Changes to the Transport Behaviour of Inhabitants of a Large City Due the Pandemic
1. Introduction
On 11 March 2020, the WHO classified the COVID-19 outbreak as a global pandemic [1]. In consequence, many countries took steps to prevent the importation and subsequent local transmission of the SARS-CoV-2 virus [2], resulting in restrictions on economic activity, transport, travel, and daily mobility [3,4,5,6]. Severe restrictions, including stay-at-home policies, remote operation of schools, public institutions, and workplaces, cancellations of mass events and public gatherings, and passenger limits on public transport, affected approximately 90% of the global population, contributing to an overall reduction in mobility on an unprecedented scale [7,8]. The introduction of non-pharmaceutical icountermeasures to reduce the spread of the coronavirus affected population mobility, especially regularly-taken journeys [4,9,10]. During the initial period of the first pandemic wave in Europe, passenger traffic fell by as much as 90% [7]. The highest drop was recorded for public transport, with demand “evaporating” and transport operators reducing services [11]. This was due to the fact that public transport was perceived as far less safe than it had been before the pandemic [12], due to the possible high risk of virus transmission on buses, trams, trains, and underground [13]. As proven by Przybyłowski et al. [4], the pandemic had a huge impact on changes in mobility patterns, with the popularity of shared means of mobility declining in favour of private modes of transport. Pandemic-related changes in the modal split were also recognised by De Haas et al. [14], Beck and Hensher [15], and Jenelius and Cebecauer [11], whose analyses revealed that there was an increase in the use of cars and non-motorised modes of transport (cycling, walking) at the expense of public transport, which was particularly noticeable when considering daily mobility.
Although the COVID-19 pandemic and its impact on daily mobility have been widely addressed in the literature [16,17], there are limited studies that indicate to what extent the changes in mobility have become permanent. Hence, the purpose of this study was to determine the nature and scale of the impact of the pandemic on the local transport system of a large city in Poland (Łódź) and, above all, to identify the constancy of this impact. The constancy of the temporal changes in travel behaviour caused by the coronavirus [18,19] is relevant when we consider the goal of implementing guidelines for sustainable urban transport. Another aspect for key stakeholders in the transport sector is a transport policy that addresses inefficiencies in controlling transport demand and supply [20].
A global pandemic with such far-reaching consequences on people’s lives is a rare occurrence [21]. This—together with the fact that researchers have had the opportunity to employ state-of-the-art information technology [22] (e.g., intelligent transport systems data) [23] for the first time to observe the effects of the global pandemic, and the measures taken on transport—means the research conducted can be considered innovative. We not only utilised data obtained from ITS in our research, but also from the surveys we conducted. This was to understand not only changes in the number of vehicles on the road network, but also the reasons for these changes and their characteristics in relation to motivation, frequencies, and journey length. Overall, it appears that post-pandemic mobility varies dependent on region. Whether the changes in travel patterns that have occurred due to the pandemic will continue post-pandemic warrants further investigation.
The research is also substantiated by the period over which the threat occurred (here: nearly four years), which enables the researchers to examine the changes when compared to periods of “normal” conditions. It is equally important, however, to determine whether the changes in the transport behaviour of the population (at least on a local scale) are likely to end with the cessation of the threat, or whether they are permanent enough that a substantial alteration to the public transport services provided is necessary. The results yield a broad diagnostic base, enabling the authors to provide a number of recommendations, including management of sustainable urban mobility. The relevance of the results presented herein for the development of social sciences, socio-economic geography, and spatial economics must not be underestimated either, as there will surely be other events in the future that will threaten people’s health and lives, thus affecting transport behaviour. The results of this study, therefore, can contribute to a better understanding of changes in the transport behaviour of the population under health-affecting and life-threatening circumstances. An innovative approach to such a defined research problem may result from: an innovative context (constant relevance of the problem), interdisciplinarity (research conducted at the interface of several scientific disciplines), the use of new research methods (e.g., big data analysis), a long-term perspective of the application of the obtained results (in the event of any factors limiting mobility), adaptability (the study takes into account the adaptability of the transport system), and potential practical implications.
