An ethnoarithmetic excursion into the Javanese calendar
AAn ethnoarithmetic excursion into theJavanese calendar
Natanael Karjanto and Franc¸ois Beauducel
Abstract
A perpetual calendar, a calendar designed to find out the day of the weekfor a given date, employs a rich arithmetical calculation using congruence. Zeller’scongruence is a well-known algorithm to calculate the day of the week for any Julianor Gregorian calendar date. Another rather infamous perpetual calendar has beenused for nearly four centuries among Javanese people in Indonesia. This Javanesecalendar combines the
Saka
Hindu, lunar Islamic, and western Gregorian calendars.In addition to the regular seven-day, lunar month, and lunar year cycles, it alsocontains five-day pasaran , 35-day wetonan , 210-day pawukon , octo-year windu ,and 120-year kurup cycles. The Javanese calendar is used for cultural and spiritualpurposes, including a decision to tie the knot among couples. In this chapter, we willexplore the relationship between mathematics and the culture of Javanese peopleand how they use their calendar and the arithmetic aspect of it in their daily lives.We also propose an unprecedented congruence formula to compute the pasaran day. We hope that this excursion provides an insightful idea that can be adopted forteaching and learning of congruence in number theory.
Introduction
Arithmetic and number theory find applications in various cultures throughout theworld. In addition to solving everyday problems using elementary arithmetic opera-
N. KarjantoDepartment of Mathematics, University College, Sungkyunkwan University, Natural Science Cam-pus, 2066 Seobu-ro, Suwon 16419, Republic of Korea e-mail: [email protected]
F. BeauducelUniversit´e de Paris, Institut de physique du globe de Paris, CNRS, 75005 Paris, FranceInstitut de recherche pour le d´eveloppement, Research and Development Technology Center forGeological Disaster, Balai Penyelidikan dan Pengembangan Teknologi Kebencanaan Geologi(BPPTKG), Jl Cendana No. 15, Yogyakarta 55166, Indonesia e-mail: [email protected] a r X i v : . [ m a t h . HO ] D ec Natanael Karjanto and Franc¸ois Beauducel tions, our ancient ancestors also developed and invented perpetual calendars withoutany aid of modern electronic calculators and the computer. A perpetual calendar is asystem dealing with periods of time that occur repeatedly. It is organized into days,weeks, months, and years. A date of a calendar structure refers to a particular daywithin that system. A calendar is used for various civil, administrative, commercial,social, and religious purposes.The English word “calendar” is derived from the Latin word which refers to thefirst day of the month in the Roman calendar. It is related to the verb calare (“toannounce solemnly, to call out”), which refers to the “calling” of the new moonwhen it was visible for the first time (Brown 1993). Another source mentions thatthe modern English “calendar” comes from the Middle English calender , which wasadopted from the Old French calendier . It originated from the Latin word calendar-ium , which meant a “debt book, account book, register”. In Ancient Rome, interestswere tracked in such books, accounts were settled, and debts were collected on thefirst day ( calends ) of each month (Stakhov 2009).
MathematicsEducation AstronomyCultureME EM MA EAAECEEME EAEMAE EMAJC
Fig. 1
A theoretical framework for an ethnoarithmetic study of the Javanese calendar. At the firstlevel of the intersection, ME means Mathematics Education, EM means Ethnomathematics, MAmeans Mathematics Astronomy, AE means Astronomy Education, EA means Ethnoastronomy, andCE means Cultural Education. At the second level of the intersection, EME means Ethnomathemat-ics Education, MAE means Mathematics Astronomy Education, EMA means EthnomathematicsAstronomy, and EAE means Ethnoastronomy Education. The third level of the intersection is theheart of discussion, we have JC as the Javanese calendar.
Generally, the calculation of and periods in the calendrical system are synchro-nized with the cycle of the Sun or the Moon. Hence, the names solar, lunar, andlunisolar calendars, where the latter combined both the Moon phase and the tropical n ethnoarithmetic excursion into the Javanese calendar 3 (solar) year. Our current Gregorian and the previously Julian calendars are solar-based calendars, as well as the ancient Egyptian calendar. An example of the lunarcalendar is the Islamic calendar. Prominent examples of the lunisolar calendar arethe Hebrew, Chinese, Hindu, and Buddhist calendars (Richards 1998; Dershowitzand Reingold 2018).Studying calendar systems from any culture cannot be separated from attempt-ing to gain insight and understanding not only the arithmetic behind it but also itsinterconnectivity with mathematics in general, history of mathematics, astronomy,mathematics education, and the sociocultural aspect itself. Hence, the study of per-petual calendars is encompassed by the fields of ethnomathematics and ethnoas-tronomy, the research areas where diverse cultural groups embrace, practice, anddevelop mathematics and astronomy into their daily lives.The theoretical framework for a discussion on the Javanese calendar consideredin this chapter can be summarized in Figure 1. Although the title of this chaptercontains the term “ethnoarithmetic”, indeed that covering a topic on the Javanesecalendar encompasses other aspects beyond the cultural and mathematical, in thiscase, arithmetical aspect per se. As we observe at the third level of the Venn dia-gram presented in Figure 1, an excursion into the Javanese calendar intersects andincludes four distinct but related disciplines: Mathematics, Education, Culture, andAstronomy.Fundamental work in the area of ethnomathematics has been documented by As-cher (2002). The author elaborated on several mathematical ideas and their culturalembedding of people in traditional or small-scale cultures, with some emphasis ontime structure and the logic of divination. In particular, the book also covered an ex-planation of the Balinese calendar. For discussion of the Balinese calendrical systemand its multiple cycles, consult Vickers (1990); Darling (2004); Proudfoot (2007);Ginaya (2018), and Gisl´en and Eade (2019c).To the best of our knowledge, the only monograph that discusses an intersectionof three components of the theoretical framework is a volume edited by Rosa et al(2017). The book covers diverse approaches and perspectives of ethnomathematicsto mathematics education, particularly in several non-Western cultures. Since thesetopics stimulate debates not only on the nature of mathematical knowledge and theknowledge of a specific cultural group but also on the pedagogy of mathematicsclassroom, the field of ethnomathematics certainly offers a possibility for improvingmathematics education across cultures.A collection of essays dealing with the mathematical knowledge and beliefs ofcultures outside the Western world is compiled by Selin and D’Ambrosio (2000).The essays address the connections between mathematics and culture, relate math-ematical practices in various cultures, and discuss how mathematical knowledgetransferred from East to West. A coverage of calendars in various cultures is alsobriefly touched.Since many calendrical systems are invented based on the movement of celestialbodies, particularly the Sun and Moon, we cannot dismantle the role of Astronomyin the study of calendars, including the Javanese one. Various civilizations incorpo-rate the cyclical movements of both the Sun and Moon into their calendrical sys-
