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THE ROLE OF SOLAR OBSERVATIONS IN DEVELOPING THE PRECLASSIC MAYA CALENDAR

Published online by Cambridge University Press:  29 March 2017

Susan Milbrath*
Affiliation:
Florida Museum of Natural History, University of Florida, Gainesville, FL 32611, USA ([email protected])
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Abstract

Intervals of 260 days are recorded by architectural orientations at a number of Maya sites, a pattern that may have developed early at sites such as Nakbe. The 260-day calendar, emphasizing sets of 13 and 20 days, dates back to the Middle Preclassic, when early E-Groups in the Maya area were used for solar observations. These observations were probably linked with a maize cycle spanning 260 days. By the end of the Late Preclassic, however, most E-Groups were abandoned or modified for a different function, serving as a stage for rituals performed by rulers at a time when the Long Count calendar was being developed. The changing role of E-Groups relates to the rise of royal rituals associated with the detailed historical records documented in Maya Long Count inscriptions.

En varios sitios en el área maya se registran, a partir de las orientaciones arquitectónicas, intervalos de 260 días. Este patrón pudo haberse desarrollado de forma temprana en sitios como Nakbe, Petén, Guatemala. El calendario de 260 días, que enfatiza los conjuntos de 13 y 20 días, data del preclásico medio, cuando se utilizaron los primeros grupos conmemorativos en el área maya para realizar observaciones solares. Estas observaciones probablemente estuvieron vinculadas con un ciclo del maíz que dura 260 días. Sin embargo, a finales del preclásico tardío, la mayoría de los grupos conmemorativos fueron abandonados o modificados para servir una función diferente. Estos grupos fueron utilizados como escenarios para rituales llevados a cabo por la realeza en el periodo durante el cual se desarrolló el calendario de cuenta larga. El nuevo papel de los grupos conmemorativos se relaciona con el aumento de los rituales reales. Estos mismos son asociados con los detallados registros históricos documentados en inscripciones mayas que usan fechas de cuenta larga.

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Articles
Copyright
Copyright © 2017 by the Society for American Archaeology 

During the Middle Preclassic (1000/900–400 B.C.), specialized architectural complexes were constructed to track the changing seasonal positions of the sun along the horizon. The oldest known complex, ca. 1000 B.C., is found in the Maya area (Inomata et al. Reference Inomata, Triadan, Aoyama, Castillo and Yonenobu2013:467). These are called E-Groups, based on an architectural assemblage first recognized in Group E at Uaxactun. They represent the earliest civic architecture and predate documented evidence of calendar records in Mesoamerica, suggesting that solar observations in these groups may have helped develop the calendar.

Middle Preclassic E-Groups had a pyramid on the west side facing a flat range structure to the east that served as an artificial horizon. These early range structures may have had wooden posts or stone markers to measure the movement of the sun along the horizon (Rice Reference Rice2007:87, 147, 155). Archaeological evidence for markers is lacking, but these could have been impermanent, such as crossed sticks or small rocks on the surface of the structure. The orientations in Middle and Late Preclassic E-Groups emphasize the solstices, and Anthony Aveni and colleagues (Reference Aveni2003:163) conclude that the earliest orientation calendar, well before written records, was based on solstice alignments.

E-Group structures clearly served some astronomical purpose in the evolution of the Mesoamerican calendar (Aveni et al. Reference Aveni, Dowd and Vining2003:174). As Aveni (Reference Aveni2002:211) notes, early Lowland Maya E-Groups concentrate in the “magic latitude,” where the year can be segmented into multiples of 20 days that separate the solstices, equinoxes, and solar zeniths. These 20-day sets are an essential component of both the Mesoamerican year and the 260-day ritual calendar. With 13 sets of 20 days, the ritual calendar apparently developed in tandem with a calendar dividing the 365-day year into 18 “months” of 20 days each and an added five-day period.

E-Groups: Changing Function Over Time

Prudence Rice (Reference Rice2007:147) points out that proto-E-Groups are evident in Middle Preclassic mound-plus-platform arrangements in Chiapas and in Tabasco at the Olmec site of La Venta (Str. D1 and D8). She suggests these sites had multiple markers along the platform to determine the solstices, equinoxes, and the zenith sun, when the marker would act as a gnomon and cast no shadow at noon (Aimers and Rice Reference Aimers and Rice2006:80, 92; Rice Reference Rice2007:87). Even though the orientations differ markedly, La Venta may be the progenitor of the early E-Group at Chiapa de Corzo (Clark and Hansen Reference Clark, Hansen, Inomata and Houston2001:4; Sullivan Reference Sullivan2015:456), or possibly vice versa because there is evidence of shared ideas that may have come from Chiapas to La Venta in the Middle Preclassic (Milbrath Reference Milbrath1979:44–45). The La Venta mounds are aligned 8° west-of-north, in keeping with the main orientation of the urban core, which translates into 8° north-of-east (90° minus 8°) for the east-facing pyramid (Rice Reference Rice2007:81–83, Figure 5.3). The E-Group at Chiapa de Corzo also follows the primary orientation of the site (28° east-of-north), translating into 28° south-of-east for the pyramid, according to Timothy Sullivan (Reference Sullivan2015:460, Figure 4), but Aveni and Horst Hartung (Reference Aveni, Hartung and Keber2000:58, 60, Table 1) measured alignments closer to 25°, which have been confirmed by Ivan Šprajc and Francisco Sánchez Nava (Reference Sánchez Nava and Šprajc2015:57, Table 3.1).

Table 1. Earliest Long Count Dates in Maya Region and Bordering Areas.

Despite widely different orientations at Middle Preclassic sites, Takeshi Inomata (Reference Inomata, Freidel, Chase, Dowd and Murdock2017) points out that recent studies by Michael Blake (Reference Blake2013) suggest the possibility that early E-Groups in Chiapas and at La Venta represent a compromise between celestial orientations and topographic landmarks, such as mountains and volcanoes. Blake found that the central axis of these E-Groups was oriented toward the winter or summer solstice sunrise, and, depending on which solstice was centered on the mound, the equinox sunrise aligned approximately with the northern or southern end of the eastern mound. Inomata concludes that these solar alignments served as generalized representations of cosmological symbolism, rather than as devices for precise solar observations. Greater precision in the solar orientations is evident in early E-Groups from the Maya Lowlands, perhaps because there were fewer topographic features on the horizon to serve as alternate sight lines.

