1. Introduction and setting
In recent decades we have seen a tremendous increase in demand for data exchange on a global scale, creating significant pressure on network operators to maintain a good quality of service. One particularly interesting concept in this development is device-to-device (D2D) communications. The idea is that network components can exchange data in a peer-to-peer fashion over a wireless channel and thereby constitute a decentralized ad hoc network. Among the many potential benefits of these networks, such as robustness, communication speed, cost efficiency, etc., one of the key challenges is their high complexity and unpredictability.
In order to cope with these challenges, since the early 1960s probabilistic modeling and analysis has been developed and employed to provide qualitative and quantitative insights for D2D networks; see, for example, [Reference Baccelli and Błaszczyszyn2, Reference Baccelli and Błaszczyszyn3, Reference Franceschetti and Meester16, Reference Haenggi20] and many more. In this context, one of the most fruitful approaches is based on stochastic geometry, where network components are conceived as point processes in space [Reference Błaszczyszyn, Haenggi, Keeler and Mukherjee10, Reference Jahnel and König26]. Such a random point cloud is then often seen as the vertex set of a random spatial graph in which edges are drawn according to some rule that reflects the peer-to-peer communication paradigm. In its purest form this is the classical Poisson–Gilbert graph [Reference Gilbert18], which serves as a prototypical model for the spatial clustering behavior of a D2D network in a non-dynamical setting. In particular, we can already observe in this model the celebrated phase transition of percolation in the following sense. Let $\lambda\gt 0$ be the intensity of the underlying homogeneous Poisson point process X, and $r\gt 0$ the connectivity threshold, i.e. the Poisson–Gilbert graph has vertex set X and any pair of vertices is connected by an edge if and only if their Euclidean distance is less than r. Then, there exists a finite and positive $\lambda_{\rm c}=\lambda_{\rm c}(r)$ such that for $\lambda\gt \lambda_{\rm c}$ the graph does not contain any infinite connected component almost surely, and for $\lambda\gt \lambda_{\rm c}$ such an infinite connected component exists with probability 1. In the context of D2D networks, the parameter regime in which an infinite component exists, the so-called percolation regime, is a regime in which data can in principle be transmitted over long (infinite) distances via multiple hops.
In the past 60 years since the first proof of continuum percolation in the Poisson–Gilbert graph, this field has expanded tremendously and the presence as well as absence of percolation has been established in a great variety of static spatial models that extend the classical setting in various ways. Keeping the application area of D2D communication systems in mind, we highlight percolation results in so-called signal-to-interference-to-noise-ratio graphs [Reference Dousse, Franceschetti, Macris, Meester and Thiran14, Reference Jahnel and Tóbiás28, Reference Tóbiás40] (SINR graphs), where the existence of an edge not only depends on the mutual distance but also on the density of other devices in the vicinity. Notably, in SINR graphs we can observe an in-and-out of percolation in the intensity parameter, since for large intensities the interference reduces the connectivity. On the other hand, let us mention Cox-percolation results [Reference Hirsch, Jahnel and Cali24, Reference Hirsch, Jahnel and Muirhead25, Reference Jahnel, Tóbiás and Cali29], where the underlying point cloud is a Poisson point process with a random intensity measure that can, for example, be used to model urban environments such as street systems. Going further in this direction, in [Reference Cali, Hinsen, Jahnel and Wary11] sub- and supercritical regimes of percolation are established in a static spatial random graph model where the edge-drawing mechanism is designed to reflect realistic features of a connectivity network of moving devices in an urban environment. In brief, any pair of devices given by a Cox point process in which the environment is a planar random segment process is connected by an edge if and only if, on their path through the environment, they spend enough time on the same segment in sufficiently close proximity. A variety of phase transitions in the different parameters can be observed, where again the speed parameter for the device movement, in certain settings, features an in-and-out of percolation.
Going beyond the setting of static random graphs and their percolation behavior, the next natural step is to investigate data transmission on random graphs. Here, the starting point is to consider growth processes in which a message is present at an initial time at some (typical) vertex and then crosses the edges of the graph according to some passage times. This is the setting of first-passage percolation (FPP) [Reference Auffinger, Damron and Hanson1, Reference Kesten30] and results often concern the speed of the data transmission over large (Euclidean) distances and the associated (asymptotic) shape of the set of vertices that have received the message up to some fixed time. In [Reference Coletti, de Lima, Hinsen, Jahnel and Valesin12], such a shape theorem is presented for FPP on the supercritical Poisson–Gilbert graph. Conceiving the message as some infection, these growth models are often presented in the context of spatial probabilistic epidemiology, and then it is natural to generalize the pure growth process of FPP to processes in which infected devices can also spontaneously heal (or messages can be dropped), giving rise to contact processes on random graphs [Reference Liggett32, Reference Liggett33]. In this setting the main concern usually becomes showing the survival and extinction of the infection, and results are also available for contact processes on random graphs in the continuum [Reference Bhamidi, Nam, Nguyen and Sly9, Reference Ménard and Singh35, Reference Nguyen and Sly36]. In the context of D2D networks, however, another antagonist of the pure growth mechanism is important. Regarding the infection as some malware, there can be special devices in the network that have the property of removing the malware from infected devices, but are otherwise indistinguishable from the infected or susceptible devices. This gives rise to chase–escape processes [Reference Beckman, Cook, Eikmeier, Hernandez-Torres and Junge4, Reference Bernstein, Hamblen, Junge and Reeves7, Reference Durrett, Junge and Tang15, Reference Hernandez-Torres, Junge, Ray and Ray21, Reference Tang, Kordzakhia and Lalley39] in which malware is transmitted from infected to susceptible devices and infected devices are patched. Again, the main results are concerned with exhibiting regimes of survival and extinction of the malware in the system, and such regimes have also been established in the continuum [Reference Hinsen, Jahnel, Cali and Wary22, Reference Hinsen, Jahnel, Cali and Wary23].
We present two sets of results for chase–escape dynamics on supercritical percolation models in the continuum. In the first set of results we use the construction of [Reference Cali, Hinsen, Jahnel and Wary11], as mentioned above, and consider a system of moving particles in an environment of line segments in $\mathbb{R}^2$ . However, we now go substantially beyond the setup in [Reference Cali, Hinsen, Jahnel and Wary11] and not only consider the resulting connectivity graph but introduce a chase–escape dynamics that respects the mobility and connectivity behavior of the network components; see Section 1.1 for further discussions. Controlling the long-range dependencies, we prove results on survival and extinction of malware in certain parameter regimes, and in particular again feature a phenomenon of in-and-out of survival with respect to the speed parameter. In the second set of results we complement these findings and present similar results in hybrid models in which the infection and patching processes are defined as an independent process on top of the (static) percolation model from [Reference Cali, Hinsen, Jahnel and Wary11].
The paper is organized as follows. In the remainder of this section we reproduce and extend our connectivity model from [Reference Cali, Hinsen, Jahnel and Wary11], starting with a dedicated comparison in Section 1.1. In Section 1.2 we construct a random street system as the first network layer via a stationary segment process that features decaying spatial correlations in the sense of stabilization plus good connectivity properties, and give examples. In Section 1.3, we place devices on the streets and describe the system of initial device positions. We then introduce the paradigmatic mobility model for the devices given by the random waypoint model, where devices individually pick a destination and velocity and commute back and forth on the shortest route on the street system. We also give the example of a uniformly chosen destination in a ball. Next, in Section 1.4, we establish our notion of connectivity where devices have to spend a sufficient amount of time in close proximity on the same street. Under these definitions, in Section 1.5 we establish the property of local connectedness in the sense that almost surely all devices have a finite degree. This concludes the construction of the connectivity network. Further, in Section 2 we introduce the chase–escape dynamics as a model for the spread of infections in the presence of a decentralized countermeasure respecting the dynamics in the connectivity model. For this system we exhibit our main results for global survival and absence of global survival of the malware, plus a statement on the in-and-out of survival with respect to the velocity parameter. Next, Section 3 features a hybrid model where the chase–escape dynamics is defined as an independent process on the connectivity graph, and we present statements about global survival and absence of global survival under a variety of parameter regimes. Finally, in Section 4 we present the proofs.
1.1. Percolation and chase escape
Percolation analysis, in the context of random graphs modeling communication systems, can be considered a first and fundamental step towards an understanding of the possibility of transmitting data over long distances in a multi-hop fashion. In that sense [Reference Cali, Hinsen, Jahnel and Wary11] provides initial statements for the absence and presence of percolation in a simplified version of the model presented in this manuscript. Let us highlight that in [Reference Cali, Hinsen, Jahnel and Wary11] only a static graph is analyzed, where, however, the edge-drawing mechanism is based on the underlying dynamic system that we pick up here as well. The first generalization of the model presented here is that we use random transition times, independent and identically distributed (i.i.d.) for each pair of devices, instead of a globally fixed transition time, reflecting fluctuation in the individual pair-connectivity. The key innovation, however, is that we now introduce a second type of device with patching capability and that we now trace the set of susceptible, infected, and patched devices over time in a non-trivial manner, leading to notions of local and global survival of the infection. Interestingly, also in the presence of the chase–escape dynamics, some of the phase transitions in the percolation analysis in [Reference Cali, Hinsen, Jahnel and Wary11] have a reincarnation in terms of transition of global survival and extinction, most noteworthy with respect to the velocity parameter.
On the technical side, the refined dynamical analysis makes it necessary to impose certain stronger conditions on the connectivity graph, such as exponential moments or reachability properties of the street system as well as the waypoint kernel, and to provide corresponding non-trivial proofs for the implied local connectedness and large-time connectedness results. Here, the large-time connectedness is the crucial ingredient for the proofs for global survival, which also leverage discretization and comparison arguments for the local percolation of areas that support the spread of the infection, already partially present in [Reference Cali, Hinsen, Jahnel and Wary11]. On the other hand, the local connectedness is crucial for the proofs of absence of global survival, which leverage multiscale arguments first presented in the context of the heavy-tailed Boolean model in [Reference Gouéré19]. The main innovations of the arguments presented in this manuscript are due to the incorporation of the mentioned random transition times between pairs of devices in the context of geostatistical markings. Finally, let us mention that our arguments for survival of the infection in the setting of chase–escape on the connectivity graph are entirely new.
