3.5.2 Density patterns of route net

3.5.2 Density patterns of route networks
If we stand back from the route network, its individual characteristics blur. We observe a simple density pattern in which some areas have a very dense route network, while in others the network is very sparse. In approaching this problem, we proceed from the local scale of the city street and subdivision network, up through regional differences within a state, to the world scale. Scale problems are considered more formally in Section 10.6 and in Chapter 12.

(a) Local and regional levels. Examination of the large scale maps or plans for any urban or rural areas usually reveals rather strong differences in route density. Villages stand out with their denser pattern from the surrounding countryside: downtown urban areas (even in geometrically planned American cities) stand out by their denser street pattern from the more open network of the suburbs. The strongly concentric pattern of the road network density zones about the two city centres in the twin-cities area of Minneapolis/St Paul is an example (Figure 3.21; Borchert, 1961). At the regional level, a very thorough investigation of the distribution of road densities in Ghana and Nigeria has been made by Taaffe, Morrill and Gould (1963). The route density of each of Ghana's 30, and Nigeria's 50,sub-regions was measured for first and second class roads, and was related in the first instance to the population and Using a simple regression, population was found to the area of each unit. explain about 50 of the variation in road density in both Ghana and percent Nigeria. When area was included with population in a multiple regression the levels of explanation to 75 and 81 per cent respectively. Taaffe, Morrill rose and Gould went on to suggest four other less important variables that might help to account for the residual differences between the actual densities and the expected densities from the regression analysis. These four variables were hostile environment, (ii) rail/road competition; (iii) identified as: (i) intermediate location; and (iv) commercialization and relation to the development sequence.
basic geographical theme, was Hostile environment, a familiar and illustrated in Ghana by the very low route densities in the swampy lands of the Volta river district and where the Mampong escarpment sharply restricts the development of feeder routes. Railroad competition was found to be a more either that railroads would curtail the complex factor, in that one could argue need for roads by providing an alternative form of transport, or that railroads would stimulate road building by their gingering effects on production for inter-regional trade. The second argument appeared the stronger in Ghana and Nigeria.
Units with an intermediate location between two important high population areas were found to have densities well above those expected on the basis of population and area alone. Road density was positively associated with the degree of commercial activity, the more productive areas had a heavier road pattern than more backward areas. An anomaly noted from this pattern was the mining areas; these rely largely on rail movements and did not follow the resource development/road density relationship

(b) International level. The comparison of network densities between countries raises acute problems of differences in the operational definition of routes. Not only are definitional problems multiplied (for example, differences between single and multiple track railways, or farm roads and eight lane freeways, but similar information is recorded and classified in very different ways. Ginsburg has attempted to standardize these conflicting figures in his Atlas of economic development (1961) and his findings will be used here as a basis for argument. Two critical maps in the Ginsburg atlas are of railway density (Map XXIV) and road density (Map XXX) on a world scale. Both maps show density as length of route 100 km2, although there are a number of other and per equally valid ways of showing density (for example, in relation to population, or population and distance). For our purposes, the density per unit area provides the more basic variable in that it describes the actual existence on the ground of specialized routes whether those routes be intensively or lightly used. The basic characteristics of the world distribution pattern are shown in summary form in Table 3.1. Road density, an index compiled from a variety of sources and with rather unstandardized figures, gives a world of average around 10 kilometres/100 square kilometres or about ten times as great a density as that for railways. The gap between the maximum values and the means is, however, considerably greater for roads; Belgium, reported with the highest road density, had about thirty times as dense a network as the world mean, while Luxembourg with the highest railway network about was only twenty times as dense as the world mean. At the other end of the distribution one country (Greenland) is reported with zero road density, and 27 countries have no railways. The distribution is then a very skewed one (cf. Section 10 with a few countries with very dense networks and countries with very many sparse networks. Nearly two-thirds of the countries have densities below the world mean.

Transport networks are demonstrably part of the development infrastructure, and the distribution of countries with high and low densities may be reasonably linked to their general level of economic development. This hypothesis can be explored by adopting the economic-demographic development scale developed by Berry (1960) from the values in the Ginsburg atlas (Ginsburg, 1961, pp. 110-19). The scale is derived from 43 separate indices of economic development, and is a plot of countries on a demographic measure (the x-axis) against a measure of technology on the y-axis. Some 95 countries are distributed along this scale (Figure 3.22A) with highly developed countries on the upper left and poorer countries on the lower right. On this continuum, countries with high and low road and rail densities have been superimposed: the first ten countries with high densities are shown with large solid circles and the last ten countries with the lowest densities are shown by large open circles. The location of the United States on this continuum has been marked with an asterisk for reference. The road density pattern (Figure 3.224) shows a cluster of high ranking countries at the developed end of the spectrum. Nine of these ten are European countries; United Kingdom (1) West Germany (2), Belgium (3), France (4), Switzerland (5), Netherlands (6, Denmark (7), Poland (8), and Ireland (10). Only one other country, Hong Kong (11), lies outside this. Indeed the only highly developed countries in the study with relatively modest road densities are the United States, Canada, and Sweden. Railway density (Figure 3.22B) follows, in general, the same with European countries in leading positions. Seven of the countries recur with two eastern European countries, Czechoslovakia (21) and Hungary (22)
and the far eastern state of Taiwan (23), coming into the picture. The apparently anomalous positions of some far eastern states reflect (i) t relatively high ranking status that the railway density of a number of map southeast Asian countries like India and Burma developed under the railroad building British colonial administration and (ii) situations like that in Japan and Taiwan la former Japanese colony where transport was deliberately developed about the railroad net. At the other end of the spectrum, the position of low ranking countries is complicated by the absence from Berry's economic-demographic development scale of most of the very underdeveloped countries. Not enough data were available to place them accurately the scale, and the ten lowest on density countries are drawn only from the 95 countries on the continuum. Nevertheless, the pattern shown is an interesting one. In terms of railway density (Figure 3.22B), the low ranking countries cluster strikingly at the bottom of the development ladder. Six of the seven countries at this base are African states Sudan (25), Ethiopia (28), Libya (30), Liberia (20), Gambia (27), and French Equatorial Africa (26)], together with Afghanistan (29). More developed colonial countries with low-density railroad Surinam (14) nets are and British Guiana (15), both with excellent river transport. The only maj anomaly is Iceland (24). For road density (Figure 3.22A) the of the low pattern ranking countries is not so clear. Relatively developed countries with very Us.s.R. (9) large land areas and Brazil (12)], stand out as major anomalies. At the lower extreme, only Liberia represents the African cluster noted on the railway density map. Surinam and British Guiana here form the centre for cluster of non-African tropical states in the lower/middle of range development, with Costa Rica (13), Ecuador (16, Bolivia (18) from the Americas, and Iran (19) and British Borneo (17) from Asia. In general, the road density pattern is less easy to interpret and reflects in part the wide range in the definition of roads. The lack of correspondence between the lows on the two media suggests that railways have served as substitutes for roads; in other cases, like British Guiana, river and coastal shipping has served as a substitute for both.