Bibliometric analysis of sharing economy logistics and crowd logistics

3.1 The structure of the literature on sharing economy logistics and crowd logistics

3.2 Linguistic analysis to identify sharing economy logistics and crowd logistics trends

We used Alceste software to analyze the words in titles, keywords and abstracts for the 85 articles. “The co-occurrence of words indicator examines the frequency with which two given words (‘co-words) in a particular field are used together. For each word, its co-occurrence with another word is analysed, along with its frequency” (Okubo, 1997, p. 30). The frequency of word associations is used to construct word clouds representing the major themes in the field under study and the relationships among them.

Alceste software allows a series of linguistic analyses (of titles, keywords and abstracts). First, it allows detailed analysis of the vocabulary in a corpus, to construct a dictionary of the words, their roots and their frequency. We obtained 17,690 forms, including 3,266 words, which represent a rich vocabulary of 87% of unique words. Second, successive fractionation splits the text up into homogeneous segments containing a certain number of reduced words forms (e.g. shar* = share, sharing, shared…). Third, we conducted a hierarchical classification of these segments, based on locating the strongest oppositions (in our case, words with at least 50 occurrences – Figure 2). The results of the analyses were sorted according to relevance, and several graphic representations (word cloud, DHC) were constructed. The size of the words in the word cloud is proportional to the number of their occurrences (greater frequency means larger font size). The word sets are based on colours of the words and constitute a first step towards a publications classification.

This representation shows the links between sharing economy logistics and platform-based collaborative consumption. The sharing economy logistics business model centres on delivery services that include crowd logistics and support sustainability.

Because it is not possible to represent all of the data in a unique multidimensional word cloud, Alceste software proposes a variety of methods based on multidimensional analysis techniques, including DHC. DHC involves successive fractionations of the text and representative extracts, based on appearance in text segments of the same terms. Each homogeneous thematic class is examined on the basis of a “profile”. For each profile, Alceste identifies a list of the most significant words and sentences. By calculating the χ², we can determine strong or weak belonging of a word to a class: the χ² highlights the most relevant terms for a given class and the most influential references per cluster (Figure 3). This method allows extraction of clusters of meaning, based on the most significant words and sentences that represent the dominant ideas and themes in the corpus. It identifies the main trends in sharing economy logistics and crowd logistics.

The three clusters discussed above encompass the main topics and dimensions revealed as decisive for an understanding of sharing economy logistics and crowd logistics. Analysis of these three thematic classes relies on a specific vocabulary:

1. Cluster 1 (red – 27%) refers to optimal allocations of costs, prices, distribution and supplier relationships. This is a multidisciplinary theme in terms of publication media and extends over more than ten years. The main, but not the only, authors and articles with significant representation in the cluster are: Karabati and Saym (2008), Wallenburg (2009), Chen et al. (2014), Beliën et al. (2017), Guiliang et al. (2017), Kong et al. (2018) and Gan et al. (2018). The starting point of this research was supply chain informational coordination incorporating buyers’ expectations within a sharing economy. Proactive enhancement of the links to logistics service providers would seem to be a driver of urban customer loyalty in the sharing economy. Over time, the central theme has become optimization of trajectory-aware coordinated urban crowdsourcing of deliveries.

2. Cluster 2 (blue – 49%) refers to businesses using crowdsourcing and international industry practices. In this cluster, the main, but not the only, authors and articles with significant representation in the cluster are: Mladenow et al. (2016), Frehe et al. (2017), Taeihagh (2017), Williams and Horodnic (2017), Wang et al. (2018), Bachnik and Szumniak-Samolej (2018), Boxall et al. (2018), Chen et al. (2018), Zhang et al. (2018) and Volgger et al. (2018). Since 2016, research in this area has focused on crowd logistics. The firms in this cluster are interested in the contribution of the social crowd to logistics activities and involve evaluation of crowd logistics business models that use members of the public to achieve last-mile delivery. This consumer participation in logistics service is crucial and depends on individuals’ cognitions and affects.

3. Cluster 3 (green – 24%) relates to the impact on the environment of transport related to last-mile delivery and crowdshipping. The main, but not the only, authors and articles with significant representation in the cluster are: Kunze (2016), Devari et al. (2017), Buldeo Rai et al. (2018), Qi et al. (2018), Gatta et al. (2019), Melo et al. (2019) and Martin et al. (2019). Research in this cluster emphasizes the environmental potential of collaborative consumption and stakeholder analysis of crowd logistics platforms in different European countries. Shared mobility, involving the crowd in last-mile delivery, relies on public transport and sustainable city logistics.