Natanael Karjanto and Franc¸ois Beauducel tems (Ruggles 2015). Some examples of this calendrical-astronomical relationshipcan be observed amongst others in the Jewish (Cohn 2007), Indian (Dershowitz andReingold 2009), Chinese (Martzloff 2000, 2016), mainland Southeast Asia (Eade1995), and Islamic calendars (Proudfoot 2006).An explanation of the mathematical and astronomical details of how many cal-endars function has been covered extensively by Dershowitz and Reingold (2018).A related series with non-Western ethnomathematics is a book on non-Westernethnoastronomy that has been edited by Selin and Sun (2000). In particular, thebook also dedicated one chapter on an astronomical feature of the Javanese calen-dar, where a season keeper ( pranotomongso or pranata mangsa ) guides agriculturalactivities among rural peasants in Java (Daldjoeni 1984; Ammarell 1988; Hidayat2000). The readers might be interested to compare this with the cultural productionof Indonesian skylore across three ethnic groups: Banjar Muslim, Meratus Dayak,and Javanese peoples (Ammarell and Tsing 2015).Integrating the Javanese calendar into elementary school education as an ethno-mathematics study has been attempted by Utami et al (2020). Another attempt isto embed some topics related to calendrical systems into the first-year seminar onthe mathematics of the pre-Columbian Americas (Catepill´an 2016). A study fromTaipei, Taiwan, on the movements of the Moon at the primary level, introducedpupils to both the Gregorian and Chinese calendars in the context of physical class-room environments (Hubber and Ramseger 2017).Although we propose an intersection of only four disciplines in our theoreticalframework, the list is by no means exhaustive. Another possibility is to includepsychology or the interaction between mathematics and psychology. For instance,a theoretical foundation on the calendrical system and the psychology of time hasbeen modeled by Rudolph (2006). In particular, the author proposed that Balinese(also equally applied to Javanese) time might be neither ‘circular’ nor ‘linear’, but profinite . Since the Javanese calendrical systems involve five-day pasaran , seven-day saptawara/dinapitu , and 30 wuku cycles, it could be modeled by the group of profinite integers (cid:98) Z . This group bundles together all different sets of the ring of p -adic integers Z p and various finite sets Z / ( p ) of integers modulo p , where p denotesprime integers (Milne 2020).A discussion on calendar timekeeping scheme in Southeast Asia is coveredby Gisl´en (2018). An overview of the calendars in Southeast Asia is given by Gisl´enand Eade (2019a). In their subsequent papers, they and Lˆan also discussed calen-dars from Burma, Thailand, Laos, and Cambodia (Gisl´en and Eade 2019b), Viet-nam (Lˆan 2019), Malaysia and Indonesia (Gisl´en and Eade 2019c), eclipse calcula-tion (Gisl´en and Eade 2019d), and chronicle inscriptions (Gisl´en and Eade 2019e).See also Eade (1995); ˆOhashi (2009), and (Golzio 2012) for basic facts and furtherexplanations of the calendrical systems in India and (Mainland) Southeast Asia.This chapter is organized as follows. After this Introduction, the following sec-tion briefly covers the calendars from ancient and contemporary times, which in-cludes the pre-Gregorian and Gregorian calendars. After that, a discussion on theJavanese calendar in the context of ethnoarithmetic will be dedicated exclusively inone section. The final section concludes our discussion. n ethnoarithmetic excursion into the Javanese calendar 5 Ancient and modern calendars
This section briefly covers the calendar in the pre-Gregorian era and Zeller’s con-gruence algorithm in the Gregorian calendar.
Pre-Gregorian calendars
Before the Gregorian calendar that we are using today, numerous calendars havebeen used in various parts of the world. The Egyptian calendar was among the firstsolar calendars with its history dated back to the fourth millennium BCE.A Mesoamerican civilization developed by the Maya peoples also developed acalendar system where the year was divided into 18 months of 20 days (Ascher2002; Stakhov 2009). The Mayan calendar system contains three separate calendars,and although they are not related mathematically, all of them are linked in a singlecalendar system. The first one is called the long count, used by the Mayans to mea-sure date chronology for history recording. The second one is the
Haab calendar,a non-chronological civil calendar. The third one is the Mayan religious calendar,also non-chronological, called the
Tzolkin (Ascher 2002; Cohn 2007).Related to the Maya civilization is the Inca Empire, where the latter also devel-oped its calendar system, which was based on several different astronomical cycles,including the solar year, the synodic and sidereal lunar cycles, and the local zenithperiod (Urton and Llanos 2010). A variety of mathematical development amongthe native Americans from the prehistoric to present has been compiled by Closs(1996). In particular, one chapter of the book discusses the calendrical system of theNuu-chah-nulth (formerly referred to as the Nootka), one of the indigenous peoplesof the Pacific Northwest Coast in Canada (Folan 1986).Some calendars are based on lunisolar, and one of them is the Jewish calendar.Also called the Hebrew calendar, it is still used until today, mainly for Jewish reli-gious observance. Although the Jewish calendar was developed in its current formatduring the Talmud period in the fifth century CE by Rabbi Hillel II, the up to datecounting has accumulated more than 5000 years (Ascher 2002; Cohn 2007). For ourinformation, AM 5781 will begin at sunset on Friday, 18 September 2020, and willend at sunset on Monday, 6 September 2021 CE. Here, AM means
Anno Mundi , theLatin phrase for “in the year of the world”.Although the traditional Chinese calendar is also a lunisolar type, the most fun-damental component is the sexagenary cycle, a cycle of sixty terms marked by co-ordination between 12 celestial stems and ten terrestrial branches, which is alsoknown as the Stems-and-Branches or g¯anzh¯ı ( 干 支 ) (Martzloff 2000). A discussionon the mathematical aspect of the Chinese calendar has been covered extensivelyby Aslaksen (2001, 2002, 2006). A historical aspect of the Chinese calendar is dis-cussed by Sun (2015). Astronomical aspects and the mathematical structures under-lying the calculation techniques of the Chinese calendar are highlighted by Martzloff(2016). Natanael Karjanto and Franc¸ois Beauducel
The
Hijri , or Islamic calendar, is a lunar calendar consisting of 12 lunar (synodic)months in a year of 354 or 355 days. It is still widely used in predominantly Muslimcountries alongside the Gregorian calendar, primarily for religious purposes. Thecurrent counting started from 622 CE, commemorating the emigration of ProphetMuhammad and his companions from Mecca to Medina ( hijra ) (Hassan 2017). Inthe Gregorian calendar reckoning, the current Islamic year is 1422 AH, which ap-proximately runs from 20 August 2020 until 9 August 2021. AH means
Anno He-girae , the Latin phrase for “in the year of the Hijra”. In particular, the history ofMuslim calendars in Southeast Asia in the historical and cultural context has beensuccessfully traced by Proudfoot (2006).