With such an expansive horizon in the lowlands, stellar alignments should also be considered. Grant Aylesworth (Reference Aylesworth2004) notes that many Maya E-Groups are aligned with the zodiacal band, a band about 18° wide centered on the ecliptic, the apparent “path” of the sun through the sky. The approximate equinox orientation of some early E-Groups is noteworthy because this alignment also marked the horizon position of Orion (ca. 1000–400 B.C.; Aveni et al. Reference Aveni, Dowd and Vining2003:173). Orion's Belt is also considered to be significant in early orientations in the Valley of Oaxaca that display alignments similar to those at La Venta (Peeler and Winter 1992/Reference Peeler and Winter1993; but see Šprajc and Sánchez Reference Šprajc and Nava2015:44–52). Around 500 B.C., Orion's Belt disappeared from the sky from April 23 to June 12 (Aveni Reference Aveni2001: Table 10). Its annual disappearance coincided with the first maize planting, and it reemerged when the maize was sprouting (Milbrath Reference Milbrath1999:248). A metaphorical connection between Orion's Belt and maize may have developed in Preclassic times because the first bright star in the belt became visible on the eastern horizon at dawn in early June, when the young maize sprouted. By September, when the maize matured, the three stars of Orion's Belt aligned vertically above the horizon around midnight, like a mature maize plant rising up tall and tasseled.

The recently discovered E-Group at Ceibal, Guatemala, first constructed around 1000 B.C., seems to confirm earlier suggestions that E-Groups originated in the Maya Lowlands (Clark and Hansen Reference Clark, Hansen, Inomata and Houston2001:23; Rice Reference Rice2007:203; Stanton and Freidel Reference Stanton and Freidel2003:9, 11). This early E-Group (ca. 1000–800 B.C.) had a platform to the west and a range structure to the east, which was buried around 800 B.C. when they built a new version of the elongated platform farther to the east (Inomata et al. Reference Inomata, Triadan, Aoyama, Castillo and Yonenobu2013:467–468).

Maya E-Groups were widely distributed in the Middle Preclassic, and are found at sites such as Caracol, Cenote, Cival, Nakbe, Takalik Abaj, and Tikal (Aveni et al. Reference Aveni, Dowd and Vining2003:Table 1; Chase and Chase Reference Chase, Chase and Grube1995; Chase et al. Reference Chase, Dowd, Freidel, Freidel, Chase, Dowd and Murdock2017; Clark and Hansen Reference Clark, Hansen, Inomata and Houston2001:9, 16; Doyle Reference Doyle2012; Estrada-Belli Reference Estrada-Belli2011:52, 68–69, 74; Hansen Reference Hansen and Houston1998:66, Reference Hansen, Boxt and Dillon2013; Laporte and Fialko Reference Laporte, Fialko C., Clancy and Harrison1990, 1995). Arlen and Diane Chase (Reference Chase, Chase, Freidel, Chase, Dowd and Murdock2017) point out that E-Groups represent the first form of public architecture in the Lowland Maya area. James Doyle (Reference Doyle2012:369, 374) emphasizes that Middle Preclassic E-Groups with their broad plazas may be the earliest large-scale settings for political and community gatherings in the Maya Lowlands. People from distant areas could have gathered in accompanying plazas, where the interchange of ideas likely developed at a time when many Middle Preclassic Maya sites shared Mamon-sphere ceramics (Doyle Reference Doyle2012:372–374).

The Late Preclassic E-Group at El Mirador aligns to the position of the sun on the summer and winter solstices, and the Central Acropolis is aligned to sunrise on February 12 and October 30, designating a 260-day interval seen in orientations elsewhere at El Mirador. This is one of the most common alignment patterns in the Maya Lowlands (Aveni et al. Reference Aveni, Dowd and Vining2003; González-García and Šprajc Reference González-García and Šprajc2016:196; Šprajc et al. Reference Šprajc, Morales-Aguilar and Hansen2009:87–90, Table 1; Sánchez and Šprajc Reference Sánchez Nava and Šprajc2015). The solstice alignments of the El Mirador E-Group repeat at Uaxactun, but many of the E-Groups Aveni profiled show a variety of orientations. Kathryn Reese Taylor (Reference Reese Taylor, Freidel, Chase, Dowd and Murdock2017) notes two patterns for E-Groups in the Karstic Uplands, home to sites such as Calakmul, El Mirador, Naachtun, Nakbe, and Yaxnohcah. One orientation group apparently tracks the Haab with alignments to dates that fall in sets of 20 days on either side of the summer solstice or zenith passage. Another less common patterning seems to commemorate the 260-day agrarian year with alignments to dates in February and October, as seen in the Middle Preclassic E-Group at Nakbe (Aveni et al. Reference Aveni, Dowd and Vining2003:Table 1).

The Middle Preclassic E-Group at Cival is typical of these constructions, characterized by bedrock knolls forming the western and eastern structures, with the western side modified into a low platform with stairs (only partially excavated) and the eastern side modified into an elongated platform (Figure 1; Estrada-Belli Reference Estrada-Belli2006:63; Reference Estrada-Belli2011:74, 78–79, 82–83, Figure 4.1; Reference Estrada-Belli, Freidel, Chase, Dowd and Murdock2016). Near the eastern range structure, a jade cache with a post marked the centerline of the platform and an axial line of 92o azimuth between the eastern and western structures. Francisco Estrada-Belli (Reference Estrada-Belli2011) concludes that the 92° alignment may have been used to mark solar positions synchronized with the agricultural season divided into four parts at the equinoxes and solar zeniths.

Figure 1. Cival E-Groups (after Estrada-Belli Reference Estrada-Belli, Freidel, Chase, Dowd and Murdock2017).

True equinox orientations with a 90° azimuth (March 20/21 and September 22/23) are uncommon. More often orientations mark the quarter days (March 23 and September 21), falling halfway between the solstices (Šprajc Reference Šprajc, Dowd and Milbrath2015; Šprajc and Sánchez Nava Reference Šprajc, Nava, Arroyo, Paiz and Mejía2012, Reference Šprajc and Nava2013). It was probably easier to divide the number of days between the two solstices than to determine the exact date of the equinox. At the solstices, the sun seems to “pause” before it moves away from its northern and southern extremes on the horizon, making the solstices easier to observe than the equinoxes.

