Land-Use Dynamics in Transport-Impacted Urban Fabric: A Case Study of Martin–Vr ú tky, Slovakia

: The paper evaluates landscape development, land-use changes, and transport infrastructure variations in the city of Martin and the town of Vr ú tky, Slovakia, over the past 70 years. It focuses on analyses of the landscape structures characterizing the study area in several time periods (1949, 1970, 1993, 2003); the past conditions are then compared with the relevant current structure (2018). Special attention is paid to the evolution of the landscape elements forming the transport infrastructure. The development and progressive changes in tra ﬃ c intensities are presented in view of the resulting impact on the formation of the landscape structure. The research data conﬁrm the importance of transport as a force determining landscape changes, and they indicate that while railroad accessibility embodied a crucial factor up to the 1970s, the more recent decades were characterized by a gradual shift to road transport.


Introduction
The evolution of geoinformation systems and technologies and the gradual digitization of previously non-public or otherwise difficult-to-reach maps [1], together with the overall advancement in cultural landscape research, have yielded valuable information facilitating detailed monitoring and evaluation regarding historical landscape development. The latter two steps are among essential tools that allow us to solve topical problems of landscape ecology, mainly because through their informative value, they open new possibilities for historical ecology as well as the application of multiple current and potentially novel methodical approaches to enable relevant analyses [2]. Historical land cover and land use, for example, are mostly reconstructed by means of historical topographic maps combined with aerial images [3][4][5][6]. Considering a long-term perspective, namely one of about 200 years, a combination of various maps with different legends, scales, and mapping modes facilitates presenting the results of land-use development within several basic categories [7,8]. Maps generated within shorter time horizons allow us to investigate the progress in functional land use by exploiting detailed categorization of individual areas [9,10]. Another approach to the historical development of land-use/land cover Exploitation of mineral resources 13 Redevelopment 7 Intensification in agriculture 14 Agricultural land loss One of the partial processes forming industrialization and technologization is the landtake by transport infrastructure. This process represents the change of a landscape element into one from the category of transport-related objects and areas (from 661 to 666) between two mapping years, with the deduction of the original transportation areas that changed into other landscape elements. The derived indicator-the intensity of landtake by transport infrastructure-is defined as the ratio of landtake by transport infrastructure and the number of years in the respective period, so the unevenly long periods between the individual mapping years will be transformed into comparable numbers. Partial processes, such as the landtake by roads and freeways (change to landscape element code 661), can be also identified if necessary.
The sources that yielded the details on land use and landscape transformation further allowed us to outline the main transport networks. It was true, especially for the old topographic maps, since the aerial images cannot show the exact categorization of the identified elements to expressways, highways, or first-, second-, and, third-class roads, where first-class roads are intended mainly for long-distance and international transport, second-class road's major use is for traffic between regions, and third-class roads are used to interconnect municipalities or to connect them to other roads. The basic transport network infrastructure was then completed with the road traffic intensity data collected from the nationwide road traffic census held in the Slovak Republic-formerly a part of Czechoslovakia-from 1949 to 1950, every five years after 1980. The census covered all expressways, highways, first-and second-class roads, and selected portions of third-class roads. Currently, following the census of 2015, a novel methodology has been applied [63], including partial changes of interpretation, by which, for example, a tractor unit towing one or more semitrailers now counts as a single vehicle. The traffic intensity is presented in the form of the traffic-engineering characteristic called Annual Average Daily Traffic (AADT) [64], where the quantity is expressed as the number of vehicles per 24 hours on a given section of the road. The characteristic represents the average value for all days of the year, comprising also weekends or less dense traffic periods (such as wintertime). The individual survey years, as related to those of the landscape structure mapping cycles, are indicated in Table 2 below. If the future traffic intensities are to be estimated, the most common approach is to use growth factors. These factors are officially published by the authorities [65] and regularly updated after each national traffic census.  [70] For the purposes of the research, we cannot assume the total traffic volume within the study area, as the extent/length of surveyed roads differed between the years. Each of the censuses, however, comprised the first-and second-class roads. Their paths inside the study area varied through time due Land 2020, 9, 273 5 of 22 to modernization-induced rerouting and, most recently, the construction of a part of the D1 freeway (completed in 2015). However, the primary traffic flow directions were preserved.
The accessibility rates were computed via least-cost modeling with the use of the r.cost tool [71]. Least-cost modeling is based upon a GIS raster called a cost-surface. The values within a cost-surface are employed to represent the per unit distance cost associated with traversing different parts of a landscape [72]. The cost surface was the whole road network at the spatial resolution of 5 m. Each cell in the input cost-surface map will contain the category value five, which represents the cost of traversing that cell. The output map layer represents the accumulated traversal cost, calculated as the product of the cost and the distance (in our case, Chebyshev distance [73]) traversed. As a result, an insight into the development of the networks related to the accessibility distances was gained. Subsequently, we compared these distances with the development of three selected landscape elements (individual housing (611), collective housing (612), and industrial and technical buildings (651)), emphasizing changes in distances up to 500 m, the limit widely considered the best, and from 501 to 1000 m, the range assumed to be the acceptable walking distance. Regarding the more remote zones, the effect of the station(s) may rest predominantly in the necessity or possibility of using other means of transport (including, for example, municipal transport or bikes).
For each time period, analyses in ArcGIS 10.6 were performed to investigate the relationship between each polygon's accessibility to the railroad station. While around six to eight thousand landscape element polygons entered the analyses in the oldest periods, more than 14 thousand did so in the most recent one. Using the Zonal Statistics Tool, the statistical parameters for all types of landscape elements were obtained. Only those landscape elements that have the highest explanatory value for the relationship between the transport accessibility and the development of the urban fabric are presented in the results.