1.2. Street systems
As a first layer of the system, we consider a stationary random planar segment process $S=\bigcup_{i\in I} \{S_i\}\subset \mathbb{R}^2$ where each $S_i$ is a line segment in $\mathbb{R}^2$ of finite length. We say that a process is stationary if its distribution is translation invariant. The line segments may intersect, and we call each maximal unintersected interval in S a street. The endpoints of each street are called crossings (even if they are dead-ends). In order to have something specific in mind, S can be, for example, some planar tessellation process like the Poisson–Voronoi tessellation (PVT) or the Poisson–Delaunay tessellation (PDT); see Figure 1 for an illustration.
We think of S as an urban street system and note that, for example, the PVT indeed shares some common characteristics with medieval city topologies; see [Reference Courtat13].
In order to control spatial dependencies in S, we will almost exclusively work with systems that satisfy a quantitative mixing property called stabilization [Reference Lee31, Reference Penrose and Yukich37, Reference Penrose and Yukich38]. Additionally, we will assume that the system is connected in large regions with high probability and call this asymptotic essential connectedness [Reference Hirsch, Jahnel and Cali24, Reference Jahnel, Tóbiás and Cali29]. More precisely, let us define the square with side length $n\ge1$ centered at $x \in \mathbb{R}^2$ by $Q_n(x) = x + [\!-n/2, n/2]^2$ , abbreviate $Q_n = Q_n(o)$ , and denote by $\textrm{Sdist}(\varphi, \psi) = \inf\{|x-y|\colon x\in\varphi, y\in\psi\}$ the distance between sets $\varphi, \psi\subset\mathbb{R}^2$ .
Definition 1. (Stabilization and asymptotic essential connectedness.) A stationary random segment process S is called stabilizing if there exists a random field of stabilization radii $R = \{R_x\}_{x\in\mathbb{R}^2}$ that is measurable with respect to S, and (S, R) is jointly stationary. Moreover, for $R(Q_n)=\sup_{y\in Q_n \cap\, \mathbb{Q}^2}R_y$ we have $\lim_{n\uparrow\infty}\mathbb{P}(R(Q_n) \lt n) = 1$ and, for all $n \ge 1$ , the random variables $\big\{f(S\cap Q_n(x))\textbf{1}\{R(Q_n(x)) \lt n\}\big\}_{x \in \varphi}$ are independent for all non-negative bounded measurable functions f and finite $\varphi \subset \mathbb{R}^2$ with $\textrm{Sdist}(x, \varphi \setminus \{x\}) \gt 3n$ for all $x \in \varphi$ . Furthermore, S is called asymptotically essentially connected if it is stabilizing and, for all sufficiently large $n \ge 1$ , whenever $R(Q_{2n})\lt n/2$ , we have $|S\cap Q_n|\gt 0$ and $S\cap Q_n$ is contained in one of the connected components of $S\cap Q_{2n}$ . Here, $|\cdot|$ represents the total edge length, i.e. the one-dimensional Hausdorff measure.
We note that PVTs and PDTs are stabilizing [Reference Hirsch, Jahnel and Cali24] but Manhattan grids or (rectangular) Poisson-line tessellations are not stabilizing.
Finally, in what follows we will always assume that the expected number of streets and the expected number of crossings in the unit square is finite, and that the intensity of the street system is normalized, i.e. $\mathbb{E}[|S\cap Q_{1}|]=1$ .
1.3. Mobile devices
As a second layer of our model we represent initial positions of devices via Cox point processes $X^\lambda = \{X_i\}_{i\ge1}$ . That is, $X^\lambda$ is a Poisson point process with a random intensity measure $\Lambda_{S}(A) = \lambda |S\cap A|$ , $A\subset \mathbb{R}^2$ measurable, where $\lambda\ge 0$ is a parameter that represents the expected number of devices per unit of street length; see Figure 2. Note that if S is stationary, so is $X^\lambda$ .
Having defined the initial positions of the devices via a Cox point process on the street system, we now introduce the random waypoint model as our destination-driven mobility scheme. Each device independently picks its destination and commutes back and forth on a shortest path.
We start by considering the probability kernel $\kappa^S(x, {\rm d} y)$ , $x\in S$ , as a probability measure on S, and assume that the support of $\kappa^S(x,{\textrm d} y)$ , defined via
is contained in S for any $x\in S$ , where $B_\varepsilon(y)$ denotes the disk with radius $\varepsilon\gt 0$ centered on y. We say that $\kappa$ has (uniformly) bounded support if there exists $K\gt 0$ such that $|{\textrm{supp}}(\kappa^S(x,{\textrm d} y))|\lt K$ for almost all S. Moreover, we will always assume that $\kappa$ is translation covariant, i.e. $\kappa^S(x,A)=\kappa^{S-x}(o,A-x)$ for almost all S, measurable $A\subset \mathbb{R}^2$ , and $x\in \mathbb{R}^2$ . The kernel $\kappa^S(x,{\textrm d} y)$ serves as a waypoint kernel [Reference Bettstetter, Hartenstein and Pérez-Costa8]. Furthermore, we require that the kernel is finitely dependent, i.e. that there is a constant $H\gt 0$ such that, for almost all S and $x\in S$ , $\kappa^S(x,{\textrm d} y)=\kappa^{S^{\prime}}(x,{\textrm d} y)$ for all $S^{\prime}$ with $S\cap B_H(x)=S^{\prime}\cap B_H(x)$ .
It will become useful to consider waypoint kernels that allow for very small displacements. In order to formalize this, we call the kernel c-well-behaved if $B_c(x) \cap S \subset \text{supp}(\kappa^S(x, {\textrm d} y))$ for almost all S, $ x\in S$ , where $\kappa^S(x,y)$ is the density, and say that it is well-behaved if it is c-well-behaved for some $c \gt 0$ . An example that fulfills all those conditions is given by
the uniform distribution on $S\cap B_L(x)$ for some $L\gt 0$ ; see also [Reference Cali, Hinsen, Jahnel and Wary11].
Then, each device $X_i\in X^\lambda$ independently picks a target location $Y_i\in S$ according to $\kappa^S(X_i,{\textrm d} y)$ . Further, we equip each device $X_i\in X^\lambda$ with an i.i.d. velocity $V_i$ , drawn from the distribution $\mu$ , for which we assume that $0\lt v_{\rm min}\le v_{\rm max}\lt\infty$ , where $v_{\rm min}\,:\!=\sup\{v\colon \mu([v,\infty))=1$ and $ v_{\rm max}\,:\!=\inf\{v\colon \mu([0,v])=1\}$ . Then, the path of the device $X_i$ is defined iteratively as follows. $X_i$ moves with speed $V_i$ to $Y_i$ along the shortest route in S that connects $X_i$ and $Y_i$ . If there are multiple shortest routes, the device chooses one such route independently and uniformly at random. It then immediately returns to its starting position with the same velocity along the same shortest path. This procedure is then repeated indefinitely; see Figure 3 for an illustration.
1.4. Connectivity of mobile devices
By a slight abuse of notation, we also denote by $X_i=(X_{i,t})_{t\ge 0}$ the trajectory of device $X_i$ in S. For any pair of devices $X_i$ and $X_j$ , we then consider the set of contact times
as the times where the devices are on the same street and r-close together, where $r\gt 0$ is another parameter in the model, the connectivity threshold. Let us note that the constraint that contact times require the devices to be on the same street can be seen as a very strict shadowing assumption [Reference Gall, Błaszczyszyn, Cali and En-Najjary17].
Next, we assume that any pair of devices $X_i$ and $X_j$ has an i.i.d. infection time $\rho(X_i,X_j)$ , drawn from the distribution $\varrho$ on $(0,\infty)$ . Then, we say that a transmission from $X_i$ to $X_j$ is possible at time $t\ge 0$ if $[t-\rho(X_i,X_j),t]\subset Z(X_i,X_j)$ ; see Figure 4 for an illustration of the resulting space–time connectivity network.
Let us note that the introduction of random transition times is a substantial generalization compared to the setup in [Reference Cali, Hinsen, Jahnel and Wary11], where only the case $\varrho=\delta_\rho$ is considered for some fixed $\rho\ge0$ .
1.5. Degree of devices
In order to avoid scenarios in which a single device can transmit to infinitely many devices in the infinite time horizon that we consider, let us finally introduce a convenient condition for the local connectedness of the connectivity graph. For this, let $\ell_S(x,y)\subset \mathbb{R}^2$ be the shortest path between x and y on S, and write
for the length of the shortest path starting in x towards any reachable target on S plus half the connectivity range. Then, consider the following Cox–Boolean model with geostatistical markings in which $X_i,X_j\in X^\lambda$ are connected whenever $|X_i-X_j|\le \ell_S(X_i)+\ell_S(X_j)$ , and note that this can be seen as a Boolean model in which the (random) disks associated to each Cox point depend on the underlying environment S. In particular, if $X_i$ can transmit to $X_j$ , there also exists an (undirected) edge between $X_i$ and $X_j$ in the Cox–Boolean model with geostatistical markings. Using this, for $X_i\in X^\lambda$ , we define its degree,
which serves as an upper bound for the degree of $X_i$ in the original model. Now, we call the model locally connected if
and we will always assume that our system is locally connected. Let us also mention that, in order to ease notation, we use generic symbols $\mathbb{P}$ and $\mathbb{E}$ for the distribution and expectation of our model, even under changing parameters.
The following proposition establishes a condition under which the network is locally connected.
Proposition 1. (Local connectedness.) If $\kappa$ has bounded support, S is exponentially stabilizing, and $|S\cap Q_1|$ has exponential moments, then the network is locally connected.
The proof rests on a contradiction that follows from a first-moment method for the expected degree of a typical point using the good control on stabilization and moment properties of the street system. We present the details in Section 4.1. Let us note that the conditions are satisfied for our standard examples for street systems given by PVT and PDT, since they are exponentially stabilizing [Reference Hirsch, Jahnel and Cali24] and have exponential moments; see [Reference Jahnel and Tóbiás27]. Also, as can be seen from the proof, the moment condition can be substantially relaxed.
Having now defined our system of moving devices in an urban street system and their connectivity relations, in the following section we introduce malware into the network that propagates like an infection starting from a single typical device.