When formal constructions began to be added to the E-Group's range structure, the first phase was usually a single elevated building at the center, as at Tikal, Nakbe, Wakna, and El Mirador (Hansen Reference Hansen and Houston1998:66). The early E-Group at Tikal in the Mundo Perdido complex (5C-54-5) began around 700–600 B.C. with a low platform to the west bearing radial stairs and an elongated range structure to the east. The central building added subsequently is aligned to sunrise on February 24 and October 18, suggesting a link with the agrarian year (discussed below), according to Šprajc et al. (Reference Šprajc, Richter, Nava, Arroyo and Salinas2013:1069, Table 1; but see Aveni et al. Reference Aveni, Dowd and Vining2003:174, Table 1 for somewhat different dates). During the Late Preclassic two more buildings were added to mark the solstices (Aveni et al. Reference Aveni, Dowd and Vining2003:174, Table 1; Laporte and Fialko Reference Laporte, Fialko C., Clancy and Harrison1990: Figures 3.9, 3.11, 1995).

In addition to changes in the configuration of E-Groups over time, their evolution shows changes in function. A long process of transformation for the Group E of Uaxactun is evident. Initially, during the Late Preclassic, the E-Group was a working observatory with a pyramid (E-7sub-1) facing an elongated platform to the east that marked both equinoxes and the solstice extremes. Later remodeling made the alignment astronomically nonfunctional. As Stanislaw Iwaniszewski (Reference Iwaniszewski2002:510–511) points out, after the three temples were added to the range structure, ca. A.D. 240–550, the direct sight line of the sun on the solstices and equinoxes was obstructed. By then, the power center at Uaxactun had shifted from Group E to Group A, which became the focal point for royal rituals (Aveni Reference Aveni2003:161–162).

The decline of E-Groups as a focus of Maya architecture is notable between 300 B.C. and A.D. 150, when the Triadic Architectural Style associated with the rise of divine kingship became dominant (Estrada-Belli Reference Estrada-Belli2011:49, 56, 68, 76–77, 144; Hansen Reference Hansen and Houston1998, Reference Hansen, Boxt and Dillon2013:157–160). This change seems related to the origin of Maya state-level society during a period when the Long Count was in the process of formation.

Near the end of the Preclassic, many E-Groups were either abandoned or modified for other purposes. The E-Group at Cival was last modified around A.D. 100 and thereafter was left to decay (Estrada-Belli Reference Estrada-Belli2011:64–65). Other E-Groups at sites like Tikal and Calakmul were transformed into stages for royal rituals in the Early Classic (Dowd Reference Dowd, Dowd and Milbrath2015). Many E-Groups were maintained for use in public gatherings during the Early Classic (Doyle Reference Doyle2012:363). These “modified” E-Groups dating from the Late Preclassic to Early Classic were apparently also used for rituals commemorating longer periods of time, especially the Katun cycle, a period approximating 20 years (Aimers and Rice Reference Aimers and Rice2006:87, 90–92; Estrada-Belli Reference Estrada-Belli2011:79–80).

By the end of the Preclassic (A.D. 250/300), E-Groups were used as stages for solar rituals, and they developed into customized complexes for royal rituals during the Classic period (Aveni et al. Reference Aveni, Dowd and Vining2003:174; Dowd Reference Dowd, Dowd and Milbrath2015; Aimers and Rice Reference Aimers and Rice2006:79, 82, 86–87). According to Aveni and colleagues (Reference Aveni2003:162–163, 174–175, Figure 4), some later E-Groups aligned to mark 20-day intervals that lead up to the solar zenith, anticipating the planting season. This reflects a greater emphasis on the solar zenith that could have begun with a calendar reform stimulated by Teotihuacan influence in the Early Classic.

Earliest Calendar Records in Mesoamerica

Both the 365-day solar calendar and the 260-day ritual calendar include sets of 20 days that may be derived from a count of fingers and toes (Stuart Reference Stuart2011:153; Rice Reference Rice2007:44). Linguistic data suggest that Tzolkin day names were probably used as early as 600 B.C. in the Maya area (Justeson Reference Justeson and Aveni1989:79). Eric Thompson (Reference Thompson1972:21–23) argued for a Highland Maya origin for the 20 day names, but most scholars now concur that the 260-day calendar probably originated in the Olmec area. David Stuart (Reference Stuart2011:36–37) notes that although Olmec dates in the ritual calendar are not preserved, the widespread distribution of the 260-day calendar suggests it was developed by the Olmec “mother culture.”

Few if any records of calendar dates survive at Olmec sites, but the ritual calendar may appear there around 900–700 B.C. (Justeson Reference Justeson and Aveni1989:79; Rice Reference Rice2007:45). Olmec symbols representing pseudo-glyphs are apparent on the Cascajal block, a monument found near San Lorenzo, but no dates are evident (Rodríguez Martínez et al. Reference Rodríguez Martínez, Ceballos, Coe, Diehl, Houston, Taube and Calderón2006). La Venta Stela 13 (“the Ambassador”) has glyph-like symbols, including possibly the number one, but no specific day signs can be identified (Lacadena Reference Lacadena2009). The range of dates proposed for Stela 13 (600–400 B.C.) places it contemporary with early Oaxacan inscriptions (Milbrath Reference Milbrath1979:41, Table 2).

By 600–400 B.C., a count of 260 days was recorded with 20 different named days in the Valley of Oaxaca (Marcus Reference Marcus1992:41). The first unequivocal evidence of the combined use of the 365-day calendar with the 260-day calendar appears in Calendar Round dates at the Zapotec site of Monte Alban. On Monte Alban Stela 12, the yearbearer 4 Wind paired with the day 8 Water forms a Calendar Round read as 594 B.C. (Edmonson Reference Edmonson1988:20–21). Inscriptions on Stelae 12 and 13 also show the earliest evidence of yearbearers, if we discount the dubious Olmec example cited by Munro Edmonson (Reference Edmonson1988:21). These early Zapotec dates are “Type II” yearbearers, comparable to yearbearers in the K'iche’ Maya system and those used by the Early Classic Maya (Ik, Manik, Eb, and Caban; Edmonson Reference Edmonson1988:8–9; Tedlock Reference Tedlock1992:89–92). Month glyphs were originally identified on Monte Alban Stelae 12 and 13, based on a notation (Glyph W) that appears in inscriptions with numbers larger than 13 (Marcus Reference Marcus1992:38–41; Prem Reference Prem, Heizer and Graham1971:119), but other scholars have concluded that Glyph W remains undeciphered, even though a calendrical function seems likely (Urcid Reference Urcid Serrano2001:273; Whittaker Reference Whittaker, Bricker and Andrews1992:18).