Study Area
The study area is located in the Martin county, within the Žilina administrative region, which occupies a substantial part of northern Slovakia ( Figure 1). The area itself comprises two major self-governing municipal units, namely, the city of Martin and the town of Vrútky. Between 1949 and 1990, the settlements formed a single city together. Currently, despite being independent of each other, Martin and Vrútky maintain close social and economic bonds within an urban agglomeration. Their total area amounts to 8604 ha (Martin: 6770 ha; Vrútky 1834 ha), and the population equaled 61,357 persons as of 31 December 2018 (Martin: 53,768; Vrútky: 7589).
Land 2020, 9, x FOR PEER REVIEW  5 of 23 however, comprised the first-and second-class roads. Their paths inside the study area varied through time due to modernization-induced rerouting and, most recently, the construction of a part of the D1 freeway (completed in 2015). However, the primary traffic flow directions were preserved. The accessibility rates were computed via least-cost modeling with the use of the r.cost tool [71]. Least-cost modeling is based upon a GIS raster called a cost-surface. The values within a cost-surface are employed to represent the per unit distance cost associated with traversing different parts of a landscape [72]. The cost surface was the whole road network at the spatial resolution of 5 m. Each cell in the input cost-surface map will contain the category value five, which represents the cost of traversing that cell. The output map layer represents the accumulated traversal cost, calculated as the product of the cost and the distance (in our case, Chebyshev distance [73]) traversed. As a result, an insight into the development of the networks related to the accessibility distances was gained. Subsequently, we compared these distances with the development of three selected landscape elements (individual housing (611), collective housing (612), and industrial and technical buildings (651)), emphasizing changes in distances up to 500 m, the limit widely considered the best , and from 501 to 1000 m, the range assumed to be the acceptable walking distance. Regarding the more remote zones, the effect of the station(s) may rest predominantly in the necessity or possibility of using other means of transport (including, for example, municipal transport or bikes).
For each time period, analyses in ArcGIS 10.6 were performed to investigate the relationship between each polygon's accessibility to the railroad station. While around six to eight thousand landscape element polygons entered the analyses in the oldest periods, more than 14 thousand did so in the most recent one. Using the Zonal Statistics Tool, the statistical parameters for all types of landscape elements were obtained. Only those landscape elements that have the highest explanatory value for the relationship between the transport accessibility and the development of the urban fabric are presented in the results.