2. Chase–escape on the dynamic graph
In the final model layer we introduce an infection into the system, which is carried by one device $X_o$ that is chosen at random and will be referred to in the sequel as the typical device. The remaining devices are, at time zero, susceptible to the infection. As a counter measure we introduce an independent (Cox) point process of so-called white knights, which is, at time zero, a homogeneous Poisson point process $Y^{{\lambda_{\rm W}}}$ with linear intensity ${\lambda_{\rm W}}\ge 0$ conditioned on S and following the same mobility scheme as devices in $X^\lambda$ . From a modeling perspective, we are guided here by the idea that white knights are also regular devices and their general behavior is indistinguishable from other devices. However, white knights are not susceptible to the infection. Moreover, each white knight carries patching software that allows it to remove the infection from any device that wants to infect it with malware and update the defensive mechanism on the attacking device. Additionally to purging the infection, the attacking device obtains all the capabilities of a white knight. Let us highlight that although there is no interaction between susceptible devices and white knights, their mere presence offers additional protection in the case of an infection.
Moreover, the process of susceptible devices is decreasing and the process of white knights is increasing, while the process of infected devices is non-monotone. More formally, let us introduce the Palm version of susceptible devices via
for bounded, measurable test functions f, and note that under $\mathbb{P}^*$ there exists a device at the origin with probability 1. We call this the typical device $X_o$ and assume that it is infected at time zero.
In order to describe the infection and patching mechanism, instead of a single infection time distribution $\varrho$ , we consider two distributions $\varrho_{\rm I}$ , respectively $\varrho_{\rm W}$ , for the infection times, respectively the patching times, and assume that they both have a density with respect to the Lebesgue measure on $(0,\infty)$ . We denote by
the minimal infection time, and analogously by ${\varrho_{\rm W,min}}$ the minimal patching time. Now, the infection will be transmitted from an infected device $X_i$ to a susceptible device $X_j$ after completion of the first infection time ${\rho_{\rm I}}(X_i,X_j)$ , drawn from $\varrho_{\rm I}$ . Analogously, the patch will be transmitted from a white knight device $X_i$ to an infected device $X_j$ after completion of the first infection time ${\rho_{\rm W}}(X_i,X_j)$ , drawn from $\varrho_{\rm W}$ . In order to formalize the whole process, let $S_t$ , $I_t$ , and $W_t$ denote the sets of susceptible, infected, and white knight devices at time $t\ge 0$ , where $S_0=X^\lambda\setminus X_o$ , $I_0=X_o$ , and $W_0=Y^{{\lambda_{\rm W}}}$ . In particular, $\big((I_s)_{0\le s\lt t},(W_s)_{0\le s\lt t}\big)$ fully describes the state of the system up to time t. Then, at time t, we add new infected devices,
and then add also new white knights,
With this construction the process is well-defined since $\varrho_{\rm I}$ and $\varrho_{\rm W}$ put no mass on zero and the number of devices that are infected is finite for any finite time by the local connectedness condition. Note that we have indirectly implemented a tie-breaker rule that favors the infection. This can be seen by considering a situation where a device $X_j$ becomes a white knight at time t; however, it can still finish a transmission of the infection at time t. We present a realization of the chase–escape dynamics in Figure 5.
We say that the infection survives locally if $|I_t|\gt 0$ for all $t\ge 0$ , it survives globally if $|I_t|\gt 0$ for all $t\ge 0$ and $\big|\bigcup_{t \ge 0} I_t\big|=\infty$ , and the infection goes extinct if $|I_t|=0$ for some $t\ge 0$ . Note that, even if the street system is connected with positive probability, there can be isolated sets of devices that are not able to form connections to the rest of the devices. If the typical device $X_o$ is contained in such a cluster and the cluster contains no white knight, the infection survives indefinitely, but no global outbreak can be observed.
Our goal is to isolate regimes of global survival and extinction of the infection using the transmission mechanism we just described. Let us start with regimes that ensure global survival of the infection even in the presence of white knights. For this, we guarantee the existence of a sequence of streets on which the infection can be transmitted to infinity with positive probability.
Note that, due to the transmission mechanism, streets need a certain minimal length in order to be useful for transmissions. We thus define a thinned system $S^a=\{s\in S \colon |s|\ge a\}$ that only contains streets of length greater or equal than $a\ge 0$ . Let us further denote by $R^a_x$ the distance of the furthest point from $x\in \mathbb{R}^2$ that is reachable without crossing $S^a$ , i.e. we define the cell of x by
and define $R^a_x=\sup\{|y-x|\colon y \in C^a_x\}$ . We say that the thinned graph is $R^a$ -connected if $\lim_{n\uparrow \infty}\mathbb{P}\big(\sup_{x \in Q_n\cap \mathbb{Q}^2}R^a_x\lt n\big) =1$ , and define
In words, for $a\lt a_{\rm c}$ the thinned street system satisfies a slightly stronger version of asymptotically essentially connectedness, and we have some control over the cell sizes. Note that $a_{\rm c}\gt 0$ for asymptotically connected street systems; see [Reference Cali, Hinsen, Jahnel and Wary11, Theorem 2.8].
In order to exhibit a regime of global survival, we will furthermore require a slightly stronger version of well-behavedness. We say that a kernel $\kappa$ is c-continuous if, for almost-all S and $x\in S$ , the uniquely defined absolutely continuous part of $\kappa^S(x,{\textrm d} y)$ is non-trivial and its density $\kappa^S(x,y)$ with respect to the Lebesgue measure on S satisfies $\inf_{y \in B_c(x)}\kappa^S(x,y)\gt 0$ . Note that c-continuous implies c-well-behaved.
Using these definitions, we can state our first main result on global survival of the infection.
Theorem 1. (Global survival.) Let $\kappa$ be c-continuous for some $c\gt 0$ and ${\varrho_{\rm W,min}}\gt{\varrho_{\rm I,min}}\gt 0$ . Then, for all sufficiently small $v_{\textrm{min}}$ such that $\min(a_{\rm c}/2,r,c/2)\gt v_{\textrm{min}} {\varrho_{\rm I,min}} \gt 0$ , there exists $\lambda_{\textrm c}$ such that, for all $\lambda\gt \lambda_{\textrm c}$ and all ${\lambda_{\rm W}}\ge 0$ , $\mathbb{P}(\textit{infection survives globally})\gt 0$ .
The punchline of the preceding statement is the fact that the critical device intensity is independent of the white knight intensity. In other words, no matter how densely we can pack white knights into the system, survival is guaranteed as long as we have sufficiently many devices in the system. Roughly, the reason for this phenomenon is that the white knights simply act too slowly since ${\varrho_{\rm W,min}}\gt{\varrho_{\rm I,min}}\gt 0$ when there are sufficiently many devices that can transmit the infection to their neighbors before white knights are able to eliminate it. The idea of the proof is to establish an infinite cluster of good streets that have the property that, if the malware enters the street on one side, it must also exit the street on the other side. We present the details in Section 4.2.
Next, we present our result on the extinction of the infection in infinite components.
Theorem 2. (Extinction.) Consider a street system given by a Poisson–Voronoi or Poisson–Delaunay tessellation. Let $\kappa$ be well-behaved with bounded support, and assume that $r\gt v_{\textrm{max}}{\varrho_{\rm W,min}}$ and ${\varrho_{\rm I,min}}\gt{\varrho_{\rm W,min}}\gt 0$ . Then, for all $\lambda\ge 0$ , there exists ${\lambda_{\rm W,c}}$ such that, for all ${\lambda_{\rm W}}\gt{\lambda_{\rm W,c}}$ , $\mathbb{P}(\textit{infection survives globally})=0$ .
The proof rests on a multi-scale argument and will be given in Section 4.3.
Finally, we present a result that features the remarkable non-monotone behavior of our model with respect to the speed parameter. More precisely, the following result states that both too-high and too-low velocities are detrimental to the propagation of the infection. We state the result only for fixed velocities and infection and patch times, and note that a corresponding result for general $\mu_{\rm v}$ , $\varrho_{\rm I}$ , and $\varrho_{\rm W}$ also holds.
Theorem 3. (Speed-dependent survival and extinction.) Consider a street system given by a Poisson–Voronoi or Poisson–Delaunay tessellation. Let $\kappa$ have bounded support and be c-well-behaved for some $c\gt 0$ . Assume further that $\varrho_{\rm W}=\delta_{\rho_{\rm W}}$ and $\varrho_{\rm I}=\delta_{{\rho_{\rm I}}}$ with $\rho_{\rm W}\gt{\rho_{\rm I}}$ , and let $0\lt v_o\lt \min(a_{\rm c}/2,r,c/2)/{\rho_{\rm I}} $ . Then, there exist $\lambda_{\rm c}\gt 0$ and ${\lambda_{\rm W,c}}\gt 0$ (independent of $\lambda_{\rm c}$ and $v_o$ ) such that, for all $\lambda \gt\lambda_{\rm c}$ and all $\lambda_{\rm W}\gt{\lambda_{\rm W,c}}$ ,
-
(i) there exists $v_o\gt v_{\rm c}(\lambda,\lambda_{\rm W})\gt 0$ such that, for all $\mu=\delta_{v}$ with $v\lt v_{\rm c}(\lambda,\lambda_{\rm W})$ , $\mathbb{P}(\textit{infection survives globally})=0$ ;
-
(ii) for $\mu=\delta_{v_o}$ , $\mathbb{P}(\textit{infection survives globally})\gt 0$ ; and
-
(iii) there exists $\infty\gt v^{\rm c}\gt v_o$ (independent of $\lambda$ and $\lambda_{\rm W}$ ) such that, for all $v\gt v^{\rm c}$ , $\mathbb{P}(\textit{infection survives globally})=0$ .
In words, the choice $\lambda \gt\lambda_{\rm c}$ puts us in a parameter regime in which survival of the infection is possible, as described in Theorem 1. However, in the presence of sufficiently many white knights and sufficiently large or small velocity we are again in regimes of extinction. One important aspect here is that sufficiently small velocities and large white knight intensities also lead to absence of global survival in the case where the infection is faster than the patching. We present the proof in Section 4.4.
3. Chase–escape on the connectivity graph
In Section 2 we exhibited rigorous results for chase–escape on the dynamic graph. One important feature here is that device mobility is intimately linked to the transmission mechanism, both of the infection and the patching, leading to a highly correlated non-Markovian space–time process. As a consequence, it currently seems out of reach to derive approximate values for the various critical parameters predicted by our rigorous analysis in ways other than computer simulations as presented, for example, in [Reference Benomar, Ghribi, Cali, Hinsen and Jahnel5, Reference Benomar, Ghribi, Cali, Hinsen, Jahnel and Wary6]. As it turns out, a major part of the computational effort has to go into simulating the movement of the devices in the environment. In an effort to produce large numbers of sample paths of the chase–escape dynamics it is therefore desirable to uncouple the connectivity graph and the epidemiological process and derive corresponding results in this mean-field type setting. This is our primary goal in this section.
