Classic Maya Plaza Size and Use

In an influential paper, Takeshi Inomata (Reference Inomata2006a) argued that plazas in Maya cities were “political theaters” where city residents gathered to witness theatrical performances by kings and elites. These were “large-scale performances involving a substantial number of participants” (Inomata Reference Inomata2006a:807). This argument originated with the notion that political power in Maya polities was based on spectacle and performance (Demarest Reference Demarest, Demarest and Conrad1992; Inomata Reference Inomata, Inomata and Coben2006b), a model originally called the “theater state” by Clifford Geertz (Reference Geertz1980). In this model, it is crucial that the entire populace is able to gather to witness royal spectacles. Inomata describes the implications of the theater state model for plazas as follows:

Inomata analyzes the number of people that could fit in plazas by multiplying the area of urban plazas by several density constants reported by Jerry Moore (Reference Moore1996). He selects three figures mentioned by Moore—0.46, 1.00, and 3.60 m² per person—and calculates the potential sizes of the groups that could fit into the plazas at Tikal, Copan, and Aguateca (Inomata Reference Inomata2006a:816). He compares these figures to the estimated populations of the three sites and concludes that the entire populations of Tikal, Copan, and Aguateca could have gathered in their respective plazas, although he admits that the entire population of Tikal would make for a tight fit, and the ceremonial plaza of Copan would not have provided the best sightlines (Inomata Reference Inomata2006a:813–814, Table 1). Despite these complications, Inomata concludes that for smaller and medium centers, the plazas would have held the majority of community members for politically charged ceremonies and that the large plazas of the large centers were made to hold large numbers of people. Even as fitting the entire population became difficult over time for the larger centers, accommodation was made to afford everyone access to mass spectacles (Inomata Reference Inomata2006a:819).

Table 1. Population and Plaza Area of Late Postclassic Settlements.

Notes: ^a Estimate 1: based on assumption of constant density; Estimate 2: based on assumption of densification (see text).

^b Settlements marked with * were used in the regression to create Population Estimate 2 (see text for discussion).

^c Source of data for settlement area: P: published datum; M: measured; A: archaeologist communication; 1: data in Smith Reference Smith2005; 2: data can be found in Smith (Reference Smith2017).

^d Estimate 2 is used to calculate plaza area per capita.

^e The identity of the main plaza is not clear.

The density constants reported in Moore (Reference Moore1996:147) are rough estimates based on a small number of heterogeneous settlements, some reported by personal communications rather than publications. Inomata (Reference Inomata2006a:812) acknowledges the provisional nature of these estimates. Nevertheless, this approach—estimating plaza occupancy based on 0.46, 1.00, and 3.60 m² per person in support of mass spectator ceremonies as the cause of plaza size—has been taken up by other Mayanists and other Mesoamericanists (Robin et al. Reference Robin, Kosakowsky, Keller and Melerhoff2014:381; Tsukamoto and Inomata Reference Tsukamoto and Inomata2014) and North Americanists (Cobb and Butler Reference Cobb and Butler2017; Thompson Reference Thompson2009). The use of these plaza size constants suggests that these authors—like Inomata—assume that the entire urban population would have gathered in the plazas.Footnote ¹

The basic assumption of Inomata's model of mass spectator ceremonies is that the entire population of a settlement (or a polity) could fit into the plazas of a capital to witness ceremonies. If this model is correct, we should expect a linear relationship between city population and plaza area. Our data, however, reveal a relationship inconsistent with this interpretation. The relationship between population and plaza size is sublinear when the variables are expressed as logarithms, which means that larger settlements have considerably less plaza space per capita than smaller settlements.

Sources of Evidence

Plaza Activities

On the basis of the above sources of evidence we identify five types of activities that likely took place in Mesoamerican urban plazas: private rituals, periodic markets, mass spectator ceremonies, participatory public ceremonies, and feasts and other popular celebrations.

Participatory Public Ceremonies

A participatory public ceremony is an event in which groups of people participate in specific movements and activities in designated locations. The Aztec monthly ceremonies, as described by Sahagún and others, provide many examples. Plazas were the settings for processions, dances, sacrifices, and offerings of incense. The Codex Borbonicus, for example, shows an Aztec urban plaza (Figure 1) that corresponds closely to the known layouts of many Aztec cities (Smith Reference Smith2008:127–132). A group of deity impersonators (ixiptla) lines the edges of the plaza, suggesting that the plaza was used for public religious ceremonies.

Figure 1. Aztec plaza with deity impersonators (ixiptla). We have rotated the image so that north is at the top. Redrawn from the Codex Borbonicus (Anders et al. Reference Anders, Jansen, García and Pérez Jiménez1991:36).

