Saros 118

Panorama of Lunar Eclipses of Saros 118

Fred Espenak

Introduction

A lunar eclipse occurs whenever the Moon passes through Earth's shadow. At least two lunar eclipses and as many as five occur every year.

The periodicity and recurrence of lunar eclipses is governed by the Saros cycle, a period of approximately 6,585.3 days (18 years 11 days 8 hours). When two eclipses are separated by a period of one Saros, they share a very similar geometry. The two eclipses occur at the same node with the Moon at nearly the same distance from Earth and the same time of year due to a harmonic in three cycles of the Moon's orbit. Thus, the Saros is useful for organizing eclipses into families or series. Each series typically lasts 12 to 15 centuries and contains about 70 to 80 eclipses. Every saros series begins with a number of penumbral lunar eclipses. The series will then produce several dozen partial eclipses, followed by several dozen total eclipses. The later portion of the series produces another set of partial eclipses before ending with a final group of penumbral eclipses. The exact numbers vary from one series to the next, but the overall sequence remains the same. For more information, see Periodicity of Lunar Eclipses.

Panorama of Lunar Eclipses of Saros 118

A panorama of all lunar eclipses belonging to Saros 118 is presented here. Each figure shows the Moon's path with respect to Earth's penumbral and umbral shadows. Below the path is a map depicting the geographic region of visibility for the eclipse. The date and time are given for the instant of Greatest Eclipse. Every figure serves as a hyperlink to the EclipseWise Prime page for that eclipse with a larger figure and complete details for the eclipse. Visit the Key to Lunar Eclipse Figures for a detailed explanation of these diagrams. Near the bottom of this page are a series of hyperlinks for more on lunar eclipses.

The exeligmos is a period of three Saros cycles and is equal to approximately 54 years 33 days. Because it is nearly an integral number of days in length, two eclipses separated by 1 exeligmos (= 3 Saroses) not only share all the characterists of a Saros, but also take place in approximately the same geographic location.

The Saros panorama below is arranged in horizontal rows of 3 eclipses. So one eclipse to the left or right is a difference of 1 Saros cycle, and one eclipse above or below is a difference of 1 exeligmos. By scanning a column of the table, it reveals how the geographic visibility of eclipses separated by an exeligmos slowly changes.

  • Click on any figure to go directly to the EclipseWise Prime Page for more information, tables, diagrams and maps. Key to Lunar Eclipse Figures explains the features in these diagrams.

For more information on this series see Statistics for Lunar Eclipses of Saros 118 .

