1. Introduction

Traffic congestion is one of the “dilemmas” encountered by metropolises around the world. The fifth type of transportation and supply system, “underground logistics system” (ULS), has been developed to address the energy consumption, environmental pollution, and safety issues [1]. Various forms of ULS with different locomotives or driving methods have been developed and applied, such as CargoCap underground freight transportation system in Germany [2], OLS-ASH project in Netherland [3], and Pipe§net vacuum freight capsule in Italy [4–7]. ULS is widely recognized as a great innovation in the logistics industry because of its huge benefits to the city. It can quickly transport goods through underground pipes or tunnels within cities or between cities [8, 9]. However, it is undeniable that the high cost, long construction period, and high-risk of underground projects [10–12] are serious obstacles to ULS development. Reducing the construction cost is critical to improve the uptake of ULS [13].

Dampier and Marinov proposed a new conception of “integrating underground freight transport into modern metro system” (metro-based ULS, designated as M-ULS), which offered a feasible way with limited budget [14]. As a special form and promising alternative of ULS network, M-ULS has become one of the hottest research topics. Especially, setting up the intermodal network aims at maximizing the efficiency of cargo transport without interfering with the passenger transport system. The organizational process of this new system is complicated. It involves the linkage and optimization of the dual objectives of the passenger and cargo transportation system. The cargo needs to be sent to the demand points via reasonable metro stations and the distribution system on the ground. Therefore, the global optimization of the M-ULS efficiency can be classified as a special type of capacitated multistage facility location problem (CMFLP). The aim of this paper is thus to design a multilevel node location-allocation solution for M-ULS through mathematical modeling and simulation.

Research on ULS has been ongoing for nearly 30 years, but M-ULS is still an emerging area. Existing studies verified the feasibility of M-ULS and proposed concept designs. M-ULS is defined as an intermodal mechanism of mixed passengers and freight, in which batch driving or attachment carriages are enabled by utilizing metro railways [15]. Their advantage not only lies on the reservation of traditional ULS benefits in alleviating traffic congestion, improving urban environment and freight efficiency, but also contributes to a huge saving of the underground space, reducing construction costs and period. The passenger transport efficiency would not be interfered through rational technology design and operation management [15]. In Tokyo, new subway-integrated ULS received public endorsement in a pilot project [16]. In Newcastle upon Tyne, metro network was used for the collection of small-sized to medium-sized parcels, low-density high-value goods, and recyclable material [17]. In Korea, the freight volume of Seoul Metro 50 platforms was predicted to validate the reduction of social cost and environmental problem [18]. Toronto subway has also been evaluated on how such a modal shift appealed to cargo shippers [19]. All in all, real-world simulations were widely developed in recent years [20–22].

However, few articles with the topics on the planning method of M-ULS network have been published. Hörl et al. and Masson et al. conducted qualitative analyses of node location problem of single-line metro freight transport [23, 24]. Fangting et al. proposed a location-routing model of multiline transfer problem of M-ULS [25], which aimed at minimizing delivery time to improve the efficiency of metro freight. The optimization of the single-layer network topology was carried out; however, the influence of urban freight flow distribution on the system service level was not involved. Ambrosino and Scutella [26] proposed a four-level complex network distribution structure including facility location, warehousing, transshipment, and strategic decisions. The findings have contribution for analyzing the CMFLP of M-ULS, although it does not directly discuss M-ULS. M-ULS itself is a complex system. Functional classification of different types of facilities is necessary to meet the needs of intermodal transport. In order to pursue higher logistics benefits, a systematic evaluation of the urban freight transport demand is required due to strict capacity constraints of M-ULS. The freight flow direction and node location are two key indicators of M-ULS network layout. Thereby, this paper proposed a hierarchical mixed integer programming model (MIPM) combined with comprehensive evaluation that could reflect the different relationships of nodes. Compared to the modeling benchmark of general facility location problem [27–29], three additional important factors had been considered: (i) Constraint of metro network. Compared to the traditional logistics LAP model, M-ULS distribution path, which is restricted by the existing metro network, cannot be freely selected and adjusted immediately. (ii) New system service area. The definition of new system service objects has to be integrated into the optimization process because maximizing the limited system service capability is a key to M-ULS planning. (iii) Mixed transport organization is complicated. The design principle of existing metro network is passenger oriented, and the passenger transportation efficiency cannot be influenced by the new system. Improving the service performance of the new system requires redesigning an organizational process of passenger and freight mixed transportation, and the global optimization of freight transportation process.