The Primeros Memoriales of Sahagún (Reference Sahagún and Anders1993) contains paintings of the 18 state-sponsored monthly ceremonies, described in detail in Book 2 of the Florentine Codex (Sahagún 1950–Reference Sahagún, Anderson and Dibble1982). The painting of the Tlacaxipeualiztli ceremony (Figure 2) includes two buildings and three shrines or altars, around which six different groups of actors are engaged in various activities, including human sacrifice, playing musical instruments, and formal processions. No spectators are depicted; each person participates in a specific, localized ritual activity. Diverse groups of people were engaged in active participation, visible to anyone who cared to look. Mass spectator ceremonies by contrast have larger crowds, packed more tightly together, whose members passively witness staged events or may participate together in activities that do not require extensive space, such as chanting or limited choreographed movement.

Figure 2. The Aztec monthly ceremony of Tlacaxipeualiztli from the Primeros Memoriales of Sahagún, modified after Seler (Reference Seler1927).

Multiple Activities Separated in Time

The three most likely activities for Mesoamerican plazas—markets, participatory ceremonies, and mass spectator ceremonies—were all episodic in time, with regular dates in the calendars of known Mesoamerican societies. Among the Aztecs, for example, markets met weekly (every five days) and participatory ceremonies and mass ceremonies monthly (every 20 days). As such it would have been convenient to use formal plazas for all three kinds of activity, instead of creating separate spaces for each. This suggestion illustrates a key insight of environment-behavior theory (Smith Reference Smith2011), which posits that “organization in time may be substituted for organization in space” (Rapoport Reference Rapoport and Kent1990:15).

The Mesoamerican ethnographic data provide insight into the nature of periodic uses of public plazas. Many indigenous towns have a central town square with a public fountain. Each week a market is held in the square, which remains empty the rest of the week. This pattern of a central square, which resembles a vacant lot most of the time but springs to life for market day, has been described by ethnographers of peasant villages in Oaxaca, western Guatemala, and other regions of Mesoamerica (e.g., Beals Reference Beals1975; McBryde Reference McBryde1947). For example, in the late twentieth century, the Mexican town of Tepoztlan, Morelos (Lewis Reference Lewis1951), had a permanent market building adjacent to the town square. Most days the square was used for informal socializing and was frequently empty. But on market day (Sunday), the market spilled out of the market hall and temporary stalls covered the plaza (Figure 3). The multifunctional character of plazas in Latin American towns has been emphasized by Daniel Gade (Reference Gade1976) with respect to six types of plaza use: as an unimproved site, a marketplace, a ceremonial center, a social concourse, a garden park, and a traffic hub. The common factor among the diverse periodic activities that likely took place in plazas is that they all involve social interactions among large numbers of urban residents.

Figure 3. Temporary market stalls in the main plaza of the village of Tepoztlan, Morelos, Mexico, on a typical market day in 1980. Photograph by Michael E. Smith.

Analytical Approach

Our approach to plaza size differs from traditional analyses by Mesoamerican archaeologists. In that scholarly tradition, archaeologists commonly use excavation data to construct detailed analyses of individual architectural features like plazas. Although comparisons may be made among sites, such comparisons are typically peripheral to the major thrust of the study. Our approach, in contrast, is explicitly comparative and statistical in nature. Any comparative analysis requires simplification and abstraction. Instead of dealing with the specific stratigraphic sequences of individual plazas, we are comparing one variable—plaza size—across three groups of settlements in relation to their estimated population. In this manner, we evaluate plaza use by considering its area in relation to its surrounding settlement population.

Estimation Framework

We hypothesize that—within individual regions or urban systems—there was a systematic relationship between the area allocated to plazas and the population size of prehispanic Mesoamerican settlements. There are various possibilities as to the quantitative relationship between plaza area and population size, specifically with regard to how plaza areas changed in response to increases in population size: proportionally, for example, or less than proportionally. We adopt power-law function to represent the relationship between settlement population and plaza area:

(1) $$\begin{equation} {Y_t} = {Y_0}N_t^\beta\,\raise 3pt\hbox{,} \end{equation}$$

where Y refers to total area of plazas, N denotes population size, Y ₀ is a prefactor (or constant) capturing the effects of technology and institutional arrangements on the relationship between population size and plaza area, and t is a subscript identifying a particular time. The value of the exponent β (an elasticity index) determines how the area of urban settlements allocated to plazas varied with settlement population within a settlement system. The choice of a power-law function assumes that the effect on plaza area of increasing population size is not additive but multiplicative, which is to say that the increase in plaza area is driven by the interaction of many factors observationally summarized in an increase in population size (Coffey Reference Coffey1979).