Stuart (Reference Stuart2011:38) points out that Maya hieroglyphic writing with calendrics is as old as 300 B.C. Mural texts at San Bartolo dating around 300–200 B.C. are only partially readable, and an early version of Ahau is used as a title rather than a day sign (Saturno et al. Reference Saturno, Stuart and Beltrán2006:1282). Stuart (Reference Stuart2005a:4–6, Figure 3) identifies a 3 Ik yearbearer date at San Bartolo, estimated to fall somewhere between 131 and 27 B.C., representing the seating of Pop (0 Pop), the first Maya month. The actual month glyph is not recorded at San Bartolo, but an understanding of the Haab cycle (18 x 20 + 5) is implicit in Stuart's interpretation. San Bartolo may also record an early Katun-ending date (255 B.C.), if Mario Giron-Ábregon (Reference Giron-Ábrego2013:9–10) is correct in proposing that a stone block in the mural complex records the Katun 5 Ahau (7.5.0.0.0).

John Justeson and colleagues (Reference Justeson, Norman, Campbell and Kaufman1985:76, n. 32) suggested that the Maya Long Count calendar was invented during Katun 7.6.0.0.0 (255–235 B.C.), beginning on the day 1 Imix and ending on 11 Ahau, which was the first Katun created according to the Chilam Balam of Chumayel. They also noted that 4 Ahau 8 Cumku may have become important as a starting point of the Maya Long Count because this Calendar Round date was a Tun ending in 7.2.7.0.0 around 300 B.C.

Early texts from the Maya area and neighboring zones apparently lack month glyphs, but they do record the 260-day calendar, and the yearbearer identified at San Bartolo indicates that the Haab was known by the Late Preclassic. Victoria Bricker (Reference Bricker1982:102–103) suggests that the Haab first developed ca. 550 B.C. when the Maya names for rainy season months appear to be correlated with the proper season and 0 Pop occurred on the winter solstice. More speculatively, Rice (Reference Rice2007:47, 57, 62–63) argues that the Haab is perhaps as old as 2060 B.C., when 0 Pop also coordinated with the winter solstice (as in 550 B.C.), and she suggests that the 52-year Calendar Round combining the 260-day calendar with the 365-day year developed as early as 1650 B.C. It remains uncertain when and where the Haab and Tzolkin developed.

Geographic Origin Point of the Haab and Tzolkin

The idea of identifying a specific site as the origin point of the Haab seems to be based on faulty premises. Vincent Malström (Reference Malström, Broda, Iwaniszewski and Maupomé1991) incorrectly used the Postclassic date (1 Pop) for the beginning of the year in Preclassic times and then later revised his argument to begin the year on the summer solstice (Malström Reference Malström1997:64), contrary to the more likely proposition that the year originally began on the winter solstice.

A stronger case for the geographical origin point of the Tzolkin has been made based on links to a locale where the dates for the two solar zeniths mark a 260-day interval. This idea, originally proposed by Zelia Nuttall (Reference Nuttall1904:497–498), was recently given a measure of support by Stuart (Reference Stuart2011:153). Malström (Reference Malström1997:50–53, Figures 9–10) proposed that the Tzolkin originated at Izapa (14o8'N), bordering the Maya area, because this site has two solar zeniths spaced at 260-day intervals, with the second one falling on August 13. He argued that the Tzolkin originated in 1359 B.C. at Izapa, when 1 Imix, the starting point of the Maya Tzolkin, coincided with the local solar zenith on August 13. He also links the August 13 date to 4 Ahau 8 Cumku, the “calendar creation date,” because it falls on 13.0.0.0.0 in the Long Count calendar, making the beginning of the Baktun cycle on August 13, 3114 B.C. (Gregorian). The lack of Long Count records from Izapa makes this theory problematic and there appears to be only one surviving Tzolkin date (6 Death on Miscellaneous Monument 60; Justeson Reference Justeson1988; Rice Reference Rice2007:116). Malström used the 584,285 correlation, but in the 584,283 correlation (discussed below), 4 Ahau 8 Cumku falls on August 11, which compromises his argument. Bordering the Lowland Maya area at 14°20' N, El Baul and Takalik Abaj (formerly Abaj Takalik) both have a zenith date on August 15 and very early Maya calendar inscriptions (Table 1; Edmonson Reference Edmonson1988:120). The zenith passage dates, however, do not show a 260/105 day split. In general, the geographic explanation for the origin of the Tzolkin at any specific latitude remains weak. On the other hand, the 260-day calendar does reflect an interval related to the Mesoamerican maize cycle in the Maya area.

Solar Observations and Subdivisions of the Calendar

The 260-day Tzolkin may have developed from a natural subdivision of the solar year relating to agriculture. The 105-day interval from April to August has been described as the growing season (Peterson Reference Peterson1962:186–187), but the Maya agricultural season actually spans 260 days, a period referred to as the agrarian year (Rice Reference Rice2007:35–36; see also Milbrath Reference Milbrath1999:15, 59). Objections have been raised that the theory explaining the origin of the 260-day calendar in terms of agricultural cycles does not account for variations in the length of the growing season that depend on altitude (Earle and Snow Reference Earle, Snow, Robertson and Fields1985:212). Nonetheless, the 260-day agricultural cycle is preserved today in both the lowlands and highlands. A span of 260 days represents a subdivision of the maize cycle into 13 sets of 20 days, surviving today in the maize cycle of the Tzeltal (Stross Reference Stross1994:29–31), and the 260-day agricultural cycle is also recorded among other Maya groups (Guiteras-Holmes Reference Guiteras-Holmes1961:33; Milbrath Reference Milbrath1999:15, 59–62; Tedlock Reference Tedlock1992). Furthermore, as noted above, orientations in the Maya area that establish a fixed 260-day period between February and October help demonstrate a focus on the agrarian year, and alignments marking 20-day intervals before and after the solar zenith reflect an interest in subdividing the 260-day agricultural period. Subdivisions of the agrarian year are also evident in clusters of architectural orientations in the Maya Lowlands corresponding to a four-part division of the maize cultivation cycle, with preparation of the plots in February, planting in April-May, first fruits in August, and the harvest in October-November (González-García and Šprajc Reference González-García and Šprajc2016:199–200).

