2.1 Interbank networks and default contagion

An interbank market can be depicted as a directed weighted graph. This approach is standard, and it has been utilized by several researchers (for instance, Acemoglu et al., Reference Acemoglu, Ozdaglar and Tahbaz-Salehi2015; Amini et al., Reference Amini, Cont and Minca2016; Cont et al., Reference Cont, Moussa and Santos2010). More specifically, an interbank market consisting of $n$ banks is described by a triplet $(X, E, C)$ , where $X=\{1,2,\ldots, n \}$ is the vertex set of the graph whose elements represent the financial institutions. Furthermore, $C=(c_1,c_2, \ldots, c_n)$ is the vector of capitals, that is, $c_i$ is the capital of the institution $i$ indicating the ability of $i$ to absorb any losses. Finally, $E=(E_{ij})_{i,j=1}^n$ is the $n\times n$ matrix of bilateral exposures. More specifically, $E_{ij}$ is the value of all liabilities of the institution $j$ to $i$ (in other words, the exposure of $i$ to $j$ ) at the date of computation. Therefore, $E$ is the adjacency matrix of the direct graph, which demonstrates the set of edges as well as the weight $E_{ij}$ of the edge from $i$ to $j$ . If $E_{ij}=0$ , then there is no (direct) edge from $i$ to $j$ . It follows that the diagonal elements of the $E$ are equal to 0, since banks cannot lend to themselves.

Additionally, if we sum up the $i$ th column of the matrix $E$ , then we obtain the total interbank liabilities of the bank $i$ . Therefore, the interbank liabilities vector can be defined as $\mathbf{L} = \left (L_i\right )_{i=1}^n =\left ( \sum _{j=1}^n E_{ji}\right )_{i=1}^n$ . Similarly, if we sum up the $i$ th raw of the matrix, then we obtain the total interbank assets of the bank $i$ . Therefore, $\mathbf{a} =\left (a_i\right )_{i=1}^n = \left ( \sum _{j=1}^n E_{ij}\right )_{i=1}^n$ is the interbank assets vector.

We now describe the fundamental mechanism of default contagion adopted in this study. We assume that a subset of banks denoted as $A$ defaults due to their inability to meet legal obligations, such as servicing loans. While real-world cases involve only a few banks in set $A$ , our abstract model allows for any subset of $X$ to be $A$ . We are primarily concerned with studying the propagation of default contagion through the interbank market, rather than the specific causes leading to $A$ ’s default.

The initial shock sets off a chain reaction of defaults: banks in subset $A$ cannot meet their obligations to creditors in $X \setminus A$ ; hence, any creditor $j\in X\setminus A$ faces losses equal to its exposures $\sum _{i\in A} E_{ji}$ . At this point, we make some further assumptions, which are realistic, especially in short run, and they have been used in other studies to investigate the worst-case scenarios. First, we assume that there is no recovery rate and, therefore, the creditor loses all its interbank assets held against the defaulted institutions $A$ (see Chinazzi et al., Reference Chinazzi, Pegoraro and Fagiolo2015; Gai & Kapadia, Reference Gai and Kapadia2010). Second, we assume that the loss of the creditor $j$ is imputed directly to the capital of this bank (see Cont et al., Reference Cont, Moussa and Santos2010). Consequently, the capital level of the bank $j$ (and thus its ability to absorb any losses) becomes $c_j-\sum _{i\in A} E_{ji}$ . In the case where the new capital is non positive, that is, if the losses exceed the initial capital $c_j$ , then the bank $j$ becomes insolvent. Our third assumption is that insolvent banks are also considered as defaulted (see Leventides et al., Reference Leventides, Loukaki and Papavassiliou2019). This is not always the case, since the bank $j$ may be able to find some liquidity and fulfill its legal obligations. However, this is extremely difficult as the creditworthiness of the bank has been irreparably affected and $j$ cannot be funded through short-term debt. Therefore, to analyze the worst-case scenarios, we consider the insolvent institutions as defaulted.

Figure 1. The contagion graph for a network consisting of three banks. The left is the graph in the case of zero contagion, whereas the right one depicts the case of total contagion.

In summary, an initial shock causing the failure of banks can lead to a cascade of defaults as the shock spreads through the interbank network. In scenarios with limited time, bolstering bank capital emerges as a reliable strategy for fortifying the interbank market against contagion.

