Your search keyword '"Lynch, Nancy"' showing total 1,516 results

1. Swarm Algorithms for Dynamic Task Allocation in Unknown Environments

Author

Balachandran, Adithya, Harasha, Noble, and Lynch, Nancy

Subjects

Computer Science - Multiagent Systems, Computer Science - Robotics

Abstract

Robot swarms, systems of many robots that operate in a distributed fashion, have many applications in areas such as search-and-rescue, natural disaster response, and self-assembly. Several of these applications can be abstracted to the general problem of task allocation in an environment, in which robots must assign themselves to and complete tasks. While several algorithms for task allocation have been proposed, most of them assume either prior knowledge of task locations or a static set of tasks. Operating under a discrete general model where tasks dynamically appear in unknown locations, we present three new swarm algorithms for task allocation. We demonstrate that when tasks appear slowly, our variant of a distributed algorithm based on propagating task information completes tasks more efficiently than a Levy random walk algorithm, which is a strategy used by many organisms in nature to efficiently search an environment. We also propose a division of labor algorithm where some agents are using our algorithm based on propagating task information while the remaining agents are using the Levy random walk algorithm. Finally, we introduce a hybrid algorithm where each agent dynamically switches between using propagated task information and following a Levy random walk. We show that our division of labor and hybrid algorithms can perform better than both our algorithm based on propagated task information and the Levy walk algorithm, especially at low and medium task rates. When tasks appear fast, we observe the Levy random walk strategy performs as well or better when compared to these novel approaches. Our work demonstrates the relative performance of these algorithms on a variety of task rates and also provide insight into optimizing our algorithms based on environment parameters., Comment: 14 pages, 10 figures

Published

2024

2. Abstraction in Neural Networks

Author

Lynch, Nancy

Subjects

Computer Science - Neural and Evolutionary Computing, Computer Science - Data Structures and Algorithms, F.1.m

Abstract

We show how brain networks, modeled as Spiking Neural Networks, can be viewed at different levels of abstraction. Lower levels include complications such as failures of neurons and edges. Higher levels are more abstract, making simplifying assumptions to avoid these complications. We show precise relationships between executions of networks at different levels, which enables us to understand the behavior of lower-level networks in terms of the behavior of higher-level networks. We express our results using two abstract networks, A1 and A2, one to express firing guarantees and the other to express non-firing guarantees, and one detailed network D. The abstract networks contain reliable neurons and edges, whereas the detailed network has neurons and edges that may fail, subject to some constraints. Here we consider just initial stopping failures. To define these networks, we begin with abstract network A1 and modify it systematically to obtain the other two networks. To obtain A2, we simply lower the firing thresholds of the neurons. To obtain D, we introduce failures of neurons and edges, and incorporate redundancy in the neurons and edges in order to compensate for the failures. We also define corresponding inputs for the networks, and corresponding executions of the networks. We prove two main theorems, one relating corresponding executions of A1 and D and the other relating corresponding executions of A2 and D. Together, these give both firing and non-firing guarantees for the detailed network D. We also give a third theorem, relating the effects of D on an external reliable actuator neuron to the effects of the abstract networks on the same actuator neuron.

Published

2024

3. Using Single-Neuron Representations for Hierarchical Concepts as Abstractions of Multi-Neuron Representations

Author

Lynch, Nancy

Subjects

Computer Science - Data Structures and Algorithms, 68W99

Abstract

Brain networks exhibit complications such as noise, neuron failures, and partial synaptic connectivity. These can make it difficult to model and analyze their behavior. This paper describes a way to address this difficulty, namely, breaking down the models and analysis using levels of abstraction. We describe the approach for the problem of recognizing hierarchically-structured concepts. Realistic models for representing hierarchical concepts use multiple neurons to represent each concept [10,1,7,3]. These models are intended to capture some behaviors of actual brains; however, their analysis can be complicated. Mechanisms based on single-neuron representations can be easier to understand and analyze [2,4], but are less realistic. Here we show that these two types of models are compatible, and in fact, networks with single-neuron representations can be regarded as formal abstractions of networks with multi-neuron representations. We do this by relating networks with multi-neuron representations like those in [3] to networks with single-neuron representations like those in [2]. Specifically, we consider two networks, H and L, with multi-neuron representations, one with high connectivity and one with low connectivity. We define two abstract networks, A1 and A2, with single-neuron representations, and prove that they recognize concepts correctly. Then we prove correctness of H and L by relating them to A1 and A2. In this way, we decompose the analysis of each multi-neuron network into two parts: analysis of abstract, single-neuron networks, and proofs of formal relationships between the multi-neuron network and single-neuron networks. These examples illustrate what we consider to be a promising, tractable approach to analyzing other complex brain mechanisms.