Adopting a power-law functional form carries another implication; namely, that the relationship between plaza area and population size is parametrized by a single number, β, which is itself scale independent. As a consequence, the rate of change or growth (in this case represented by the increase in the population size of settlements within a coherent system) is a constant fraction of the relative change in population. If empirically robust, such a regularity is a hint that indeed there were underlying socioeconomic and cultural processes that generated and maintained the same relationship among two structural and functional variables, plaza area and population, over the range of scales found within a settlement system (Brown et al. Reference Brown, West, Enquist, Brown and West2000). As suggested by Chave and Levin (Reference Chave and Levin2003:551), “scaling concepts offer an avenue to study heterogeneous assemblies for which the microscopic processes are not known, and probably not knowable (e.g., in the case of social systems) except in terms of their statistical properties.” Thus, a scaling relation is perhaps the best evidence for the existence of general features in the immensely complex dynamics of social and economic systems (Brock Reference Brock1999).

Taking the natural logarithm of Equation (1) we obtain a simple linear regression equation:

(2) $$\begin{equation} \ln {Y_t} = c + \beta \ln {N_t} + {\varepsilon _t}, \end{equation}$$

in which ɛ is an IID noise term (Gaussian white noise). Whether or not it is reasonable to adopt the assumptions carried along by the choice of a power-law functional form can be evaluated by performing the usual goodness-of-fit tests on Equation (2). The values for the β coefficients reported in the present discussion were estimated for all three data sets using ordinary least squares (OLS) regression with a correction for heteroscedasticity (the estimations were done using the Stata 12SE software package). Note that our three steps—the choice of a power-law functional form, estimation of the scaling coefficients, and provision of a model or explanation for the estimated coefficient values—are distinct analytical exercises.

Late Postclassic Mesoamerican Settlements

Our first set of observations is drawn from a sample of Late Postclassic Mesoamerican settlements whose size and demography were analyzed previously by Smith (Reference Smith2005). The 2005 sample consisted of all Late Postclassic towns or cities with published detailed maps of their total extent, their urban epicenter, or both. Smith returned to that sample with Alexandra Norwood and measured the sizes of mapped plazas in all sites with adequate maps, yielding a sample of 22 sites. He then located eight additional sites fitting these criteria that were published after the data for the 2005 paper were collected. The sites are listed in Table 1. They are organized by region (see Figure 4); details of measurement and data collection are provided in Smith (Reference Smith2017).

Figure 4. Map of Mesoamerica showing regions for the Late Postclassic sample of settlements. The Mixtequilla and Palenque regions are also shown. Map created by Michael E. Smith.

Most Late Postclassic cities and towns had well-defined formal plazas located in the center of the site. Larger cities often had subsidiary plazas built away from the central area. Because we are interested in the sum of all plaza activities in each settlement, we use the sum of the areas of all plazas in our analyses. The basal areas of shrines, platforms, or buildings located within plazas were subtracted from plaza areas, yielding the space available for movement and social interaction that we call the “plaza interaction area.” Many of these settlements were capitals of city-states or other types of small polity. Although precise data are lacking, it is likely that the central plazas were designed and built early in the history of each settlement, and then subsidiary plazas were constructed at a later point as the city expanded. Figure 5 shows how plazas were measured in two sites: Teopanzolco (not part of this sample) and Moxquivil. The central plazas are labeled A, and secondary plazas are labeled B.

Figure 5. Plaza delineation in two Late Postclassic sites: Teopanzolco (Smith Reference Smith2008:33) and Moxquivil (map provided by Elizabeth Paris). Maps redrawn showing plaza space by Michael E. Smith.

For most of the 30 sites in Table 1, we have measurements of their total settled area but lack independent population estimates. We calculate two separate population estimates for each site. The first (Estimate 1) is based on the common archaeological practice of multiplying site area by a density constant (Drennan et al. Reference Drennan, Adam Berrey and Peterson2015:106). We use a constant of 50 persons per hectare, which is the median population density of Aztec cities (Smith Reference Smith2008:152). The median is used instead of the mean because the mean is biased by the large population of Tenochtitlan. For four sites whose populations have been estimated independently of their area by archaeologists (Cuexcomate, Tenochtitlan, Mayapan, and Mitla Palace), we use those estimates. Estimate 2—which we consider more realistic and accurate—builds from the observation that human settlements generally increase in density as their populations grow. This pattern has been observed in a number of demographic analyses of both modern and premodern settlement systems, where settlement area exhibits a regular sublinear scaling relationship with respect to population (Cesaretti et al. Reference Cesaretti, Lobo, Bettencourt, Ortman and Smith2016; Cook and Heizer Reference Cook, Heizer and Chang1968; Ortman et al. Reference Ortman, Cabaniss, Sturm and Bettencourt2014; Ortman et al. Reference Ortman, Davis, Lobo, Smith, Bettencourt and Trumbo2016). The elasticity of the population-area relationship in these studies is similar to that found in contemporary urban systems, and it matches the value predicted by current models (Bettencourt Reference Bettencourt2013). Estimate 2 takes this general relationship into account. Specifically, we use Equation (1) in the case where Y refers to the settled area. Rearranging this equation to solve for N, we obtain:

(3) $$\begin{equation} N = {\left( {Y/{Y_0}} \right)^{1/\beta }}. \end{equation}$$

We use the subset of cases for which population is estimated independent of area (Cuexcomate, Tenochtitlan, Mayapan, Mitla Palace) to estimate Y ₀ and β, using Equation (1), and then apply these figures to the settled area for each site to estimate the total population N using Equation (3).

Therefore, two regression models were estimated, using different population estimates: model 1, which uses population Estimate 1 (based on the assumption of constant density); and model 2, which uses population Estimate 2 (based on the assumption that larger sites had denser populations than smaller sites). The number of observations (n = 30) is not very large but is sufficient to invoke the central limit theorem and thus estimate confidence intervals around the regression coefficient. The estimation results are shown in Table 2. Not surprisingly, the estimated regression coefficient for the effect of population size on plaza area differs between the two models—0.55 for model 1 and 0.44 for model 2—but the 95% confidence intervals for the two estimated coefficients include each other. The proportion of the variability in plaza area explained by population size alone—about 65%—is very similar in the models. The consistency of these results is somewhat remarkable given the simplicity of the model and the messiness of archaeological data.

Table 2. Regression Results.

Note: Figures in parentheses are standard errors.

Classic Period South-Central Veracruz (Mixtequilla) Settlements

Intensive settlement pattern research by the Proyecto Arqueológico La Mixtequilla (PALM) I and II, undertaken by Barbara Stark, forms the basis for our study of plazas and settlements in south-central Veracruz, Mexico (Mixtequilla). The plaza information was obtained from the centers and monumental complexes in a contiguous block of survey, or “main block” of the PALM projects, using detailed topographic maps (Figure 6). These data include the Classic period centers and related complexes of Cerro de las Mesas and Azuzules, in addition to minor monumental complexes and centers (see Table 3).

Figure 6. Mixtequilla survey block map. Map created by Alanna Ossa using PALM data provided by Dr. Barbara L. Stark.

Table 3. Population and Plaza Area of Classic Period Mixtequilla Sites.

Notes: ^a Scale attraction in meters.

^b Plaza area measured in square meters; site area measured in hectares.

^c None; default value of 500 m.

The original settlement study captures the majority of the centers that were identifiable within the delta of the lower Blanco (Stark Reference Stark2001). The PALM survey covered 49 km² for the main survey block and identified approximately 13 civic ceremonial complexes, including the 10 centers with formal plazas that were used in this study (Stark Reference Stark1999). For the Classic period Mixtequilla, formal plazas were typically configured in a recognizable “standard plan” that included a conical mound accompanied by two elongated mounds forming a plaza with a ball court opposite the conical mound (Daneels Reference Daneels2002), although some locally identified variants of this plan exist (Stark Reference Stark, Fargher and Heredia Espinoza2016). Two of the three complexes not used in our study had no formal plaza space and may not be public complexes (Ossa Reference Ossa, Tsukamoto and Inomata2014). The third complex was Postclassic, an era excluded from our study.

The largest contiguous block or “main block” of the settlement study captured all of the identifiable centers. As such, these centers can be considered a single population within a defined spatial area. The status of these sites as a population affects their statistical treatment (see below) and allows us to do more with them.

Only general data are possible for plazas on a very broad time scale, encompassing the Classic/Late Classic (AD 300–900) period. We use the plan data obtained from the contour maps and GPS footprints to establish plaza area. We recognize that these areas could have changed during their use of several hundred years and that a certain amount of mound erosion-based error is also possible.