Panorama of Lunar Eclipses of Saros 118
Penumbral Lunar Eclipse
1105 Mar 02

Penumbral Lunar Eclipse
1123 Mar 13

Penumbral Lunar Eclipse
1141 Mar 24

Penumbral Lunar Eclipse
1159 Apr 04

Penumbral Lunar Eclipse
1177 Apr 14

Penumbral Lunar Eclipse
1195 Apr 26

Penumbral Lunar Eclipse
1213 May 06

Penumbral Lunar Eclipse
1231 May 17

Penumbral Lunar Eclipse
1249 May 28

Partial Lunar Eclipse
1267 Jun 08

Partial Lunar Eclipse
1285 Jun 18

Partial Lunar Eclipse
1303 Jun 29

Partial Lunar Eclipse
1321 Jul 10

Partial Lunar Eclipse
1339 Jul 21

Partial Lunar Eclipse
1357 Jul 31

Partial Lunar Eclipse
1375 Aug 12

Total Lunar Eclipse
1393 Aug 22

Total Lunar Eclipse
1411 Sep 02

Total Lunar Eclipse
1429 Sep 13

Total Lunar Eclipse
1447 Sep 24

Total Lunar Eclipse
1465 Oct 04

Total Lunar Eclipse
1483 Oct 16

Total Lunar Eclipse
1501 Oct 26

Total Lunar Eclipse
1519 Nov 06

Total Lunar Eclipse
1537 Nov 17

Total Lunar Eclipse
1555 Nov 28

Total Lunar Eclipse
1573 Dec 08

Total Lunar Eclipse
1591 Dec 30

Total Lunar Eclipse
1610 Jan 09

Total Lunar Eclipse
1628 Jan 20

Total Lunar Eclipse
1646 Jan 31

Total Lunar Eclipse
1664 Feb 11

Total Lunar Eclipse
1682 Feb 21

Total Lunar Eclipse
1700 Mar 05

Total Lunar Eclipse
1718 Mar 16

Total Lunar Eclipse
1736 Mar 27

Total Lunar Eclipse
1754 Apr 07

Total Lunar Eclipse
1772 Apr 17

Total Lunar Eclipse
1790 Apr 28

Total Lunar Eclipse
1808 May 10

Total Lunar Eclipse
1826 May 21

Total Lunar Eclipse
1844 May 31

Total Lunar Eclipse
1862 Jun 12

Total Lunar Eclipse
1880 Jun 22

Partial Lunar Eclipse
1898 Jul 03

Partial Lunar Eclipse
1916 Jul 15

Partial Lunar Eclipse
1934 Jul 26

Partial Lunar Eclipse
1952 Aug 05

Partial Lunar Eclipse
1970 Aug 17

Partial Lunar Eclipse
1988 Aug 27

Partial Lunar Eclipse
2006 Sep 07

Partial Lunar Eclipse
2024 Sep 18

Penumbral Lunar Eclipse
2042 Sep 29

Penumbral Lunar Eclipse
2060 Oct 09

Penumbral Lunar Eclipse
2078 Oct 21

Penumbral Lunar Eclipse
2096 Oct 31

Penumbral Lunar Eclipse
2114 Nov 12

Penumbral Lunar Eclipse
2132 Nov 23

Penumbral Lunar Eclipse
2150 Dec 04

Penumbral Lunar Eclipse
2168 Dec 14

Penumbral Lunar Eclipse
2186 Dec 26

Penumbral Lunar Eclipse
2205 Jan 06

Penumbral Lunar Eclipse
2223 Jan 18

Penumbral Lunar Eclipse
2241 Jan 28

Penumbral Lunar Eclipse
2259 Feb 08

Penumbral Lunar Eclipse
2277 Feb 19

Penumbral Lunar Eclipse
2295 Mar 02

Penumbral Lunar Eclipse
2313 Mar 13

Penumbral Lunar Eclipse
2331 Mar 25

Penumbral Lunar Eclipse
2349 Apr 04

Penumbral Lunar Eclipse
2367 Apr 15

Penumbral Lunar Eclipse
2385 Apr 26

Penumbral Lunar Eclipse
2403 May 07

Statistics for Lunar Eclipses of Saros 118

Lunar eclipses of Saros 118 all occur at the Moon’s ascending node and the Moon moves southward with each eclipse. The series will begin with a penumbral eclipse near the northern edge of the penumbra on 1105 Mar 02. The series will end with a penumbral eclipse near the southern edge of the penumbra on 2403 May 07. The total duration of Saros series 118 is 1298.17 years.

Summary of Saros 118
First Eclipse 1105 Mar 02
Last Eclipse 2403 May 07
Series Duration 1298.17 Years
No. of Eclipses 73
Sequence 9N 7P 28T 8P 21N

Saros 118 is composed of 73 lunar eclipses as follows:

Lunar Eclipses of Saros 118
Eclipse Type Symbol Number Percent
All Eclipses - 73100.0%
PenumbralN 30 41.1%
PartialP 15 20.5%
TotalT 28 38.4%

The 73 lunar eclipses of Saros 118 occur in the order of 9N 7P 28T 8P 21N which corresponds to the following.

Sequence Order of Lunar Eclipses in Saros 118
Eclipse Type Symbol Number
Penumbral N 9
Partial P 7
Total T 28
Partial P 8
Penumbral N 21

The 73 eclipses in Saros 118 occur in the following order : 9N 7P 28T 8P 21N

The longest and shortest eclipses of Saros 118 as well as largest and smallest partial eclipses appear below.

Extreme Durations and Magnitudes of Lunar Eclipses of Saros 118
Extrema Type Date Duration Magnitude
Longest Total Lunar Eclipse 1754 Apr 0701h39m23s -
Shortest Total Lunar Eclipse 1880 Jun 2200h37m09s -
Longest Partial Lunar Eclipse 1375 Aug 1203h14m48s -
Shortest Partial Lunar Eclipse 2024 Sep 1801h02m49s -
Longest Penumbral Lunar Eclipse 1249 May 2804h25m12s -
Shortest Penumbral Lunar Eclipse 1105 Mar 0200h56m18s -
Largest Partial Lunar Eclipse 1375 Aug 12 - 0.95134
Smallest Partial Lunar Eclipse 2024 Sep 18 - 0.08491

Eclipse Publications

by Fred Espenak

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Calendar

The Gregorian calendar (also called the Western calendar) is internationally the most widely used civil calendar. It is named for Pope Gregory XIII, who introduced it in 1582. On this website, the Gregorian calendar is used for all calendar dates from 1582 Oct 15 onwards. Before that date, the Julian calendar is used. For more information on this topic, see Calendar Dates.

The Julian calendar does not include the year 0. Thus the year 1 BCE is followed by the year 1 CE (See: BCE/CE Dating Conventions). This is awkward for arithmetic calculations. Years in this catalog are numbered astronomically and include the year 0. Historians should note there is a difference of one year between astronomical dates and BCE dates. Thus, the astronomical year 0 corresponds to 1 BCE, and astronomical year -1 corresponds to 2 BCE, etc..

Eclipse Predictions

The eclipse predictions presented here were generated using the JPL DE406 solar and lunar ephemerides. The lunar coordinates have been calculated with respect to the Moon's Center of Mass.

The largest uncertainty in the eclipse predictions is caused by fluctuations in Earth's rotation due primarily to tidal friction of the Moon. The resultant drift in apparent clock time is expressed as ΔT and is determined as follows:

  1. pre-1950's: ΔT calculated from empirical fits to historical records derived by Morrison and Stephenson (2004)
  2. 1955-present: ΔT obtained from published observations
  3. future: ΔT is extrapolated from current values weighted by the long term trend from tidal effects

A series of polynomial expressions have been derived to simplify the evaluation of ΔT for any time from -2999 to +3000. The uncertainty in ΔT over this period can be estimated from scatter in the measurements.

Acknowledgments

Some of the content on this web site is based on the books Five Millennium Canon of Lunar Eclipses: -1999 to +3000 and Thousand Year Canon of Lunar Eclipses 1501 to 2500. All eclipse calculations are by Fred Espenak, and he assumes full responsibility for their accuracy.

Permission is granted to reproduce eclipse data when accompanied by a link to this page and an acknowledgment:

"Eclipse Predictions by Fred Espenak, www.EclipseWise.com"

The use of diagrams and maps is permitted provided that they are NOT altered (except for re-sizing) and the embedded credit line is NOT removed or covered.