Published

2024

4. Parallel Algorithms for Exact Enumeration of Deep Neural Network Activation Regions

Author

Drammis, Sabrina, Zheng, Bowen, Srinivasan, Karthik, Berwick, Robert C., Lynch, Nancy A., and Ajemian, Robert

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Neural and Evolutionary Computing

Abstract

A feedforward neural network using rectified linear units constructs a mapping from inputs to outputs by partitioning its input space into a set of convex regions where points within a region share a single affine transformation. In order to understand how neural networks work, when and why they fail, and how they compare to biological intelligence, we need to understand the organization and formation of these regions. Step one is to design and implement algorithms for exact region enumeration in networks beyond toy examples. In this work, we present parallel algorithms for exact enumeration in deep (and shallow) neural networks. Our work has three main contributions: (1) we present a novel algorithm framework and parallel algorithms for region enumeration; (2) we implement one of our algorithms on a variety of network architectures and experimentally show how the number of regions dictates runtime; and (3) we show, using our algorithm's output, how the dimension of a region's affine transformation impacts further partitioning of the region by deeper layers. To our knowledge, we run our implemented algorithm on networks larger than all of the networks used in the existing region enumeration literature. Further, we experimentally demonstrate the importance of parallelism for region enumeration of any reasonably sized network.

Published

2024

5. Multi-Neuron Representations of Hierarchical Concepts in Spiking Neural Networks

Author

Lynch, Nancy A.

Subjects

Computer Science - Neural and Evolutionary Computing, Computer Science - Data Structures and Algorithms

Abstract

We describe how hierarchical concepts can be represented in three types of layered neural networks. The aim is to support recognition of the concepts when partial information about the concepts is presented, and also when some of the neurons in the network might fail. Our failure model involves initial random failures. The three types of networks are: feed-forward networks with high connectivity, feed-forward networks with low connectivity, and layered networks with low connectivity and with both forward edges and "lateral" edges within layers. In order to achieve fault-tolerance, the representations all use multiple representative neurons for each concept. We show how recognition can work in all three of these settings, and quantify how the probability of correct recognition depends on several parameters, including the number of representatives and the neuron failure probability. We also discuss how these representations might be learned, in all three types of networks. For the feed-forward networks, the learning algorithms are similar to ones used in [4], whereas for networks with lateral edges, the algorithms are generally inspired by work on the assembly calculus [3, 6, 7]., Comment: In the previous version, we had an unduly restrictive statement about the order of choices of included edges, input set, and failing neurons. We have loosened this restriction. We generalized the model slightly to allow more freedom in choice of maximum layer number. We fixed a few typos and polished wording in a few places

Published

2024

6. Learning Hierarchically-Structured Concepts II: Overlapping Concepts, and Networks With Feedback

Author

Lynch, Nancy and Mallmann-Trenn, Frederik

Subjects

Computer Science - Neural and Evolutionary Computing

Abstract

We continue our study from Lynch and Mallmann-Trenn (Neural Networks, 2021), of how concepts that have hierarchical structure might be represented in brain-like neural networks, how these representations might be used to recognize the concepts, and how these representations might be learned. In Lynch and Mallmann-Trenn (Neural Networks, 2021), we considered simple tree-structured concepts and feed-forward layered networks. Here we extend the model in two ways: we allow limited overlap between children of different concepts, and we allow networks to include feedback edges. For these more general cases, we describe and analyze algorithms for recognition and algorithms for learning.