Gregorian calendar
The language of congruences is a basic building block in arithmetic and numbertheory. It allows us to operate with divisibility relationships in a similar way aswe deal with equalities. Congruences have many applications, and one of them isto determine the day of the week for any date for a given perpetual calendar. Inparticular, the procedure for finding the day of the week for a given date in theGregorian calendar has been discussed by Carroll (1887); Conway (1973); Rosen(2011). See also Gardner (1996); Cohen (2000).The Gregorian calendar was promulgated by Pope Gregory XIII and is a replace-ment of the Julian calendar, proposed by Julius Caesar in 46 BC. Starting from 1582,the Catholic states were among the first countries to adopt the Gregorian calendarby skipping ten days in October, Thursday, 4 October 1582 was followed by Fri-day, 15 October 1582. Greece and Turkey are among the last countries that adoptedthe Gregorian calendar when they changed on 1 March 1923 and 1 January 1926,respectively.Let W denote the day of the week from Saturday = 0 to Friday = 6, k denote theday of the month, m denote month, and N denote year. For the month, the conventionis March = 3, April = 4, . . . , but January = 13, and February = 14. For the year, N isthe current year unless the month is January or February, for which N is the previousyear. The relationship between year and century is given by N = C + Y , where C denotes zero-based century and Y denotes a two-digit year. Note that the purposeof adopting this expression is not to confuse C with the standard century number,which is C + W of day k of month m of year N is given by Zeller’s congruence algorithm (Zeller1882, 1883, 1885, 1887): W ≡ (cid:18) k + (cid:22) ( m + ) (cid:23) + Y + (cid:22) Y (cid:23) + (cid:22) C (cid:23) − C (cid:19) ( mod 7 ) . (1)Here, (cid:98) x (cid:99) denotes the floor function or greatest integer function and mod is themodulo operation or remainder after division. n ethnoarithmetic excursion into the Javanese calendar 7 As an example, we are interested in finding the days of the week when a Ja-vanese heroine and educator Raden Adjeng Kartini was born and passed away. Shewas born in Jepara, a town on the north coast of Java, around 80 km north-east di-rection from Semarang, the present capital of Central Java province in Indonesia.Kartini was a pioneer for girls’ education and women’s emancipation rights in In-donesia, at the time when Indonesia was still a part of the Dutch East Indies colonialempire. She could be correlated with her European counterparts, including an En-glish advocate of women’s right Mary Wollstonecraft (27 April 1759–10 September1797) or a Finnish social activist Minna Canth (19 March 1844–12 May 1897) (cf.Kartini 1911, 1920; Wollstonecraft 1792; Canth 1885).Kartini was born on 21 April 1879, so we have k = m = N = C = Y =
79. She passed away on 17 September 1904, at the age of 25, and weidentify that k = m = N = C =
19, and Y =
4. Using Zeller’s congru-ence formula (1), the days when Kartini was born W b and passed away W d can becalculated as follows, respectively: W b ≡ (cid:18) + (cid:22) ( ) (cid:23) + + (cid:22) (cid:23) + (cid:22) (cid:23) − (cid:19) ( mod 7 ) ≡ ( + + + + − ) ( mod 7 ) ≡ ( mod 7 ) ≡ ( mod 7 ) W d ≡ (cid:18) + (cid:22) ( ) (cid:23) + + (cid:22) (cid:23) + (cid:22) (cid:23) − (cid:19) ( mod 7 ) ≡ ( + + + + − ) ( mod 7 ) ≡ ( mod 7 ) ≡ ( mod 7 ) . Hence, Kartini was born on Monday, 21 April 1879 and passed away on Saturday,17 September 1904. She was buried at Bulu Village, Rembang, Central Java, around100 km east of Jepara.
Javanese calendar
This section features the main characteristics of the Javanese calendar. We startwith the geographical location of the island of Java, the Javanese people, and abrief historical background of the calendar. After providing a detailed discussion,we close the section by computer implementation of the Javanese calendar.
Where is Java?
Java is an island in Indonesia, not a programming language, although the latter wasrenamed after some Javanese coffee by its founders. It is located in the southernhemisphere, around 800 km from the Equator. It extends from latitude 6 ◦ to 8 ◦ South, and longitude 105 ◦ to 114 ◦ East. With an area of 150,000 square kilometers,
Natanael Karjanto and Franc¸ois Beauducel it is about 1000 km long from west to east and around 200 km wide from north tosouth. The island lies between Sumatra to the west and Bali to the east. It is borderedby the Java Sea on the north and the Indian Ocean on the south (see Figure 2). It isthe world’s 13 th largest island (Cribb 2000). Who are Javanese people?