2.2 Contagion map and contagion graph

The phenomenon of default contagion through an interbank network can be modeled with the so-called contagion map $T\colon 2^X\to 2^X$ (see Leventides et al., Reference Leventides, Poulios and Camouzis2022), where $2^X$ is the powerset of $X$ (the collection of all subsets of $X$ ). Given $A\subseteq X$ , the map $T$ returns the set $T(A)\subseteq X$ which contains $A$ and also all the creditors that bankrupt due to the failure of the banks of the set $A$ . By the description of the mechanism of default contagion, the map $T$ is formally defined as $T(A) = \{ j\in X \mid j\in A \text{ or } \sum _{i\in A} E_{ji} \ge c_j \}$ .

It should be noted that $T(A)$ contains the banks of the set $A$ as well as the banks that fail at the first stage after the initial shock. The set $T(A)$ may contain new defaulted institutions which, in turn, create losses to their creditors and a new round of failures occurs. Hence, at the second stage, the set of defaulted institutions is $T(T(A))$ and the propagation may continue in the same manner. The transmission of the initial shock ends when we reach an equilibrium set of $T$ , that is, a set $V$ with the property that $T(V)=V$ .

The contagion map $T$ produces a dynamical system on the powerset $2^X$ . The trajectories $\{A, T(A), T^2(A), \ldots, T^m(A)\}$ (where $m$ has the property that $T^{m+1}(A)=T^m(A)$ ) of this dynamical system describe the propagation of default through the interbank market for all possible initial shocks $A$ . Furthermore, the powerset $2^X$ acquires the structure of a directed graph which has (directed) edges from $A$ to $T(A)$ for all $A\in 2^X$ . This is called the contagion graph, and it is different from the initial triplet $(X,C,E)$ (which is also modeled as a directed weighted graph).

For the contagion map $T$ (and consequently for the contagion graph), there are two extreme cases denoted by $T_0$ and $T_1$ . The first one is defined by $T_0(A)=A$ , for all $A\in 2^X$ , that is, in this case there is no contagion at all. The corresponding contagion graph has $2^n$ edges of the form $(A,A)$ , for all $A\in 2^X$ . The other extreme case is the total contagion defined by $T_1(A) =X$ for all non-empty sets $A$ . Hence, any initial shock promptly results in the complete collapse of the entire market. The contagion graph consists of the $2^n-1$ directed edges $(A,X)$ for all non-empty sets $A$ . Figure 1 illustrates the contagion graph in these two extreme cases for a network consisting of three banks.

In general, the contagion graph contains several connected components. Each component has a single maximal element and various minimal elements. The maximal element is an equilibrium point of the map $T$ and, therefore, it describes a situation where the contagion ends.

Because handling subsets is not convenient for calculations, an equivalent formulation of the contagion map would be desirable. This can be obtained by identifying as usual a subset $A$ of $X$ with the indicator vector $\mathbf{1_A}$ whose entries are zero except those corresponding to the elements of $A$ which are equal to $1$ . In terms of the interbank market, $1$ means that the corresponding bank defaults, while $0$ implies non-default. Hence, the powerset $2^X$ can be identified with the set $\mathbb{Z}_2^n =\{0,1\}^n$ of all vectors with entries $0$ or $1$ . As a consequence, the contagion map can be seen as a map from $\mathbb{Z}_2^n$ to $\mathbb{Z}_2^n$ which associates every vector $\mathbf{1_A}$ with the vector $1_{T(A)}$ . In this setting, it can be proved that the contagion map is given by $T(\mathbf{1_A}) = g(C - E_0 \cdot \mathbf{1_A})$ , where $E_0$ is the $n\times n$ matrix which follows from $E$ by replacing the zero diagonal with the vector $C$ of capitals and $g\colon \mathbb{R}^n \to \mathbb{Z}_2^n$ is the function:

\begin{equation*}g(\mathbf {x})(i) = \left \{ \begin{array}{l@{\quad}l} 1, & \hbox {$\mathbf {x}(i)\le 0$;} \\[5pt] 0, & \hbox {$\mathbf {x}(i)\gt 0$.} \end{array} \right . \end{equation*}

for any vector $\mathbf{x} \in \mathbb{R}^n$ ( $\mathbf{x}(i)$ denotes the $i$ th coordinate of $\mathbf{x}$ ).