Published

2023

7. A Comparison of New Swarm Task Allocation Algorithms in Unknown Environments with Varying Task Density

Author

Cai, Grace, Harasha, Noble, and Lynch, Nancy

Subjects

Computer Science - Multiagent Systems, Computer Science - Robotics

Abstract

Task allocation is an important problem for robot swarms to solve, allowing agents to reduce task completion time by performing tasks in a distributed fashion. Existing task allocation algorithms often assume prior knowledge of task location and demand or fail to consider the effects of the geometric distribution of tasks on the completion time and communication cost of the algorithms. In this paper, we examine an environment where agents must explore and discover tasks with positive demand and successfully assign themselves to complete all such tasks. We first provide a new discrete general model for modeling swarms. Operating within this theoretical framework, we propose two new task allocation algorithms for initially unknown environments -- one based on N-site selection and the other on virtual pheromones. We analyze each algorithm separately and also evaluate the effectiveness of the two algorithms in dense vs. sparse task distributions. Compared to the Levy walk, which has been theorized to be optimal for foraging, our virtual pheromone inspired algorithm is much faster in sparse to medium task densities but is communication and agent intensive. Our site selection inspired algorithm also outperforms Levy walk in sparse task densities and is a less resource-intensive option than our virtual pheromone algorithm for this case. Because the performance of both algorithms relative to random walk is dependent on task density, our results shed light on how task density is important in choosing a task allocation algorithm in initially unknown environments., Comment: 11 pages, 11 figures

Published

2022

8. Symbolic Knowledge Structures and Intuitive Knowledge Structures

Author

Lynch, Nancy

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, 68Q07

Abstract

This paper proposes that two distinct types of structures are present in the brain: Symbolic Knowledge Structures (SKSs), used for formal symbolic reasoning, and Intuitive Knowledge Structures (IKSs), used for drawing informal associations. The paper contains ideas for modeling and analyzing these structures in an algorithmic style based on Spiking Neural Networks, following the paradigm used in earlier work by Lynch, Musco, Parter, and co-workers. The paper also contains two examples of use of these structures, involving counting through a memorized sequence, and understanding simple stylized sentences. The ideas presented here are preliminary and speculative, and do not (yet) comprise a complete, coherent, algorithmic theory. I hope that posting this preliminary version will help the ideas to evolve into such a theory., Comment: 33 pages

Published

2022

9. A Geometry-Sensitive Quorum Sensing Algorithm for the Best-of-N Site Selection Problem

Author

Cai, Grace and Lynch, Nancy

Subjects

Computer Science - Multiagent Systems

Abstract

The house hunting behavior of the Temnothorax albipennis ant allows the colony to explore several nest choices and agree on the best one. Their behavior serves as the basis for many bio-inspired swarm models to solve the same problem. However, many of the existing site selection models in both insect colony and swarm literature test the model's accuracy and decision time only on setups where all potential site choices are equidistant from the swarm's starting location. These models do not account for the geographic challenges that result from site choices with different geometry. For example, although actual ant colonies are capable of consistently choosing a higher quality, further site instead of a lower quality, closer site, existing models are much less accurate in this scenario. Existing models are also more prone to committing to a low quality site if it is on the path between the agents' starting site and a higher quality site. We present a new model for the site selection problem and verify via simulation that is able to better handle these geographic challenges. Our results provide insight into the types of challenges site selection models face when distance is taken into account. Our work will allow swarms to be robust to more realistic situations where sites could be distributed in the environment in many different ways., Comment: 17 pages, 4 figures, submitted to ANTS 2022

Published

2022

10. A Superconducting Nanowire-based Architecture for Neuromorphic Computing

Author

Lombo, Andres E., Lares, Jesus E., Castellani, Matteo, Chou, Chi-Ning, Lynch, Nancy, and Berggren, Karl K.