The Javanese people are a native ethnic group to the island of Java. They form thelargest ethnic group in Indonesia, with more than 95 million people live in Indone-sia and approximately 5 million people live abroad. Although they predominantlyreside in the central and eastern parts of the island, they are also scattered in var-ious parts of the country (Taylor 2003; Ananta et al 2015). The Javanese peoplepossess and speak a distinct language from Indonesian, called the Javanese lan-guage, a member of the Austronesian family of languages written in Javanese script hanacaraka or dentawyanjana . Thanks to its long history and legacy of Hinduismand Buddhism in Java, the language adopted a large number of Sanskrit words (Marrand Milner 1986; Errington 1998). ° S ° S ° S ° S ° S YogyakartaSemarangSurakartaJakartaBandung Surabaya
Sumatra Madura Bali
Java SeaIndian Ocean
Javanese
Sundanese
Betawi
Madurese
Balinese
Fig. 2
The situation of the Java island, main cities, and present spoken languages: Javanese (Cen-tral and East Java, and a small enclave in North-West Java), Sundanese (West Java), Betawi (in andaround Jakarta metropolitan area), Madurese (Madura Island and a part of North-Eastern Java, andBalinese (Bali Island and a small part of Eastern Java). Basemap uses ETOPO5 and SRTM3 topo-graphic data and shaded relief mapping code (Beauducel 2020a). ETOPO5 is a five arc-minute res-olution relief model for the Earth’s surface that integrates land topography and ocean bathymetrydataset. SRTM3, the Shuttle Radar Topography Mission, is a three arc-second resolution digitaltopographic database of land elevation limited to latitudes from 60 ◦ South to 60 ◦ North.n ethnoarithmetic excursion into the Javanese calendar 9
A background of the Javanese calendar
Javanese people use the Javanese calendar simultaneously with two other perpetualcalendars, the Gregorian and Islamic calendars. The former is the official calendarof the Republic of Indonesia and the latter is used mainly for religious purposes.Prior to the adoption of the Javanese calendar in 1633 CE, Javanese people used acalendrical system based on the lunisolar Hindu
Saka calendar (Ricklefs 1993).
Fig. 3
Table list of 8 taun , 12 wulan , 7 dinapitu , and 5 pasaran names in Javanese Sanskrit, afterWarsapradongga (1892).0 Natanael Karjanto and Franc¸ois Beauducel
The Javanese calendar was inaugurated by Sultan Agung Adi Prabu Hanyakraku-suma (1593–1645 CE), or simply Sultan Agung, the third Sultan of Mataram whoruled Central Java from 1613 CE until 1645 CE. Although the counting of the yearfollows the Saka calendar, the Javanese calendar employs a similar lunar year asthe Hijri calendar instead of the solar year system like the former (Gisl´en and Eade2019a). The Javanese calendar is sometimes referred to as AJ (
Anno Javanico ), theLatin phrase for Javanese Year. Since 2008, the difference between the Gregorianand Javanese calendars is about 67 years, where the current year 2020 CE corre-sponds to 1953 AJ (Oey 2001; Raffles 1817).
Table 1
Main cycles of the Javanese calendar.Cycle Name Length Unit CommentPancawara 5 day Javanese week5 pasaran names (see Table 2)Wuku 7 day Gregorian/Islamic week7 dinapitu names (see Table 3)30 wuku namesWetonan 35 day 35-day names as
Dinapitu and
Pasaran
Wulan 29 or 30 day day number in a wulan is dina wulan names (see Table 5)Pawukon 30 Wuku
30 weeks ≡
210 daysTaun 12
Wulan
354 or 355 days taun number starts on 1555 AJ8 taun names (see Table 6)Windu 8
Taun wulan ≡ Wetonan ≡ Windu taun , 4 windu namesLambang 2 Windu taun , 2 lambang namesKurup 15 Windu
Taun − ≡ kurup names until today (see Table 8) Some characteristics of the Javanese calendar
Different from many other calendars that employ a seven-day week cycle, the Ja-vanese calendar adopts a five-day week cycle, known as pancawara . Amalgamatingwith the seven-day week cycle of the Gregorian and Islamic calendars, namely the saptawara cycle, one obtain the 35-day cycle, known as wetonan (Darling 2004).This foundation cycle interferes with additional cycles:• a 210-day cycle of 30 weeks, named as the pawukon ;• a more complex combination of the lunar month wulan , which has 29 or 30 days,the lunar year taun , which is 12 lunar months, windu , which is eight lunar years, n ethnoarithmetic excursion into the Javanese calendar 11 and finally kurup of 15 windu or 120 lunar years minus one day, which matchesexactly the Islamic calendar cycle (Proudfoot 2007).There are also additional cycles, but they are no longer used in the Javanesetradition. To be exhaustive, we list them here (Richmond 1956; Zerubavel 1989):• a six-day cycle called the
Paringkelan : ‘Tungle’, ‘Aryang’, ‘Wurukung’, ‘Pan-ingron’, ‘Uwas’, and ‘Mawulu’;• an eight-day cycle called the
Padewan : ‘Sri’, ‘Indra’, ‘Guru’, ‘Yama’, ‘Rudra’,‘Brama’, ‘Kala’, and ‘Uma’;• a nine-day cycle called the
Padangon : ‘Dangu’, ‘Jagur’, ‘Gigis’, ‘Kerangan’,‘Nohan’, ‘Wogan’, ‘Tulus’, ‘Wurung’, and ‘Dadi’;The list of main cycles and characteristics are summarized in Table 1 and are de-tailed in the following subsubsections. Figure 3 shows an original table of the maincycles’ names written in the Javanese script hanacaraka . Table 2
Names of the five pasaran days in the Javanese week and commonly associated symbols.Ngoko Krama Meaning Element Color Direction PosturePon Petak – water yellow West sleepWage Cemeng dark earth black North sit downKliwon Asih affection spirit mixed color focus/centre stand-upLˆegi Manis sweet air white East turn backPahing Pahit bitter fire red South to face
Pancawara and Pasaran
The Javanese five-day cycle is named pancawara and made of five days knownas pasaran : ‘Pon’, ‘Wage’, ‘Kliwon’, ‘Lˆegi’, and ‘Pahing’ (or ‘Paing’). The wordcomes from ‘pasar’ which means market. Historically, the market was held and op-erated on a five-day cycle based on a pasaran day, e.g., ‘Pasar Kliwon’, or ‘PasarLegi’. Until today, most of the markets in Java still have a pasaran name like the Kli-won Market in Kudus, Central Java, although they usually operate every day (Oey2001).Each pasaran is associated with some symbols, in particular, the five classicalelements of Aristotle, colors, cardinal directions (note that the Javanese culture hasfive of them including a Center), and human posture (Pigeaud 1977), (cf. Brinton1893). See Table 2.The computation of the pasaran day from the Gregorian or Islamic calendardate can be performed using a similar strategy as Zeller’s congruence algorithm.Indeed, the formula is based on the observation that the day of the week progressespredictably based upon each subpart of the date, i.e., day, month, and year. In this case, we will consider the five-day Javanese week pasaran . Each term within theformula is used to calculate the offset needed to obtain the correct day.Let P denote the pasaran day, in the order of Pon =