Study Area
The study area is located in the Martin county, within the Žilina administrative region, which occupies a substantial part of northern Slovakia ( Figure 1). The area itself comprises two major self-governing municipal units, namely, the city of Martin and the town of Vrútky. Between 1949 and 1990, the settlements formed a single city together. Currently, despite being independent of each other, Martin and Vrútky maintain close social and economic bonds within an urban agglomeration.   The study area is a part of the Turčianská Kotlina Basin, whose western border is formed by the Malá Fatra mountain range, which constitutes a certain transportation barrier ( Figure 2). Two rivers, the Váh and the Turiec flow through the basin and both were previously regulated. The weather is characterized by frequent atmospheric inversions leading to, among other issues, air pollution. The study area is a part of the Turčianská Kotlina Basin, whose western border is formed by the Malá Fatra mountain range, which constitutes a certain transportation barrier ( Figure 2). Two rivers, the Váh and the Turiec flow through the basin and both were previously regulated. The weather is characterized by frequent atmospheric inversions leading to, among other issues, air pollution.
The area was colonized in the Eneolithic period. During the second half of the 19th century, it grew into a hub of Slovak national politics and culture, thanks to the introduction of and connection to a railroad track (see below). Consequently, the population increased, and the two municipalities expanded rapidly. A further period of growth caused by industrial development followed the end of WWII.

Transportation Networks
The Y-shaped backbone transportation network within the area pursues orographically preconditioned lines that are simultaneously also defined by the Trans-European Transport (TEN-T) core network. The Váh valley conducts, in the west-to-east direction, the northern branch of the multimodal Rhine-Danube Corridor (the road and railroad components being the D1 freeway and the track Žilina-Košice-EU to Ukraine border, respectively). Concerning D1, construction work has been completed only on an isolated section between Dubná Skala and Turany (commissioned in 2015), including the access route forming the initial sector of the R3 expressway.
While the importance of the first-class road I/18, or more concretely, the portion that passes through Vrútky, decreased after the opening of the D1 section routed in parallel, the road transportation in Martin still relies on the individual branches of I/65. As the backbone network remains incomplete, most first-class roads in the Martin subregion are in an unsatisfactory condition due to being heavily overladen, carrying the burden of not only local but also transit traffic. Moreover, there are locations where the entire load has been routed via third-class or urban roads.
The planning and construction of railroads too were adjusted to respect the landscape patterns. In this context, 1871 and 1872 embodied the threshold years, marking the commissioning of the Žilina-Poprad line, a major subsection of the Košice-Bohumín railroad [74]. The track ran along the Váh valley to be joined-from the south, through the Turčianská Kotlina Basin-by the Hungarian northern railroad proceeding from Zvolen [75]. The lines met at the Vrútky station; and the route originating in Žilina to pass Vrútky and run towards Košice and Ukraine is significant even presently, having considerable importance for passenger transport and potential for long-distance freight hauling. The area comprises several sidings that interconnect the railroad network and various industrial plants or facilities, and it is served by the Priekopa stop situated between the Vrútky and Martin stations.
The air transport relies on the domestic, leisure aviation-oriented civil airport at Martin-Tomčany. The area was colonized in the Eneolithic period. During the second half of the 19th century, it grew into a hub of Slovak national politics and culture, thanks to the introduction of and connection to a railroad track (see below). Consequently, the population increased, and the two municipalities expanded rapidly. A further period of growth caused by industrial development followed the end of WWII.

Transportation Networks
The Y-shaped backbone transportation network within the area pursues orographically preconditioned lines that are simultaneously also defined by the Trans-European Transport (TEN-T) core network. The Váh valley conducts, in the west-to-east direction, the northern branch of the multimodal Rhine-Danube Corridor (the road and railroad components being the D1 freeway and the track Žilina-Košice-EU to Ukraine border, respectively). Concerning D1, construction work has been completed only on an isolated section between Dubná Skala and Turany (commissioned in 2015), including the access route forming the initial sector of the R3 expressway.
While the importance of the first-class road I/18, or more concretely, the portion that passes through Vrútky, decreased after the opening of the D1 section routed in parallel, the road transportation in Martin still relies on the individual branches of I/65. As the backbone network remains incomplete, most first-class roads in the Martin subregion are in an unsatisfactory condition due to being heavily overladen, carrying the burden of not only local but also transit traffic. Moreover, there are locations where the entire load has been routed via third-class or urban roads.
The planning and construction of railroads too were adjusted to respect the landscape patterns. In this context, 1871 and 1872 embodied the threshold years, marking the commissioning of the Žilina-Poprad line, a major subsection of the Košice-Bohumín railroad [74]. The track ran along the Váh valley to be joined-from the south, through the Turčianská Kotlina Basin-by the Hungarian northern railroad proceeding from Zvolen [75]. The lines met at the Vrútky station; and the route originating in Žilina to pass Vrútky and run towards Košice and Ukraine is significant even presently, having considerable importance for passenger transport and potential for long-distance freight hauling. The area comprises several sidings that interconnect the railroad network and various industrial plants or facilities, and it is served by the Priekopa stop situated between the Vrútky and Martin stations.
The air transport relies on the domestic, leisure aviation-oriented civil airport at Martin-Tomčany.

