṣṭhādi/uttarāyaṇa epoch - VGJ/11 Ādityachāra and Parāśharatantra

• Ādityachāra, section 11 of VGJ, describes the transit of Sun through 9 seasonal nakṣatras .
• Similar information is presented in PT in prose.
• The Ādityachāra passage is shown below.
• Passage maps 6 ṛtus mapped to 9 seasonal nakṣatras
• Mapping enables passage dating

Dating Ādityachāra - by minimizing error

• The best fit method finds the epoch where most stars of nakṣatra-s are in their prescribed span

  • Get longitude of 83 stars from -2500 to 500 in 50 year epoch steps
  • For each epoch compute this error metric
  • The epoch with lowest error metric is the best fit

• The error metric for each epoch is calculated as the mean of the containment error of each nakshatra. The containment error for each nakshatra is calculated as the mean of eachs star's error. The error for each star is calculated as follows:

  • If the longitude of the star is within the prescribed span of the nakshatra, the error is 0.
  • Otherwise, the error is the minimum distance between the longitude of the star and the boundaries of the prescribed span of the nakshatra.

The Śravaṇādi epoch VGJ/59 Ṛtusvabhāva

• Ṛtusvabhāva dates to ~500 BCE
  
  
• This is different from आदित्यचारः
  • Ṛtu sequence begins with वसन्त not शिशिर
  • Ṛtu are related to months, not nakṣatra span & boundaries
  • A 12 month solar zodiac, obviating intercalation, emerges
    
    
• It describes Sun's path through
  • 6 seasons and their months
  • 12 vaidika and equivalent laukika months and 12 nakṣatra-s for each of these months - ~30° apart

A chronology of Solar transits

Solar zodiac is certainly part of original Indian knowledge - that has been recorded and evolved over time.

References

Backup Slides from Here

Observational Astronomy of the Sun

Sun, Ayanas and Ṛtus

An observer noticing the sunrise point of the eastern horizon will notice the point oscillate between north-east in the summer to south-east in the winter and back to north-east in the summer - much like a swing.

The extreme north and south points are the dakṣiṇāyana and uttarāyaṇa start - the winter and summer solstices respectively. The points in between are called the viṣuvat - spring and autumn equinoxes.

One full swing of the sun lasts 366 days and is made of two ayanas the dakṣiṇāyana and uttarāyaṇa each of 183 days

In one full swing from uttarāyaṇa, the sun traverses through six ṛtus (seasons) in order - namely varṣā, śarad, hemanta, śiśira, vasanta, grīṣma,- each ṛtu is of 61 days.

Just as a swing appears to be stationary at the extreme points, the sun appears to be stationary at the uttarāyaṇa and dakṣiṇāyana start points before resuming its oscillation. An observer will notice that the sun is stationary at the uttarāyaṇa and dakṣiṇāyana start points for about 14 sunrises each.

The period from one sunrise to another is called a ahorāṭra/day. A ṛtu is made of 61 ahorāṭras/days. An ayana is made of 183 ahorāṭras/days.One swing of the sun with 366 ahorāṭras/days is samvatsara/year.

Assuming the dakṣiṇāyana point to be the day 1 of the 366 day cycle, the following table shows the day number of the start of each ṛtu and ayanas.

day num	ṛtu	ayana	equinox/ solstice	sunrise image as seen by an observer
1	varṣā start	dakṣiṇāyana start	summer solstice	sun rises north east
62	śarad start	dakṣiṇāyana	-	-
92	śarad mid	viṣuvat	autumn equinox	sun rises true east
123	hemanta start	dakṣiṇāyana	-
183 184	śiśira start	dakṣiṇāyana end uttarāyaṇa start	winter solstice	sun rises south east
245	vasanta start	uttarāyaṇa	-	-
274	vasanta mid	viṣuvat	spring equinox	sun rises true east
306	grīṣma start	uttarāyaṇa	-	-
366	grīṣma-end	uttarāyaṇa end dakṣiṇāyana start	summer solstice	sun rises north east