0, Wage =
1, Kliwon = =
3, and Pahing =
4. We now propose the following pasaran day congruenceformula: P ≡ (cid:18) k + (cid:22) ( m + ) (cid:23) + (cid:22) Y (cid:23) + C − (cid:22) C (cid:23)(cid:19) ( mod 5 ) . (2)where k , m , C , and Y denote the same variables as the ones defined for Zeller’scongruence formula (see expression (1) in the previous section). Each term in (2)can be analyzed as follows:• k represents the progression of the day of the week based on the day of the monthsince each successive day results in an additional offset of one;• the term + (cid:106) ( m + ) (cid:107) adjusts for the variation in the days of the month. Indeed,starting from March to February, the days in a month are {
31, 30, 31, 30, 31,31, 30, 31, 30, 31, 31, 28/29 } . The last element, February’s 28/29 days, is not aproblem since the formula had rolled it to the end. The number of days for the11 first elements of this sequence modulo 5 (still starting with March) would be {
1, 0, 1, 0, 1, 1, 0, 1, 0, 1, 1 } which basically alternates the subsequence {
1, 0,1, 0, 1 } every five months and give the number of days that should be added tothe next month. The fraction ≡ . m + ( mod 5 ) ≡
0, there is no needto add an offset for the normal year;• for the leap years, 366 ( mod 5 ) ≡ + (cid:4) Y (cid:5) ;• there are 36 ,
524 days in a normal century and 36 ,
525 days in each century di-visible by 400; the term 4 C adds 36 , ( mod 5 ) ≡ − (cid:4) C (cid:5) removes these 4 days for a century divisible by 400;• the overall function, ( mod 5 ) , normalizes the result to reside in the range from 0to 4, which yields the index of the correct day for the date being analyzed.For example, to find the pasaran of the very first day in the Javanese calendar (1Sura 1555 AJ Alip) which corresponds to 8 July 1633 CE, we have k = m = C =
16, and Y =
33. Using (2), we obtain P ≡ + + + − ≡ ( mod 5 ) ≡
3. Hence, 8 July 1633 CE was a ‘Lˆegi’. From the previously considered example,the pasaran days when Kartini was born P b and passed away P d can be calculatedas follows: P b ≡ ( + + + − ) ( mod 5 ) ≡ ( mod 5 ) ≡ ( mod 5 ) P d ≡ ( + + + − ) ( mod 5 ) ≡ ( mod 5 ) ≡ ( mod 5 ) . Hence, both 21 April 1879 and 17 September 1904 fall on a Pahing. n ethnoarithmetic excursion into the Javanese calendar 13
Fig. 4
An example of the Javanese calendar for December 2020 CE issued by the Kraton palacein Yogyakarta. It contains information on
Jimakir taun , Bakdamulud and
Jumadilawal wulans , pasaran day, padinan weekday, wuku , and paringkelan amongst others. Dinapitu, Wuku and Pawukon
Dinapitu literally means ‘day seven’ in Javanese, and corresponds to the day namesin the Gregorian/Islamic calendar week with exact equivalence, i.e., from Mon- day to Sunday: ‘Sˆen`en’, ‘Selasa’ (or ‘Slasa’), ‘Rˆebo’, ‘Kˆemis’, ‘Jemuwah’ (or ‘Ju-mungah’), ‘Sˆetu’, and ‘Ngahad’ (or ‘Ahad’). In recent literature, we often find thename of the days in the Indonesian language (from Monday to Sunday: ‘Senin’,‘Selasa’, ‘Rabu’, ‘Kamis’, ‘Jumat’, ‘Sabtu’, and ‘Minggu’). They are also associ-ated with particular symbolic meanings. See Table 3. The names of the days of theweek are similar in both languages as they are absorbed from Arabic except forSunday in Indonesian which was assimilated from the Portuguese ‘Domingo’.
Table 3
List of names of the seven days in a wuku
Gregorian week (cf. Rizzo 2020).Dinapitu Padinan Week Day SymbolNgahad Dite Sunday silentSˆen`en Soma Monday forwardSelasa Anggara Tuesday backwardRˆebo Buda Wednesday turn leftKˆemis Respati Thursday turn rightJemuwah Sukra Friday upSˆetu Tumpak Saturday down
The seven-day cycle is called saptawara or padinan and a week is named a wuku .The period of 30 wuku makes the pawukon cycle, i.e., 210 days (Proudfoot 2007).There are 30 different names of wuku (Soebardi 1965; Headley 2004). See Table 4.Figure 4 shows an example of the Javanese calendar with padinan , pasaran , wuku ,and paringkelan information amongst others. Table 4
List of names of the 30 different wuku in a pawukon .1 Sinta 7 Warigalit 13 Langkir 19 Tambir 25 Bala2 Landep 8 Warigagung 14 Mandasiya 20 Medangkungan 26 Wugu3 Wukir 9 Julungwangi 15 Julungpujut 21 Maktal 27 Wayang4 Kurantil 10 Sungsang 16 Pahang 22 Wuye 28 Kulawu5 Tolu 11 Galungan 17 Kuruwelut 23 Manahil 29 Dukut6 Gumbreg 12 Kuningan 18 Marakeh 24 Prangbakat 30 Watugunung
Wetonan
The wetonan cycle combines the five-day pancawara cycle with the seven-day wuku week cycle. Each wetonan cycle lasts for 7 × =
35 days, with 35 distinct combina-tions of the couple ‘ dinapitu pasaran ’ which is called the weton . Figure 5 displaysthe 35-day wetonan cycle of the dual dinapitu pasaran . The seven-day wuku cycleis arranged clockwise from Monday to Sunday and the five-day pasaran day pro-gresses from the center of the disk outwardly from Legi to Kliwon. It shows a spiral n ethnoarithmetic excursion into the Javanese calendar 15 pattern that repeats seven times and sweeping five sectors each, indicated by solidblack, solid blue, dashed-black, dashed-blue, dashed-dotted black, dashed-dottedblue, and dotted black spirals, respectively.
Lˆegi PahingPonWag´eKliwon MondaySundaySaturdayFriday Thursday Wednesday Tuesday1 2345 6 7 8 910111213 14 1516171819 20 21 22 232425 2627 28 29 30313233 34 35
Fig. 5
A 35-day cycle of wetonan in the Javanese calendar. The regular Gregorian seven-day cycleis arranged clockwise from Monday to Sunday. The five-day pasaran cycle is arranged from insideto outside. The white disk, red, blue, green, and yellow rings correspond to Lˆegi, Pahing, Pon,Wag´e, and Kliwon, respectively.