Landscape Structure
Although the entire study area of 8604 ha has experienced major landscape structure changes (see Table 3) since approximately 1950, the seven decades have been characterized by a predominance of landscape elements classified as trees and shrubs. Over time, the category has come to dominate, albeit by a relatively narrow margin, and it currently occupies more than half of the area. The second-largest share has been assigned to agricultural crops whose areal extent gradually shrank. The area of grass and herbaceous vegetation exceeded residential and built-up land; however, after 1993, the share has dropped markedly down to one-third of its original extent. Residential and built-up land, expectably, has expanded progressively to more than three times above the former proportion values. The two remaining classes have been represented only marginally, with none of them taking over 1% of the area. The landscape structure maps for the individual periods are presented in Appendix B, Figure A1. More details about the landscape structure development within the study area during the post-socialist decades can be found in research by Nozdrovická et al. [76].

Processes of Landscape Changes
Between 1949 and 2018, in the course of the evaluated period (69 years), a mere 59% of the examined area remained unchanged. A significant portion of the landscape (41%) was altered through human activity, with urbanization and industrialization-related processes affecting approximately 8% of the area (662 ha).
Urbanization proceeded at a constant intensity throughout the evaluated period, except from 2003 to 2018, when the process virtually came to a standstill (Table 4). In Central Europe, the post-2000 trends markedly favored suburbanization not only in large cities, which had experienced the process already in the mid-1990s [77][78][79] but also mid-sized settlements [80,81] such as the Martin-Vrútky conurbation. The discussed tendencies found almost no response within the study area as this encompasses only the source city and town, and settlements where built-up land could be expected to expand, by virtue of suburban processes, are located outside the area's limits. The opposite trend, deurbanization, remained comparatively steady except for the last of the monitored periods and was induced especially by urban sanitation. Industrialization and technologization manifested themselves in full, even dominantly, during the oldest stages of the examined time interval; in the more recent decades, the process gradually lost its initial strength. The marked expansion of industrial estates and transport infrastructure is associated with the 1950s and 1960s, correspondingly to the state-orchestrated industrialization of Slovakia, which yielded major heavy industry enterprises.

Transportation-Related Landscape Elements
Details on the evolution of the areal extent of landscape elements associated with transportation, including roads, buildings, and facilities during the individual periods of interest are summarized in Table 5. Already in 1949, the largest part of the land dedicated to transportation in Martin and Vrútky was occupied by roads (661) while railroad tracks (663) covered approximately half of the area taken by roads. Within the following decades, the areal extent of road transportation expanded rapidly, subsuming roads as well as static transport facilities (such as parking lots or multi-story car parks). The growth of railroad-occupied areas was significantly less steep, and after 1993 we can clearly recognize the onset of stagnation. The rising importance of road transportation was confirmed by its increasing share in the overall landtake of transport infrastructure: the appropriate indicator grew from 68.5% in 1949 to 84.3% in 2018. However, Figure 3 clearly shows visible deceleration after 1990.

