Transport and Economic Development in Roman Britain

Long-distance travel existed in Britain well before the Roman conquest of ad 43. Log- and plank-built boats are known from the mid-second millennium bc (Wright, Reference Wright1990; Jones, Reference Jones2012: 33–37), and similarities in material across the English Channel from the later part of the second millennium demonstrate a regular seaborne traffic (Lehoërff & Talon, Reference Lehoërff and Talon2017). From the late second/early first century bc onwards, seaborne trade from Gaul brought Roman goods, including Italian amphorae and Armorican ceramics, to southern Britain, with trade between south-eastern Britain and Gaul intensifying from the mid first century bc (Webley, Reference Webley, Anderson-Whymark, Garrow and Sturt2015). Within Britain, wheeled vehicles and fittings are attested from the earlier part of the first millennium onward (e.g. a wheel at Flag Fen, 1300–900 bc; Pryor, Reference Pryor2001). There are also several long-distance routeways, such as the Wiltshire–Oxfordshire Ridgeway, which are also generally thought to date to prehistoric times (Miles et al., Reference Miles, Palmer, Lock, Gosden and Cromarty2003).

Within decades of the Roman conquest continental pottery imports, including samian ware from Gaul and amphorae to transport olive oil from Baetica, reached locations throughout Britain, which implies that Britain had a province-wide transport system in place from the second half of the first century ad. Nevertheless, several aspects of transport technology clearly improved during the Roman era. These include: a) increased use of wheeled carts and wagons pulled by draft animals; b) an increase in the size of draft animals; c) a province-wide system of well-engineered roads and bridges; d) the construction of harbours and quays along inland waterways; and e) the excavation of canals, particularly in the East Anglian fens. The initial purposes of the road system involved facilitating flows of people, material, and information between military sites (Haynes, Reference Haynes and Erdkamp2002). These military installations were placed in strategic locations for the administration of the new province, and so probably balanced geographic factors such as topography, navigable rivers, and natural resources with social and demographic aspects including the distribution of populations and ethnic groups. Roads and bridges were also engineered specifically for the movement of soldiers on foot and supplies by horse-drawn carts, given that horses were used for transport to a much greater extent during the Roman period than had been the case during the Late Iron Age (Mattingly, Reference Mattingly2006: 256–90). The importance of these roads is reflected in their relationship with population centres. The earliest roads linked the primary towns, which mostly grew at locations of earlier Late Iron Age oppida and subsequent Roman military activity, while in subsequent centuries many of the so-called small towns developed along major roads or at crossroads, indicating that the population was becoming more orientated to the movement of people and goods.

Coincident with this expansion in transport, several lines of evidence—such as the increased use of stone masonry, the greater frequency of mosaics and hypocaust heating systems, increasing rates of coin loss, larger numbers of metal artefacts, growing evidence of industrial specialization, and evidence of increased agricultural labour and productivity—lead us to conclude that material living standards increased for at least some people during the Roman period (Casey, Reference Casey1986; Ward-Perkins, Reference Ward-Perkins2006; Lodwick, Reference Lodwick, Allen, Lodwick, Brindle, Fulford and Smith2017; Jongman et al., Reference Jongman, Jacobs and Klein Goldewijk2019). Taken together, these data suggest that the economy of Roman Britain experienced substantial per capita growth, not just increases in gross output, and that reductions in transport costs played a role in this process. Here, we attempt to measure these reductions by considering the spatial distribution of pottery produced in specific locations at different times.

Measuring Transport and their Costs Consequences

Consumption, prices, and distance-decay

The interpretation of pottery distributions, and especially ‘fall-off’ curves with distance from the source, has a long history in Romano-British archaeology (Hodder, Reference Hodder1974; Fulford & Hodder, Reference Fulford and Hodder1975; Hodder & Orton, Reference Hodder and Orton1976: 98–153). Early studies suggested that fall-off curves could be interpreted in terms of strictly economic processes. More recently, researchers have viewed exponential decay as the expectation of a purely ‘rational’ process, with deviations from the expected pattern reflecting the social embeddedness of economic relations (Allen & Fulford, Reference Allen and Fulford1996; Allen et al., Reference Allen, Lodwick, Allen, Lodwick, Brindle, Fulford and Smith2017; Rippon, Reference Rippon2018; Rippon & Holbrook, Reference Rippon and Holbrook2021). We build from this approach; while many social, cultural, geographic, political, and economic factors are responsible for consumption patterns in specific locations, the primary factor behind exponential decay with distance in the proportional consumption of pottery from specific industries is accumulating transport costs.