The contributions of this study mainly lie in three aspects: (1) an effective organizational planning method for M-ULS was proposed; (2) a mixed integer programming model with multiple constraints was developed to solve the capacitated metro-based underground logistics system location-allocation problem (CM-ULSLAP); (3) a hybrid heuristic algorithm was developed for the simulation of real-world. Two lines of Nanjing Metro were selected as a case to validate the proposed planning method. The findings can promote the implementation of ULS. In addition, this study offers new ideas and quantitative optimization approaches for linear or network-based complex engineering projects. The supplied case study provides additional insights for research and practices.

2. Problem Description

The CM-ULSLAP can be described as follows: there are m operating metro lines, n urban distribution centers (designated as UDCs), and k demand points. Firstly, cargo from the open UDCs which provide ULS services is imported into underground network through the nearby metro stations (designated as ULS terminal). Then, dedicated cargo trains travel between ULS terminals and different underground depots (designated as UDs). Those UDs refer to the retrofitted metro stations, in which UD-oriented trains are bypassed to the parallel freight platforms before entering the passenger platforms. In this process, the frequency of freight fleet keeps interlaced with metro, and existing transfer points can be activated as underground hubs (designated as UHs) to support underground transshipment. Finally, freight units floating up from UDs are allocated to the corresponding ground terminals (designated as GTs) by ground electric vehicles. Cargo is delivered to the customers who are within the service scope of M-ULS after automated sorting and packaging at GTs. The reversed procedures are presented in mirror image. Figure 1 demonstrates the organizational breakdown structures with planning issues of M-ULS.

[figure omitted; refer to PDF]

The initial data that can be used for the metro freight planning usually focus on several incomplete customers characteristics, such as location, regular delivery route, and handover period record. Other important input data are the demand for travel, which is commonly formulated as the origin-destination (OD) matrix [30]. The freight OD matrix in this study is extracted based on the counts of travels multiplied by order capacity from one area to another. On this basis, the alternative solution aims to improve the current customer service with low cost and high efficiency. The high efficiency of M-ULS depends on the coordination of its own technical integration and freight flow distribution. In order to get this, the joint freight function should not lead to any degradation or disruption of passenger service [15]. As a result, goods and passengers must be separated. Meanwhile, the efficiency loss caused by intermodal transport can also be compensated by a highly integrated urban logistics benchmark. Taking into account the regional development density and spatial impact on the surrounding environment, in M-ULS, freight flows cannot be detained too much after reaching corresponding underground destinations. Instead, they should be transferred directly to the newly built ground terminals for processing. By setting such a transit layer between customers and underground distribution network, the transport efficiency and system service capacity can be largely improved by dividing the M-ULS from the traditional logistics systems. Based on the planning principles discussed above, the node facilities are divided into the following four layers:

3. E-TOPSIS for Evaluation of Underground Freight Volume

The entropy weighted TOPSIS method (E-TOPSIS) is applied in the weighting process of the evaluation indicator system [31]. The information entropy calculated in the indicator matrix is used to weight the dispersion degree of demand characteristics, all that can avoid the influence of human subjective factors [32]. The final points of the evaluation objects in multiobjective decision-making are gotten by the TOPSIS method which can solve the higher requirement for the sample.

This paper used unity of freight flows (UFFs), regional accessibility (RA), and source distance (SD) as three dimensions to reflect UDC’s preference for the characteristics of customers’ demand. Therein, variables UFF and RA were obtained from Nathanail et al. [33], who maintained that the urban traffic alleviation and the development of integrated transport to reduce the scattered freight delivery were two of the most remarkable characteristics of the sustainable city logistics. In our study, we took these two quantitative features as the functional requirements of the metro freight system, where UFF was formulated as the accumulated OD from different directions according to Masson et al. [24] and RA was formulated as the accumulated delivery period from different directions divided by average path length according to Montoya-Torres et al. [34]. SD was formulated as a variable that supplemented UFF with distance influence, which involved the data of spatial distance and freight OD from different directions. These 3 variables share the initial data mentioned above.