2. The Impact of the Pandemic on Urban Transport Behaviour and Mobility
Transport mobility is an activity undertaken by residents to meet their transport needs [24,25]. Analysis of the transport behaviour of residents in cities has been the subject of a number of academic studies, where the authors have primarily attempted to identify its contributing factors [26,27,28,29,30]. The spatial-temporal data that predicts population movement is gaining increasing attention among researchers [31].
A new train of thought in this regard emerged in 2019, when the COVID-19 outbreak caused a huge change in the behaviour and mobility of citizens across the globe [3,32]. This change mainly stemmed from the strict measures taken by governments to ensure people remained isolated and kept social distance. In addition to these restrictions, changes in mobility were compounded by fear of contracting the virus or infecting others when travelling and sharing common space. Even though the combined safety measures and restrictions that were adopted in different countries varied, thus affecting people’s lives in slightly different ways, they still produced similar changes in behaviour [11,14,33,34,35,36,37]. Severe restrictions, including stay-at-home policies, the remote operation of schools, public institutions, and workplaces, cancellations of mass events and public gatherings, and passenger limits on public transport, affected approximately 90% of the global population, contributing to an overall reduction in mobility on an unprecedented scale [7,8]. Commuting rates fell, and public transport operators sharply decreased their frequency/routes [11]. There was also an increase in the use of cars and non-motorised modes of transport, i.e., cycling, at the expense of public transport, especially for daily mobility, including shopping trips [14,15], with the increase in online grocery shopping certainly being of particular impact [6]. The largest decrease in the number of trips taken was for those related to leisure [38].
Research from the early stages of the pandemic shows significant differences in psychosocial health between countries. It is well known that younger age groups had greater problems with mental health, loneliness and, therefore, quality of life than older age groups. Other features that affected the deterioration of psychosocial health during this period were: gender, marital status, level of education, status on the job market, and geographical factors (whether a person resides in a rural or urban setting) [39]. Research carried out over a similar period in Italy shows the fear of illness during the pandemic fully mediates the relationship between negative affect and spiritual well-being and flourishing; moreover, this fear partially mediates the relationship between negative affect and post-traumatic stress disorder (PTSD) symptoms [40]. Psychosocial well-being was also studied among parents and children, and the results of this research testify, inter alia, to the fact that pandemics can have serious psychosocial consequences for parents of children, with this population having experienced more psychosocial problems than adults without children [41]. It is difficult to clearly assess to what extent psychosocial changes in the face of the pandemic have influenced, and will influence, the mobility of residents. This depends on many variables, including the effectiveness of plans to mitigate the psychosocial consequences of COVID-19 [42]. However, the pandemic seems to have left its mark on the use of public transport. Yap et al. [43] showed the increasing role of crowding in public transport and its impact on the assessment of its functioning.
A number of studies have clearly shown that there was a markedly lower propensity to travel during the pandemic, which affected public transport in particular [44]. The restrictions and fear of contracting the virus on mass transit meant people more frequently opted to use their own car for regular journeys [45], while the modal share of cycling also increased [34]. The reduced access to public transport particularly affected people with disabilities, however [46]. Trips taken to access public amenities or reach commercial facilities were significantly reduced [47], as were commuting to work and school [15,48], trips to visit friends and family, or to go to church or seek medical advice [49,50,51]. The results of studies on mobility conducted in a number of countries explicitly indicated correlations between the restrictions imposed and changes in transport behaviour during the COVID-19 pandemic. These restrictions on mobility did, however, lead to a significant drop in the number of new cases [2,52,53,54]. Studies that have addressed the issue of how changes in spatial mobility affected the spread of the COVID-19 pandemic [55] have also shown that public transport was a key factor in the spread of the pandemic. Researchers also investigated how the pandemic and the accompanying nationwide and local restrictions reduced demand for public transport, thereby limiting mobility in cities [56,57].
The analysis of the comprehensive review of the literature on the COVID-19 pandemic performed by Shortall et al. [58] reveals the need for research on the permanence of its social and economic effects. Therefore, the authors of the research presented herein address the question of which transport behaviour that emerged during the pandemic has been perpetuated. The analyses and results presented both aim to identify the changes in the transport behaviour of the population during the pandemic (their nature and the magnitude of impact on the local transport system) in a selected large city in Poland (Łódź), and to determine the permanence of these changes, which is vital for planning technical infrastructure and managing the various modes of transport. This approach was intended to gauge whether the post-pandemic reality had permanently changed transport behaviour (as indicated by observations related to the limitation of mobility and changes in the means of transport used for its implementation), or whether the pandemic period was a temporary influence on the functioning of the transport system, before returning to the state observed before the pandemic.