2.3 The bankruptcy sets

The bankruptcy set of the bank $i\in X$ (see Leventides et al., Reference Leventides, Livada, Poulios, Rassias and Raigorodskii2020), denoted by $U_i$ , is defined as the collection of all $A\subseteq X\setminus \{i\}$ with the following property: if the banks belonging to $A$ default, then $i$ becomes insolvent. By the description of the mechanism of contagion it follows that:

\begin{equation*} A\in U_i \Leftrightarrow i\in T(A) \Leftrightarrow \sum _{j\in A} E_{ij} \ge c_i. \end{equation*}

Observe that, if $A\in U_i$ and $B$ is any set with $A\subseteq B$ , then $B$ also belongs to the bankruptcy set $U_i$ . Hence, $U_i$ has the structure of an upper set with respect to the order of inclusion.

2.4 Quantitative analysis of the network

If the bank $i$ is prone to financial contagion, then it is expected to be seen in the set $T(A)\setminus A$ for many $A\in 2^X$ not containing $i$ . This justifies the definition of the contagion vector as:

\begin{equation*}\mathbf {V} = \sum _{A\in 2^X} (\mathbf {1_{T(A)}}-\mathbf {1_A} ) \in \mathbb {Z}^n.\end{equation*}

Consequently, the smaller coordinates of the above vector correspond to the more robust banks of the network, while the bigger coordinates indicate weaker institutions. For instance, in the extreme case $T_0$ of zero contagion, the corresponding vector $\mathbf{V_0}$ is zero. On the other hand, in the case of total contagion $T_1$ , the coordinates of the contagion vector have the maximum possible value, that is, $\mathbf{V_1} = (2^{n-1}-1) \cdot \mathbf{1}$ (where $\mathbf{1}$ is the vector with all coordinates equal to $1$ ).

Furthermore, from the contagion vector the indicator $I_1$ can be defined as:

\begin{equation*} I_1(T) = \frac {\left \langle \mathbf {V},\mathbf {1}\right \rangle }{\left \langle \mathbf {V_1}, \mathbf {1}\right \rangle } = \frac {\left \langle \mathbf {V},\mathbf {1}\right \rangle }{n\cdot (2^{n-1}-1)},\end{equation*}

where $\mathbf{V_1} = (2^{n-1}-1) \mathbf{1}$ is the vector in the case of total contagion. The above quantity takes values between $0$ and $1$ (in the cases of zero and total contagion, respectively). Roughly speaking, it measures the stability of the network as a proportion of the corresponding network in total contagion. The smaller the indicator $I_1$ , the more stable the network and vice versa.

Additionally, two other indicators can be defined. The indicator $I_2$ is related to the capitals that are destroyed and the indicator $I_3$ to the loans that are not paid back (again as a proportion of the network in total contagion). More specifically,

\begin{equation*}I_2(T) = \frac {\left \langle \mathbf {V}, C\right \rangle }{\left \langle \mathbf {V_1},C\right \rangle } = \frac {\left \langle \mathbf {V}, C\right \rangle }{(2^{n-1}-1)\left \langle \mathbf {1_X},C\right \rangle }, \quad I_3(T) = \frac {\left \langle \mathbf {V}, \mathbf {L}\right \rangle }{\left \langle \mathbf {V_1},\mathbf {L}\right \rangle } = \frac {\left \langle \mathbf {V}, \mathbf {L}\right \rangle }{(2^{n-1}-1)\left \langle \mathbf {1_X},\mathbf {L}\right \rangle }.\end{equation*}

The quantities take also values between $0$ and $1$ , and smaller values indicate more stable networks.

Finally, the indicator $m=\frac{f}{2^n}$ can be defined, where $f$ denotes the number of equilibrium sets (or fixed points) of the contagion map $T$ . These are the sets $A\subseteq X$ with the property that $T(A)=A$ . Their importance stems from the fact that they are the points where the propagation of an economic crisis eventually stops. There are at least two fixed points (the sets $\emptyset$ and $X$ ). Consequently, the indicator $m$ takes values between $\frac{1}{2^{n-1}}$ and $1$ . The higher the index, the more stable the network, since there are a lot of fixed points.