(i) Unity of freight flows. Since UD does not have the function of parcel disassembly, logistics benefits are promoted along with the growth of underground mileages [35]. Therefore, M-ULS should provide centralized supplies as much as possible to areas with huge demand:$$\begin{array}{}\text{(1)}& x_{1j}=\overline{Q_j},\end{array}$$where $Q$ is the total amount of freight picked up and delivered per day at demand point $j$.

(ii) Regional accessibility. The efficiency of urban logistics is largely influenced by traffic congestion [36–38]. By removing goods from above to underground, the freight mobility of some regions with poor accessibility can be effectively improved [39]. The index of regional accessibility can be characterized by the time-road response function:$$\begin{array}{}\text{(2)}& x_{2j}={\displaystyle \sum }_{i=1}^m{\left(\frac{t_{ij}}{S}\right)}^{{\tau }_{ij}},\end{array}$$where $t_{ij}$ is the average delivery time form UDC i to demand point j, $S$ is the length of the delivery route, and ${\tau }_{ij}\in \left(\mathrm{0,1}\right)$ is the time sensitive factor.

(iii) Source distance. Underground logistics can generate considerable internal and external benefits [40]. M-ULS should take full advantage of the length of metro lines. Putting goods which are far from the source (ULS terminal) but in huge demand into the system will lead to the overall increase of logistics values. The source distance index can be portrayed as$$\begin{array}{}\text{(3)}& x_{3j}={\displaystyle \sum }_{i=1}^m‖d_{ij}‖\cdot {\left[{\gamma }_i\left(x_j\right)\right]}^{{\alpha }_j},\end{array}$$where $‖d_{ij}‖$ is the Euclidean distance between UDC i and demand point j, ${\gamma }_i\left(x_j\right)$ is the freight correction factor of the sample, which represents the proportion of the freight volume from direction i, and ${\alpha }_j$ is an amplification coefficient.

An evaluation model for the priority level of M-ULS service is constructed.

(1) The initial decision matrix. Assuming there are m evaluation indicators and evaluation indicator sets have n subsets, the evaluation value of indicator i in subset j is $x_{ij}$. The decision matrix of all subsets is$$\begin{array}{}\text{(4)}& R={\left(x_{ij}\right)}_{m\times n}=\left[\begin{array}{ccc}{x}_{11}& \cdots & x_{1n}\\ ⋮& \ddots & ⋮\\ x_{m1}& \cdots & x_{mn}\end{array}\right].\end{array}$$

(2) Standardization of the decision matrix. In order to solve the uniform of indicators’ units, this paper makes the standardization on all indicators. Take the best value of indicator i as $x_i^{\text{best}}$, the worst as $x_i^{\text{worst}}$. The efficacy coefficient $\alpha$ is introduced to obtain the normalized data matrix B:$$\begin{array}{}\text{(5)}& B={\left[x_{ij}\right]}^{\prime }=\frac{x_{ij}-x_i^{\text{worst}}}{x_i^{\text{best}}-x_i^{\text{worst}}}\cdot \alpha +\left(1-\alpha \right),\hspace{1em}\alpha \in \left(\mathrm{0,1}\right).\end{array}$$

(3) Determine the indicators weight. The indicator weights are determined by the expert evaluation method in the TOPSIS. The results are quite subjective. Therefore, this paper adopts the information entropy method to determine the indicators weight.

$e_i$ denotes the entropy of indicator i in the standardized decision matrix:$$\begin{array}{c}\text{(6)}& T_{ij}={\displaystyle \sum }_{k=1}^l\left(\frac{x_{ij}}{{{\displaystyle \sum }}_{j=1}^n{x}_{ijk}}\right),e_i=h\cdot {\displaystyle \sum }_{j=1}^n{T}_{ij}\ln \left(T_{ij}\right),\hspace{1em}\forall i=\mathrm{1,2},\dots ,m,\\ h=\frac{1}{\ln n},\hspace{1em}0\le e_i\le 1.\hspace{1em}\text{If}\hspace{1em}{T}_{ij}=0,\hspace{1em}{T}_{ij}\ln \left(T_{ij}\right)=0.\end{array}$$