There are variations in practices depending on altitude, but generally the pattern of rainfall determines when the main crop is planted. Although there may be multiple plantings, there is considerable uniformity in the lowlands, with the main crop planted at the onset of the rainy season, around the first solar zenith (Milbrath Reference Milbrath1999:13). In Yucatán, some farmers risk an early planting (tikin muk) during April, in hopes of early rainfall, but the main crop (xnuk nal) is planted in May through June to coincide with the rainy season, which runs through October. There is a repeat of planting in June through August to take care of any shortcomings in the crop caused by dry weather or pests (Terán and Rasmussen Reference Terán and Rasmussen1994:127, 205–207). The pattern along the coast of Belize seems to be the same, with rainfall beginning in May, but there is enough rain for a second crop to be planted in the alluvial soils beginning in November, and this extra crop is harvested during the dry period that spans from January through April (Iwaniszewski Reference Iwaniszewski2002:506). In some other Maya areas it is also possible to plant a second crop during the dry season, but generally the second crop is planted around July in the midst of the rainy season, as is the practice in Yucatán and among the Ch'orti’, whose territory spans from eastern Guatemala to Honduras (Estrada-Belli Reference Estrada-Belli2011:79; Girard Reference Girard1962; Milbrath Reference Milbrath1999:13–14, Plate 1).

According to Raphael Girard, the Ch'orti’ begin their 365-day year and a fixed 260-day agricultural calendar on New Year's day (February 8), but because their calendar year is said to start with the first visible crescent moon, there seems to be some flexibility for the beginning date (Girard Reference Girard1962:3–15, 55, 76, 328–342). Girard (Reference Girard1962:340, n. 21) noted that the Ch'orti’ agricultural calendar is like that recorded in Yucatán by Diego de Landa, with a beginning date of 1 Imix falling in February (Tozzer Reference Tozzer1941:151–152). Critics of Girard's work have questioned how the Ch'orti’ could relate 1 Imix to the beginning of their agricultural count on February 8, not only because the Tzolkin does not have a fixed relationship to the solar year, but also because other ethnographers have not found evidence of the survival of the Tzolkin among the Ch'orti’ (Starr Reference Starr1951:263, 265). Even though the Ch'orti’ do not use day signs in the Tzolkin, Girard's data suggest they maintained a count of 260 days using 52-day sets and multiples of 20 days.

The Ch'orti’ 260-day agricultural count starts during the dry season with preparation of fields for 80 days, a period subdivided at the March equinox into two 40-day periods. The 80-day period ends on the first solar zenith on May 1, coinciding with the onset of the rainy season, when the planting begins. Then a count of 52 days leads up to the summer solstice (June 21 or 22), followed by another 52-day period that includes the Día de Santiago (July 25), which marks a brief halt in rains associated with canícula (a brief midsummer drought). The second 52-day set ends on the second solar zenith on August 12/13 (Girard Reference Girard1962:250–253, 257–258, table facing 328). The remainder of the fixed agricultural count is used to plant a second crop shortly after the ears of the first crop are doubled over, which keeps the birds from eating the kernels and rainfall from rotting of the maize cobs. The second crop, planted in July, is cultivated during a period that includes the fall equinox, a time of maximum rainfall, but doubling the ears of this second crop is not necessary because by the time the maize matures, the rain has ceased (Girard Reference Girard1962:265–268). Harvesting begins in October, and Girard notes that on October 25 the fixed 260-day agricultural count ends with a midnight ceremony. The residual period of 105 days in the year is considered to be a period of rest that completes the year, ending with a five-day period (February 3–7) directly before the New Year.

In the mountains of Guatemala, the K'iche’ year-end events seem to take place just before a time of heightened agricultural activity, as they do among the Ch'orti’ (Tedlock Reference Tedlock1992:35, 189–190). Taking advantage of the mist and fog that retard evaporation, mountain maize is planted beginning in March and harvested in December, with the agricultural cycle spanning 260 days. March is also the month of the New Year when the new Mam or yearbearer is installed—a Tzolkin date that names the year. The relationship between the 260-day count and the agricultural season echoes the pattern seen among the Ch'orti’, living hundreds of miles away, and the fact that the yearbearer falls near the beginning of the 260-day agricultural count is useful in designating a span of 260 days.

The yearbearer cycle has implications for the early calendar because it indicates a division of the year into two sections of 260 and 105 days. The same division of the year into 260- and 105-day periods is evident in a number of orientations documented in the Maya area and beyond (Aimers and Rice Reference Aimers and Rice2006:88; Aveni Reference Aveni2001:228–229; Šprajc Reference Šprajc2000:409). Many alignments facing to the east in the Maya Lowlands seem to mark intervals of 260 and 105 days, with subsets of 13 and 20 days, or alternatively, intervals of 240 and 125 days (González-García and Šprajc Reference González-García and Šprajc2016:196–197, Table 9; Šprajc and Sánchez Nava Reference Šprajc, Nava, Arroyo, Paiz and Mejía2012:984).

Šprajc (Reference Šprajc2000) notes that orientations at Teotihuacan also suggest a 260-day cycle beginning in February, with alignments to a prominent peak on the eastern horizon marking the dates February 11 and October 29 (see also Iwaniszewski Reference Iwaniszewski, Wiesheu and Fournier2005). These dates reflect measurements taken from the summit of the Pyramid of the Sun, and those taken from the base differ by only a day (Šprajc Reference Šprajc2001:226–229, Tables 5.38, 5.39). Alignment at the base facing east mark the rising sun on February 10 and October 30, and the setting sun to the west on April 30 and August 13. Šprajc concludes that these four dates divide the agricultural season in quarters, beginning with preparations for planting in early February, then planting with the onset of the rains (late April or early May), followed in mid-August by the first ears of maize, and then the beginning of the main harvest in late October. The Teotihuacan alignments involve a mountainous horizon, but Šprajc and colleagues (Reference Šprajc, Morales-Aguilar and Hansen2009:88–90, Table 2) note that in the Maya area, with a flat horizon, the same group of dates corresponds to a 14° orientation like that found in Preclassic El Mirador and Yaxnohcah, sites characterized by alignments marking the dates February 12 and October 30. Like the Teotihuacan alignments, these dates define a 260-day period that Šprajc describes as an observational calendar related to agriculture, like that surviving today among the Maya.