7.1 Problem I: Increase the robustness with the minimum cost

In this approach, we seek to reach some predefined improvement of the network given that the capital raise should be the less possible. Therefore, we have the following three steps.

Step 1: Measurements and network evaluation. The first step involves the evaluation of the interbank network at a particular stage. The supervisors of the network examine the balance sheet size of each bank. Capital levels, liabilities, and assets are measured. The contagion graph can also be constructed showing the development of a crisis through the interbank market for all possible scenarios of initial default. Finally, the indicators are calculated and the network is evaluated for its robustness and resilience to systemic risk.

Step 2: Setting the goal. The supervisors and policymakers may observe that the indicators are not satisfactory and some criteria are not met. This implies that the network is weak or it has some weak points. Consequently, they may decide that specific proactive actions should be taken. In this work, we only examine the capital raise of each bank.

At this stage, a specific goal should be set. For instance, the supervisors should agree on a specific value $a\in (0,1)$ for the indicator $I$ that has to be met.

Step 3: Capital raise. After the goal has been set, the best method for achieving it has to be found. This translates into the following problem that has to be solved. Find the capitals $(c_1^\ast, c_2^\ast, \ldots, c_n^\ast )$ such that

(7.1) \begin{equation} I(c_1^\ast, c_2^\ast, \ldots, c_n^\ast ) \le a \quad (\text{or } m(c_1^\ast, c_2^\ast, \ldots, c_n^\ast ) \ge a \text{ for the indicator }m) \end{equation}

(7.2) \begin{equation} (c_1^\ast, c_2^\ast, \ldots, c_n^\ast ) \ge (c_1, c_2, \ldots, c_n) \quad \text{in the pointwise sense} \end{equation}

(7.3) \begin{equation} \text{minimize } \sum _{j=1}^{n} c_i^\ast . \end{equation}

7.2 Problem II: Increase the robustness with respect to a specific capital raise

In this approach, we seek to find the optimal improvement of the network given that a total capital raise has been decided for the set of banks. We have again three steps.

Step 1: Measurements and network evaluation. The network should be evaluated as in the previous problem.

Step 2: Setting the goal. A total capital raise should be agreed for the set of banks. This means that we will have new vector of capitals $C=(c_1^*, c_2^*, \ldots, c_n^*)$ , such that $c_i\le c_i^*$ for every $i=1,2, \ldots, n$ and $\sum _{i=1}^{n} c_i^* = A$ , where $A$ is a constant representing the new total capital of the interbank market.

Step 3: Capital raise. Finally, the following optimization problem has to be solved. Find the capitals $(c_1^\ast, c_2^\ast, \ldots, c_n^\ast )$ such that

(7.4) \begin{equation} c_i\le c_i^* \text{ for every } i=1,2, \ldots, n, \end{equation}

(7.5) \begin{equation} \sum _{i=1}^{n} c_i^* = A, \end{equation}

(7.6) \begin{equation} \text{minimize the indicator } I \quad (\text{or maximize the indicator } m). \end{equation}

7.3 Algorithm

At this stage, we present an algorithm for addressing the above problems. The algorithm contains the next steps.

Step 1: The first step is to measure the characteristic features of the interbank market at a particular stage and to depict the contagion graph showing the progression of a crisis for all possible initial defaults. Additionally, the indicators should be calculated which provide a measure of the network robustness.

Step 2: For each bank $i$ , we place in ascending order the potential losses that may be created from other banks. This contains the loan levels $r_A= \sum _{j\in A} E_{ij}$ for all $A\in 2^{X\setminus \{i\}}$ . A chain of losses is created as follows:

\begin{equation*} \begin {array}{c} r_{A_1} \\[4pt] r_{A_2} \\[4pt] \vdots \\[4pt] r_{A_{2^{n-1}}} \end {array} \end{equation*}

Then the capital level $c_i$ is placed within this chain of losses in order to evaluate the minimum raise in capital levels that has to be made for the network to be resilient in case of a systematic shock:

\begin{equation*} \begin {array}{c@{\quad}c@{\quad}c} & & r_{A_1} \\[4pt] & & r_{A_2} \\[4pt] & & \vdots \\[4pt] c_i & \rightarrow & \\[4pt] & & \vdots \\[4pt] & & r_{A_{2^{n-1}}} \end{array} \end{equation*}

The condition that suffices higher network robustness is that each time the capital levels $c_i$ of each bank should surpass by 1 the elements of the chain. To decide upon the optimal strategy, that will provide such a robustness, the minimum capital raise each time for $c_i$ should be as least as the value of the next chain element in order and a bit more. In other words, if $r_{A_j} \lt c_i \le r_{A_{j+1}}$ then the new capital level $c_i^* = r_{A_{j+1}} + \epsilon$ for $\epsilon$ relatively small.