Transportation-Related Landscape Elements
Details on the evolution of the areal extent of landscape elements associated with transportation, including roads, buildings, and facilities during the individual periods of interest are summarized in Table 5. Already in 1949, the largest part of the land dedicated to transportation in Martin and Vrútky was occupied by roads (661) while railroad tracks (663) covered approximately half of the area taken by roads. Within the following decades, the areal extent of road transportation expanded rapidly, subsuming roads as well as static transport facilities (such as parking lots or multi-story car parks). The growth of railroad-occupied areas was significantly less steep, and after 1993 we can clearly recognize the onset of stagnation. The rising importance of road transportation was confirmed by its increasing share in the overall landtake of transport infrastructure: the appropriate indicator grew from 68.5% in 1949 to 84.3% in 2018. However, Figure 3 clearly shows visible deceleration after 1990. When comparing the landtake intensity indicator (Figure 4) in each monitored interval, the total areal expansion in transport-related buildings and facilities progressed at approximately 4 ha a year, except for the last span, when the pace increased by only about one quarter. In terms of the landscape elements, the most dynamic landtaking category was that of roads (outside 1993/2003), where rapid growth in the static transportation areas can be observed.

Road Network Evolution and Traffic Intensity
Figures 5a to 5e display a gradual growth in traffic intensities on the major road network during the examined time periods. The highest intensity rates are invariably reached in first-class roads, or more concretely, their transit segments passing through both settlements. Such a scenario is due to the roads functioning dually as local and transit paths. Typical of the post-1990 situation, the intensities increased rapidly, especially on I/18, which substitutes for the incomplete segment of the trans-European multimodal corridor. The lack of a state-of-the-art backbone network in the study area thus requires the existing urban roads to accommodate and manage the most substantial portion of traffic, exacerbating the risk of serious population exposure.

Road Network Evolution and Traffic Intensity
Figure 5a-e display a gradual growth in traffic intensities on the major road network during the examined time periods. The highest intensity rates are invariably reached in first-class roads, or more concretely, their transit segments passing through both settlements. Such a scenario is due to the roads functioning dually as local and transit paths. Typical of the post-1990 situation, the intensities increased rapidly, especially on I/18, which substitutes for the incomplete segment of the trans-European multimodal corridor. The lack of a state-of-the-art backbone network in the study area thus requires the existing urban roads to accommodate and manage the most substantial portion of traffic, exacerbating the risk of serious population exposure.
Moreover, relevant road transport growth predictions propose a further rise in the intensities; I/65 and I/18 can then be theoretically expected to carry, before the year 2040, up to 33.2 and 39.4 thousand vehicles a day, respectively. Such an increase is far beyond the technical and structural capabilities of the regional road network, meaning that this traffic could not be effectively managed.
These adverse prospects appear to be eliminable through two steps, these being the construction of appropriate segments of the R3 expressway, conceived to form the north-to-south transportation backbone passing through the Turčianská Kotlina Basin on to the town of Zvolen and the Hungarian capital of Budapest, and the completion of further sections of the D1 freeway. At present, construction work has begun on the D1 segment between Lietavská Lúčka and Dubná Skala. For technical reasons, this portion of the freeway will nevertheless not be put in service before 2023.