The Puuc-Maya site orientations seem to be distributed into two groups: the 25° group translating into a winter solstice sunrise alignment and a 14° group more closely related to Teotihuacan (Aveni Reference Aveni2002; Aveni et al. Reference Aveni, Dowd and Vining2003). The 14° east-of-north group marks alignments that are at 20-day intervals from the solar zenith, and Aveni and Hartung (Reference Aveni and Hartung1986:18–19, Table 3) also note that the 14° alignment would coincide with dates in February and October, important dates in the agricultural calendar spanning 260 days. They propose a hypothetical solar orientation calendar centered on the zenith passage dates at different latitudes in the Maya area, with alignments focusing on the horizon position of the sun on the zenith passage date, or intervals of 20 or 40 days before and after the zenith date that mark sets of 20 days useful in recording subdivisions of the agricultural cycle. A similar 14° orientation is found at Late Preclassic T'isil in Quintana Roo, where the main sacbé is aligned to sunrise in mid-February and late October (Vadala Reference Vadala2009), recalling the El Mirador alignments, and T'isil also has a winter solstice alignment (25° orientation) like the E-Group at El Mirador.

An agrarian year of 260 days beginning in February and ending in October may have been widespread early on in the Lowland Maya area. Aveni (Reference Aveni, Nichols and Pool2012) suggests that the fixed count of 260 days predates the solar-based cycle of 365 days, and this count was used for the period of subsistence activities. This fixed agricultural cycle of 260 days was probably measured using day names that developed from a count of 20 used to subdivide the solar year. By the Middle Preclassic, tracking the solar positions using E-Groups helped to formulate more detailed subdivisions of the agricultural cycle in relation to the solar year. By the Late Preclassic multiple calendar cycles developed, and the solar and agricultural cycles were subsumed in the complex workings of the Maya Long Count calendar of the Classic period. Throughout the Preclassic and Classic, the Tzolkin was probably used to calculate the fixed agricultural cycle, so that any date in the Tzolkin could begin the agrarian year, and the agricultural cycle would end when that date repeated again 260 days later.

Early Long Count Inscriptions

The earliest Maya inscriptions record the Tzolkin and possibly also the yearbearer cycle. The 365-day Haab may have originally coordinated with the seasonal cycles, but as the Preclassic drew to a close it became subordinate to the Long Count, which provided a more precise record of time. In the Long Count, the base unit is the day itself, but the primary intervals are multiples of 20 days. The Long Count calendar combined many cycles, including the Baktun (20 x 20 x 360 days), the Katun (20 x 360 days), the Tun (18 x 20 days), and the Uinal (20 days).

An important consideration in any discussion of the early calendar is the correlation factor, a coefficient added to the Long Count date to obtain the equivalent date in the European calendar. The 584,285 correlation, originally proposed by Eric Thompson in 1972 and revived by Floyd Lounsbury (Reference Lounsbury and Aveni1982, Reference Lounsbury, Aveni and Brotherston1983), is generally referred to as the GMT correlation. Although Gerardo Aldana (Reference Aldana and Steele2011, Reference Aldana2015:12–17) has questioned the GMT correlation and disputes supporting evidence from the Tikal lintels, Douglas Kennett and colleagues (Reference Kennett, Hajdas, Culleton, Belmecheri, Martin, Neff, Awe, Graham, Freeman, Newsom, Lentz, Anselmetti, Robinson, Marwan, Southon, Hodell and Haug2013:4) conclude that the Tikal lintels were probably carved by removing the exterior wood (the more recent wood), so the radiocarbon dates assessed with Bayesian modelling help confirm the GMT correlation. Of course, this evidence cannot be used to distinguish between variants of the GMT that adjust dates by only a few days or weeks.

For the general discussion of E-Groups in relation to the developing calendar, it is not essential to know the exact correlation factor, but it does become important when tying astronomical events with specific dates on monuments. In an analysis of a possible solar eclipse record on Poco Uinic Stela 3, a 584,286 correlation (584,285 + 1 day) has been proposed (Martin and Skidmore Reference Martin and Skidmore2012), but there are several other possible explanations for this date (Daniel Graña-Behrens, personal communication 2012). Astronomy also figures prominently in the correlation proposed by Justeson (Reference Justeson, Morely and Renfrew2010; see also Kaufman and Justeson Reference Kaufman and Justeson2001) for the Isthmus region, an area where the earliest complete Long Count inscription is found at Tres Zapotes (Table 1). He suggests that an Epi-Olmec correlation factor displaced the months by 20 days (584,285 - 20 days = 584,265), which makes the Long Count dates on La Mojarra Stela 1 align with specific astronomical events, including a solar eclipse and a Venus elongation. Aveni (Reference Aveni2001:167, Figure 65) supports this interpretation of the astronomical events, but it should be noted that Venus elongations probably were not significant in the Maya records (Bricker and Bricker Reference Bricker and Bricker2011:39), and the solar eclipse glyph is unlike ones seen in later texts.

Using the Epi-Olmec correlation factor of 584,265, Tres Zapotes Stela C is interpreted as a record of a lunar eclipse followed by an almost total eclipse (Justeson et al. Reference Justeson, Norman, Campbell and Kaufman1985:75, n. 31; Pool Reference Pool2007:252, 307, n.1). La Mojarra Stela 1, a monument from Veracruz, has a Long Count in A.D. 143, recorded as 8.5.3.3.5 13 Snake (Table 1; Kaufman and Justeson Reference Kaufman and Justeson2001:2.34–2.35). The month patron is incorporated in the ISIG (Initial Series Introductory Glyph) with a Tun sign directly below it, and the Tzolkin date appears at the end of the column. This Long Count inscription (A1-9) and a second one (M8-16) have been linked to Venus events separated by the interval of 13.6.2 (4,802 days), and the first interval (H3–I4) links two eclipse events, whereas the second (I5–J5) leads to a solstice date, using the 584,265 correlation factor (Kaufman and Justeson Reference Kaufman and Justeson2001:2.37–2.38, 2.71). Problems with the astronomical events cited on the monument have already have been noted, and until more of the script is understood, caution is required (Houston and Coe Reference Houston and Coe2003). Scholars such as Prudence Rice (Reference Rice2007) and Martha Macri and Laura Stark (Reference Macri and Stark1993) use the 584,283 correlation (GMT − 2 days) for the La Mojarra texts, the same correlation used here in Table 1, but the case remains open on the correlation in the Isthmus region, which may be displaced by 18 to 20 days.