Step 3: The next step is the new Boolean graph of the network to be created and the new values of the indicators that measure network’s resilience or robustness to be computed.

Step 4: The previous steps create actually a map which assigns to every possible combination of (discrete) capital raise the contagion graph of the network and the values of the indicators after the capital raise has been realized. Therefore, a pivot table can be created with all possible scenarios and indicators, in which the supervisors could allocate the optimal solution according to their needs.

8.1 The Lattice structure on the set of contagion graphs

For the interbank network of the example, there are totally $2^3=8$ contagion graphs corresponding to all possible combinations of capital raise of the banks. We denote this graphs by $G_\delta$ where $\delta = (\delta _1, \delta _2, \delta _3) \in \{0,1\}^3$ . Thus, $\delta _i=1$ means that the capital of the bank $i$ increases. According to the results of Section 6, if $\delta \le \delta '$ (in the pointwise sense) then the set $\textrm{Fix}(G_\delta )$ of fixed points of $G_\delta$ is contained in the set $ \textrm{Fix}(G_\delta ')$ .

The set $\mathfrak{G}$ of all contagion graphs inherits the partial order:

\begin{equation*}G_\delta \le _{\mathfrak{G}} G_{\delta '} \Leftrightarrow \textrm{Fix}(G_\delta ) \subseteq \textrm{Fix}(G_{\delta '}).\end{equation*}

This set becomes a lattice isomorphic to the lattice $\mathcal{L}=\{0,1\}^3$ . This lattice is depicted in Figure 4.

Figure 4. The lattice of contagion graphs.

9.1 Formulation in terms of Operational Research

The mathematical model describing the interbank market has been extensively analyzed in previous sections. Hence, we can now proceed with the formulation in terms of Operational Research. To be more specific, we consider the problem described in Section 7.2. Therefore, we assume that a predefined capital raise has been agreed, and the objective is to find out how this new capital should be delivered between the banks of the market. The problem has the parameters shown in Table 1.

Furthermore, the variables of the problem are as follows:

\begin{equation*}IC_i \,\, : \,\, \text { new (increased) capitals at bank i}\end{equation*}

\begin{equation*}T_{s,i,j} = \left \{ \begin{array}{l@{\quad}l} 1, & \hbox {if bank i defaults because of bank j at stage s of the process;} \\[5pt] 0, & \hbox {otherwise.} \end{array} \right .\end{equation*}

The objective of the proposed model is to determine optimal values for the new capitals $IC_i$ such that the contagion effects are minimized. The model is formulated as follows:

\begin{equation*}\textrm{minimize }\,\, Z= \frac {\sum _i [(C_i+IC_i) \cdot \sum _{j} T_{N,i,j}]}{\sum _i (C_i+IC_i)},\end{equation*}

subject to:

(9.1) \begin{align} T_{s,i,j} &= 1 & \text{for all } s,i,j \text{ with } i=j \end{align}

(9.2) \begin{align} T_{1,i,j} &\ge \frac{E_{ij}-(C_i+IC_i)}{\sum _{k,l}E_{kl}} +\epsilon & \text{for all } i,j \text{ with } i\ne j \end{align}

(9.3) \begin{align} T_{1,i,j} &\le 1+\frac{E_{ij}-(C_i+IC_i)}{\sum _{k,l}E_{kl}} & \text{for all } i,j \text{ with } i\ne j \end{align}

(9.4) \begin{align} T_{s,i,j} &\ge \frac{\sum _k T_{(s-1),k,j}\cdot E_{ik}-(C_i+IC_i)}{\sum _{k,l}E_{kl}} +\epsilon & \text{for all } s,i,j \text{ with } s\gt 1 \text{ and }i\ne j \end{align}