Although the weton can be calculated independently using either equation (1)or (2), it is also possible to propose a single congruence formula: w = k + (cid:22) ( m + ) (cid:23) + Y + (cid:22) Y (cid:23) + C + (cid:22) C (cid:23) + W ≡ w ( mod 7 ) P ≡ w ( mod 5 ) (3) where k , m , C , and Y are the same variables as defined for previous congruenceformulas, w is a 35-day offset congruence, and W or P corresponds to the index of dinapitu or pasaran day, respectively. Each term of the congruence can be analyzedas follows:• k represents the progression of the day of the week based on the day of the month,since each successive day results in an additional offset of one;• + (cid:106) ( m + ) (cid:107) adds the proper amount of days for each month, considering Jan-uary and February as the 13 th and 14 th months of the previous year, respectively;• + Y adds an offset of 365 ( mod 35 ) ≡
15 days for the common, non-leap years;• + (cid:4) Y (cid:5) adds one more day for the leap years since 366 ( mod 35 ) ≡ + C adds 36 , ( mod 35 ) ≡
19 days for any regular century (a century withnon-leap year);• + (cid:4) C (cid:5) adds one more day for a century leap year that is divisible by 400 since36 , ( mod 35 ) ≡ + dinapitu W and pasaranP after ( mod 7 ) and ( mod 5 ) , respectively.Let take the same example of 8 July 1633 CE with k = m = C =
16, and Y =
33. Using (3) we have w ≡ + + + + + ≡ W ≡ ( mod 7 ) ≡
6, and P ≡ ( mod 5 ) ≡
3. Hence, the 8 July 1633 CE was a ‘Jemuwah Lˆegi’.Notice that we are able to replace both the congruence formulas (1) and (2) using ouroriginal single congruence relationship (3). Obtaining both dinapitu and pasaran days using a tabular method has been attempted by Arciniega (2020) and a
Java application based on the Indian calendar for calculating the Javanese calendar hasbeen developed by Gisl´en and Eade (2019e).The wetonan cycle is especially important for divinatory systems, celebrations,and rites of passage as birth or death. Commemorations and events are held on daysconsidered to be auspicious. In particular, the weton of birth is considered playingan important role in any individual personality, in a similar way as a zodiac signdoes in Western astrology. The two weton days of future spouses are supposed todetermine their background nature compatibility and are used to compute the bestdate of marriage using a strict arithmetic formula (Utami et al 2019). It also figuresin the timing of many ceremonies of slametan ritual meal and many other traditionaldivinatory systems (Utami et al 2020). The eve of ‘Jumat Kliwon’ is consideredparticularly popular and auspicious for magical and spiritual matters (Darling 2004;Arciniega 2020).The anniversary of Javanese birthday occurs every 35 days, so about a thousandtimes in a century (exactly 1043 times). For a newborn baby, the first occurrence of weton , i.e., aged 35 days, is named ‘selapanan’ where the parents will cut hairs andnails of their child for the first time. For adults, the weton of birth is considered asan eminent day, not festive but expressing humility and blissfulness. For example,a person may fast (sometimes also the day before and the day after), stop his com-mercial activity, avoid taking any major decision, or simply be more generous tosurrounding people through philanthropic actions like share a blessed meal or some‘jajan pasar’ (early morning fresh sweet snacks from the market). n ethnoarithmetic excursion into the Javanese calendar 17
The weton for the birth and death of Sultan Agung is ‘Jemuwah Lˆegi’, whichis also the first day of the Javanese calendar he created. This weton is thereforeone of the recurrent noble days (see subsubsection
Dina Mulya ) and consideredas an important night for pilgrimage. Indeed, the weton of every King’s birth is aspecial day; the present Sultan Hamengkubuwana X was born on 2 April 1946 CE,a ‘Selasa Wage’. This weton has been chosen for His ascension to the throne, on 7March 1989 CE. Every ‘Selasa Wage’, the animated touristic center of Yogyakarta,Jalan Malioboro, is closed to motor vehicles, and the covered sidewalks ‘kaki lima’,where commercial activity usually abound, is entirely cleaned.As another especially prominent example, the present palace of Yogyakarta hasbeen inhabited by Sultan Hamengkubuwana I and His regal suite on the ‘13 Sura1682 AJ’ (7 Oktober 1756 CE), a ‘Kemis Pahing’. In 2015, the Governor decidedthat every ‘Kemis Pahing’, schoolchildren, public servants, and in particular thoseworking in territorial services of Yogyakarta, must wear the traditional costume allday long, as a reminder of their regional culture. Merchants from traditional marketsare encouraged to do the same.