To start, recall the connectivity rule, introduced in Section 1.4, where for every pair of devices $X_i$ , $X_j$ the set of connection times is denoted $Z(X_i,X_j)$ . Now, we want to fix the infection time $\rho \ge 0$ , i.e. assume that $\varrho=\delta_\rho$ and define the connectivity graph $g_{\rho,r}(S,X^\lambda \cup Y^{{\lambda_{\rm W}}})$ , in which any two vertices $X_i, X_j \in X^\lambda\cup Y^{{\lambda_{\rm W}}}$ are connected by an edge if there exists a $t\ge 0$ such that $[t,t+\rho]\subset Z(X_i,X_j)$ . Let us highlight that this connectivity graph is static even though the edge-drawing mechanism is based on an underlying space–time process. The main computational advantage of this connectivity graph lies in the fact that the connections can be determined purely from the device trajectories and speeds without the need to simulate in which connection interval the connection is realized. This avoids the computationally expensive collective movement of the devices.
Now, we consider the chase–escape model as an independent space–time process on realizations of the connectivity graph. This also brings us much closer to the existing literature on chase–escape dynamics on fixed and random graphs; see, for example, [Reference Beckman, Cook, Eikmeier, Hernandez-Torres and Junge4, Reference Bernstein, Hamblen, Junge and Reeves7, Reference Durrett, Junge and Tang15, Reference Hernandez-Torres, Junge, Ray and Ray21–Reference Hinsen, Jahnel, Cali and Wary23, Reference Tang, Kordzakhia and Lalley39], as chase–escape has not been studied on a dynamic graph so far. More precisely, we consider $g_{\rho,r}(S,X^\lambda \cup Y^{{\lambda_{\rm W}}})$ under the Palm distribution with respect to the $X^\lambda$ described in (1) and let $N(X_i)$ denote the set of direct neighbors of vertex $X_i$ . Further, we consider two general transmission-time distributions ${\varrho_{\rm I}}$ and ${\varrho_{\rm W}}$ on $(0,\infty)$ that govern the i.i.d. times ${\rho_{\rm I}}(X_i,X_j)$ , respectively ${\rho_{\rm W}}(X_i,X_j)$ , needed to pass an infection, respectively a patch, from device $X_i$ to $X_j$ . Then, at time zero, the set of infected devices $I_0$ is given by the typical device $X_o$ , which is positioned at the origin $o\in \mathbb{R}^2$ with probability 1, i.e. $I_0=\{X_o\}$ . For the initial set of white knights we have $W_0=Y^{\lambda_{\rm W}}$ . Then, as in Section 2, we define the process iteratively by considering the system $\big((I_s)_{0\le s\lt t},(W_s)_{0\le s\lt t}\big)$ up to time $t\gt 0$ and then defining the newly infected devices at time t by
where $S_s=X^\lambda\setminus I_s$ , and the newly patched devices at time t by
Let us comment on the construction. As mentioned above, the model can be seen as an approximation of chase–escape on the dynamical graph where we associate to every edge an independent random time that represents the time that it takes to transmit the infection. The distribution of this transfer time can be, for example, sampled by considering the transmissions of a typical device towards its neighbors in an independent simulation step. In other words, we insert information about the typical transmission behavior and apply it independently to every edge of the static graph. Let us mention that this approach is not unlike the approach used in [Reference Benomar, Ghribi, Cali, Hinsen, Jahnel and Wary6, Section V], where the spatial graph was replaced by a sequence of edges which had the length distribution of a typical edge in the PVT.
We are again interested in the conditions under which global survival is possible or impossible. Let us start with the preliminary observation in the case where the transmission times are fixed, i.e. ${\varrho_{\rm I}}=\delta_{T_{\rm I}}$ and ${\varrho_{\rm W}}=\delta_{T_{\rm W}}$ for some $T_{\rm W},T_{\rm I}\gt 0$ . In this case, survival and extinction essentially depend on the ordering of $T_{\rm W}$ and $T_{\rm I}$ . We say that the graph $g_{\rho,r}(S,X^\lambda)$ is in the supercritical percolation regime if there is an unbounded connected component, and we note that [Reference Cali, Hinsen, Jahnel and Wary11] exhibits non-trivial criteria that guarantee the existence of a supercritical percolation regime. We first formulate a result for constant transmission times. Extended results with respect to general ${\varrho_{\rm I}}$ and ${\varrho_{\rm W}}$ are presented in Theorems 4, 5, and 6.
Proposition 2. Assume that $g_{\rho,r}(S,X^\lambda)$ is in the supercritical percolation regime. Then,
The proof is based on a robust descending-chain argument that in fact generalizes to arbitrary supercritical graphs, and is presented in Section 4.5.
Let us now present our main results for general ${\varrho_{\rm I}}$ and ${\varrho_{\rm W}}$ . In order to prove global survival of the infection we need to require stronger notions of percolation of the connectivity graph. We present two alternative conditions in Theorems 4 and 5. First, in Theorem 4 we require a parameter regime for the street system and waypoint kernel that guarantee a strongly percolating structure similar to Theorem 1. Recall the definition of $a_{\rm c}$ from (2), and let us denote, for any $b\gt 0$ , by ${\varrho^b_{\rm I}}$ the shifted version of ${\varrho_{\rm I}}$ defined via $\int f(x/b){\varrho^b_{\rm I}}({\textrm d} x)=\int f(x) {\varrho_{\rm I}}({\textrm d} x)$ for all measurable functions with bounded support f.
Theorem 4. (Mean-field survival I.) Let $\kappa$ be c-well-behaved for some $c\gt 0$ , and assume that $v_{\textrm{min}}$ satisfies $0\lt v_{\textrm{min}} \rho \lt \min(a_{\rm c}/2,r,c/2)$ and that ${\varrho_{\rm W,min}}\gt 0$ . Then, there exists $\lambda_{\rm c}\lt\infty$ such that, for all $\lambda \gt\lambda_{\rm c}$ and ${\lambda_{\rm W}}\ge 0$ , there exists $b_{\rm c}\lt\infty$ such that, for ${\varrho^b_{\rm I}}$ with $b\gt b_{\rm c}$ , $\mathbb{P}(\textit{infection survives globally})\gt 0$ .
The proof rests on percolation arguments similar to the ones used for the proof of Theorem 1. The details are presented in Section 4.6.
Next, we present an alternative result for global survival which requires that a subgraph of the connectivity graph is in the supercritical percolation regime. More precisely, we define the random subgraph $g^{M,p}_{\rho,r}(S,X^\lambda)\subset g_{\rho,r}(S,X^\lambda)$ via the following thinning procedure. Let $(\textrm{Ber}_p(X_i))_{X_i \in X^\lambda}$ be an i.i.d. field of Bernoulli random variables with parameter p, and define the vertex set of $g^{M,p}_{\rho,r}(S,X^\lambda)$ by
where $N(X_i)$ denotes the number of neighbors in the graph $g_{\rho,r}(S,X^\lambda, Y^{{\lambda_{\rm W}}})$ that also includes the white knights. In words, vertices with more than M neighbors are eliminated, and additionally each of the remaining vertices is kept independently with probability p. The edge set of $g^{M,p}_{\rho,r}(S,X^\lambda)$ is then inherited from the edge set of $g_{\rho,r}(S,X^\lambda)$ , but only those that connect $X_i,X_j\in V^{M,p}$ . It is not hard to see that
weakly; however, for global observables such as percolation this is non-trivial. We have the following result.
Theorem 5. (Mean-field survival II.) Assume that there exist $M\gt 0$ and $p\gt 0$ such that $g^{M,p}_{\rho,r}(S,X^\lambda)$ is in the supercritical percolation regime. Then, for all ${\lambda_{\rm W}}\ge 0$ , there exists $b_{\rm c}\lt\infty$ such that, for all ${\varrho^b_{\rm I}}$ with $b\gt b_{\rm c}$ , $\mathbb{P}(\textit{infection survives globally})\gt 0$ .
The proof rests on the idea that, for a sufficiently fast infection rate, the process of nodes with maximal degree, which also transmit the infection faster than being patched, is already in the supercritical percolation regime. A motivation for this thinning lies in an application of the SINR: In this connection model, communication is only possible if the incoming signal strength is high enough compared to the total interference. If too many devices are transmitting simultaneously in a small area, communication is not possible due to background noise. We present the details in Section 4.7.
We conclude this section with our result on the absence of global survival.
Theorem 6. (Mean-field extinction.) Consider a street system given by a Poisson–Voronoi or Poisson–Delaunay tessellation and assume that ${\varrho_{\rm I,min}}\gt{\varrho_{\rm W,min}}$ . Then, there exists ${\lambda_{\rm W,c}}\lt\infty$ such that, for all ${\lambda_{\rm W}}\gt{\lambda_{\rm W,c}}$ , $\mathbb{P}(\textit{infection survives globally})=0$ .
The proof is based on the idea that, for a sufficiently large intensity of white knights, any connection between susceptible devices is accompanied by many white knight connections. In this case, it becomes highly unlikely that the infection is passed on before being eliminated by the white knights. In order to make this precise, we have to leverage local independence properties of the propagation model. We present the details in Section 4.8.
