Curvature-based Analysis of Network Connectivity in Private Backbone Infrastructures-Reference-Cited by-同舟云学术

Curvature-based Analysis of Network Connectivity in Private Backbone Infrastructures

Published:2022-02-24 Issue:1 Volume:6 Page:1-32
ISSN:2476-1249
Container-title:Proceedings of the ACM on Measurement and Analysis of Computing Systems
language:en
Short-container-title:Proc. ACM Meas. Anal. Comput. Syst.

Author:

Salamatian Loqman¹,Anderson Scott²,Matthews Joshua²,Barford Paul²,Willinger Walter³,Crovella Mark⁴

Affiliation:

1. Columbia University, New York, NY, USA

2. University of Wisconsin Madison, Madison, WI, USA

3. NIKSUN, Inc., Princeton, NJ, USA

4. Boston University, Boston, MA, USA

Abstract

The main premise of this work is that since large cloud providers can and do manipulate probe packets that traverse their privately owned and operated backbones, standard traceroute-based measurement techniques are no longer a reliable means for assessing network connectivity in large cloud provider infrastructures. In response to these developments, we present a new empirical approach for elucidating private connectivity in today's Internet. Our approach relies on using only "light-weight" ( i.e., simple, easily-interpretable, and readily available) measurements, but requires applying a "heavy-weight" or advanced mathematical analysis. In particular, we describe a new method for assessing the characteristics of network path connectivity that is based on concepts from Riemannian geometry ( i.e., Ricci curvature) and also relies on an array of carefully crafted visualizations ( e.g., a novel manifold view of a network's delay space). We demonstrate our method by utilizing latency measurements from RIPE Atlas anchors and virtual machines running in data centers of three large cloud providers to (i) study different aspects of connectivity in their private backbones and (ii) show how our manifold-based view enables us to expose and visualize critical aspects of this connectivity over different geographic scales.

Funder

National Science Foundation

Publisher

Association for Computing Machinery (ACM)

Subject

Computer Networks and Communications,Hardware and Architecture,Safety, Risk, Reliability and Quality,Computer Science (miscellaneous)

Link

https://dl.acm.org/doi/pdf/10.1145/3508025

Reference91 articles.

1. Emile Aben. 2021. Latency Into Your Network - As Seen From RIPE Atlas. (2021). https://labs.ripe.net/author/emileaben/latency-into-your-network-as-seen-from-ripe-atlas/ Emile Aben. 2021. Latency Into Your Network - As Seen From RIPE Atlas. (2021). https://labs.ripe.net/author/emileaben/latency-into-your-network-as-seen-from-ripe-atlas/

2. On the internet delay space dimensionality

3. Najam Ahmad. 2016. Building one of the highest-capacity subsea cables in the Pacific . https://engineering.fb.com/connectivity/building-one-of-the-highest-capacity-subsea-cables-in-the-pacific/. (2016). Najam Ahmad. 2016. Building one of the highest-capacity subsea cables in the Pacific . https://engineering.fb.com/connectivity/building-one-of-the-highest-capacity-subsea-cables-in-the-pacific/. (2016).

4. Marder Alexander , Matthew Luckie , Amogh Dhamdhere , Bradley Huffaker , Claffy KC, and Smith M. Jonathan . 2018. Pushing the Boundaries with bdrmapIT: Mapping Router Ownership at Internet Scale . In Proceedings of the ACM Internet Measurement Conference. Marder Alexander, Matthew Luckie, Amogh Dhamdhere, Bradley Huffaker, Claffy KC, and Smith M. Jonathan. 2018. Pushing the Boundaries with bdrmapIT: Mapping Router Ownership at Internet Scale. In Proceedings of the ACM Internet Measurement Conference.

5. Anima Anandkumar Avinatan Hassidim and J. Kelner. 2011. Topology discovery of sparse random graphs with few participants. ArXiv Vol. abs/1102.5063 (2011). Anima Anandkumar Avinatan Hassidim and J. Kelner. 2011. Topology discovery of sparse random graphs with few participants. ArXiv Vol. abs/1102.5063 (2011).