(9.5) \begin{align} T_{s,i,j} &\le 1+\frac{\sum _k T_{(s-1),k,j}\cdot E_{ik}-(C_i+IC_i)}{\sum _{k,l}E_{kl}} & \text{for all } s,i,j \text{ with } s\gt 1 \text{ and }i\ne j \end{align}

(9.6) \begin{align} \sum _i IC_i & \le R & \end{align}

(9.7) \begin{align} IC_i &\ge 0 & \text{ for all } i \end{align}

(9.8) \begin{align} T_{s,i,j} & \in \{0,1\} & \text{ for all } s,i,j \end{align}

The objective function expresses the index of lost capitals, initial and new ones, due to the failure of banks and the possible contagion effects throughout the whole network.

Table 1. Parameters of the problem

Constraints (9.1) ensure that at each stage $s$ of the default process, the elements along the main diagonal of the matrix $T_{s,i,j}$ are equal to $1$ , reflecting the default of bank i. Constraints (9.2) stipulate that at the initial stage of the default process, when the exposure of bank i to bank j exceeds the capitals available at bank i, then the variable $T_{1,i,j}$ is equal to 1, indicating that bank i also defaults as a result of the failure of bank j. Note that $0\lt \epsilon \ll 1$ is a small positive number. More specifically, when $E_{ij}\ge C_i+IC_i$ , then $T_{1,i,j}\gt 0$ , which forces $T_{1,i,j}=1$ . On the other hand, constraints (9.3) ensure that when the total capitals of bank i are sufficient to cover its loans to j, namely when $E_{ij}\lt C_i+IC_i$ , then $T_{1,i,j}\le f\lt 1$ , which forces $T_{1,i,j}=0$ . Similarly, constraints (9.4) and (9.5) determine the values of variables $T_{s,i,j}$ for $i\ne j$ at each stage $s$ of the process, taking into account all banks that may have defaulted at stage $s-1$ . Hence, constraints (9.2) to (9.5) describe the contagion effects throughout the network due to possible defaults. Constraint (9.6) expresses the restriction in the availability of new capitals to support the network. Finally, constraints (9.7) and (9.8) express the nature of the variables.

The model is a MINLP model due to the objective function. It was implemented within the AIMMS modeling platform which is essentially a programming environment for developing and solving optimization problems under constraints. The model is solved using the standard Outer Approximation Algorithm (OAA), introduced by Duran and Grossman (Reference Duran and Grossmann1986), which is available within AIMMS (2023).

9.2 Computational experiments

The model was tested on a series of randomly generated instances with 20 or 80 banks in the system. The values of the loans $E_{ij}$ were generated such that the total loans issued by each bank sum up to twice its initial capitals with a standard deviation of 10%. The number of loans issued by each bank was also randomly selected such that the density of the whole table is around 10%. Finally, the values of a randomly generated set of loans were artificially increased to ensure that contagion effects are created in the system.

Concerning the available new capitals for supporting the system (parameter $R$ ), we experimented with different values ranging from $10\%$ down to $3\%$ of the value D = SL-SC, where SL is the sum of loans issued by all the banks in the system and SC the sum of their initial capitals.

We applied the OA Algorithm in its default settings, with a maximum of 10 iterations. At this stage, we did not experiment with different settings of the OAA parameters such as different multi-start strategies or penalty functions, since our objective was to investigate whether the proposed approach can be used to model contagion effects in realistic bank networks. In all instances, the OA Algorithm was able to converge to solutions that kept the contagion effects under control given the restricted availability of new capitals.

Indicatively, in Table B1 of Appendix B we present the solutions given by the algorithm in a randomly generated instance with 80 banks. Columns (2) and (3) of the table show the initial capital and the total loans issued by each bank, respectively. Columns (4)–(6) show the allocation of new capitals in the system to alleviate contagion under the three scenarios mentioned earlier.

These results indicate that the banks that should be supported by the increased capital are primarily the ones having relatively small initial capitals and whose total loans are more than twice the level of these initial capitals. On the other hand, banks with sufficiently large initial capitals do not seem to be requiring assistance even when they have large total loans that are distributed over many other banks. These results make sense from a practical point of view and further support the validity of the model and its applicability in realistic situations.