Human behaviour generally involves dedicating time and effort to different activities which generate outcomes (Pryor, Reference Pryor2005). Producing and distributing goods of any type would have required time and resources and would have closed off opportunities for the individuals involved to carry out other desirable activities. Therefore, production and distribution had ‘costs’ in a broad sense, regardless of whether these costs were monetized. Likewise, consumers have limited resources to exchange for goods they want and need, leading to decisions regarding the allocation of these limited resources. Finally, given that producing and distributing goods involves some ‘cost’, producers and distributors will only give a good to someone else in exchange for something of perceived equivalent value, even if this ‘price’ is not monetized or involves delayed reciprocity. Various factors influence human behaviour in specific contexts, but when integrated across a great number of people at large spatial and temporal scales, human behaviour tends to strike a balance between costs and benefits, in aggregate, on average, and over time. Note that in our study there is no presumption of a centralized market or price system across Britannia, nor is there any assumption that the motivation for selling pottery was profit. The considerations above do not define a capitalist economy—they merely define a system where producers, distributors, and consumers seek to balance costs and benefits, which could have been accounted for formally or informally, in the moment or over a period of time.

Here, we develop formal models rooted in this aggregate balancing of costs and benefits to derive expected average relationships between transport costs, distance, and pottery consumption. We then combine this model with data for pottery consumption and distance to estimate changes in transport costs over time. We begin by considering the implications of distance-decay relationships for the character of transport costs. Mathematically, a quantity is subject to exponential decay if it decreases at a consistent proportional rate per increment (of time or distance). For artefact distributions, exponential decay represents a process in which the probability of consumption decreases as the distance from the production location increases. An exponential decay function that captures this process can be written as:

(1)$$P_x = P_0e^{-\mu x}, \;$$

where x is the distance from the source, P _x is the probability of consumption at that distance, P ₀ is the probability of consumption at the source, and μ is the rate of decay in the probability of consumption per unit distance. Equation (1) describes the process of reducing an amount by a constant percentage per unit distance, as the distance increases. Exponential decay is different from linear decay in that the decay factor is a fraction of the remaining amount, which means the actual amount the original amount is reduced by decreases with each additional increment of distance; in linear decay, by contrast, the original number is decreased by the same amount with each additional increment of distance.

Equation (1) can be transformed into a linear function by taking the logarithm of both sides, yielding:

(2)$$\ln P_x = \ln P_0-\mu x, \;$$

and this can be rearranged to solve for the decay rate:

(3)$$\displaystyle{{\ln P_x-\ln P_0} \over x} = {-}\mu \to \displaystyle{{\Delta \ln P} \over {\Delta x}} = {-}\mu .$$

The left side of Equation (3) represents the slope of the fit line relating the log-proportion of the artefact category to distance from the source, and the right side of the equation indicates that this quantity is equal to the rate of decay in the proportion with distance. Notice also that Equation (2) is a linear function that relates the log-proportion of a particular good to the distance from the source x, via the factor μ representing the decay rate. Therefore, when the spatial distribution of an artefact type exhibits exponential decay, this will be reflected in a linear relationship between the log-proportion and the distance. It will also imply that consumption of the artefact type decreases by a consistent fraction with each additional increment of distance, with the slope of the fit line to the data reflecting this fraction.

Why should the probability of consumption of a specific variety of pottery exhibit exponential decay with distance from the production source? Our chain of reasoning is as follows: 1) consumption of a given variety of manufactured good is proportional to the price (whether mediated through money, barter, or reciprocal exchange) of that variety in the local market relative to other varieties; 2) the increase in the price of a good with distance from its source is proportional to the total transport cost; 3) transport costs accumulate in a linear fashion with distance; and 4) linear transport costs lead to a consistent fractional decline in the probability that a good will ‘survive’ to be consumed over the next increment of distance (Lee & Wang, Reference Lee and Wang2003). When transport costs increase proportionally with distance, the fraction of consumption represented by pottery from a given source will be highest at its production location, and with each additional increment of distance the likelihood of ‘survival’ to be consumed at an even greater distance (the remaining fraction) will be reduced by the unit distance cost of transport of a pottery vessel. This cost per unit distance is represented by μ in Equation (1). Thus, the slope of the relationship between the log-proportion and distance can be interpreted directly as the cost of transport per unit distance, as specified in Equation (3). Note that μ is agnostic regarding the determinants of transport costs, which could lie in transport technology (horses, wheeled vehicles, watercraft), physical infrastructure (roads, bridges, ferries, locks, quays), or even social infrastructure (tariffs, social hostility, protection from bandits, etc.). For additional discussion of these arguments, see the Supplementary Materials.

Transport, specialization, diversity, and consumption

We also consider how changes in transport costs might be expected to affect overall patterns of pottery production and consumption. As the frictional effect of distance declines, the total cost of pottery at a given distance from the production location will also decline. As a result, the area over which a product can be effectively distributed will expand, and this will expand the potential market for the product. This will in turn stimulate an expansion in the scale and specialization of production (Arrow, Reference Arrow, Buchanan and Yoon1994; Kelly, Reference Kelly1997; Smith, Reference Smith2007). Overall, reductions in transport costs will result in an increase in specialized production, or a decrease in the diversity of production, as production focuses on fewer, more intensively produced and generally higher-quality varieties. In addition, lower transport costs would have had consequences not just for individual industries but would also have allowed competing industries to have easier access to local markets. Even sites where pottery was being produced would have been increasingly open to wares produced elsewhere. Read in terms of Equation 2, the implication is that at production sites (where the distance x = 0), the proportion of locally produced wares should decrease as transport costs decrease and wares produced by competitors became increasingly available.