Subjects

Computer Science - Emerging Technologies, Condensed Matter - Superconductivity, Physics - Applied Physics

Abstract

Neuromorphic computing is poised to further the success of software-based neural networks by utilizing improved customized hardware. However, the translation of neuromorphic algorithms to hardware specifications is a problem that has been seldom explored. Building superconducting neuromorphic systems requires extensive expertise in both superconducting physics and theoretical neuroscience. In this work, we aim to bridge this gap by presenting a tool and methodology to translate algorithmic parameters into circuit specifications. We first show the correspondence between theoretical neuroscience models and the dynamics of our circuit topologies. We then apply this tool to solve linear systems by implementing a spiking neural network with our superconducting nanowire-based hardware., Comment: 29 pages, 10 figures

Published

2021

11. A Spatially Dependent Probabilistic Model for House Hunting in Ant Colonies

Author

Cai, Grace, Wu, Wendy, Zhao, Wayne, Zhao, Jiajia, and Lynch, Nancy

Subjects

Computer Science - Multiagent Systems

Abstract

Ant species such as Temnothorax albipennis select a new nest site in a distributed fashion that, if modeled correctly, can serve as useful information for site selection algorithms for robotic swarms and other applications. Studying and replicating the ants' house hunting behavior will also illuminate useful distributed strategies that have evolved in nature. Many of the existing models of househunting behaviour for T. albipennis make the assumption that all candidate nest sites are equally distant from the ants' home nest, or that an ant has an equal probability of finding each candidate nest site. However, realistically this is not the case, as nests that are further away from the home nest and nests that are difficult to access are less likely to be found, even if they are of higher quality. We extend previous house-hunting models to account for a pairwise distance metric between nests, compare our results to those of real colonies, and use our results to examine the effects of house hunting in nests of different spatial orientations. Our incorporation of distances in the ant model appear to match empirical data in situations where a distance-quality tradeoff between nests is relevant. Furthermore, the model continues to be on par with previous house-hunting models in experiments where all candidate nests are equidistant from the home nest, as is typically assumed.

Published

2021

12. A superconducting nanowire spiking element for neural networks

Author

Toomey, Emily, Segall, Ken, Castellani, Matteo, Colangelo, Marco, Lynch, Nancy, and Berggren, Karl K.

Subjects

Quantitative Biology - Neurons and Cognition, Condensed Matter - Superconductivity, Computer Science - Emerging Technologies, Computer Science - Neural and Evolutionary Computing, Physics - Applied Physics

Abstract

As the limits of traditional von Neumann computing come into view, the brain's ability to communicate vast quantities of information using low-power spikes has become an increasing source of inspiration for alternative architectures. Key to the success of these largescale neural networks is a power-efficient spiking element that is scalable and easily interfaced with traditional control electronics. In this work, we present a spiking element fabricated from superconducting nanowires that has pulse energies on the order of ~10 aJ. We demonstrate that the device reproduces essential characteristics of biological neurons, such as a refractory period and a firing threshold. Through simulations using experimentally measured device parameters, we show how nanowire-based networks may be used for inference in image recognition, and that the probabilistic nature of nanowire switching may be exploited for modeling biological processes and for applications that rely on stochasticity., Comment: 5 main figures; 7 supplemental figures

Published

2020

13. Learning Hierarchically Structured Concepts

Author

Lynch, Nancy and Mallmann-Trenn, Frederik

Subjects

Computer Science - Artificial Intelligence, Computer Science - Neural and Evolutionary Computing

Abstract

We study the question of how concepts that have structure get represented in the brain. Specifically, we introduce a model for hierarchically structured concepts and we show how a biologically plausible neural network can recognize these concepts, and how it can learn them in the first place. Our main goal is to introduce a general framework for these tasks and prove formally how both (recognition and learning) can be achieved. We show that both tasks can be accomplished even in presence of noise. For learning, we analyze Oja's rule formally, a well-known biologically-plausible rule for adjusting the weights of synapses. We complement the learning results with lower bounds asserting that, in order to recognize concepts of a certain hierarchical depth, neural networks must have a corresponding number of layers.