During (and also after) the pandemic, a drop in demand for public transport was inevitable due to the associated high risk of infection. In addition, the impact on mobility that the pandemic had has further increased the need for new transport policies [59]. It is particularly important in urban areas to deliver transport solutions that meet the changing needs of the population. As each city has different endogenous conditions, it is worth conducting research on different locations so that any recommendations and conclusions will not only reflect this diversity but also show common features. Many potential passengers who curtailed or eschewed public transport altogether during and after the pandemic declare that they would consider returning to its regular use if it met certain requirements. These include, first and foremost, that public transport be integrated with other forms of mobility and, secondly, that the policy on fares is fair. The pandemic caused a significant drop in the use of public transport in all Polish cities, but the magnitude of this decline varied, depending, inter alia, on ticket costs (when fares are higher, the propensity to avoid public transport also increases). The appeal of the public transport option is also affected by the ease of purchasing tickets and the range of tickets offered. In the age of online and digital communication technologies (whose popularity increased even further during the pandemic), there has been a noticeable rise in demand for such solutions as e-ticketing and ticket vending machines. Another factor that contributed to the drop in the popularity of public transport was remote learning and working, both imposed during the pandemic. The latter in particular has proven (at least in some industries and sectors) to be not only as efficient as the previous form of work organisation, but also considerably cheaper. It is therefore estimated that despite the cessation of the pandemic, this factor could still see an ongoing reduction in trips taken by public transport of as much as 20% [60].
Research on the post-pandemic reality indicates the effect of the pandemic on modal choice. Bouhouras et al. [61] showed that residents of urban areas were more willing to change the means of transport used for their journeys (to a bike sharing system) during the pandemic. Their study showed that after the pandemic ended, the role of these means of transport in the post-pandemic reality had strengthened compared to pre-pandemic observations. Similarly, research using the Sankey diagram showed that modality profiles have been transformed due to the pandemic, and that a number of these changes will remain post-pandemic [62,63]. However, this study did not show the whole picture of residents’ modality profiles, as it concerned trips unrelated to commuting to the main city.
3. Description of the Research Areas
The study was conducted in Łódź, a large Central European city with a population of over 658,000 [64]. It is difficult to conclusively indicate how the number of trips made within the Łódź transport system has changed in recent years, or to present the changes that have occurred in the modal split of these trips in the last few decades, as research in this regard was performed sporadically by the city administration in 1995 [65] and 2013 [66]. However, this study has recently been conducted more systematically by a local research centre (Łódź University). Earlier studies revealed that the average daily number of trips made by the average resident of Łódź increased from 2.13 in the mid-1990s to 2.4 in 2013. However, subsequent studies from late 2021 have shown a significant decrease in daily mobility (to below 1.4 trips per day on weekdays) [63], which has been attributed to the effects of the pandemic [63,67].
On weekdays, daily mobility in Łódź is dominated by obligatory motivations (slightly over 50% of all trips are to commute to school or work) [63], which is in line with the situation in other Polish cities [68], whereas optional trips on weekdays were mainly made to retail facilities (26.2%), to visit friends and family (5.3%), and for recreational purposes (4.1%).
With regard to the modal split of regularly-taken trips, clear changes have been observed, i.e., an increasing switch from public transport in favour of private cars (Table 1), which is mainly due to a rise in car ownership and changes to the family model. Since Łódź is the most congested Polish city (according to the Tom Tom Traffic Index [69]), the increase in the share of passenger cars in the modal split may only deepen this unfavourable condition. That is why it is so important to conduct research that could help those responsible for transport policy take action to improve this situation [63].
The aforesaid functional parameters (modal shift, mobility levels, etc.) of the urban transport system in Łódź are long-established. However, they have been undergoing significant transformations over the last ten years. The transport system of Łódź is concentric in nature, partially delimited by the ring road of motorways and expressways running primarily around the edge of the city or beyond its defined limits. This layout features a grid-like network, where the routing of public transport lines is determined by the existing infrastructure, whose shape depends on the mode of transport: concentric (tram lines), concentric with an emerging band-shaped layout (bus lines), and circular and peripheral (train lines).