Railroad Transport as a Localizing Factor in Selected Landscape Elements
The last of the analyses was designed to verify whether good accessibility of a railroad station or stop embodies a significant localizing factor in the distribution and eventual placement of individual or collective housing and industrial facilities.
At the respective stages of the research, we revealed a significant concentration of individual housing within 1500 m during the first monitored period (see Table 6). In close vicinity of the stations (up to 500 m), the areas occupied by individual housing were progressively modified to suit other forms of use, including, but not limited to, community services. Currently, individual housing has mostly shifted to the range of 1501-2000 m (Figure 6a-e). This type of area expanded significantly between 2003 and 2018, in the ranges of 2001-2500 m and 2501-3000 m. In the Martin-Vrútky conurbation, the walking distance to the closest station was the decisive developmental localizing measure only from 1949 to 1970; in the more recent decades, this factor began to be substituted by the increasingly more favored private vehicles or municipal transport. In terms of collective housing, the study area exhibits noticeable construction rates mainly between 1970 and 1993 (Table 7), with the largest areas concentrated at 1001-1500 m and 2001-2500 m from the railroad stations; such distances are already very near the limits of effective walkability and may necessitate the use of public transport (Figure 6a-e). Through the years, apartment blocks were built also in the immediate surroundings of the stations, but the intensity of the process never matched the pace characterizing the construction activities within the farther ranges. Compared to the areas in individual housing and community services, the indicators in collective housing adjacent to the stations thus, cannot be interpreted as showing high advancement potential in the given category.  In the category of individual housing (611), the median gradually increased since 1949 (Table 9), pointing to the gradual growth of the city and the possibility of building houses on the edge of a  The study area's industrial and technical facilities were originally centralized in close proximity to the railroad stations (Table 8) (Figure 6a-e). Viewed through the lens of spatial arrangement, many such facilities are comparatively well accessible from the stations, both on foot and by municipal transport. A significant portion of the areas, however, are subsumed also within other ranges (both closer and more remote), including, above all, those of 501-1000 m and 3001-3500 m. Concerning freight transport availability, a notable aspect, for large industrial premises in particular, has been embodied in autonomous connection to the nearest station via railroad sidings. Towards the beginning of the 1970s, collective housing in the conurbation had started to exhibit rapid growth, predominantly in the ranges 1001-1500 m and 2001-2500 m ( Table 7); upon evaluation, this trend indicates the rising importance of road transport as compared to railroads. Even more pronounced was the increase in industrial and technical facilities, where the relevant process manifested itself especially in the range 1001-1500 m ( Table 8); at this stage, the proximity of a branch railroad track still constituted an advantage. In the same period, the new industrial premises that had begun to be developed on the outskirts of the city, usually further than 3 km from the train stations, already relied on trucks, and the employees commuted via public transport and/or passenger cars. As for individual housing, the areas increased only slightly, and the rise occurred within the range of 500 to 2500 m ( Table 6). The more remote housing sites gradually disappeared, and the range above 5000 m lost almost all of the residential buildings; the secluded mountain homes were abandoned altogether with the demise of traditional mountain farming. The count of utility and other houses adjacent to the railroad stations dropped markedly, reducing the area dedicated to urban amenities.
Between 1970 and 1993, individual housing coverage decreased somewhat in the ranges extending from 0 to 1500 m but rose within the ranges delimited by 1500 and 4000 m ( Table 6), meaning that the built-up pattern turned less compact. Such a tendency can be ascribed to urban sanitation, which eliminated old and/or dilapidated buildings in the city center. The vacant lots in the vicinity of the railroad stations were then used to develop, for instance, collective housing, industrial facilities, community services, and traffic areas. Over the whole study area, the collective housing construction rate increased almost threefold (Table 7), with strong dynamics especially in the range of 1000-2500 m. The discussed time-span involved a marked growth in the areal extent of industrial and technical premises, both in the vicinity of the train stations (up to the walkable distance of 1000 m) and at the more remote localities.
In 1993, the pace of transformation affecting the three monitored categories generally decelerated. Individual housing went through a minor rise, mainly in the ranges of 1001-1500 m and 2501-3000 m from the stations (Table 6), these ranges embodying the zones of potential development beyond walkable reach. Collective housing construction, however, stopped almost completely. The conurbation's industrial and technical areas experienced steady growth, particularly in the ranges of 2501-3000 m and 1001-2000 m ( Table 8). The transport connectivity of these industrial parks materializes mainly via passenger cars and trucks.
Between 2003 and 2018, the housing trends duplicated the characteristics of the previous period. While the individual housing exhibited a tendency to grow, collective housing projects came to a virtual standstill. Again, individual housing progressed further predominantly in the ranges defined by the limits of 1501 and 3500 m (Table 6), which embrace, in particular, the city's (or town's) suburbs and denote the necessity to use means of private and municipal transport. The areal extent of the industrial premises in some of the ranges was slightly reduced (Table 8), mainly due to the revitalization of some of the brownfields in the ranges of 0-500 m and 1501-2000 m. Conversely, the industrial and technical areas increased within the range of 2001-2500 m, resulting from suburban building schemes centered on delivering greenfield industrial parks.
In the category of individual housing (611), the median gradually increased since 1949 (Table 9), pointing to the gradual growth of the city and the possibility of building houses on the edge of a growing settlement, from which the distance separating the railroad stations rose progressively. The standard deviation was the highest in the first reference period, meaning a relatively large dispersion between the different objects in terms of railroad availability. In the collective housing category (612), the standard deviation was significantly lower in all of the periods. Sites with apartment buildings are more concentrated in certain parts of the city; however, there is also a trend towards significant increase in the median of accessibility of the railroad stations, especially until 1993. In the later period, the intensity of collective housing construction already decreased considerably. This is related to the support of the construction of collective housing in the period of socialism and later to the achievement of certain buildability limits in the area around the city center. The median availability of railroad stations increased also within the category of industrial and technical building (651), and between 1949 and 1970 there was even a jump (Table 9). In the last period, both the median and the standard deviation values for the availability of railroad stations are close to the values for individual housing. The newly built industrial and technical building is therefore already harder to access from railroad stations. Table 9. Statistical analysis of the accessibility of selected landscape elements from railroad stations (in meters). By evaluating the accessibility, we exposed the formerly pivotal role of railroad transportation in localizing residential housing projects and large industrial premises into the city and town centers; this scenario characterizes the years 1949 and (partially) 1970. In the more recent decades, however, the expanding motorization process, which arose and gained momentum in the 1960s, allowed residential, industrial, and utility grounds to spread farther from the train stations, as was also necessary due to the more densely built-up central sectors of the settlements. The above mentioned Land 2020, 9, 273 15 of 22 progressive evolution corresponds to the conclusions proposed in the paper by Antrop [82] and the metastudy by Kasraian et al. [83].