4. Proofs
4.1. Proof Proposition 1
Proof Proposition 1. First, let us assume that $\mathbb{P}($ there exists $X_i\in X^\lambda$ such that $\deg (X_i)=\infty)\gt 0$ . Then, by continuity of measures, there exists $R\gt 0$ such that $\mathbb{P}($ there exists $X_i\in X^\lambda\cap Q_{R}$ such that $\deg (X_i)=\infty)\gt 0$ and hence, by translation invariance, also $\mathbb{P}($ there exists $X_i\in X^\lambda\cap Q_1$ such that $\deg\! (X_i)=\infty)\gt 0$ . But the last inequality implies that $\mathbb{E}\big[\sum_{X_i \in X^\lambda \cap Q_1}\deg\!(X_i)\big]= \infty$ . However, in order to derive a contradiction, we can use the Mecke–Slivnyak theorem twice to see that
Next, we bound the maximal reach $\ell_S$ by the street length in a stabilized region. For this, let $K\,:\!= \sup\{|x-y|\colon x\in S, y\in{\textrm{supp}}(\kappa^S(x,{\textrm d} y))\}\lt\infty$ denote the maximal reach of the kernel $\kappa$ , which exists due to the assumption of a uniformly bounded support of $\kappa$ . Using this, we can bound the length of any shortest path starting in $x\in S$ to any $y \in S\cap B_K(x)$ by the total street length of the box in which there is a connection between x and y, due to asymptotic essential connectedness. More precisely, note that if $R(Q_{2n}(x)) \lt n/2$ then $\ell_S(x) \le |S\cap Q_{2n}(x)|+r/2$ , for any $n\gt 2K$ , and we can define
In particular, for all $y \in Q_1(z)$ we have $\ell_S(y) \le |S\cap Q_{2N(z)+1}(z)|+r/2$ , and hence
where we used $|y|\le|z|+ 1/2$ for $y \in Q_1(z)$ in order to eliminate the dependence of the integrals on x and y respectively and thus derive a uniform bound for the integrals. It remains to show that this bound is integrable. By Hölder’s inequality we can bound each summand by
for some constants $C_1,c_1\gt 0$ due to the existence of exponential moments for $|S\cap Q_1|$ as well as the assumption of exponential stabilization. Now, the last factor can be further bounded by Markov’s inequality as
for some constants $C_2,c_2\gt 0$ . Finally, we can use $|z|\gt|z|_{\infty}$ , where $|\cdot|_\infty$ denotes the $\ell_\infty$ -norm, combined with the fact that for $k\in \mathbb{N}_0$ we have $\sum_{z\in Z}\textbf{1}\{|z|_{\infty}=k\} \le 4k+1$ , to see that
and hence the proof is finished.
4.2. Proof of Theorem 1
Proof of Theorem 1. For simplicity we only prove the case where $\mu=\delta_v$ . The general case can be verified using a thinning argument where we ignore all devices that have a speed greater than $v_{\rm min}+\varepsilon$ for an arbitrarily small $\varepsilon$ , only leading to a potentially larger value of $\lambda_{\textrm c}$ .
First note that the assumption that $\kappa$ is translation covariant and c-well-behaved for some $c\gt 2{\varrho_{\rm I,min}} v$ ensures that it is possible for the kernel to generate a shortest path from one street to an adjacent street while spending a sufficient amount of time on both streets to allow an infection to be passed on to another device. Further, the requirement that $r\gt{\varrho_{\rm I,min}} v$ ensures that the communication radius is large enough such that an infection transmission can happen between devices with initial and target locations in the vicinity of the crossing. Also recall that we require that the streets of length larger than $2v{\varrho_{\rm I,min}}$ percolate with positive probability.
Since we assume ${\lambda_{\rm W}}$ to be arbitrary, in spirit, we think of white knights being everywhere. We consider open streets as well as open crossings. Let us start with the streets. Let $0\lt\varepsilon\lt\min\!(r/4 ,v({\varrho_{\rm I,min}} -{\varrho_{\rm W,min}})/2)$ and define $n(s)= \lfloor |s|/(2r)\rfloor$ , which will represent the number of devices on the street s on which the infection will be propagated. We call a street $s=(c_1,c_2)$ open if there are devices $X_0^s, \dots, X_{n(s)}^s$ such that:
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(S1) $|s|\gt v{\varrho_{\rm I,min}}+\varepsilon$ ;
-
(S2) for all t, $X_{i,t}^s \in B_\varepsilon\bigg(c_1+\dfrac{ri}{2}\dfrac{c_2-c_1}{|c_2-c_1|}\bigg)$ for all $i \in \{1,\dots, n(s)\}$ ;
-
(S3) ${\rho_{\rm I}}\big(X_i^s,X_{i+1}^s\big)\lt {\varrho_{\rm W,min}}$ for all $i \in \{1,\dots, n(s)-1\}$ ; and
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(S4) ${\rho_{\rm I}}\big(X_i^s,X_{i-1}^s\big)\lt {\varrho_{\rm W,min}}$ for all $i \in \{2,\dots, n(s)\}$ .
In words, a street is open if, by Condition (S1), the street is long enough that an infection transmission is possible. By Condition (S2), there is a chain of devices reaching from the crossing $c_1$ to the crossing $c_2$ such that each pair of neighboring devices has distance less than r. In particular, if device $X_0^s$ is infected, Condition (S3) ensures that the infection cannot be stopped by white knights as they are too slow and hence the infection propagates from $X_0^s$ to $X^s_{n(s)}$ . Similarly, Condition (S4) ensures that an infection also propagates from $X^s_{n(s)}$ to $X^s_0$ . Let us call $X^s_{c_1}=X^s_1$ and $X^s_{c_2}=X^s_{n(s)}$ the boundary devices of an open street $s=(c_1,c_2)$ .
Next, for a street $s=(c_1,c_2)$ , denote by $[a,b]_{s,c_1}$ the segment
on s such that $\{0\}_{s,c_1}$ is identified with the crossing $c_1$ . Consider again $0\lt\varepsilon\lt\min(r/4 ,v({\varrho_{\rm I,min}} -{\varrho_{\rm W,min}})/2)$ to be small enough that $v_{\textrm{min}} {\varrho_{\rm I,min}} +\varepsilon\lt c/2 $ . We call a crossing c open at time t if, for any ordered pair of open streets $s_1,s_2$ that share the crossing c, there exists a bridging device $X^{s_1,s_2}$ such that:
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(C1) $X_{0}^{s_1,s_2}\in A_{s_1}=[v{\varrho_{\rm I,min}}/2+\varepsilon/2,v{\varrho_{\rm I,min}}/2+\varepsilon]_{s_1,c}$ ;
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(C2) $X^{s_1,s_2}$ has its target location in $B_{s_2}=[v{\varrho_{\rm I,min}}/2,v{\varrho_{\rm I,min}}/2+\varepsilon]_{s_2,c}$ ;
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(C3) $X_{t}^{s_1,s_2}\in J_{s_1}=[0,\varepsilon/2]_{s_1,c}$ and is on its way back to its starting location;
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(C4) ${\rho_{\rm I}}\big(X^{s_1,s_2},X_{c}^{s_1}\big)\lt {\varrho_{\rm I,min}}+\varepsilon/(2v)$ ; and
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(C5) ${\rho_{\rm I}}\big(X^{s_1,s_2},X_{c}^{s_2}\big)\lt {\varrho_{\rm I,min}}+\varepsilon/v$ .
These conditions roughly guarantee that, for sufficiently long streets, the bridging device $X^{s_1,s_2}$ propagates the infection from $s_1$ to $s_2$ . The time the bridging device stays on each of the streets is insufficiently long to allow patching by white knights. This is ensured by Conditions (C1) and (C2), as the distance the devices travel on each street before entering the crossing is at most $v{\varrho_{\rm I,min}}+2\varepsilon\lt v{\varrho_{\rm W,min}}$ , since $\varepsilon$ is sufficiently small. Together then, since $s_2$ is open, due to the configuration of the devices on the open street and the fact that $r\gt v{\varrho_{\rm I,min}} $ , $X^{s_1,s_2}$ will pass the infection on to the boundary device $X^{s_2}_c$ of the chain of transmitting devices on $s_2$ . This is ensured by Condition (C5). Finally, Conditions (C3) and (C4) ensure that $X^{s_1,s_2}$ becomes infected if $X^{s_1}_c$ becomes infected at time t, as it is on its way back to its starting location and will spend at least a time of ${\varrho_{\rm W,min}}+\varepsilon/(2v)$ in the vicinity of $X^{s_1}_c$ .
The following statement guarantees that there exists a uniform bound for the probability that a given crossing is open for all sufficiently large times. In particular, this bound converges to 1 as $\lambda$ tends to infinity. Recall that we denoted by H the range of dependence of $\kappa$ , and define $L= {H+v{\varrho_{\rm I,min}}/2+\varepsilon}$ .
Lemma 1. For almost all S we have that $(\{c \textit{ is open at time } t\})_{c\in S}$ is an independent family of events, conditioned on S. Further, there exists $T_0\gt 0$ such that, for almost all S and all crossings $c\in S$ , there exists a constant $C_c=C_c(S\cap B_L(c),T)$ such that $\mathbb{P}(c$ is open at time $ t\mid S)\ge 1-\exp\!(\!-\lambda C_c)$ for all $t\ge T_0$ .
We present the proof of the lemma later in this section.
Consider $\tau_{s_1,c}$ , the time that a boundary device associated with the crossing c is infected; then, for $\tau_{s_1,c}\gt T_0$ and conditioned on S, we can couple the event that c is open at time $\tau_{s_1,c}$ to a Bernoulli random variable $\mathcal{B}_c$ with parameter $1-\exp\!(\!-\lambda C_c)$ , and note that the $\mathcal{B}_c$ are independent conditioned on S and only depend on S in the region $S\cap B_L(c)$ . For $\tau_{s_1,c}= \infty$ , i.e. if the boundary device never becomes infected, we assume that the crossing is open nonetheless. We say that a crossing is open if $\mathcal{B}_c=1$ . In order to make use of this observation, we need to ensure that the infection survives up until time $T_0$ . However, note that survival for long but finite times has a positive probability and can be constructed locally by an appropriate isolation procedure for the typical device.
Now we consider the model at time $t\ge T$ and show that the graph of open streets and open crossings percolates with positive probability via stabilization arguments. For this, let us fix an a such that ${\varrho_{\rm I,min}} \lt a/2 \lt a_{\rm c}/2$ and recall that we have the random field of stabilizing radii $\{R_x\}_{x\in\mathbb{R}^2}$ for the street system at our disposal, in addition to the random field $\{R^a_x\}_{x\in\mathbb{R}^2}$ that acts as a replacement for the asymptotically essentially connectedness of the thinned graph $S^a$ . Then, we say that $z \in \mathbb Z^2$ is n-open if
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(a) $R(Q_{3n}(nz))\lt n$ ;
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(b) $R^a(Q_{n}(nz))\lt n/2$ ;
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(c) every street fully contained in $Q_{3n}(nz)\cap S^a$ is open; and
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(d) every crossing in $Q_{3n}(nz)$ is open.
Condition (b) limits the size of cells of points in $Q_{n}(nz)$ to a diameter of at most $n/2$ with respect to $S^a$ . Further, under the condition, there exists a unique giant component in $Q_{n}(nz)\cap S^a$ , built by the boundaries of the cells, that is connected in $Q_{3n}(nz)$ . If, now, adjacent sites $z_1$ and $z_2$ both satisfy Condition (b), they form a joint connected component, since there exist cells that are simultaneously in $Q_{n}(nz_1)$ and in $Q_{n}(nz_2)$ . Due to Conditions (c) and (d), the infection is able to propagate through open streets and open crossings unpatched.