The dispersity of the evaluation value of indicator i can be represented as follows:$$\begin{array}{}\text{(7)}& {\beta }_i=1-e_i,\hspace{1em}\forall i=\mathrm{1,2},\dots ,m.\end{array}$$

If $T_{ij}$ is more dispersed, ${\beta }_i$ is bigger and indicator i is more important. If $T_{ij}$ is relatively concentrated, indicator i is less important. If all $T_{ij}$ are equal and the distribution is absolutely concentrated, indicator i is invalid. So, the weight factor of nonsubjective preference for indicator i is$$\begin{array}{c}\text{(8)}& Y={\left(y_1,y_2,\dots ,y_m\right)}^T,\forall y_i=\frac{{\beta }_i}{{{\displaystyle \sum }}_{i=1}^m{\beta }_i}.\end{array}$$

(4) The weighted matrix of indicators’ value. According to the normalized data matrix B and the obtained entropy weight $y_i$, the weighted matrix of indicators’ value is calculated by following formula:$$\begin{array}{}\text{(9)}& K=Y\cdot \left[\begin{array}{ccc}{T}_{11}& \cdots & T_{1n}\\ ⋮& \ddots & ⋮\\ T_{m1}& \cdots & T_{mn}\end{array}\right]=\left[\begin{array}{ccc}{k}_{11}& \cdots & k_{1n}\\ ⋮& \ddots & ⋮\\ k_{m1}& \cdots & k_{mn}\end{array}\right].\end{array}$$

(5) Calculating the relative distance. The selection scheme of candidate GT for this phase is calculated with the relative proximity ${\rho }_j$ of positive and negative ideal solutions under weighted matrix K:$$\begin{array}{}\text{(10)}& d_j^{+}={\left[{\displaystyle \sum }_{i=1}^m{y}_i{{\displaystyle \sum }_{k=1}^l\left(k_{ij}-x_i^{+}\right)}^2\right]}^{1/2},\hspace{1em}\forall j=\mathrm{1,2},\dots ,n.\end{array}$$where $d_j^{-}$ denotes the Euclidean distance between $k_{ij}$ and negative ideal solution:$$\begin{array}{c}\text{(11)}& d_j^{-}={\left[{\displaystyle \sum }_{i=1}^m{y}_i{{\displaystyle \sum }_{k=1}^l\left(k_{ij}-x_i^{-}\right)}^2\right]}^{1/2},\hspace{1em}\forall j=\mathrm{1,2},\dots ,n,{\rho }_j=\frac{d_j^{-}}{\left(d_j^{+}+d_j^{-}\right)}.\end{array}$$

For the candidate location scheme, ${\rho }_j$ is generally between 0 and 1. The closer to 1, the more appropriate the corresponding scheme. Finally, demand points in the newly built GT are selected to accept the M-ULS service according to the value of ${\rho }_j$ listing in descending order, until one of the nodes or underground sections is overloaded. Underground freight OD can be uniformly formulated as$$\begin{array}{c}\text{(12)}& \overline{Q}=Q_i^x\cdot A_j,\forall A_j=\left\{\begin{array}{c}{\left(\mathrm{1,1},\dots ,1\right)}^T,\hspace{1em}1\ge {\rho }_j\ge {\overline{\rho }}_j,\\ {\left(\mathrm{0,0},\dots ,0\right)}^T,\hspace{1em}0\le {\rho }_j\le {\overline{\rho }}_j.\end{array}\right.\end{array}$$