4. Data and Methods
Typically, research on the spatial mobility of people is based on the use of one of the data sources used in this article [70,71]. Each of them on their own offers a considerable amount of information and can be perceived as a reliable and relatively comprehensive (with an awareness of their weaknesses) source of data. However, only when the analysis is carried out in two ways, specifically in parallel on complementary data (ITS and data from the questionnaire survey), is a synergistic value achieved. Each source has weaknesses that the other successfully complements. Thanks to ITS technologies, it is possible to obtain accurate data on road traffic, travel times, road capacity, etc. Questionnaires can complement this data by providing information about traveller preferences and behaviour. The ITS data and the results from the questionnaires enable the analysis of trends in the transport behaviour of the population, which is important for planning the development of transport infrastructure. The combination of ITS data and questionnaire results allows for a better understanding of the needs of road users and the adaptation of transport infrastructure to meet these demands. The information collected from ITS can be used for route planning and optimisation of the transport network. Questionnaires may reveal preferred travel routes and the factors that influence their choice. Data from ITS can be used for dynamic traffic management, which leads to increased efficiency of transport systems and a reduction in traffic congestion. Questionnaires can provide additional information about preferred travel times and travel purposes. Understanding the preferences and habits of road users allows for better adaptation of the transport on offer, including timetables, types of connections, and means of transport. By combining the ITS data and the information obtained from questionnaires, it is possible to identify the issues in the transport system and introduce appropriate solutions (Figure 1).
ITS data and questionnaire surveys on the spatial mobility of people can be used in various studies and projects related to transport planning, road traffic analysis, transport infrastructure management, and social research, including those phenomena not directly related to the transport system (e.g., changes in legislation or the impact of natural conditions). In this way, it is possible to analyse a very wide set of factors modifying the functioning of the transport system (marked in red in Figure 1). By examining the results of population spatial mobility questionnaires in combination with ITS data, it is possible to gauge the population’s attitude towards changes in the fare structure. ITS data can provide information on actual traffic patterns, such as traffic volumes at different times of the day, the busiest locations, and seasonal changes. Combined with survey results, how these traffic patterns correlate with traveller preferences and the reasons why people choose certain travel routes can be assessed. Data from questionnaire surveys can help identify those areas affected by insufficient transport accessibility for residents, e.g., areas where there is a lack of convenient transport links. ITS data can provide information on existing transport infrastructure and actual travel patterns, enabling the assessment of transport accessibility in various areas. Once transport investments have been made, such as changes to road infrastructure or the introduction of new transport services, both ITS data and survey results can be used to assess the effects of these interventions on population mobility, traffic congestion, travel times, and other indicators. Using ITS data and questionnaire survey results, it is possible to create forecasting models that help predict changes in population mobility behaviour in response to factors such as demographic changes, changes in transport policy, or the introduction of new transport technologies [72,73,74].
4.1. Data from Surveys
In order to determine the permanence of the impact that the pandemic had on the local transport system in Łódź, a survey was conducted using the CATI. This involved a representative sample of 500 adult residents (sample size was determined at a confidence equalling of 97%, with a maximum error of 5%). The research tool was a survey questionnaire consisting of two parts: respondent’s particulars and questions on daily mobility in autumn 2019 and autumn 2022, including the impact of the pandemic on possible changes in transport behaviour (Table 2). The period of autumn in 2019 was chosen as it was a time that people still remember that is not associated with the pandemic or Christmas. Autumn 2022 (post-pandemic period) was chosen for comparison of a similar period.
The research was performed in October 2022 by an external company (specialising in questionnaire research). The company endeavoured to ensure the sample selected for the study was representative. The survey was representative in terms of gender and age (Table 3). The population of Łódź is ageing rapidly due to demographic reasons. We are dealing here with ageing both from the base of the age pyramid and from its apex. This process is the most advanced among all voivodeship cities in Poland, which explains why it is so important to undertake research especially concerning older age groups.