Now, we can use the domination by product measures theorem [Reference Liggett, Schonmann and Stacey34, Theorem 0.0] to establish Bernoulli site percolation of n-open sites on $\mathbb Z^2$ since Condition (a) guarantees 7-dependence of $S^a$ , and under Condition (a) Conditions (b) and (c) can also be decided within the 7-dependent region. By choosing $n\gt L$ , the crossing-dependent constant $C_{\rm c}$ from Lemma 1 is also 7-dependent like the street system. Hence, using translation invariance, it suffices to show that
To show this, we denote by A(n), B(n), $C(n,\lambda)$ , and $D(n,\lambda)$ the events that Conditions (a), (b), (c), and (d) are not satisfied for $z=o$ . Then, $\mathbb{P}( o \text{ is} \textit{n}\text{ -open})\ge 1-\mathbb{P}(A(n)\cup B(n))-\mathbb{P}(C(n,\lambda))-\mathbb{P}(D(n,\lambda))$ . By assumption, $\limsup_{n\uparrow \infty}\mathbb{P}(A(n)\cup B(n)) = 0$ independently of $\lambda$ . For fixed n, using Markov inequality and dominated convergence, we now also have $\limsup_{\lambda \uparrow \infty}(\mathbb{P}(C(n,\lambda)) +\mathbb{P}(D(n,\lambda))) = 0$ , as $\lambda$ increases, where we used that the expected number of streets and crossings is finite.
Finally, due to the translation invariance of the model, the existence of an infinite cluster of open sites implies that an infinite cluster of good streets and good crossings exists, and, thus, there is a positive probability that the typical device transmits the infection to infinity.
Proof of Lemma 1. First note that the conditions are only dependent on the bridging devices, which have their initial positions and their destinations close to the crossing and move over the crossing, and are therefore independent for distinct crossings. This guarantees the independence of the events.
In order to bound the probability of openness at late times, we compute the intensity of devices that satisfy Conditions (C1), (C2), and (C3) at time t and then show that, as t tends to infinity, this intensity converges to a positive crossing-dependent value. In turn, the probability that no such devices exist can be seen as a Poisson void probability.
Let us start by deriving expressions for the intensity of devices at time t in the desired interval, i.e. devices that start on $s_1$ in the interval $A_{s_1}$ and have a target location in $B_{s_2}$ , on $s_2$ . Recall that the streets $s_1$ and $s_2$ have a joint crossing c. Note that, by the displacement theorem for Poisson point processes, the number of devices that satisfy the conditions is a Poisson-distributed random variable and its parameter is given by $\lambda p_S(s_1,s_2)$ , where
where $|z,x|_S$ denotes the shortest distance between x and z on S, and $r_t(|z,x|_S)$ is uniquely defined as $vt=|z,x|_S n_t+r_t(|z,x|_S)$ with $n_t$ the largest odd number such that $0\le r_t(|z,x|_S)\le 2|z,x|_S$ . In words, $n_t(|z,x|_S)$ denotes the number of times that the device has traveled from x to z and back, and since we want the device to be on the way back, we require $n_t(|z,x|_S)$ to be odd. Then, $r_t(|z,x|_S)$ is the distance from z on the way back. Subtracting the distance from z to the joint crossing c, we obtain the traveled distance on $s_1$ , which has to lie in the interval $(0,\varepsilon)_{s_1,c}$ .
We will show that there is a time $T_0$ such that, for all $t \ge T_0$ , we can bound $p_S(s_1,s_2)$ from below by a constant that only depends on $S\cap B_{L}(c)$ .
Let us define for $x\in A_{s_1}$ by
the minimal density for the kernel, starting in x and having a destination in $B_{s_2}$ . This value $\eta_x$ is positive as the kernel is c-continuous, $B_{s_2} \subset B_c(x)$ , and we use our assumption that $2v {\varrho_{\rm I,min}} +2\varepsilon\lt c$ .
In order to simplify the notation for $A_{s_1}$ and $B_{s_2}$ let us abbreviate $b=v{\varrho_{\rm W,min}}/2$ and associate bijectively the interval $A=[b+\varepsilon/2,b+\varepsilon]$ to $A_{s_1}$ such that $x\mapsto {x}_{s_1,c}$ . We associate $B=[b,b+\varepsilon]$ in a similar way to $B_{s_2}$ . Then,
where we also dropped the singular part in $\kappa^S(x,{\textrm d} y)$ . Now, let us define by
the density of points started at x that are on their way back from their target location, and that are at time s precisely at the origin. Note that a device satisfies Condition (C3) at time t if and only if it passes the crossing on its way to its starting location in the time interval $[t-\varepsilon(2v)^{-1},t]$ . Therefore, we can rewrite
and we will prove that, $\mathbb{P}$ -almost surely, conditioned on S, there exist constants $T_0$ and C that depend on v, ${\varrho_{\rm I,min}}$ , and $\varepsilon$ but not on S, x, or $\kappa^S$ , such that $\inf_{t\ge T_0}\phi_x(t)\gt C\gt 0$ . In order to derive this statement, the main tool is the following identity for $\phi_x(t)$ :
Let us explain this formula. Here, n represents the number of times that a device started at x reaches its destination, which is uniformly distributed in B. With every reflection in B, the density is distributed to an interval of length $2\varepsilon n$ , where $\varepsilon$ is the length of B, again uniformly at random. Now, $x+2b$ , respectively $x+2b+2\varepsilon$ , are the shortest, respectively the longest, distance that a device started at x travels before it revisits the crossing c for the first time. For each consecutive visit to the origin an additional length of $2(b+x)$ , respectively $2(x+b+\varepsilon)$ , has to be added as the length of a complete cycle from the origin to its destination and back.
In other words, each indicator becomes non-zero in $x+2b+(n-1)2(x+b)$ and adds a mass of $(2\varepsilon n)^{-1}$ over a length of $2n\varepsilon$ . For $n\lt(x+b)/\varepsilon$ the indicator functions are disjoined, i.e. for $vt\lt x+2b+((x+b)/\varepsilon-1)2(x+b)$ there is at most one indicator function that is non-zero. Now, for $n\gt(x+b)/\varepsilon$ , the interval for vt in which the indicator function is non-negative is longer than the minimal cycle length. In other words, it is possible that at least two indicator functions are non-negative.
Now, for $(x+b)/\varepsilon\lt n\lt 2(x+b)/\varepsilon$ the indicator functions contribute for more than the length of a full cycle $2(x+b)$ and less than twice that length. Therefore, for each $vt \in [x+2b+(n_1-1)2(b+x),x+2b+(n_2-1)2(b+x)]$ there are either exactly one or two non-negative indicators, where $n_i=\lceil i(x+b)/\varepsilon \rceil$ . As each indicator has a weight of at least $(4\varepsilon(x+b)/\varepsilon)^{-1}$ we can bound $\phi_x(t)\gt(4\varepsilon(x+b)/\varepsilon)^{-1}$ .
More generally, in the interval $vt \in [x+2b+(n_m-1)2(b+x),x+2b+(n_{m+1}-1)2(b+x)]$ there are either m or $m+1$ overlapping indicator functions whose contributions can each be bounded by $(2n_{m+1}\varepsilon)^{-1}$ . Therefore, we can bound
where we used that the bound monotonically increases in m and $x\le b+\varepsilon$ . Therefore, for $T_0=(x+2b+(n_1-1)2(b+x))v^{-1}$ the desired bound is realized and integration of (3) yields
Noting that the requirements in Conditions (C4) and (C5) can be considered independently, respectively with probability $p_4={\varrho_{\rm I}}([{\varrho_{\rm I,min}},{\varrho_{\rm I,min}}+\varepsilon/2])$ and $p_5={\varrho_{\rm I}}([{\varrho_{\rm I,min}},{\varrho_{\rm I,min}}+\varepsilon])$ , the number of devices that satisfy the criterion of a bridging device $X^{s_1,s_2}$ can be bounded from below by a Poisson-distributed random variable with expectation $\tilde p_S(s_1,s_2)p_4p_5$ . As c is open if there is at least one bridging device for each combination of open adjacent streets, we can bound
which proves the lemma.
4.3. Proof of Theorem 2
For the proof we adopt a multiscale argument in the spirit of the proof of existence of subcritical regimes for the Poisson–Boolean model with random radii in [Reference Gouéré19]. We note that this approach has also been applied in the setting of Cox–Boolean models with random radii in [Reference Jahnel, Tóbiás and Cali29]. More specifically, we adapt the arguments for absence of percolation in the connectivity graph for sufficiently large velocities presented in [Reference Cali, Hinsen, Jahnel and Wary11]. Roughly speaking, we prove that a Cox–Boolean model in which any two devices that could transmit the infection somewhere on their path and are sufficiently close are connected, becomes subcritical if the white knight intensity is sufficiently large.
First, we call a street $s=(c_1,c_2)$ blocked for (device) x if either $|s|\lt v_{\rm min}{\varrho_{\rm I,min}}/2$ or there exist two white knights $Y_1,Y_2\in Y^{{\lambda_{\rm W}}}$ such that for $i\in \{1,2\}$ we have ${\varrho_{\rm I,min}}\gt{\rho_{\rm W}}(Y_i,x)$ , $Y_{i,t}\in s$ , and $|c_i-Y_{i,t}|\lt r$ for all $t\ge 0$ . Otherwise we call s unblocked for x. Then, we consider the thinned process
In words, for devices in $X^\lambda\setminus X^{\lambda,{\rm th}}$ every possible path only contains streets that are either too short to perform any transmission of the infection or contain a white knight that patches the device before it can transmit the infection on the street. Let us note that here we use that $r\gt v_{\rm max}{\varrho_{\rm W,min}}$ is large enough to allow a successful patch. Using these definitions, we note that, if the infection survives globally, then this implies that the geostatistical Cox–Boolean model $\mathcal{C}=\bigcup_{X_i\in X^{\lambda,{\rm th}}}B_{\ell_S(X_i)}(X_i)$ contains an unbounded component. Hence, in order to prove absence of global survival, it suffices to prove the absence of percolation in this Cox–Boolean model, which is also well-defined by the local connectedness assumption. Let $\mathcal{C}_x(V)$ denote the connected component containing x of the geostatistical Cox–Boolean model, based on points in $V\subset\mathbb{R}^2$ . Then, we define, for any $x\in \mathbb{R}^2$ and $\alpha\gt 0$ , the event
that the cluster containing x, formed by disks whose centers lie in $B_{10\alpha}(x)$ , reaches beyond $B_{8\alpha}(x)$ . Consider the set of $\alpha$ -local points $A_S(\alpha)=\{x\in S\colon \ell_S(x)\lt\alpha \}$ , let $S^*$ denote the Palm version of S, and recall the stabilization radii $R_y$ of the street system. Recall that $R(V)=\sup_{y\in V\cap\, \mathbb{Q}^2}R_y$ for any $V\subset\mathbb{R}^2$ . Then, we can employ the following key lemma that establishes a scaling relation in the model.