Each of these three clusters reveals trends that are presented and discussed in the succeeding sections.

4.1 Trend 1. Optimization of urban logistics problems

Cluster 1 includes research on urban logistics and real problems, based on optimal allocation of costs, prices and distribution models. Several articles focus on decision protocols, planning and distribution models and optimization processes. For example, one of the solutions suggested to achieve higher system profitability and save on agents’ costs is for the platform to leverage public parking spaces. The solution is feasible, but has yet to be incorporated into a system and verified in real-world application (Kong et al., 2018). Other articles highlight how the rapid growth of logistics distribution is revealing an imperfect logistics distribution network infrastructure (Li et al., 2018) and high distribution costs (Gan et al., 2018). The main works propose new intelligent solutions to these urban problems, such as collaborative shipping to reduce fuel and emissions costs (Beliën et al., 2017), shared warehousing to maximize space (He and Gu, 2018) and coordination in single-supplier/multiple-buyer supply chains (Karabati and Saym, 2008). These solutions are proving efficient and are increasing profitability (Kong et al., 2018; Karabati and Saym, 2008).

Several papers provide analyses of worker trajectories within a platform-enabled coordinated task assignment approach (Chen et al., 2014). This strand of work looks at detour optimization to allow the worker to complete his/ser assigned tasks (Chen et al., 2014) and customers’ shopping behaviour, which affects the customer’s delivery logistics preferences (high speed, low cost, etc). (Gan et al., 2018). Other problems are being tackled by application of IT and big data, which are able to capture customers’ logistics needs by analyzing their distribution logistics preferences and are promoting integration and optimization of logistical resources (Zhai and Du, 2017), improving participant satisfaction Gan et al. (2018) and allowing more efficient performance at lower cost, all of which increase customer loyalty (Gkatzelis et al., 2016; Wallenburg, 2009). In the case of simple outsourced services and short contracting periods, customer loyalty depends only on costs (Wallenburg, 2009). Crowd logistics have the potential to improve city logistics; however, it is not obvious, from an economic, societal and environmental perspective, how the crowd could best be exploited for the performance of logistics services.

4.2 Trend 2. Mobilization of crowd logistic for efficient business crowdsourcing

In Cluster 2, business research focuses on the crowd and business models (Mehmann et al., 2015; Frehe et al., 2017). As the sharing economy has evolved, it has spread to multiple economic sectors across the world. Sharing is defined as the simultaneous or sequential use, by several people, of an object (e.g. a car), a space (e.g. a living room) or an intangible element (e.g. an identity) (Rudmin, 2016). Initially, sharing was related to achieving more sustainable use of resources (Pottinger, 2018; Mishra, 2018; Geissinger et al., 2019); it has become significant for business practices, logistics and supply chain management. Most authors distinguish between the sharing economy and crowdsourcing (Taeihagh, 2017; Tong et al., 2017), although both involve use of IT, trust in exchanges and reputation systems. They tend to be distinguished by their use of these IT systems to resolve specific problems (Taeihagh, 2017). Some works focus on different sharing best practice and the factors involved in successful development of logistics and supply chain management (Zinn and Goldsby, 2017). Examples include analysis of opportunities for social crowd integration in logistics processes (Mladenow et al., 2016) and the types of services proposed by crowd logistics (Carbone et al., 2017, 2018). Some recent food consumption and food distribution initiatives are related to sustainable consumption, the sharing economy and collaborative consumption. This stream of work indicates that, in the area of consumer durables, individual consumers seem to be recognizing the value to be derived from more responsible behaviour and collaborative economy projects (Ukolov et al., 2016; Bachnik and Szumniak-Samolej, 2018). Online platforms that connect and facilitate transactions between the owners of underutilized assets and users who will pay to use these assets for a limited time are disrupting many sectors (Zhang et al., 2018). Traditional businesses facing this new competition are implementing new strategies (Ukolov et al., 2016; Ocicka and Wieteska, 2017). Social exchanges involve aspects such as user motivation and attitude, consumption experience and cultural usage of the sharing economy. Several studies suggest that the link between human intelligence and the choice of modes of access based on social exchanges can be explained by individual and institutional consumers’ increased social trust (Wang et al., 2018; Aspara and Wittkowski, 2018). This strand of work is complemented by studies of crowd intelligence platforms (Li et al., 2017). Planners and decision-makers should consult with one another and take account of the needs of socially excluded groups when deciding how to regulate shared economy enterprises. Broader social inclusion rather than the regulation of peer platforms should be the primary focus of legislation (Boxall et al., 2018).