Published

2019

14. How to Color a French Flag--Biologically Inspired Algorithms for Scale-Invariant Patterning

Author

Ancona, Alberto, Bajwa, Ayesha, Lynch, Nancy, and Mallmann-Trenn, Frederik

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

In the French flag problem, initially uncolored cells on a grid must differentiate to become blue, white or red. The goal is for the cells to color the grid as a French flag, i.e., a three-colored triband, in a distributed manner. To solve a generalized version of the problem in a distributed computational setting, we consider two models: a biologically-inspired version that relies on morphogens (diffusing proteins acting as chemical signals) and a more abstract version based on reliable message passing between cellular agents. Much of developmental biology research has focused on concentration-based approaches using morphogens, since morphogen gradients are thought to be an underlying mechanism in tissue patterning. We show that both our model types easily achieve a French ribbon - a French flag in the 1D case. However, extending the ribbon to the 2D flag in the concentration model is somewhat difficult unless each agent has additional positional information. Assuming that cells are are identical, it is impossible to achieve a French flag or even a close approximation. In contrast, using a message-based approach in the 2D case only requires assuming that agents can be represented as constant size state machines. We hope that our insights may lay some groundwork for what kind of message passing abstractions or guarantees, if any, may be useful in analogy to cells communicating at long and short distances to solve patterning problems. In addition, we hope that our models and findings may be of interest in the design of nano-robots.

Published

2019

15. Winner-Take-All Computation in Spiking Neural Networks

Author

Lynch, Nancy, Musco, Cameron, and Parter, Merav

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Neural and Evolutionary Computing, Quantitative Biology - Neurons and Cognition

Abstract

In this work we study biological neural networks from an algorithmic perspective, focusing on understanding tradeoffs between computation time and network complexity. Our goal is to abstract real neural networks in a way that, while not capturing all interesting features, preserves high-level behavior and allows us to make biologically relevant conclusions. Towards this goal, we consider the implementation of algorithmic primitives in a simple yet biologically plausible model of $stochastic\ spiking\ neural\ networks$. In particular, we show how the stochastic behavior of neurons in this model can be leveraged to solve a basic $symmetry-breaking\ task$ in which we are given neurons with identical firing rates and want to select a distinguished one. In computational neuroscience, this is known as the winner-take-all (WTA) problem, and it is believed to serve as a basic building block in many tasks, e.g., learning, pattern recognition, and clustering. We provide efficient constructions of WTA circuits in our stochastic spiking neural network model, as well as lower bounds in terms of the number of auxiliary neurons required to drive convergence to WTA in a given number of steps. These lower bounds demonstrate that our constructions are near-optimal in some cases. This work covers and gives more in-depth proofs of a subset of results originally published in [LMP17a]. It is adapted from the last chapter of C. Musco's Ph.D. thesis [Mus18].

Published

2019

16. Spike-Based Winner-Take-All Computation: Fundamental Limits and Order-Optimal Circuits

Author

Su, Lili, Chang, Chia-Jung, and Lynch, Nancy

Subjects

Quantitative Biology - Neurons and Cognition, Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

Winner-Take-All (WTA) refers to the neural operation that selects a (typically small) group of neurons from a large neuron pool. It is conjectured to underlie many of the brain's fundamental computational abilities. However, not much is known about the robustness of a spike-based WTA network to the inherent randomness of the input spike trains. In this work, we consider a spike-based $k$--WTA model wherein $n$ randomly generated input spike trains compete with each other based on their underlying statistics, and $k$ winners are supposed to be selected. We slot the time evenly with each time slot of length $1\, ms$, and model the $n$ input spike trains as $n$ independent Bernoulli processes. The Bernoulli process is a good approximation of the popular Poisson process but is more biologically relevant as it takes the refractory periods into account. Due to the randomness in the input spike trains, no circuits can guarantee to successfully select the correct winners in finite time. We focus on analytically characterizing the minimal amount of time needed so that a target minimax decision accuracy (success probability) can be reached. We first derive an information-theoretic lower bound on the decision time. We show that to have a (minimax) decision error $\le \delta$ (where $\delta \in (0,1)$), the computation time of any WTA circuit is at least \[ ((1-\delta) \log(k(n -k)+1) -1)T_{\mathcal{R}}, \] where $T_{\mathcal{R}}$ is a difficulty parameter of a WTA task that is independent of $\delta$, $n$, and $k$. We then design a simple WTA circuit whose decision time is \[ O( \log\frac{1}{\delta}+\log k(n-k))T_{\mathcal{R}}). \] It turns out that for any fixed $\delta \in (0,1)$, this decision time is order-optimal in terms of its scaling in $n$, $k$, and $T_{\mathcal{R}}$.