Table 5
List of names of the 12 wulan
Javanese lunar months and the associated number of days,depending on the taun and kurup (see Table 6). Wulan length (days)Taun 1-4,6-8 Taun 5No Wulan Name All Kurup Kurup 1 Kurup 2 Kurup 3 Kurup 41 Sura 30 30 30 30 302 Sapar 29 29 30 30 293 Mulud 30 30 29 29 304 Bakdamulud 29 29 29 29 295 Jumadilawal 30 30 30 29 306 Jumadilakir 29 29 29 29 297 Rejeb 30 30 30 30 308 Ruwah 29 29 29 29 299 Pasa 30 30 30 30 3010 Sawal 29 29 29 29 2911 Dulkangidah 30 30 30 30 3012 Besar 29/30 30 30 30 29Total (days) 254/355 355 355 354 354
Wulan
The lunar month is named a wulan and lasts for 29 or 30 days. There are 12 differentnames: ‘Sura’, ‘Sapar’, ‘Mulud’, ‘Bakdamulud’, ‘Jumadilawal’, ‘Jumadilakir’, ‘Re-jeb’, ‘Ruwah’, ‘Pasa’, ‘Sawal’, ‘Dulkangidah’ (or ‘Sela’), and ‘Besar’. The lengthof each wulan is attributed as follows (see Table 5 and the next subsubsections): • ‘Sura’, ‘Rejeb’, ‘Pasa’, and ‘Dulkangidah’ are always 30 days;• ‘Bakdamulud’, ‘Jumadilakir’, ‘Ruwah’, and ‘Sawal’ are always 29 days;• ‘Sapar’, ‘Mulud’, ‘Jumadilawal’, and ‘Besar’ have lengths depending on the taun and kurup . Taun A taun is a cycle on 12 wulan and corresponds to the Javanese lunar year. Thereare eight different taun names: ‘Alip’, ‘Eh´e’, ‘Jimawal’, ‘J´e’, ‘Dal’, ‘B´e’, ‘Wawu’,and ‘Jimakir’, formed by different wulan length sequences (see Table 5). For sevenof the taun , the sequence alternates monotonically between 30 and 29-day lengths.For the final wulan ‘Besar’, it can be either 29 or 30 days, depending not only onthe taun but also on the kurup , the 120 lunar year cycle, which has different daylength sequences for the fifth taun ‘Dal’. As a result, the total day length of a taun varies from 354 (short or normal year, named ‘Taun Wastu’) to 355 (long or leapyear, named ‘Taun Wuntu’), as described in Table 6:• ‘Alip’, ‘Jimawal’, and ‘B´e’ are always normal years, with a wulan ‘Besar’ of 29days;• ‘Jimawal’ and ‘Wawu’ are always leap years, with a wulan ‘Besar’ of 30 days;• ‘J´e’ and ‘Dal’ are normal or leap depending on the kurup ;• ‘Jimakir’ is a leap year for the 14 first windu , but becomes a normal year for thefinal windu of a kurup cycle. Table 6
List of names of the eight taun
Javanese lunar years forming a windu , and the associatednumber of days, an alternate between 354 (short or normal year) and 355 (long or leap year, gray-shaded cells) days, depending on the kurup . Taun Length (days)No Name Krama Meaning Kurup 1 Kurup 2 Kurup 3 Kurup 41 Alip Purwana intention 354 354 354 3542 Eh´e Karyana action 355 355 355 3553 Jimawal Anama work 354 354 354 3544 J´e Lalana destiny 354 354 355 3555 Dal Ngawanga life 355 355 354 3546 B´e Pawaka back and forth 354 354 354 3547 Wawu Wasana orientation 354 354 354 3548 Jimakir Swasana empty 355 355 355 355
Each taun is assigned by a monotonic increasing number, based on the Indiancalendar ‘Saka’. The reason was Sultan Agung decided to continue the countingfrom the Shalivahana era, which was 1555 at the time when inaugurating the Ja-vanese calendar (cf. Nuraeni and Azizah 2017). Thus, the Javanese calendar beganon ‘1 Sura Alip 1555 AJ’, which corresponds to 8 July 1633 CE. n ethnoarithmetic excursion into the Javanese calendar 19
Windu and Lambang
Eight taun make a windu (Proudfoot 2006). Despite the variability of each taun length, the total length of a normal windu is constant since it always contains bothfive short and three long taun , which is a total of 2,835 days (about 7 years 9 monthsin the Gregorian/Islamic calendar). This corresponds to exactly 81 wetonan . Thismeans that each ‘New Windu’ day, dated as ‘1 Sura Alip’, falls on the same weton .There is an exception to that rule: the final windu of a kurup cycle (see the nextsubsubsection) is always shortened by one day, with a 29 days wulan ‘Besar’ duringthe final taun ‘Jimakir’. This induces a shift in the wetonan cycle at each kurup .Furthermore, there are four different names of windu : ‘Adi’, ‘Kuntara’, ‘Sen-gara’, and ‘Sancaya’ that compose a 32 taun cycle. Another cycle of 16 taun is com-bined using two different names of windu , called lambang : ‘Kulawu’ and ‘Langkir’.These two cycles are summarized in Table 7.
Table 7
List of names of the four windu and two lambang .Windu Name Lambang NameAdi LangkirKuntara KulawuSˆengara LangkirSancaya Kulawu
Kurup
The longest cycle in the Javanese calendar is called a kurup , formed by 15 windu ,which is equivalent to 120 taun or 1440 wulan (Gisl´en and Eade 2019c). But thevery last wulan of the cycle, i.e., the twelfth wulan ‘Besar’ of the eighth taun ‘Ji-makir’ of the fifteenth windu , has only 29 days, such as the total length of a ku-rup is 2 , × − = ,
524 days (about 116 years and 6 months in the Grego-rian/Islamic calendar) (Rosalina 2013). This is the same number of days as in 120lunar years of the Tabular Islamic calendar. This is a rule-based variation of the Is-lamic Hijri calendar. Although the number of years and months are identical, themonths are determined by arithmetical rules instead of observation or astronomicalcalculations.Moreover, each kurup determines:• which of the taun ‘J´e’ or ‘Dal’ has a long wulan ‘Besar’,• the sequence of wulan lengths in the taun ‘Dal’,as given in Tables 5 and 6. Hence, the full date sequences in the calendar varybetween kurup . As the weton of the first day of a kurup repeats at each first day of the windu , a kurup is named using the corresponding weton falling on ‘1 Sura Alip’. Table 8 liststhe first five kurup .Meanwhile, the Sultanate of Mataram was divided under the Treaty of Giyantibetween the Dutch and Prince Mangkubumi in 1755 CE. The agreement divided os-tensible territorial control over Central Java between Yogyakarta and Surakarta Sul-tanates. The former was ruled by Prince Mangkubumi, also known as Raden MasSujana or Hamengkubuwono I (1717–1792 CE) and the latter was administrated bySinuhun Paliyan Negari, who was known as Pakubuwana III (1732–1788 CE) (Rick-lefs 1974; Soekmono 1981; Frederick and Worden 1993; Brown 2004).