4. Multistage Node Location Model for M-ULS

5. Solution Method

CM-ULSLAP is an NP-hard problem in which the customer layer (demand point), middle layer (GT), underground logistics layers (UD and UH), and supply layer (UDC) are integrated into a complex intermodal network. This problem is computationally intractable due to the following reasons. First, there is not a single layer of node information that can be fully invoked. Different intermodal strategies result in the conflict between customer demands and economic considerations. The evaluation procedure is hard to carry out. On the contrary, the possible paths for each OD pairs are so huge that it is computationally expensive and unsustainable to enumerate all of them for each configuration involving transport mode choice and corresponding routing transfer. Once the supply relationship and the generation strategy of candidate GT are determined, CM-ULSLAP reduces to the bi-level capacitated intermodal network design problem (BCIND). For calculation efficiency and stability, the access routes from UDCs to ULS terminals were determined in advance to cut off the supply layer. Then the entropy weighted TOPSIS method (E-TOPSIS) was applied to evaluate the demand characteristics in model (P1). Next, an exact algorithm for set coverage model is served for obtaining feasible solutions in model (P2), thereby cutting off the customer layer by replacing abundant demand points with candidate GT sets. Immune Clone Selection Algorithm (ICSA) was applied to optimize the location of UD and allocation of deterministic GT which following the minimum objective cost in model (P3). An adaptive mechanism of underground route navigation was also embedded in ICSA where fleet flows always follow the shortest path that is currently available until the certain section is blocked. Finally, the solution space of combined models has been reduced from five dimensions $M\ast N\ast K\ast \left|V_{\mathrm{C}}\right|\ast \left|V_{\mathrm{P}}\right|$ to three dimensions $M\ast \left|V_{\mathrm{C}}\right|\ast \left|V_{\mathrm{P}}^{″}\right|$ which contributes a lot to the computational efficiency. The relationships and decomposition of models are shown in Figure 2.

[figure omitted; refer to PDF]

The ICSA was inspired by the principle of clonal selection of antibodies in the biological immune system [41]. It was used to explain the basic characteristics of adaptive immune response to antigen stimulation. The ICSA has been widely used in solving problems such as combinatorial optimization, intelligent optimization, and production scheduling due to its powerful data search capabilities [42–44]. However, the convergence rate of original ICSA is slower, immune probability and cloning probability are relatively fixed, and the degree of change is relatively low when solving complex problems. In this paper, we introduced a self-adaptive mutation operation based on normal distribution to achieve a uniform and dynamic global high-level ambiguity for each antibody that meets the mutation rate for the characteristics of multiple UD feasible solutions and frequent information feedback at each stage. Probability variation enhances the randomness and stability of the search and can effectively prevent the solution from falling into local optimum. The main operation of the heuristic algorithm is shown in Figure 3.

[figure omitted; refer to PDF]

The solution steps of GT location are listed in Algorithm 1.

Algorithm 1: Set coverage model for ground terminal.

Step 1: Generate Initial Population. The initial antibodies were obtained from the memory cells that were generated randomly from the feasible solution space. The coding of antibodies includes the UD open strategies and the location information of newly built GT which were fed back by E-TOPSIS. The initial antibody population was recorded as $P_0\left(\text{RC}\right)$, which was composed by RC number randomly generated antibodies.

Step 2: Diversity Evaluation. Select k individuals with the highest fitness value and t individuals with the lowest affinity from the parent population $P_n\left(\text{RC}\right)$ to compose the solution vector, where $k=\text{RC}\times 20\%$ and $t=\text{RC}\times 10\%$. Affinity was used to indicate the matching degree between antibody and antigen, namely, the optimal satisfaction between the candidate GT sets and open UD in objective (19). Lehmer mean [45] was recommended to the affinity determination. The affinity of the uth solution vector can be described as$$\begin{array}{}\text{(28)}& I_u=\frac{1}{1+L\left(u,v\right)};\forall L\left(u,v\right)=\frac{{{\displaystyle \sum }}_{u\ne v}{‖J_b\left(u\right)-J_b\left(v\right)‖}^2}{{{\displaystyle \sum }}_{u\ne v}‖J_b\left(u\right)-J_b\left(v\right)‖}.\end{array}$$

Step 3: Clone Operation. The clone ratio was calculated by the evaluation of affinity and similarity between antigen and other antibodies. The cloned population $Z_n\left(N_{\mathrm{C}}\right)$ is produced by replicating $k+t\pm d$ number of selected antibodies. Specifically, the total number of clones generated for all selected antibodies is$$\begin{array}{}\text{(29)}& N_{\text{RC}}={\displaystyle \sum }_{u=1}^{k+t\pm d}\text{round}\left(\text{RC}\left(1-I_u\right)\right).\end{array}$$