The Wilcoxon test, which is a non-parametric alternative to the Student’s t-test, was employed to analyse the results of the questionnaire survey, as it enables one to compare population means that do not follow a normal distribution, which is impossible with the majority of parametric tests for equality of means within groups [75].
For data analysis, the authors have utilized Python along with the numpy (NumPy), pandas, and scipy modules (SciPy).
Questionnaire-based research on people’s transport behaviour has great potential. The questionnaire distributed by telephone made it possible to collect data from a relatively large and diverse group of respondents representing various socially, demographically and spatially diverse groups. Compared to other research methods, such as personal interviews or field observations, questionnaire research can be relatively cheap, especially when using remote tools (e.g., the telephone). Respondents are more likely to answer honestly when the survey is anonymous, which may lead to better data quality. Questionnaires also allow for the standardisation of questions and procedures, which facilitates the comparison of data between different groups and over different time periods (as seen in the case of this study). A questionnaire survey can be easily scaled, which means it can be carried out on a large scale over a short time period. Nevertheless, this method of obtaining information about spatial mobility has certain limitations. It can be difficult to obtain a high response rate, especially when the survey is long and requires considerable respondent involvement. There is also a risk of measurement errors related to the interpretation of questions by respondents or distortions resulting from imprecise answers. Certain social groups, such as older people, uneducated people, or people who did not consent to having their telephone numbers included in the research contractor’s databases, may be excluded from the study, which may introduce distortions in the results. However, in this study, measures were taken that eliminated the indicated imperfections [76].
4.2. Load on the Urban Road Network
The third main source of data on the transport behaviour of the population in Łódź (besides the results of the questionnaire survey and data on the number of tickets validated in public transport vehicles) are empirical measurements made by induction loops supporting the ITS system in Łódź [77]. The data was collected between 2016 and 2022, although this study employs only data from the years 2019–2022. This data boasts a range of attributes that allow it to be classified as a big data set [78], and it is applicable in both geographic and traffic engineering studies [79,80]. Due to changes in the way the data is archived (by the City of Łódź) and the properties of the detectors and the system built around them, it had to undergo a number of validation procedures to enable its application in the study [81].
The first stage, which is continuous and performed automatically by the Sydney Coordinated Adaptive Traffic System (SCATS), involves traffic monitoring based on measurements from detectors (induction loops). The system aggregates the number of vehicles recorded at 15-min intervals 24 h a day for each lane within the junctions covered by the system (the system was monitoring over 270 junctions at the time this paper was being prepared). The data is archived and can be exported as a tabular summary containing the measurements at 15-min intervals for each loop installed within a single junction (the database allows the export of a single file containing data on a given junction). The series of files retrieved from the archives must then be combined into a single, uniform database, which poses a major methodological challenge but is necessary for the inter-period comparability of the data. The procedure also involved the removal of measurement errors, both those detected directly by the system and those manifested by abnormal vehicle numbers recorded (e.g., the number of vehicles passing through a given junction within a 15-min time interval was greater than the reasonable lane capacity in free-flow traffic). As the traffic monitoring system underwent some changes (e.g., quantitative; the number of induction loop detectors increased from ca. 230 to 270 monitored junctions) over the years in question, the authors decided to limit the study area only to those junctions and detectors for which there were observations in each of the analysed periods in order to eliminate the effect of excessive accumulation of vehicles from measurements made by the increasing number of detectors. The final database contains information on the junction, lane, date, and time of measurements (in 15-min intervals).
This allowed the authors to analyse the temporal changeability of vehicle traffic flows on the urban road network. However, a weakness of the inference based on the data from inductive loops must be stated here. Namely, the vehicle numbers reported by the sensors do not reveal the magnitude of capacity overruns at junctions or the resulting traffic queues. As a result, the representation of traffic volumes at 15-min intervals on the road network only shows the proportion of traffic that passed through a junction in a given interval. In addition, the ITS data shows only the entire traffic volume with no breakdown into trip motivation, thus forcing the researcher to be cautious when drawing conclusions regarding the impact of the pandemic on traffic volumes related to commuting to work, school, retail facilities, etc. For each year in question (2019–2022), the average vehicle number recorded by the urban ITS in 15-min intervals for each day of the week was determined. In order to analyse the spatial dimension of the changes under study, the volume of the average daily traffic at the junctions covered by induction loops was “superimposed” (presented as a pie chart) on the map of the road network in the city.