4.3 Trend 3. Shared mobility for last-mile delivery

In Cluster 3, shared mobility for last-mile delivery is the source of numerous innovative solutions that reduce environmental impact. There are two main strands of research in the field of transport. The first is related to shared mobility for last-mile delivery. Parcel delivery, a major outcome of the growth of e-commerce, is challenging urban logistics (Akeb et al., 2018) and highlighting the need to transform current consumption patterns to achieve more sustainable practices. The research proposes several solutions related to last-mile delivery, based on crowd-tasking models and scalable solutions. In the context of urban logistics, last-mile delivery from the warehouse to the consumer’s home has become particularly complex. It requires elaborate planning and scheduling to minimize overall transport costs and environmental pollution, but can result in a failed delivery if the consumer is not at home. Several shared mobility solutions have been proposed to address this problem (Qi et al., 2018), including Post 4.0 using ground drones (Kunze, 2016), mobile crowd-tasking involving a large pool of citizen workers to achieve last-mile delivery (Wang et al., 2016), crowdsourcing of last-mile deliveries of online orders by exploiting the social networks of retail store customers or reception of deliveries by friends and neighbours. These solutions reduce emissions and ensure speedy and reliable delivery (Devari et al., 2017; Akeb et al., 2018). Peer-to-peer product sharing platforms integrated with package drop-off/pick-up services in urban districts are also reducing the impact on the environment (Martin et al., 2019).

The second strand of work focuses on public transport-based crowdshipping for sustainable city logistics (Sampaio et al., 2017). This research is aimed at understanding and evaluating the environmental and economic impacts of crowdshipping platforms in urban areas (Gdowska et al., 2018). Environmentally friendly crowdshipping is based on use of mass transit city networks and customers/crowdshippers picking up/dropping off goods using automated parcel lockers, located in or near transit stations. Crowdshippers include individuals who use the transit network for other activities (e.g. travel to and from work), which avoids additional trips (Serafini et al., 2018; Gatta et al., 2019). Crowdshipping platforms match supplies to requests to planned trips by community members (Behrend and Meisel, 2018). Crowd logistics allow more sustainable urban freight transport. Also, the emergence of smart transport is highlighting opportunities to relieve road congestion through use of collaborative and connected mobility models (Hensher, 2018). Crowd logistics envisages delivery operations using excess passenger capacity on scheduled routes; this has the potential to provide economic, social and environmental benefits (Buldeo Rai et al., 2017, 2018). Crowd logistics offers an alternative to traditional home deliveries by parcel companies and is considered more sustainable. The rationale underlying crowd logistics are that parcels and passengers are co-transported on a passenger journey. It relies on opportunities to monetize the already existing resources rather than creating additional infrastructure to try to meet demand (Melo et al., 2019).

Bibliometric analysis allows an overview of the development of the field and identifies research trends. The crowd allows optimization of urban logistics, increases crowdsourcing business efficiency and exploits shared mobility for last-mile delivery. But, there are still questions. How the crowd can be mobilized, organized and optimized to exploit their travel time and travel mode? How appreciate their diversity, their behaviour and their intelligence?

5.1 The emergence of a crowd cyber system

We have shown that sharing economy logistics and crowd logistics are undergoing a continuous evolutionary process, which is highlighting crowd cyber systems as a promising research topic. Li et al. (2018, p. 343) see this evolution as “a golden period towards smart logistics” while underlining that the social crowd could be integrated into logistical processes that include international industry practices and last-mile delivery.

We have seen that logistics (transportation, warehousing, support services, cargo handling, etc). has evolved from being a work management tool to becoming a managerial approach (Zhai and Du, 2017), involving the coordination of goods and/or information deliveries to the right person, in the right place and at the right time (Mladenow et al., 2016). In the delivery race, last-mile delivery is the most cost-intensive part of the transport chain, from both a financial and an ecological point of view (i.e. in terms of greenhouse gas emissions). In this case, crowd logistics allow shared activities that enhance flows of information and goods (Mladenow et al., 2016). Crowd logistics services refer to the outsourcing of logistics services to a mass of actors and to categories such as personal transport, freight transport and purchase and delivery services (combination of e-commerce, food shopping and deliveries). In the first two cases, the crowd is both the carrier and the beneficiary. The crowd logistics company acts as the mediator. In the third case, crowd logistics are an alternative to drones used for same-day delivery (Kunze, 2016). More research is needed on the returns to investment. Indeed, the research tends either to ignore the economic benefits or discuss them only briefly and little is known about the long-term profitability and the risks involved in crowd logistics. This is a research direction where more work is needed.

