On the distance between random events on a network

Abstract: In this paper, we study several statistical properties regarding the distance between events that take place on random locations along the edges of a given network. We derive analytical expressions for the arbitrary moments of such a distance, its probability density function, its cumulative distribution function, as well as their conditional counterparts for the cases in which the position of one event is known in advance. As part of this study, we implement our developments as a callable library for the Pyth… Show more

“…Therefore, equation (18) degenerates to the product of just two terms, 4λra 2 and 4λra 3 , scaled by P 0 , and the result for the probability P 5|{3,2} directly follows. Now, it is also clarified that in the calculation of P 3 in equation (9), the first term corresponds to the partition {1, 1, 1} with a 1 = a 0 − e −2rλg , the second term to the partition {2, 1} with a 2 = a 0 − e −2rλg − rλ g e −2rλg , and the last term to the partition {3} with a 3 = 1 2 a 0 −e −2rλg −rλ g e −2rλg − 2 3 r 2 λ 2 g e −2rλg . For completeness, the pseudocode used to calculate P k is also provided as Algorithm 1.…”

“…Another line of research in graph-based models, which is particularly useful for emergency response planning, assumes that the edge weights are proportional to the length of the associated streets, and models random events along the edges of the graph. If these events represent points of emergency, the graph distance distributions, investigated in [9], can reveal the intrinsic properties of the response system we need to build to combat all emergencies effectively. For instance, they can be used to infer the number of ambulances, medical personnel, etc.…”

On the $k$ Nearest-Neighbor Path Distance from the Typical Intersection in the Manhattan Poisson Line Cox Process

“…Therefore, equation (18) degenerates to the product of just two terms, 4λra 2 and 4λra 3 , scaled by P 0 , and the result for the probability P 5|{3,2} directly follows. Now, it is also clarified that in the calculation of P 3 in equation (9), the first term corresponds to the partition {1, 1, 1} with a 1 = a 0 − e −2rλg , the second term to the partition {2, 1} with a 2 = a 0 − e −2rλg − rλ g e −2rλg , and the last term to the partition {3} with a 3 = 1 2 a 0 −e −2rλg −rλ g e −2rλg − 2 3 r 2 λ 2 g e −2rλg . For completeness, the pseudocode used to calculate P k is also provided as Algorithm 1.…”

“…Another line of research in graph-based models, which is particularly useful for emergency response planning, assumes that the edge weights are proportional to the length of the associated streets, and models random events along the edges of the graph. If these events represent points of emergency, the graph distance distributions, investigated in [9], can reveal the intrinsic properties of the response system we need to build to combat all emergencies effectively. For instance, they can be used to infer the number of ambulances, medical personnel, etc.…”

On the $k$ Nearest-Neighbor Path Distance from the Typical Intersection in the Manhattan Poisson Line Cox Process

“…Another line of research, particularly useful for emergency response planning, assumes that the edge weights are proportional to the length of the associated streets, and models random events along the edges. If these events represent points of emergency, the graph distance distributions can reveal the intrinsic properties of the response system we need to build to combat all emergencies effectively [9]. For instance, the distance distribution can be used to infer the number of ambulances, medical personnel, etc.…”

On the k Nearest-Neighbor Path Distance from the Typical Intersection in the Manhattan Poisson Line Cox Process