Lemma 2. ([Reference Cali, Hinsen, Jahnel and Wary11, Lemma III.1].) Consider the geostatistical Cox–Boolean model. There exists a constant $c\gt 0$ such that, for all $\alpha\gt 0$ ,
In the next lemma we deviate from [Reference Cali, Hinsen, Jahnel and Wary11, Proof of Theorem II.3]. We show that the local percolation probability becomes zero for large white knight intensities.
Lemma 3. There exists $c\gt 0$ such that
and $\mathbb{P}\big(\textit{there exists }y\in{\textrm{supp}}\big(\kappa^{S^*}(o,{\textrm d} y)\big)\textit{ and at least one unblocked }s\in\ell_{S^*}(o,y)\big)$ tends to zero as ${\lambda_{\rm W}}$ tends to infinity.
Proof of Lemma 3. Note that
But, by dominated convergence,
tends to zero as ${\lambda_{\rm W}}$ tends to infinity, and hence we arrive at the desired result.
As a final input for the proof, we recall the following essential result about convergence properties of functions satisfying some scaling inequality.
Lemma 4. ([Reference Gouéré19, Lemma 3.7].) Let f and g be two bounded measurable functions from $[1,\infty]$ to $[0,\infty)$ . Additionally, let f be bounded by $1/2$ on [Reference Auffinger, Damron and Hanson1, Reference Błaszczyszyn, Haenggi, Keeler and Mukherjee10], g be bounded by $1/4$ on $[1,\infty]$ , and assume that $f (\alpha) \le f (\alpha/10)^2 + g(\alpha)$ for all $\alpha\ge 10$ . Then, $\lim_{\alpha\uparrow\infty}g(\alpha)=0$ implies that $\lim_{\alpha\uparrow\infty}f(\alpha)=0$ .
Now we are in the position to prove the theorem.
Proof of Theorem 2. Recall that S is assumed to be a PVT or PDT. In order to prove that ${\lambda_{\rm W,c}}\lt\infty$ , it suffices to show that $\lim_{\alpha\uparrow\infty}\mathbb{P}\big(X^{\lambda,{\rm th}}(\mathcal{C}_o(\mathbb{R}^2))\gt X^{\lambda,{\rm th}}(B_{8\alpha})\big)=0$ for all sufficiently large ${\lambda_{\rm W}}$ . But this is true if $\lim_{\alpha\uparrow\infty}\mathbb{P}(G(0,\alpha))=0$ since, by [Reference Cali, Hinsen, Jahnel and Wary11][Lemma III.4 and III.5],
where $\mathbb{E}\big[\int_{S}{\textrm d} x\,\textbf{1}\{10\alpha\le |x|\le 9\alpha+\ell_S(x)\}\big]$ tends to zero as $\alpha$ tends to infinity. Now, in order to show that $\lim_{\alpha\uparrow\infty}\mathbb{P}(G(0,\alpha))=0$ we apply Lemmas 2, 3, and 4 for proper choices of f and g.
For this, note that, in Lemma 2, since we assume stabilization, $\mathbb{P}(R(Q_{10\alpha})\ge \alpha)$ tends to zero as $\alpha$ tends to infinity, and the same is true for $ \alpha ^2\mathbb{P}(o\in A^{\rm c}_{S^*}(\alpha))$ by [Reference Cali, Hinsen, Jahnel and Wary11, Lemma III.2]. Hence, we can define
set $\alpha_{\rm c}=\alpha_1\vee\alpha_2$ , and note that $\alpha_{\rm c}\lt\infty$ . Further, we let
where ${\lambda_{\rm W,c}}\lt\infty$ by Lemma 3. Then, we write $f(\alpha)=c\mathbb{P}(G(o,10\alpha_{\rm c}\alpha))$ and $g(\alpha)=c^2(\phi_1(\alpha_{\rm c}\alpha)+\phi_2(\alpha_{\rm c}\alpha))$ and hence, again using Lemma 3, we have $f(\alpha)\le \frac12$ for all $1\le \alpha\le10$ and ${\lambda_{\rm W}}\gt{\lambda_{\rm W,c}}$ , and, by definition, $g(\alpha)\le \frac14$ for all $1\le \alpha$ . Finally, using Lemma 2,
Hence, since $\lim_{\alpha\uparrow\infty}g(\alpha)=0$ , an application of Lemma 4 gives the result.
4.4. Proof of Theorem 3
We prove the theorem in two parts.
Proof of Theorem 3 parts (ii) and (iii). Note that part (ii) is the statement of Theorem 1 which puts no restrictions on the white knight intensity. Further, part (iii) follows from [Reference Cali, Hinsen, Jahnel and Wary11][Theorem 3.3] where a subcritical percolation regime is established for sufficiently fast speeds, independent of the device intensities. This in particular implies that global survival is possible only with probability 0.
Hence, it only remains to prove part (i). The main idea is that small velocities make it impossible to transmit the infection through crossings if sufficiently many white knights are available. We say that a street $s=(c_1,c_2)$ is closed if:
-
(A) $|s|\gt 2v{\rho_{\rm W}}$ ;
-
(B) there exist white knights $Y^s\subset Y^{{\lambda_{\rm W}}}$ such that, for all $t\ge 0$ and $x\in s$ , $|x-Y_{i,t}|\lt r/2$ for some $Y_i\in Y^s$ ; and
-
(C) if, at time $t\ge 0$ , there exists an infected $X_i\in X^\lambda$ with $X_{i,t}=c_1$ (respectively $X_{i,t}=c_2$ ), then $\{X_j\in X^\lambda\cap s\colon |X_{j,u}-c_2|\le v{\rho_{\rm W}}\text{ for some }u\in \tau(t)\}=\emptyset$ (respectively $\{X_j\in X^\lambda\cap s\colon |X_{j,u}-c_1|\le v{\rho_{\rm W}}\text{ for some }u\in \tau(t)\}=\emptyset$ ). Here, $\tau(t)$ is the time interval in which the infection reaches $s\cap B_{v{\rho_{\rm W}}+r}(c_2)$ (respectively $s\cap B_{v{\rho_{\rm W}}+r}(c_1)$ ).
A street is called open if it is not closed. The key idea is that a closed street cannot be used for the transmission of the infection. Indeed, Condition (A) guarantees that the street is sufficiently long to allow the white knights to patch, and the probability that the condition is satisfied tends to 1 as v tends to 0. Further, Condition (B) guarantees the existence of white knights at all times close to every point on the street, and in particular close to the crossings. These white knights help to patch any incoming infected device, and the condition becomes likely to be satisfied for large white knight intensities. Now, for Condition (C), note first that a large device intensity $\lambda$ makes it probable that an infection travels through a street unpatched since we assume that ${\rho_{\rm W}}\gt{\rho_{\rm I}}$ . Also, due to the continuous movement of the devices, it is unavoidable that an infected device enters the street at some time. However, in order for an infected device to leave the street unpatched, it needs to receive the infection at the opposite end of the street, sufficiently close to the crossing, i.e. in $s\cap B_{v{\rho_{\rm W}}+r}(c_2)$ (respectively $s\cap B_{v{\rho_{\rm W}}+r}(c_1)$ ). Only in this case can it exit the street unpatched from the blocking white knight that is positioned there. Very roughly, then, again for small v, Condition (C) becomes likely.
What makes the probability that Condition (C) is satisfied challenging to control is the fact that, in principle, a street at any given time could host devices from distant spatial areas. In order to cope with this we again employ a multi-scale argument very similar to the one presented in Section 4.3. Using the definitions for $\ell_S$ from there, we now consider the thinned point cloud
Again, the idea is that any device that is not in $X^{\lambda,{\rm th}}$ only finds closed streets on any possible path and hence cannot contribute to the spread of the infection. Thus, it suffices to show subcriticality in the associated geostatistical Cox–Boolean model $\mathcal{C}=\bigcup_{X_i\in X^{\lambda,{\rm th}}}B_{\ell_S(X_i)}(X_i)$ . However, the situation is more complicated compared to the proof of Theorem 2 since the thinning procedure depends on the entire point cloud. Still, we can employ Lemmas 2 and 4, and only need to replace Lemma 3 with the following, which is presented in terms of $\mathbb{P}^*$ , the Palm version of $\mathbb{P}$ .
Lemma 5. There exists $c\gt 0$ such that
and
Proof of Lemma 5. First note that we can use the Slivnyak–Mecke formula and translation invariance to estimate
We highlight here that, differently to Lemma 3, the probability also extends to the devices $X^\lambda$ since openness is defined not only with respect to white knights and the street system.
In order to show the second statement of the lemma, we employ stabilization based on the stabilizing random field $\{R_x\}_{x\in\mathbb{R}^2}$ . For all sufficiently large n, we have, for $\varepsilon^{\prime}\gt 0$ ,
where we used that $\mathbb{P}(R(Q_{2n})\ge n/2)$ tends to zero as n tends to infinity, as well as the fact that under the event $R(Q_{2n})\lt n/2$ any shortest path starting in o must be contained in $Q_{2n}$ . Now, by the Markov inequality,
and, using dominated convergence and the fact that $\mathbb{E}^*[\#\{s\in S\cap Q_{2n}\}]\lt\infty$ for PVT and PDT, it suffices to show that, for all $s\in S\cap Q_{2n}$ , $\limsup_{{\lambda_{\rm W}}\uparrow\infty}\limsup_{v\downarrow0}\mathbb{P}^*(s\text{ is open}\mid S)=0$ almost surely with respect to S. In view of the definition of closed streets, let C(v) denote the event that Condition (A) is satisfied for s, and similarly $D({\lambda_{\rm W}})$ and $E(v,\lambda,{\lambda_{\rm W}})$ for the events associated with Conditions (B) and (C). Then,
where the first and third summands tend to zero as v tends to zero, and then the second summand also tends to zero as ${\lambda_{\rm W}}$ tends to infinity. This completes the proof.