4.3. Public Transport Provision and Its Uptake
The performance of public transport in Łódź was analysed to assess the quality and quantity of the service provided, the ticketing options available, and the degree to which these services were used in 2019–2022. Data on the temporal and spatial fluctuations in the number of tickets validated in public transport vehicles was provided by the transport organiser, the city council, represented by the road and transport management authority within the boundaries of the city [82]. The data on ticket validations, which provides information on date and time, vehicle identity card, and geographical location, has been structured as follows:
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the total number of ticket validations on all public transport vehicles at hourly intervals for the second week of October in each year between 2019 and 2022,
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the number of ticket validations per tram and bus for the second week of October in each year between 2019 and 2022,
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the number of ticket validations by passengers (either beginning a journey or continuing their journey by punching another ticket) registered by the system in the vicinity of a given tram or bus stop for the second week of October in each year between 2019 and 2022.
Measurements are taken automatically in each public transport vehicle and then sent to the system’s headquarters. In order to visualise the temporal and spatial changeability of how the urban public transport system is used, averaged data on the number of tickets validated was used for the adopted time intervals. Thematic maps showing the number of ticket validations by route for each tram and bus line were compiled using spatial concatenation. This allowed the aggregation of the number of ticket validations for those sections of the public transport network where there is reciprocal substitutability in service by the vehicles of the public transport operator.
Information on the temporal changes in the services provided by the transport operator was taken from the website of the city’s municipal transport body (The Municipal Transport Company in Łódź—MPK Łódź). Historical timetables for the indicated dates were obtained via their server. The number of trips taken by pairs of trams or buses (with each member of the pair travelling in the opposite direction) on a given day was then totalled using an additional division into pre-peak, peak, and post-peak periods (for working days).
When reviewing the results and drawing conclusions, one must remember that the data on which the study is based takes into account neither holders of period tickets (monthly, weekly, etc.) or single-line tickets, nor those entitled to travel for free (e.g., senior citizens). What is more, the data only indicates where and when a given user validated their ticket. Although it is reasonable to assume that they punched it at the beginning of the journey, this is obviously not the only possibility. The researcher is also unable to determine how long a given trip on a given ticket lasted, as the data does not indicate where and when the user got off (ended the trip) or transferred (changed vehicles and continued the trip). After all, a given passenger could have punched consecutive tickets in the course of a single journey [82]. In addition, there is no possibility to keep track of trips made by those passengers who did not punch a ticket even though they were obliged to do so. Despite the said limitations, the data employed is still the largest and most accurate dataset available to illustrate the nature of how public transport is actually used in Łódź.
The undoubted advantages of analyses conducted on the basis of ITS data include the fact that the ITS generates large amounts of data from a number of sources, such as road sensors, traffic monitoring systems, and navigation applications. This rich source of data allows for a more accurate understanding of movement and mobility. Thanks to the automation of the data collection process, ITS data is often more reliable and accurate than that collected using traditional methods. ITS data can also be collected and shared in real time, enabling quick analysis and rapid response to changes in road traffic. The availability of ITS data enables the integration of different data sources, which can lead to more comprehensive analyses and a better understanding of mobility. The limitations of this approach include the risk of system failure and data loss; ITS systems are susceptible to technical failures, which can lead to interruptions in data collection or inaccurate analysis results. The effectiveness of ITS data depends on the installed infrastructure, which, in cases of absence or insufficiency, may lead to the inability to collect comprehensive data. There is also a risk of manipulation of ITS data by the intentional actions of third parties, which may lead to false or distorted analysis results. Collecting large amounts of data can lead to privacy concerns, especially when it comes to tracking vehicle and user movements. This study implemented remedial actions that addressed the identified threats to the reliability and validity of these data.