Thompson's (Reference Thompson1960) long-standing correlation (584,283) used here is vigorously championed by Harvey and Victoria Bricker (Reference Bricker and Bricker2011:90–99) and Munro Edmonson (Reference Edmonson1988), and is also supported by Barbara Tedlock (Reference Tedlock1992), based on the Tzolkin cycle surviving among the K'iche’. The precise correlation factor used is not essential to the broader discussion of the relationship of E-Groups to the development of the calendar, but to provide specific dates in Table 1 it was necessary to select a specific correlation factor, with the caveat that some dates have alternate readings or different correlation factors.

Whether the Long Count first developed in the Maya area and diffused to Mixe-Zoque sites in the Isthmus area or vice versa remains uncertain (Justeson et al. Reference Justeson, Norman, Campbell and Kaufman1985:42). Cycle 7 (Baktun 7) monuments are often linked with the Mixe-Zoque language area and calendar innovations may have passed from there to the Lowland Maya. Stela C at Tres Zapotes is the earliest example of a Long Count inscription with a complete column of five numbers (Table 1). An early example of the yearbearer (6 Ben) is recorded in the Long Count on Chiapa de Corzo Stela 2 (Coe Reference Coe and Nicholson1976), sometimes dated to 36 B.C. (7.16.3.2.13), but owing to its fragmentary condition the Baktun and Katun inscriptions have to be reconstructed (Table 1). Furthermore, some scholars place this monument more than two centuries later (8.7.3.2.13 or A.D. 182; Riese Reference Riese, Boone and Willey1988:68, Table 1).

The most ancient Maya Long Count dates seem to come from Takalik Abaj and El Baul on the Pacific Slope, bordering the Lowland Maya area. Takalik Abaj Stela 2 has been described as a Cycle 7 monument (Coe Reference Coe1957:605), with an estimated date between 7.6.0.0.0 and 7.16.0.0.0, falling between 235 and 18 B.C. (Graham et al. Reference Graham, Heizer, Shook and Graham1978:89–91). Nonetheless, high definition digital imaging indicates that the original inscription was actually Cycle 8, and two of the three dots in the Baktun inscription have flaked off (Doering and Collins Reference Doering and Collins2011). The calendar inscription on El Baul Stela 1 is first century, but its exact date remains tentative. Given the Tzolkin inscription of 12 Eb, Michael Coe (Reference Coe1957:603) reconstructs the date as A.D. 37 (7.19.15.7.12; Table 1). Both monuments are sometimes considered to be Izapan in style (Guernsey Reference Guernsey2006:46–47, Figures 3.3b, 3.4), but they may be a variant of the early Maya style. An even earlier date has been proposed for Takalik Abaj Monument 11, a boulder carved with a column of glyphs and an inscription possibly dating to Cycle 6 (Middle Preclassic), based on a Tzolkin date (11 Ik) that may have an Initial Series glyph attached, but the only legible number is 11 (Graham and Porter Reference Graham and Porter1989). This site also has a Middle Preclassic E-Group that was probably used to peg solar dates before the calendar was more fully developed in Cycle 7. An interest in tracking solar events at this site is also evident in a boulder with relief-carved footprints that are aligned to the winter solstice sunrise (Altar 46; Hatch Reference Hatch2010; Milbrath Reference Milbrath, Freidel, Chase, Dowd and Murdock2017:Figure 1).

Cycle 8 Long Count dates are more clearly documented at Takalik Abaj, but interpreting these dates is not without controversy, because the texts lack period glyphs and are partially effaced. Stela 5 records dates in two side-by-side glyphic columns (Figure 2; Table 1), which John Graham and his colleagues (Reference Graham, Heizer, Shook and Graham1978:92) read as 8.4.5.17.11 and 8.2.2.10.5, but they note the Katun inscription is not clear in the right-hand column and the date could be 8.3.2.10.5 (Table 1). On the other hand, Justeson (Reference Justeson, Morely and Renfrew2010:48–49, Reference Justeson, Nichols and Pool2012:834) argues that the notation of zero was not yet known, so the zero for the 20-day Uinal (month) was omitted, making the last number in each column a reference to the Tzolkin date and rendering the date as 8.4.5.[0].17 11 Earthquake and 8.3.2.[0].10 5 Coyote. Regardless of whether this alternate reading is accepted, these two early Cycle 8 inscriptions follow Maya Long Count patterns, like Stela 1 from El Baul, placing the beginning of the Baktun cycle on 4 Ahau 8 Cumku.

Figure 2. Takalik Abaj Stela 5; left 1980, right 2012 (photos by Susan Milbrath).

The Hauberg Stela, an early monument presumably from the lowland Maya area, has an expanded Long Count inscription with a lunar calendar with a nine-day cycle, variously dated to A.D. 197 or A.D. 199 (Bricker and Bricker Reference Bricker and Bricker2011:720–723, Figure 12-2; Justeson Reference Justeson and Aveni1989:79), but it may be much later. Based on its style, Stuart (Reference Stuart2005b:163) dates the monument no earlier than 8.15.0.0.0 (A.D. 337). Given this uncertainty, I have expanded my discussion of this monument to a more lengthy treatment in another publication (Milbrath Reference Milbrath, Freidel, Chase, Dowd and Murdock2017).

One of the markers of the Early Classic period (A.D. 250/300–600) in the Maya Lowlands is the use of the fully developed Long Count calendar with period glyphs. Tikal Stela 29 remains the earliest known stela with an ISIG Long Count documented from a Maya site in the lowlands. Stela 29 lacks the lower part of the inscription, which would have had the Haab and Tzolkin recorded at the bottom. The Long Count date is reconstructed as 8.12.14.8.15, equivalent to July 6, A.D. 292 in both the Julian and Gregorian calendars (Jones and Satterthwaite Reference Jones and Satterthwaite1982: Figure 29). The ISIG month patron is Zip, and the ISIG has the Tun sign, but it lacks the T25 (ka) element that became common later (Coe Reference Coe and Nicholson1976:11). It may have been erected in the Mundo Perdido E-Group during the Manik 1 ceramic phase (A.D. 250–300), when the complex had a radial pyramid and three structures on the range to the east (Laporte Reference Laporte1987; Laporte and Fialko Reference Laporte, Fialko C., Clancy and Harrison1990:46, Figure 3.13).