Conclusions
The paper was designed to identify and characterize the interaction of landscape structure changes and transportation systems that occurred or were adopted in the city and town of Martin and Vrútky, respectively, after 1949. The two urban units, located close together, are administratively independent of each other but share infrastructures and maintain strong social and economic bonds. Previously, the settlements were joined to form the Martin-Vrútky conurbation, and, later, Vrútky became a city district of Martin. The area is generally diversified, offering a wide variety of natural elements and landscape uses. To a great extent, the landscape structure evolution reflects significant historical events and driving forces that exerted an impact on landscape utilization in Slovakia following the mid-20th century. The political system installed in 1948 markedly influenced the development of the agricultural land in that the state had become the exclusive landowner, with private land ownership abolished [84]; analogically, ideology-induced transformations widely affected also the urbanization and industrialization of Slovakia. The results of the research confirmed transportation and the relevant infrastructure as a major factor of importance for long-term landscape changes in the monitored zones.
The highest traffic intensity rates determined through the series of censuses denote a gradual traffic increase; interestingly, the indicators grew ten-to twentyfold throughout the overall period, especially on the backbone routes substituting for the presently incomplete European multimodal corridor. However, the actual traffic intensity growth cannot be directly related to the expansion of the residential and utility built-up land within the area. To facilitate such a purpose, it would be necessary to know the details of both the traffic flow as regards its internal, external, and transit components and the variation in the behavior of road users. The data are obtainable exclusively via travel behavior surveys [85], direction and target questionnaires, and exact traffic models [86]. These specialized surveys and instruments, unlike common nationwide censuses to determine traffic intensities, are not conducted or applied regularly, being financially challenging and technically demanding if employed over large areas. Consequently, appropriate information on the past periods is unavailable as well.
By evaluating the accessibility of the railroad stations, we exposed the formerly pivotal role of railroad transportation in localizing individual housing and large industrial premises into the city and town centers; this scenario characterizes the years 1949 and (partially) 1970. The median availability of the railroad stations for collective housing increased significantly in 1970, with the growth completed in 1993 and remaining stable since then. The median availability of the railroad stations to the industrial and technical buildings rose markedly between 1949 and 1970; since the latter year, however, the newly built enterprises were harder to access from the railroad stations. In the more recent decades, the expanding motorization process, which formed and gained momentum in the 1960s, allowed residential, industrial, and utility grounds to spread farther from the train stations, as was also necessary due to the more densely built-up central sectors of the settlements.
The results of the relationships and links between transport accessibility, the development of transport infrastructure, and landscape elements can be important in urban spatial planning and strategic planning of city development. Acknowledgments: The authors would like to thank the anonymous reviewers who have made a significant contribution to the quality of the paper.

Conflicts of Interest:
The authors declare no conflict of interest.