Proof of Theorem 3 part (i). For the proof we can follow the same line of argument as used for the proof of Theorem 2, replacing Lemma 3 with Lemma 5 and adjusting the subsequent arguments. We need to prove existence of ${\lambda_{\rm W,c}}\lt\infty$ such that, for all ${\lambda_{\rm W}}\gt{\lambda_{\rm W,c}}$ , there exists $v_{c}(\lambda,{\lambda_{\rm W}})$ such that $\lim_{\alpha\uparrow\infty}\mathbb{P}(X^{\lambda,{\rm th}}(\mathcal{C}_o(\mathbb{R}^2))\gt X^{\lambda,{\rm th}}(B_{8\alpha}))=0$ for all $v\lt v_{c}(\lambda,{\lambda_{\rm W}})$ . Referencing [Reference Cali, Hinsen, Jahnel and Wary11][Lemmas III.2, III.4, and III.5], as well as Lemma 2 and the initial argument presented in Theorem 2, it suffices to note that, with the help of Lemma 5, there exists ${\lambda_{\rm W,c}}\lt\infty$ such that, for all ${\lambda_{\rm W}}\gt{\lambda_{\rm W,c}}$ , there exists $v_{c}(\lambda,{\lambda_{\rm W}})$ such that, for all $v\lt v_{c}(\lambda,{\lambda_{\rm W}})$ ,
where $\alpha_{\rm c}$ is defined as in the proof of Theorem 2. Then, using the same definitions for f and g, the result follows by an application of Lemma 4.
4.5. Proof of Proposition 2
Proof of Proposition 2. First note that, by the assumption of supercriticality, there is a positive probability that the typical device is connected to infinity within $g_{\rho,r}(S,X^\lambda)$ via at least one path of susceptible devices, i.e. in the absence of white knights. However, in the case that $T_{\rm I}\le T_{\rm W}$ , any white knight that is connected to the path can only eliminate the infection after the infected device has already passed the infection to the subsequent susceptible device, leading to an unstoppable sequence of infections along the path, independent of the choice of ${\lambda_{\rm W}}$ .
On the other hand, in the case $T_{\rm I}\gt T_{\rm W}$ , it suffices to consider the model conditioned on the event $\{X_o\leftrightsquigarrow\infty\}$ that $X_o$ is in the infinite cluster of $g_{\rho,r}(S,X^\lambda)$ . Let us denote by D the graph distance of $X_o$ to the set of white knights, and note that $D\lt\infty$ almost surely as ${\lambda_{\rm W}}\gt 0$ . Then, the closest white knight $Y_i$ experiences an infection attempt at time $DT_{\rm I}$ . Note that, at this time, any infected device has a distance to $Y_i$ given by at most 2D. This comes from the fact that the transmission times are deterministic and there is a one-to-one correspondence between the graph distance to the typical device and elapsed time. However, there exists $N\in \mathbb{N}$ such that $NT_{\rm I}\gt(N+2D)T_{\rm W}$ , and therefore the infection can reach at most a graph distance of $N+D$ . Indeed, any device $X_i$ at graph distance $N+D$ from $X_o$ is in contact with $Y_i$ via $N+2D$ edges connecting infected or patched devices. But, since the patching is faster than the infection, for this N, on the joint path between $X_o$ , $Y_i$ , and $X_i$ , the patch will have caught up with the infection before time $DT_{\rm I}+(2D+N)T_{\rm W}$ , which is strictly smaller than $(N+D)T_{\rm I}$ .
4.6. Proof of Theorem 4
Proof of Theorem 4. As ${\varrho_{\rm W,min}} \gt 0$ , we can choose b large enough that ${\varrho^b_{\rm I,min}}\lt {\varrho_{\rm W,min}}$ . Furthermore, we can choose $\mu^{\prime}$ with $v^{\prime}_{\textrm{min}}$ such that $v_{\textrm{min}}\rho\lt v^{\prime}_{\textrm{min}}{\varrho^b_{\rm I,min}}\lt\min(a_{\rm c}/2,r,c/2)$ . Now $v^{\prime}_{\textrm{min}}$ and ${\varrho^b_{\rm I,min}}$ satisfy the conditions of Theorem 1. A close inspection of the proof of Theorem 1 reveals that, under the conditions in this theorem, there exists an infinite sequence of crossing devices, boundary devices, and devices connecting boundary devices $\{X_{n_i}\}_{i\in \mathbb{N}}$ that connect the typical device to infinity in the dynamical model considered in Theorem 1. Let us argue that this given sequence is also connected in $g_{\rho,r}(S, X^\lambda)$ . Indeed, as the chain of devices between boundary devices is strongly localized, they are connected for all $t\ge 0$ , especially for a continuous time window of length $\rho$ . Now, the crossing devices are localized in such a way that they travel at least a distance of $v^{\prime}_{\textrm{min}}{\varrho^b_{\rm I,min}}$ on their respective streets. As $v_{\textrm{min}}\rho\lt v^{\prime}_{\textrm{min}}{\varrho^b_{\rm I,min}}$ the bridging devices can connect to their respective boundary devices. Therefore, the infection can propagate in $g_{\rho,r}(S, X^\lambda)$ along the given sequence to infinity, which completes the proof.
4.7. Proof of Theorem 5
Proof of Theorem 5. Using similar arguments to the analysis of chase–escape dynamics on the Gilbert graph in [Reference Hinsen, Jahnel, Cali and Wary23], we call a device $X_i\in V^{M,p}$ good if, in the case of an infection, the infection is transmitted to all neighbors of $X_i$ before any neighbor of $X_i$ is able to patch it. If there is an infinite path of good devices, every device on this path is guaranteed to become infected and hence, if there exists an infinite component of good devices with positive probability, this implies survival of the infection also with positive probability. Now, if a device $X_i$ has at most M neighbors, the probability of being good is bounded by
independently of $X_i$ , where the $\rho_{{\rm I},i}^b$ , and respectively the $\rho_{{\rm W},i}$ , are i.i.d. random variables with distribution ${\varrho^b_{\rm I}}$ and $\varrho_{\rm W}$ .
Now, by assumption, we can choose M and p such that $g^{M,p}_{\rho,r}(S,X^\lambda)$ percolates with positive probability. Hence, as ${\varrho_{\rm W}}$ had no atom at zero we can choose $b=b(M)$ sufficiently large such that the bound in (4) is larger than p.
Note that the bound is uniform over the devices, since the infection and patch times are independent by definition, and therefore we can couple the connectivity graph to an independent thinning with parameter p that dominates the process of good devices. As a consequence, $g^{M,p}_{\rho,r}(S,X^\lambda)$ is a subgraph of the thinned graph of good devices with at most M neighbors. Hence, we have established percolation of good devices with positive probability as desired.
4.8. Proof of Theorem 6
Proof of Theorem 6. Our strategy is again to employ the arguments from Sections 4.3 and 4.4. That is, we realize that it suffices to show absence of percolation in the geostatistical Cox–Boolean model $\mathcal{C}=\bigcup_{X_i\in X^{\lambda,{\rm th}}}B_{\ell_S(X_i)}(X_i)$ , where
with $N_\lambda(X_i)$ the set of neighbors of $X_i$ in $g_{\rho,r}(S,X^\lambda)$ and $N_{{\lambda_{\rm W}}}(X_i)$ the set of neighbors of $X_i$ in $g_{\rho,r}(S,X_i\cup Y^{\lambda_{\rm W}})$ . Indeed, devices in $X^\lambda\setminus X^{\lambda,{\rm th}}$ are patched before they can transmit the infection and can therefore not contribute to the dissipation of the infection.
Again, the thinning procedure depends on the entire point cloud, but we can still employ Lemmas 2 and 4 and only need to replace Lemma 3 by the following, which is presented in terms of $\mathbb{P}^*$ , the Palm version of $\mathbb{P}$ .
Lemma 6. There exists $c\gt 0$ such that
and
Proof of Lemma 6. Again, by the Slivnyak–Mecke formula and translation invariance we can estimate
Now,
where ${\rho_{\rm W}}$ is a random variable distributed according to ${\varrho_{\rm W}}$ . Note that $\mathbb{P}({\rho_{\rm W}}\gt{\varrho_{\rm I,min}})\lt 1$ by our assumptions on ${\varrho_{\rm W,min}}$ . Further, the expression on the right-hand side of (5) can be further bounded from above by considering only those white knights that mimic the behavior of the typical device at the origin in the sense that they start close to the origin and have a target location close to the target location of the typical device. Then, by dominated convergence, the right-hand side of (5) tends to zero as ${\lambda_{\rm W}}$ tends to infinity, and this completes the proof.
As the lemma is now proved, this concludes the proof of Theorem 6.
Proof of Theorem 3 part (i). We can follow the same line of argument as used for the proof of Theorem 2, replacing Lemma 3 by Lemma 5 and adjusting the subsequent arguments. We need to prove the existence of ${\lambda_{\rm W,c}}\lt\infty$ such that, for all ${\lambda_{\rm W}}\gt{\lambda_{\rm W,c}}$ , there exists $v_{c}(\lambda,{\lambda_{\rm W}})$ such that $\lim_{\alpha\uparrow\infty}\mathbb{P}\big(X^{\lambda,{\rm th}}(\mathcal{C}_o(\mathbb{R}^2))\gt X^{\lambda,{\rm th}}(B_{8\alpha})\big)=0$ for all $v\lt v_{c}(\lambda,{\lambda_{\rm W}})$ . Referencing [Reference Cali, Hinsen, Jahnel and Wary11][Lemmas III.2, III.4, and III.5], as well as Lemma 2 and the initial argument presented in Theorem 2, it suffices to note that, with the help of Lemma 5, there exists ${\lambda_{\rm W,c}}\lt\infty$ such that, for all ${\lambda_{\rm W}}\gt{\lambda_{\rm W,c}}$ , there exists $v_{c}(\lambda,{\lambda_{\rm W}})$ such that, for all $v\lt v_{c}(\lambda,{\lambda_{\rm W}})$ ,
where $\alpha_{\rm c}$ is defined as in the proof of Theorem 2. Then, using the same definitions for f and g, the result follows by an application of Lemma 4.
Acknowledgement
We thank the two anonymous referees for their careful considerations and insights which helped to substantially improve the manuscript.
Funding information
This work was funded by Orange Labs S.A. under project ID CRE K07151; the German Research Foundation under Germany’s Excellence Strategy MATH+: The Berlin Mathematics Research Center, EXC-2046/1 project ID 390685689; and the German Leibniz Association via the Leibniz Competition 2020.
Competing interests
There were no competing interests to declare which arose during the preparation or publication process of this article.