The Leiden Plaque, dating to September 14, A.D. 320 Julian (September 15, A.D. 320 Gregorian), is an early Maya example of a standardized Long Count with the Haab month recorded at the base of the inscription and the corresponding month patron in the ISIG (Figure 3; after Milbrath Reference Milbrath1999: Plate 2). The month patron represents Yaxkin in the ISIG, which is followed by the Long Count inscription: 8.14.3.1.12 1 Eb 0 Yaxkin. A seating symbol refers to zero paired here with Yaxkin to be read as 0 Yaxkin. In addition to the Haab date, it also bears an early reference to the G5 in the cycle of nine glyphs in the Lunar Series (Thompson Reference Thompson1960: Figure 34, no. 25). The image probably shows the accession of a ruler. The plaque may be from the tomb beneath Mundo Perdido Structure 5D-86-6 (Laporte Reference Laporte1987). As in the case of Stela 29, this links an early inscription to Tikal's E-Group.

Figure 3. Leiden Plaque (modified after Milbrath 1999:Plate 2).

By the time these inscriptions were carved, E-Groups like the one at Tikal had lost any function in terms of solar observations, having been converted into a stage for royal rituals. Some Classic inscriptions record solar events, especially the solstices (Milbrath Reference Milbrath1999:64–65; Šprajc and Sánchez Nava Reference Šprajc and Nava2013:334), but they seem to be subordinate to more complex astronomical cycles and records of historical events in the lives of rulers. Although Classic period architecture continued to be characterized by astronomical alignments, the most common orientations are to dates in February and October, months coinciding with the initial phases of the agricultural cycle and the beginning of the harvest (Sánchez and Šprajc Reference Sánchez Nava and Šprajc2015: Tables 7–10).

The Role of E-Groups in Formulating the Early Calendar

The fixed 260-day count surviving today in the Maya agricultural cycle is apparently quite ancient and may have originated as a subdivision of the 365-day year, first tracked by marking the solstices in the earliest E-Groups. Tzolkin records appear earlier than the Haab in the Maya area, but 20-day sets in the Maya Haab most probably developed in tandem with the 20 day signs of the Tzolkin, and the Tzolkin itself may have evolved from observing the maize cycle in relation to solar positions noted in early E-Groups.

The maize cycle probably inspired Mesoamerican calendar priests to develop a 260-day calendar that coordinated with the agricultural cycle. The 260/105 split of the year is codified in the yearbearer cycle. The yearbearer appears in the Maya area at San Bartolo as early as 131 B.C., and even earlier in Oaxaca (600–400 B.C.). The early development of the pattern subdividing the year into a 260-day agricultural period and 105-day residual, non-agricultural season, may have been widespread.

The early calendar record from San Bartolo uses a yearbearer cycle that signals a division of 260 days in the solar year in the Southern Lowland Maya area. The two annual occurrences of the yearbearer would mark a 260/105 split in the 365-day year. It seems likely that the 260-day period originally was visualized as a subdivision of the 365-day year. Measuring these intervals in the solar year initially involved E-Group architectural orientations keyed to the seasonal cycle, dating back to 1000 B.C. in the Maya area, well before calendar records were recorded on monumental art. Observations of the solar cycle were initially important in early E-Groups, but as the precision of the calendar developed the apparent interest in tracking the solstices declined.

Early Epi-Olmec records often use the month patron system developed in the Late Preclassic to indicate positions in the 365-day cycle before the Haab dates were incorporated in the Long Count inscriptions. These texts lack true Haab notations, and the same is true of early Cycle 8 dates from the Pacific Slope. These texts also lack the month patron, which seems to make its earliest appearance in the Isthmus region. Nonetheless, early calendar records from the Pacific slope of Guatemala could be considered formative to the Maya Long Count.

Because the Long Count was not useful in recording the tropical year, solar observations continued to be important (Šprajc Reference Šprajc1995:598). Alignments marking intervals of 260 days that were useful in tracking the agrarian year are evident in both the Preclassic and Classic (González-García and Šprajc Reference González-García and Šprajc2016). There is evidence that the 260-day agrarian year was timed by the Tzolkin during the Postclassic (Milbrath Reference Milbrath1999:60–62), and it clearly survives in modern times among the K'iche’. With minor adjustments to correlate with lunar phases, this 260-day agrarian count is fixed within the year, and can be calculated using the Tzolkin, because whatever day begins the agrarian year will also end the cycle.

Early records from the Maya area show the yearbearers, a cycle useful in subdividing the year into sets of 260 and 105 days. The agrarian year developed earlier than the yearbearer cycle, but this calendar cycle no doubt helped to record the two segments of the year. Architectural alignments helped codify the continued importance of the 260-day agricultural cycle and lend support to its long-standing link with the ritual calendar.

Acknowledgments

I thank Anthony F. Aveni, Victoria Bricker, Francisco Estrada-Belli, Anne Dowd, and Ivan Šprajc for commenting on earlier drafts, and anonymous reviewers who helped improve this article. My thanks also to Tomás Barrientos for inviting me to Takalik Abaj on a field trip linked with a conference in 2012 at La Universidad del Valle in Guatemala, a trip that inspired me to begin this study of the early calendar, and to David Freidel for including me in a series of workshops to study E-Groups at the Santa Fe Institute. No permits were required to conduct this investigation. With the exception of one personal communication cited in the text, the data used in this study are all from published sources cited in the text and references.

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Figure 0

Table 1. Earliest Long Count Dates in Maya Region and Bordering Areas.

Figure 1

Figure 1. Cival E-Groups (after Estrada-Belli 2017).

Figure 2

Figure 2. Takalik Abaj Stela 5; left 1980, right 2012 (photos by Susan Milbrath).

Figure 3

Figure 3. Leiden Plaque (modified after Milbrath 1999:Plate 2).