Step 4: Gene Mutation. Select a group of clones from $Z_n\left(N_{\text{RC}}\right)$ and perform Gaussian mutation on them to obtain population $S_n$. The mutation rate adopts an adaptive strategy [46] which is related to the adaptation value $f_k$ of the antibody. This mutation operation can be described as $m_j=\text{normrnd}\hspace{1em}\left(m_j,\sigma ,\mathrm{1,1}\right)$, where $m_j$ is the jth attribute of the clone, and normrnd is a normal-distribution random number with a mean of $m_j$ and a standard deviation of $\sigma$. The $\sigma$ domain of the antibody is adaptively adjusted to $\sigma =\omega \cdot I_u/f_k$ following its adaptation value and affinity.

Step 5: Immune Selection. The memory population M is consisted of a batch of antibodies with the highest $f_k$ from the set $S_n\cup Z_n$. Then select 30% k number of antibodies with the highest fitness value from M to update the equal number of antibodies with the lowest fitness value in the population $P_n$ to form the progeny population $P_{n+1}$.

Step 6: Node Search Reset. After reaching the maximum number of iterations N, check $I_y^{\left(n+1\right)}\left(i\right)$, if i exists so that $I_y^{\left(n+1\right)}\left(i\right)>\underset{t\ne y}{\max }{I}_t^{\left(n+1\right)}$. Then update the objective cost $J_b\left(i\right)$. Let $y=y+1$, returning to step 2; if not exists, step forward.

Step 7. The algorithm terminates when reaching iteration number N. Extract the most-affinity antibodies with their attributions as the preferred configuration of M-ULS.

6. Scenario Analysis

7. Conclusions

This paper developed a multistage model with a combined algorithm based on hierarchical optimization, which aimed to deal with optimal nodes location-allocation problem in the cooperative operation of M-ULS. The applicability of the model was proven by selecting the appropriate metro lines and stations for problem solving. The critical issue of developing a M-ULS network is to establish an operational framework and optimization method for multiple nodes. Three types of nodes were defined as underground depot (UD), underground hub (UH), and ground terminal (GT), in accordance with the current state and planning of the city, logistics, and metro network. The M-ULS is in limited capacity, which has a multiple network hierarchy and multiple sources of freight. Therefore, it is necessary to screen the demand points and integrate them into the model for global optimization. A set of mixed integer programming model combined with comprehensive evaluation was developed as a more rigorous and convenient analysis approach to solve CM-ULSLAP. The model was embedded with three evaluation variables, namely, UFF, RA, and SD. A hybrid algorithm composed of E-TOPSIS, exact algorithm, and heuristic algorithm was designed to obtain the solution of the model. A real-world simulation based on Nanjing Metro was carried out to verify the effectiveness of proposed models and algorithms.

It was proved that the potential of metro stations and underground tunnels can be fully exploited to achieve higher logistics benefits. According to the results, optimized M-ULS contributed to reducing the overall ground traffic volume by 49.09% and the daily comprehensive cost by 6.44% within the service scope. Served by the new logistics system, 62.47% of the total freight was completed by ULS, and the remaining 37.53% was delivered to all demand points which were delivered by road distribution. Furthermore, compared to traditional point-to-point logistics mode, the price gap of M-ULS optimal cost has mostly remained stable, regardless of the number of UDs. The realization of these advantages neither affects the normal operation of the metro system nor further increases the amount of underground space development. The other comprehensive benefits for urban transport, environment, and society are obvious. This paper not only proposes a well-designed location-allocation model for joint operation of ULS and metro but provides a possible method for the collaborative research of different urban infrastructures. Moreover, it can provide novel ideas for the sustainable urban development.

Despite the above contributions, this study has several noteworthy limitations. First, the proposed model was exclusively applied to cross-shaped or #-shaped radial metro layout. The loop network will have some special problems that cannot be ignored, for example, the trade-off among transshipment efficiency, routing selection, and budget. Second, the proposed deterministic system in which the UHs were always opened was actually not economical. Although the new problem always starts from certainty, future research needs to explore the uncertainty problems. Robust optimization approach can be used to study the UH scheduling strategy under conditions of stochastic disruption and demand uncertainty. Additionally, research on network planning or underground space can be further extended by considering the operational conflicts between M-ULS and metro system.