Published

2019

17. Integrating Temporal Information to Spatial Information in a Neural Circuit

Author

Lynch, Nancy and Wang, Mien Brabeeba

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Neural and Evolutionary Computing

Abstract

In this paper, we consider networks of deterministic spiking neurons, firing synchronously at discrete times; such spiking neural networks are inspired by networks of neurons and synapses that occur in brains. We consider the problem of translating temporal information into spatial information in such networks, an important task that is carried out by actual brains. Specifically, we define two problems: "First Consecutive Spikes Counting (FCSC)" and "Total Spikes Counting (TSC)", which model spike and rate coding aspects of translating temporal information into spatial information respectively. Assuming an upper bound of $T$ on the length of the temporal input signal, we design two networks that solve these two problems, each using $O(\log T)$ neurons and terminating in time $1$. We also prove that there is no network with less than $T$ neurons that solves either question in time $0$.

Published

2019

18. Learning Hierarchically-Structured Concepts II: Overlapping Concepts, and Networks with Feedback

Author

Lynch, Nancy, primary and Mallmann-Trenn, Frederik, additional

Published

2023

19. A Basic Compositional Model for Spiking Neural Networks

Author

Lynch, Nancy, Musco, Cameron, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Jansen, Nils, editor, Stoelinga, Mariëlle, editor, and van den Bos, Petra, editor

Published

2022

20. SNOW Revisited: Understanding When Ideal READ Transactions Are Possible

Author

Konwar, Kishori M, Lloyd, Wyatt, Lu, Haonan, and Lynch, Nancy

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

READ transactions that read data distributed across servers dominate the workloads of real-world distributed storage systems. The SNOW Theorem stated that ideal READ transactions that have optimal latency and the strongest guarantees, i.e. "SNOW" READ transactions, are impossible in one specific setting that requires three or more clients: at least two readers and one writer. However, it left many open questions. We close all of these open questions with new impossibility results and new algorithms. First, we prove rigorously the result from the The SNOW Theorem paper saying that it is impossible to have a READ transactions system that satisfies SNOW properties with three or more clients. The insight we gained from this proof led to teasing out the implicit assumptions that are required to state the results and also, resolving the open question regarding the possibility of SNOW with two clients. We show that it is possible to design an algorithm, where SNOW is possible in a multi-writer, single-reader (MWSR) setting when a client can send messages to other clients; on the other hand, we prove it is impossible to implement SNOW in a multi-writer, single-reader (MWSR) setting, which is more general than the two-client setting, when client-to-client communication is disallowed. We also correct the previous claim in The SNOW Theorem paper that incorrectly identified one existing system, Eiger, as supporting the strongest guarantees (SW) and whose read-only transactions had bounded latency. Thus, there were no previous algorithms that provided the strongest guarantees and had bounded latency. Finally, we introduce the first two algorithms to provide the strongest guarantees with bounded latency.

Published

2018

21. Collaboratively Learning the Best Option on Graphs, Using Bounded Local Memory

Author

Su, Lili, Zubeldia, Martin, and Lynch, Nancy

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Mathematics - Optimization and Control

Abstract

We consider multi-armed bandit problems in social groups wherein each individual has bounded memory and shares the common goal of learning the best arm/option. We say an individual learns the best option if eventually (as $t\to \infty$) it pulls only the arm with the highest expected reward. While this goal is provably impossible for an isolated individual due to bounded memory, we show that, in social groups, this goal can be achieved easily with the aid of social persuasion (i.e., communication) as long as the communication networks/graphs satisfy some mild conditions. To deal with the interplay between the randomness in the rewards and in the social interaction, we employ the {\em mean-field approximation} method. Considering the possibility that the individuals in the networks may not be exchangeable when the communication networks are not cliques, we go beyond the classic mean-field techniques and apply a refined version of mean-field approximation: (1) Using coupling we show that, if the communication graph is connected and is either regular or has doubly-stochastic degree-weighted adjacency matrix, with probability $\to 1$ as the social group size $N \to \infty$, every individual in the social group learns the best option. (2) If the minimum degree of the graph diverges as $N \to \infty$, over an arbitrary but given finite time horizon, the sample paths describing the opinion evolutions of the individuals are asymptotically independent. In addition, the proportions of the population with different opinions converge to the unique solution of a system of ODEs. In the solution of the obtained ODEs, the proportion of the population holding the correct opinion converges to $1$ exponentially fast in time. Notably, our results hold even if the communication graphs are highly sparse., Comment: arXiv admin note: text overlap with arXiv:1802.08159. Authors' note: This work shares some overlap with our preliminary preprint arXiv:1802.08159 which focuses on complete graphs. arXiv:1802.08159 is combined with this work