Table 8
List of names of the five first kurup
Javanese 120 lunar year cycles, their short names (acontraction of the weton at each new windu , i.e., on ‘1 Sura Alip’), the first and last taun , the totalamount of taun , and the starting dates in the Gregorian calendar.No Kurup Name Short Name First Taun (AJ) Last Taun (AJ) Taun Start Date (CE)1 Jamingiyah A’ahgi Alip 1555 Jimakir 1674 120 8 July 16332 Kamsiyah Amiswon Alip 1675 Eh´e 1748 74 11 December 17493 Arbangiyah Aboge Jimawal 1749 Jimakir 1866 118 28 September 18214 Salasiyah Asapon Alip 1867 Jimakir 1986 120 24 March 19365 Isneniyah Anenhing Alip 1987 Jimakir 2106 120 26 August 2052
During the second kurup (1749–1821 CE), some experts realized that the Ja-vanese calendar was still one day behind compared to the Islamic Hijri calendar.Hence, the King of Surakarta, Susuhunan Pakubuwana V (1784–1823 CE), decidedto end the
Kurup ‘Amiswon’ in the year 1748 AJ, even though it had only been run-ning for nine windu and two taun . So, the taun ‘Eh´e’ 1748 AJ, which was supposedto be a leap year, was made only 354 days and the third kurup ‘Aboge’ started onthe taun ‘Jimawal’ 1749 AJ. But some noticed that it would be more appropriate ifthe incrementation of kurup should have been carried out two lunar years before,namely on the taun ‘Alip’ 1747 AJ. As a consequence of this delay, the third kurup ‘Aboge’ is only 118 taun long. However, the Sultanate of Yogyakarta did not makea similar decision and pursued the second kurup normally, so that the calendar inthe two concurrent regions was different during 46 years (see Table 9). On taun ‘Ji-makir’ 1794 AJ, the Sultan of Yogyakarta, Hamengkubuwana VI (1821–1877 CE),finally agreed and decided that the third kurup ‘Aboge’ will also end with taun ‘Ji-makir’ 1866 AJ, reconciling the two calendars.
Table 9
List of dates of the second and third kurup in the Sultanate of Yogyakarta.
No Kurup Name Short Name First Taun (AJ) Last Taun (AJ) Taun Start Date (CE)
The fourth and present kurup ‘Asapon’ is planned to last a normal length of120 lunar years, and will end on ‘29 Besar Jimakir 1986 AJ’, which is 25 Au-gust 2052 CE. The following day will start the fifth kurup ‘Anenhing’ (‘Alip SenenPahin’) on ‘1 Sura 1987 AJ Alip’, but the sequence of leap years has not yet beendecided, so it is formally impossible to calculate the exact dina , wulan , and taun for such a distant future date. Nevertheless, there is no obstacle with other strictlymonotonic cycles like weton , wuku , and windu . Dina Mulya
Dina mulya are the noble days in the Javanese calendar. Excepted for the ‘Siji Sura’which is the new lunar year and falls on the first day of the first wulan every taun ,others are associated with a specific weton and specific taun or wuku (see Table 10). Table 10
List of the noble days dina mulya .Dina Mulya Weton Wuku Dina WulanTaun OccurrencesSiji Sura – – 1 Sura – 1 every 354/355 days(new lunar year)Aboge Rˆebo Wage – – – Alip 10 during the
Taun every 7/8 yearsDaltugi Sˆetu Legi – – – Dal 10 during the
Taun every 7/8 yearsKuningan Sˆetu Kliwon Kuningan – – – every 210 daysHanggara Asih Selasa Kliwon Dukut – – – every 210 daysDina Mulya Jemuwah Kliwon Watugunung – – – every 210 daysDina Purnama Jemuwah Lˆegi – – – – every 35 days
Computer implementation of the Javanese calendar
The computation of the full Javanese calendar has been implemented using
GNUOctave scientific language with a single function ‘weton.m’ (Beauducel 2020b).When using a computer, however, the determination of the weekday or pasaran dayfrom a date in the Gregorian calendar does not require the congruence formula (3).In fact, most computer languages are able to calculate the exact number of days thatlast from any reference date, correctly taking into account leap years. In the case ofthe Javanese calendar, the linear timeline will be the number of days counted from8 July 1633 CE, which falls on ‘Jemuwah Lˆegi 1 Sura Alip 1555 AJ Jamingiyah’,the first day of the first kurup . Using that facility, calculation of the 7-day weekcycle can be made by a simple modulo 7, the pasaran cycle by a modulo 5, the wetonan cycle by a modulo 35, and the pawukon cycle by a modulo 210 functions.Moreover, since any modern digital calendar is able to set a periodic event, a specific weton date repeated every 35 days will smoothly give the corresponding wetonan cycle over the whole calendar.On the other hand, the computation of dina , wulan , taun , windu , and kurup ismore complicated since the exact sequences vary throughout history following hu-man decisions, making these cycles not exactly cyclic nor monotonic. Hence, theproposed computing strategy is to construct, for each kurup , a windu table as a8 ×
12 matrix of rows taun versus columns wulan , containing the day length of thatspecific wulan . This matrix is repeated 15 times to form a complete kurup , or lessfor the second and third kurup . Then, all the matrices are concatenated. The cumu-lative sum of this table elements, in the row order, gives the total number of daysthat lasts from the origin at the beginning of each lunar month, and can be comparedto the linear timeline described above. Thus, a simple ‘table lookup’ function willgive the corresponding kurup , windu , taun , and wulan indexes, and the dina will begiven by the remainder. Conclusion
In this chapter, we have discussed the cultural, historical, and arithmetic aspects ofthe Javanese calendar. Along with the internationally acknowledged Gregorian andthe majority-embraced religiously Islamic Hijri calendars, the Javanese calendar hasits unique place among the heart of many Javanese people in Indonesia as well asJavanese diaspora overseas. Although many Javanese people have adopted modernlifestyle, the Javanese calendar is still utilized in various daily affairs, including tochoose the best possible time for arranging a wedding day.While determining the day of the week for any given date can be computedusing Zeller’s congruence algorithm of modulo seven, the pasaran day of the Ja-vanese calendar can be calculated using a new congruence formula of modulo five.Additionally, we have also proposed a unique and combined congruence formulafor calculating both the day of the week and pasaran day for any given date inthe Gregorian calendar. Furthermore, using a computer program
GNU Octave ‘we-ton.m’ (Beauducel 2020b), all the cycles of the Javanese calendar, i.e., wetonan , wuku , wulan , windu , lambang , and kurup can also be determined straightforwardly. Acknowledgment
The authors would like to thank Matthew Arciniega (Vortx, Inc., Ashland, Ore-gon, United States of America) for sharing the contents of his old website andRoberto Rizzo (University of Milano–Bicocca, Italy) for pointing to the article writ-ten by Proudfoot (2007). NK dedicated this chapter to his father, who introduced to n ethnoarithmetic excursion into the Javanese calendar 23 and taught him about calendars during his early childhood. FB warmly thanks AlixAim´ee Triyanti for her cultural influence and inspiration, and all his Javanese friendsfor their enthusiastic support.
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