Population estimates for south-central Veracruz were based on a Monte Carlo simulation that tested the existence and scale (where possible) of individual domestic mound associations with centers (Ossa Reference Ossa, Tsukamoto and Inomata2014). The domestic mounds are remnants of residential occupation based on excavations and multiple years of intensive survey (Stark Reference Stark1999, Reference Stark2001). The simulation allowed us to identify the scale at which residences were associated with centers by measuring the highest densities of residences. Since the region is characterized by a distribution of residences without easily identified drop-offs that could mark the edges of center-associated populations, the simulated residential association scale provided a quantifiable settlement population boundary for most, though not all, of the centers in this study. Residences were assigned to the closest center based on the identified scale. For those centers where settlement attraction scales were not identified, a scale was selected based on size. Once a scale was identified/selected, all residential mounds within each center buffer were tabulated at 5.6 persons per individual mound to come up with a population estimate per center (Table 3). The figure of 5.6 persons per household is taken from Kolb's (Reference Kolb1985) thorough study of Mesoamerican household size.

Given that the Classic period occupation is the longest, the majority of residences used in this analysis probably date to the Classic period, although their exact contemporaneity is unknown. Site areas were calculated based on the scale of settlement association identified by the original simulation (Ossa Reference Ossa, Tsukamoto and Inomata2014). Finally, the location of Azuzules near the survey boundary means that some boundary effect in measuring settlement (and therefore population) is possible, although ground reconnaissance in the areas south of Azuzules indicate that residential mounds are not found in abundance in that area.

The decision to treat the data set for the Classic period Mixtequilla settlements as a population makes it possible to estimate β notwithstanding the small number of observations (therefore a confidence interval around the estimated regression coefficient is not reported). The estimated coefficient is 0.61, indicating a sublinear relationship between population size and plaza area. The larger size of the coefficient relative to the Postclassic sites (Table 2) indicates that the per capita plaza area declines more slowly with population size in the Mixtequilla population. The R² value of 0.63 is very similar to that for the Postclassic cities data, and again it is remarkable that over 60% of the variability in the area of plazas in the Mixtequilla centers is explained by population size alone.

The Palenque Region in the Classic Period

Our third case consists of the Classic period Maya city of Palenque and a group of 10 nearby sites from a regional survey directed by Rodrigo Liendo Stuardo (Reference Liendo Stuardo2002, Reference Liendo Stuardo2011). Palenque was a major urban center renowned for its architecture, art, and hieroglyphic inscriptions (Marken Reference Marken2007). Liendo Stuardo surveyed an area of 470 km² around Palenque. He published tables of data that include areal extent and population estimates (based on counts of house mounds) of several hundred sites (Liendo Stuardo Reference Liendo Stuardo2011:25–33). The sites are classified into five types that form an ordinal scale of decreasing architectural complexity. Our data are from a table of the sites with civic-ceremonial architecture published in Liendo Stuardo (Reference Liendo Stuardo, López Mejía, Campisani, Tsukamoto and Inomata2014:117). Sites with civic-ceremonial architecture are classified as Category 5 in the survey typology (Liendo Stuardo Reference Liendo Stuardo2011:25–33); these sites are further subdivided into two “ranks.” There are two regional capitals (Rank 1)—Palenque and Chinikiha—and nine minor civic centers (Rank 2).

These sites can be considered a population following the same logic applied to the Mixtequilla sites; they consist of all of the centers present within a defined spatial zone (survey area). The sites and measurements are shown in Table 4. Site populations were estimated by Liendo Stuardo and colleagues (Reference Liendo Stuardo, López Mejía, Campisani, Tsukamoto and Inomata2014:117) by multiplying the number of house mounds by the same constant of 5.6 as was applied in the Mixtequilla, maintaining internal consistency. Liendo Stuardo also provides an illustration of how the main plaza at Chinikiha was delimited for purposes of measuring its area (Liendo Stuardo et al. Reference Liendo Stuardo, López Mejía, Campisani, Tsukamoto and Inomata2014:113). We remeasured this plaza, using the protocols established for measuring Postclassic plaza size, and our result—13,034 m² after removing the area of a structure in the center of the plaza—is within 0.53% of Liendo Stuardo's figure. On this basis we conclude that Liendo Stuardo's plaza area measurements are equivalent to our measures of “interaction area” in the Postclassic sample described above.

Table 4. Population and Plaza Area of Classic Period Palenque Region Sites.

Notes: Data from Liendo Stuardo et al. (Reference Liendo Stuardo, López Mejía, Campisani, Tsukamoto and Inomata2014:117).

^a Area in square meters.

As in the Mixtequilla, the decision to treat the data set for the Classic period Palenque area cities as a population makes it possible to estimate β notwithstanding the small number of observations. The estimated coefficient is 0.40, very close to the value for population Estimate 2 of the Postclassic sample. The R² value of 0.44 is smaller than that for our other cases, partially due to the small number of observations, but it does show that population size is an important determinant of plaza area in the Palenque survey region.