The distribution of people in space also exerts an influence on production and consumption patterns. Populations that are more concentrated in space will interact more frequently with more people of different kinds, and this will increase the connectivity of, and information available to, an individual (Ortman & Lobo, Reference Ortman and Lobo2020). Thus, at any given time, individuals who live in more populous settlements will integrate more information about choices available to them in their daily activities, including their consumption activities, than individuals who live in less populous settlements (Hanson & Ortman, Reference Hanson and Ortman2020). Individuals in an agglomerated population can also become more productive as a result of learning and sharing skills (Ortman & Lobo, Reference Ortman and Lobo2020). This increase in individual-level productivity can in turn support increases in consumption. Transport costs and population thus have seemingly opposed effects on patterns of pottery consumption, with increasing population supporting greater diversity in consumption, and declining transport costs leading to greater specialization in production. These two effects are connected via the increase in demand for all goods that a reduction in ‘price’ (in turn the result of decreased transport costs) creates.

In the Supplementary Materials, we employ the analytical framework known as Settlement Scaling theory (Lobo et al., Reference Lobo, Bettencourt, Ortman and Smith2020) to show that the amount of information embedded in a pottery assemblage, captured by the Shannon Index $H = {-}\sum ( {p_i\ast \ln p_i} ) $, can be expected to grow with the number of interacting people represented by that assemblage according to:

(4)$$H( {N_t} ) = \delta [ {\ln N_t} ] + H_{0_t}, \;$$

where $H_{0_t}$ represents the baseline information available to an individual at time t, H(N _t) represents the amount of information embedded in a pottery assemblage derived from consumption by N persons, at time t, and δ ≅ 1/6 represents the growth rate of information as the interacting population grows. Equation (4) can be tested directly by fitting a linear function to the logarithm of a population proxy and the Shannon Diversity Index of the associated pottery assemblage for data from a variety of settlements dating to different times. As population increases, one would expect H(N _t) to increase due to an increase in the information that is integrated by consumers in consumption choices; and as transport costs decline one would expect $H_{0_t}$ to decline due to increasing specialization in production.

Finally, we note that, due to the many positive effects of declining transport costs, one would expect such reductions to increase the carrying capacity of a region by stimulating more widespread flows of goods; an increase in the number of people who can live close together by increasing the effective catchment from which individuals can obtain products necessary to them; and an increase in household inventories and use-rates of pottery through overall economic growth. These changes should be apparent in increases in pottery consumption rates per unit time and unit area.

Expectations

The observations made above lead to the following expectations regarding patterns in pottery assemblages from Romano-British settlements:

1. 1. The slope μ of the linear fit of the log-proportion of pottery consumed at a specific site to the distance from its production location reflects the decay rate of this proportion with distance from the source. One would expect this decay rate to become less negative (closer to zero) with improvements in transport technology over time.

2. 2. The intercept, ln P ₀, of the linear fit of the log-proportion of pottery vs distance from its source, which represents the proportional consumption of pottery at production locations, provides a measure of the access of individuals at a source to products of industries from other sources. Since one would expect opportunities for greater variety in consumption to develop with decreasing transport costs, one would expect the value of this intercept to decrease as transport costs decrease.

3. 3. Assuming our sample of pottery assemblages is roughly representative (we selected excavations irrespective of location, date, or settlement type, focusing solely on the presence of quantified assemblages containing more than 500 sherds or 4 kg of pottery), the total amount of pottery from an industry found across all assemblages assigned to a period and industry should reflect the relative amount of production of that industry in each period. If transport costs did decrease over time, one would expect the average level of production of an industry to increase, the variation in production levels across industries to decrease, and production levels of the largest industries to increase, as producers took advantage of expanded markets.

4. 4. Pottery recovered from an excavation reflects consumption activities by a certain number of people over a given period. Since the process of assigning pottery to a specific industry and period controls for variation in the duration of an assemblage, variation in assemblage size should be proportional to the number of people whose activities contributed to the assemblage. The Shannon Diversity Index calculated from an assemblage reflects the average information integrated by one of these individuals in their consumption choices over that same period. As transport costs decrease, diversity in production will also decrease; but diversity in consumption will also be consistently higher in larger local markets. As a result, the y-intercept of the linear fit of the Shannon Diversity Index vs the logarithm of apportioned assemblage size (a proxy for relative population) should decrease over time, but the slope should remain a constant δ ≅ 1/6 across periods, regardless of changes in transport (see the Supplementary Materials).

5. 5. Finally, decreases in transport costs should lead to increases in pottery densities, measured as grams of pottery per year per m² of excavation. This may be due to increases in consumption rates of pottery, increases in the size and density of settlements, or both.