6. Conclusions
The COVID-19 pandemic has undoubtedly impacted numerous facets of day-to-day life, particularly in terms of daily mobility patterns, and these may have long-lasting effects. Although the future remains uncertain, we can anticipate certain shifts in travel behaviour based on current trends and expectations. Understanding individuals’ travel patterns is necessary to promote changes to the modal split and increase the resilience of cities when faced by future emergencies and pandemics. The purpose of the study was to determine the nature and scale of the impact of the COVID-19 pandemic on the local transport system of a large city in Poland (Łódź) and, above all, to identify the permanence of this impact. The study employed both quantitative and qualitative data, which made it possible to determine not only whether vehicle numbers on the network had changed in the period under study, but also what had caused this change. This study provides new knowledge on the widely-addressed impact of the pandemic on various aspects of life by addressing the overlooked issue of how persistent these changes are. Not only did the pandemic change the frequency of spatial motivations, but it also affected trip durations and preferred modes of transport. According to respondents, the greatest pandemic-related changes were related to remote working. This was the only motivation for spatial behaviour where the frequency increased, while in all other cases a decrease was noted whenever it was necessary to travel or commute. As regards trip duration, this decreased for each motivation under study. The changes that were triggered to the greatest extent by the pandemic pertained to two motivations: tourism, and recreation/sport and hobbies. As for preferred modes of transport, there was a rise in the use of private transport at the expense of mass transit. The largest percentage change in the modal shift for the different trip motivations directly influenced by the pandemic applied to two motivations: working outside the home, and mobility related to entertainment and culture.
These results confirm that it has become noticeably more popular to work remotely. As for the other daily motivations, the respondents stated that they can also be pursued online, so there was less pressure to commute. For these motivations, however, the pace of change has not been that dynamic. As regards sustainable transport, the most adverse changes concern the growing popularity of the car in the modal split. To address the reluctance to use public transport, measures must be taken to improve the cleanliness of public transport vehicles, which could help to increase the use of mass transit for regularly-taken journeys. Future studies should address the reluctance of the general public to use mass transit and the actions that would encourage them to do so once again. If cities are to pursue sustainable mobility, knowledge of how permanent the pandemic-related changes in spatial mobility of the population are could facilitate the development of sustainable transport policies.
Research on population mobility was extremely important for transport organisers and decision-makers in organising public transport after the COVID-19 pandemic. For example, do more people prefer their own means of transport over public transport? Have preferences regarding travel times changed? It was possible to identify peak times and places where the demand for public transport was highest, allowing transport organisers to adapt timetables to the changing needs of passengers. Based on mobility data, vehicle capacity and frequency of trips could also be adjusted to actual demand. In the event of future crisis situations, more journeys can be planned during peak hours or on heavier routes. Mobility studies also helped identify the risk of COVID-19 infection and suggested appropriate preventative measures. Transport bodies could alter cleaning and disinfection procedures and introduce restrictions on the number of passengers in vehicles. The analysis helped promote alternative forms of travel, such as cycling, hiking, and carpooling. Thanks to this, it was possible to reduce the pressure on public transport during peak hours and minimize the risk of infection. The research also provided valuable information on travel patterns, which could be useful when planning new transport infrastructure or modifying existing ones.
This study on the lasting impact of changes in transport behaviour due to the COVID-19 pandemic contributes to the development of scientific achievements in the field of socio-economic geography on several levels. It contributes to understanding how changes in transport behaviour vary depending on the geographical space considered, e.g., a city or a district. This may include analysing differences between urban or suburban areas (with different daily mobility patterns), areas with different levels of population density, or areas with different levels of socio-economic development. The study helps identify changes in population patterns, prime business locations, and infrastructure development in the context of the pandemic. The study also gauges how changes in transport behaviour have affected accessibility to services, jobs, education, and important destinations. This may lead to a better understanding of inequalities in transport accessibility for different social groups and regions. Based on the collected data, models for predicting spatial behaviour in the context of crisis situations can be developed. The study helps identify areas of the economy most exposed to the effects of changes in transport behaviour and suggest best responses.
Potential limitations of the study presented include: the study may capture changes that may not be representative of long-term trends; residents may be more inclined to exaggerate or minimize changes due to concerns or expectations; different social groups may have different experiences and reactions to changes in communication behavior, which may make it difficult to obtain a representative cross-section of the population; the period of the pandemic may make it difficult to compare current communication behavior with that from previous years, which may limit the ability to assess changes; and the pandemic may have had differential impacts on different aspects of travel behavior, depending on the specific urban environment, infrastructure, culture and other local factors, which may limit the geographical universality of inferences.