Coordination of the logistics services outsourced to the crowd is supported by technical platforms, which are hosted and managed by crowd logistics providers and accessed via mobile apps, computer software or websites (Frehe et al., 2017). These technical platforms are used, primarily, as communication media and can be accessed in multiple ways using SMAC solutions. They use advanced technologies to coordinate supply and demand for transport services and to connect shippers to drivers. Crowd logistics platforms allow resources matching (Mladenow et al., 2016), operations management (route planning, driver monitoring – Punel and Stathopoulos, 2017), higher-quality services (Buldeo Rai et al., 2018) and risk control (Mehmann et al., 2015). Crowd logistics platforms connect Web-based industries within an industrial eco-structure (Chai et al., 2017). This cyber-crowd system is enabled by a set of intelligent agents guided by the joint optimization of logistics operations. This network of intelligent agents is coordinated by the platform, which acts as an e-intermediary. Platforms are offering crowd management competence via Web media and resource utilization and business process management algorithms. They are allowing management of the crowd’s intelligent transactions (supply and demand) and enabling dynamic pricing.

Each of the intelligent agents in the crowd cyber system has a particular role, which allows this eco-structure to adapt transactions to ongoing changes: “Transaction efficiency is the main inducement to the evolution of ecostructure” (Chai et al., 2017, p. 5). To adapt to variations in their environment, intelligent agents can implement collective strategies.

Therefore, a study of the crowd cyber system requires systemic analysis of the network connectivity among intelligent agents to assess the value they create (Li et al., 2019a, 2019 b). Measuring both profitability and risk is not straightforward; account needs to be taken of operating costs, customer availability, transaction costs related to transparent information and optimization models. The pricing model will reflect the crowd cyber system base value price for a set of intelligent agents, i.e. the margins related to the services delivered. The literature does not clarify how platforms create value. Crowd logistics involved private consumers, a few professional consumers and a customer network (Frehe et al., 2017; Li et al., 2017) and offers resources either for free (private individuals’ resources e.g. free carsharing) or for a fee (crowdshipping) (Serafini et al., 2018). Crowd logistics are confined to specific regions or cities and are increasing competition and changing the behaviours of residents and attitudes to traffic problems. There are no national- or international-wide services in place, but they represent opportunities for firms. The proposed legislation, the transport infrastructures and the political constraints on crowd logistics need more in-depth investigation. Finally, in an urban context, transport logistics involves the public transport network (metro, buses, etc). to make last-mile delivery more efficient and reduce transport costs and emissions (Bubner et al., 2014). It should enable the ultimate environment-friendly service. Similar to most crowdsourced activities, the network of carriers and customers is an essential component. The service requires a critical mass, which might require incentives. Marketing research has investigated the need to implement mechanisms that take account of the motivation, availability, remuneration, satisfaction and intelligence of the crowd. Most current research proposes frameworks, models and algorithms for a better theoretical understanding of how the social crowd can be integrated into logistics processes. Some studies propose several solutions to enhance last-mile delivery, based on crowd-tasking models and scalable solutions; in urban logistics, last-mile delivery from warehouse to consumer is increasingly complex. The inclusion of customers in these logistics processes could reduce transportation costs, CO₂ emissions and traffic congestion, but crowdshipping, based on scheduled transport, will require a high level of involvement from the crowd logistics and a better understanding of the intelligence of the crowd.

5.2 Crowd intelligence – the cornerstone of the crowd cyber system

Crowd intelligence emerges from the collective intelligence efforts (and different levels of expertise and dedication) of the crowd of autonomous individuals, organized in online networks and motivated to conduct transportation, services and computational tasks within the sharing economy. The theory of crowd intelligence or crowd wisdom was popularized by James Surowiecki (2004) who suggested that more effective problem perception and resolution can be achieved by a crowd compared to individual members acting alone. However, not all crowds are wise. Crowds have statistical evaluation power that is useful in logistics flow management. The crowd has knowledge and is capable of coordination and cooperation. Several studies try to understand the circumstances, which allow crowd wisdom to take effect. Crowds are defined by a diversity of opinion, independence, decentralization and aggregation. The crowd is composed of people from different backgrounds, with different ideas; the resulting crowd wisdom comes from the combination of ideas and knowledge. There are some mechanisms in place to translate private judgements into a collective decision. Diversity introduces corrective factors into statistical estimates. According to Surowiecki (2004, p. 29), “Diversity helps because it actually adds perspectives that would otherwise be absent and because it takes away, or at least weakens, some of the destructive characteristics of group decision making”.