Sun's annual cycle

• The sunrise point at horizon moves/swings from
  • north east to south east called dakṣiṇāyana
  • back to same north east called uttarāyaṇa
• 366 sunrises makes a cycle - a solar year
• The sunrises are associated with specific background stars called nakṣatra-s

Sun and Nakṣatras

We noted that each of the 366 sunrises occurs at different points on the eastern horizon due to the sun's swing. In addition, the stars that are visible just prior to each sunrise at the sunrise point also change. The stars that are visible just prior to sunrise are said to belong to the nakṣatra of that day.

During uttarāyaṇa and dakṣiṇāyana the sun seems to rise at a stationary point for about 14 days. The stars visible prior to sunrise for these two stationary points define the sector/span of a nakṣatra - of about 14 days - more precisely 13⁵/₉ days.

A nakṣatra is a span of time of about 14 days and contains the stars that are visible at sunrise in its time span. There are 27 such equal nakṣatra spans in a 366 day cycle. Each of the 27 nakṣtra while of equal time span contains varying counts of stars - between 1 and 6 - totaling 83 stars. The 27 nakṣatra are named in a fixed cyclical order.

The current order starting from Aśvinī along with their star count listed below, is an inherited order from around 1500 years ago. The order of the nakṣatra begins with Kṛttikā and ends with Revatī in more ancient texts.

The choice of the first nakṣatra to start the cycle contains information on the epoch and the convention for the year start.

There are texts that associate specific nakṣatras with the ṛtus - seasonal naḳsatras . Such seasonal naḳsatras also contain vital information on the epoch of the text.

Nakṣatra-s starting from Maghā at day 1

In this Maghādi epoch day 1 of dakṣiṇāyana is at Maghā start.

• The sun traverses through the 27 nakṣatras in order and returns to Maghā start at the end of the 366 day cycle.
• The 1st and 367th sunrise are at
  • the same nakṣatra/star - Maghā/ε-Leonis
  • the same point on the horizon and

Over 100's of years,

• the nakṣatra/star to shift by about 1 day in about 72 years.
• This shift is called the ayanāṃśa/precession.

Precession and its effects

We see the start of Maghā nakṣatra on day 1 of dakṣiṇāyana in the chart above. This is true for a certain epoch. After about a 1000 years, the start of Maghā nakṣatra will be on day 14 of dakṣiṇāyana. Equivalently day 1 of dakṣiṇāyana will move to Āśleṣā start.

The precession is a slow process and takes about 25,800 years to complete one cycle. That is the sunrise point will return to the same nakṣatra/star for the same ṛtu after 25,800 years.

Precession causes the seasonal nakṣatras to drift with time. Many ancient text associate nakṣhatras with seasons - this association contains vital information on the epoch of the text.

The direction of precession is opposite to the direction of the sun's annual transit through the nakshatras. Incidentally the moon also transits through the nakṣatras in the same direction as the sun. The moon's transit through the nakṣatras is called the lunar month of about 27 days.

Effect of precession over millennia

• About every 1000 years the start of season move backwark by one naḳsatra. In addition the precession causes the pole star to change.

• The following table/pictures shows the start of the spring equinox seasonal naḳsatra and the pole star for the last 5000 years.

Epoch	Spring Equinox	Dakṣiṇāyana	Uttaryāṇa	Pole Star	Image
Present	Uttara Bhādrapadā	Ārdrā	Mūla	Polaris
1000 years ago	Revatī	Punarvasu	Pūrva Aṣāḍhā	-
2000 years ago	Aṡvinī	Puṣya	Uttara Aṣāḍhā	-
3000 years ago	Bharanī	Aśleṣā	Śravaṇa	-
4000 years ago	Kṛttikā	Maghā	Śraviṣṭhā	-
5000 years ago	Rohiṇī	Pūrva Phalgunī	Śatabhiṣā	Thuban

Present Day	5000 years ago

Precession over 5000 years