Thus, the wisdom of the crowd is not a philosophical entity, but rather a mathematical and statistical phenomenon that is aligned to Li et al.’s (2017, p. 17) view that “the crowd intelligence system interweaves crowd and machine capabilities seamlessly to address challenging computational problems”. In this context, the crowd is no longer just a network agent/carrier or a user; it becomes a solutions creator that allows the creation of value. There are several reasons why the crowd can fulfil this role. Customers become contributors because of social motivation: priority is given to the process of exchanges among individuals, interpersonal aspects and consumer awareness of sustainability issues (Li et al., 2017). There is the possibility of financial gain from reduced transport costs, reduced prices and faster delivery. This research stream examines the effectiveness of the crowd organization because, in crowd logistics, the individuals involved are a priori unknown, are highly autonomous and may behave unpredictably. This unpredictable behaviour is explained in the crowd intelligence theory as informational effects. For example, when individuals lack information, they tend to imitate. They conform to whoever seems to “know”, and the result can be positive or negative depending on whether the leader is right or wrong. Similarly, to safeguard their reputation, individuals may endorse the point of view of the majority. Several studies (Hadzikadic and Sun, 2010) provide simulations that consider the continuity in decision-making, the complexity of the world and the rapid evolution of individual interactions, irrational individuals and learning capacity to make individuals and crowds “smarter” over time.

Thus, “the crowd intelligence therein has great potential to explore beyond those from individual entities” (Wang et al., 2019, p. 25). Understanding how the crowd is organized and appreciating its diversity, behaviours and intelligence are all topics requiring further research.

So, how can individuals with different backgrounds and skills be organized to generate efficiency and persistent crowd intelligence? Coordination involves deciding which choices to consider based on an assessment of the other choices. The most promising approach, after the game theory and various optimization models, would seem to be machine learning, which takes account of the tacit conventions among the members of the crowd. According to Li Y (2019, p. 168), “it is of crucial importance to study how such smart entities interact with each other, to understand their decision-making process, to analyze how they influence each other and the impact of such interactions on the entire crowd intelligence networks”. Investigating how information propagates within a crowd network could be informative for the design of efficient and effective resource allocation mechanisms, crowd intelligence network management approaches and measures of social welfare.

So, how can we capture the patterns of crowd intelligence and their mechanisms, in different scenarios, to design incentives and operational methods to best realize the crowd intelligence? According to Liu et al. (2018, p. 2) “in the crowd cyber system, the motivation and incentive of different intelligent agents are distinct. For individuals, they try to maximize their utility. For enterprises, they pursue higher profit. For governments, they need to take the welfare of the whole economy into consideration”. Although financial incentives can be effective, reputation is also important. Other forms of incentives should be investigated in future research. Motivation and incentives are fundamental for the formation of a crowd network.

How should subtasks be distributed and outcomes aggregated? We need to know how to assess, control and guarantee the quality of the work, how to handle the potential risks related to the distribution of responsibilities, privacy issues, additional costs, delivery delays and security issues. It has been suggested that AI could enable interaction among the smart entities in the crowd cyber system. On online community platforms, AI enables knowledge sharing and knowledge management among individuals involved in large-scale collaborations. Finally, the link between AI and the internet of things could facilitate the management of crowd intelligence because crowd logistics is related to the idea of the physical internet. According to Buldeo Rai et al. (2017 p. 2), “The idea, is to encapsulate physical objects in modular packets and containers of which the header contains all information required for identifying the packet. These packets and containers are then routed as efficiently as possible so that it absorbs spare capacity in transport systems, ensuring that they get to their destination in time, regardless of the route followed”.

Therefore, digitalization, analysis of big data and AI could connect cyber physical production systems and the crowd cyber system to optimize, control and predict the behaviour of all the systems involved in the sharing economy.

We have shown that crowd intelligence is becoming critical for an intelligent logistics ecosystem based on big data. The crowd cyber system is a major and growing multidisciplinary concept. It is both interesting and complex to analyze because of the multiplicity of approaches that could be used. The disciplines of business management, psychology, economics and computational intelligence are all conducting research in this area, based on different theories, approaches and tools such as collective intelligence, decision-making, cognition, AI, etc. Scientists, business people and computer programmers are all interested in this area. Big data is an important innovation and is influencing many areas of our global society (Chen, 2019). We need a systemic approach to digitalization of supply chains based on the crowd cyber system that links people, products, platforms and the crowd. The information contained in each digital technology is combined to provide an overall understanding of the intelligent digital ecosystem. This is the first step towards achieving Logistics 4.0 to support industry 4.0. Logistics 4.0 focuses on integrating within a network the most advanced information and communication solutions to ensure system interoperability and real-time communication (Bayarçelik and Bumin Doyduk, 2020), e.g. to enable last-mile delivery.