Published

2018

22. A Basic Compositional Model for Spiking Neural Networks

Author

Lynch, Nancy and Musco, Cameron

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Neural and Evolutionary Computing

Abstract

We present a formal, mathematical foundation for modeling and reasoning about the behavior of $synchronous$, $stochastic$ $Spiking$ $Neural$ $Networks$ $(SNNs)$, which have been widely used in studies of neural computation. Our approach follows paradigms established in the field of concurrency theory. Our SNN model is based on directed graphs of neurons, classified as input, output, and internal neurons. We focus here on basic SNNs, in which a neuron's only state is a Boolean value indicating whether or not the neuron is currently firing. We also define the $external$ $behavior$ of an SNN, in terms of probability distributions on its external firing patterns. We define two operators on SNNs: a $composition$ $operator$, which supports modeling of SNNs as combinations of smaller SNNs, and a $hiding$ $operator$, which reclassifies some output behavior of an SNN as internal. We prove results showing how the external behavior of a network built using these operators is related to the external behavior of its component networks. Finally, we define the notion of a $problem$ to be solved by an SNN, and show how the composition and hiding operators affect the problems that are solved by the networks. We illustrate our definitions with three examples: a Boolean circuit constructed from gates, an $Attention$ network constructed from a $Winner$-$Take$-$All$ network and a $Filter$ network, and a toy example involving combining two networks in a cyclic fashion.

Published

2018

23. Self-Stabilizing Task Allocation In Spite of Noise

Author

Dornhaus, Anna, Lynch, Nancy, Mallmann-Trenn, Frederik, Pajak, Dominik, and Radeva, Tsvetomira

Subjects

Computer Science - Multiagent Systems, Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

We study the problem of distributed task allocation inspired by the behavior of social insects, which perform task allocation in a setting of limited capabilities and noisy environment feedback. We assume that each task has a demand that should be satisfied but not exceeded, i.e., there is an optimal number of ants that should be working on this task at a given time. The goal is to assign a near-optimal number of workers to each task in a distributed manner and without explicit access to the values of the demands nor the number of ants working on the task. We seek to answer the question of how the quality of task allocation depends on the accuracy of assessing whether too many (overload) or not enough (lack) ants are currently working on a given task. Concretely, we address the open question of solving task allocation in the model where each ant receives feedback that depends on the deficit defined as the (possibly negative) difference between the optimal demand and the current number of workers in the task. The feedback is modeled as a random variable that takes value lack or overload with probability given by a sigmoid of the deficit. Each ants receives the feedback independently, but the higher the overload or lack of workers for a task, the more likely it is that all the ants will receive the same, correct feedback from this task; the closer the deficit is to zero, the less reliable the feedback becomes. We measure the performance of task allocation algorithms using the notion of regret, defined as the absolute value of the deficit summed over all tasks and summed over time. We propose a simple, constant-memory, self-stabilizing, distributed algorithm that quickly converges from any initial distribution to a near-optimal assignment. We also show that our algorithm works not only under stochastic noise but also in an adversarial noise setting.

Published

2018

24. ARES: Adaptive, Reconfigurable, Erasure coded, atomic Storage

Author

Nicolaou, Nicolas, Cadambe, Viveck, Prakash, N., Trigeorgi, Andria, Konwar, Kishori M., Lynch, Nancy, and Medard, Muriel

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

Atomicity or strong consistency is one of the fundamental, most intuitive, and hardest to provide primitives in distributed shared memory emulations. To ensure survivability, scalability, and availability of a storage service in the presence of failures, traditional approaches for atomic memory emulation, in message passing environments, replicate the objects across multiple servers. Compared to replication based algorithms, erasure code-based atomic memory algorithms has much lower storage and communication costs, but usually, they are harder to design. The difficulty of designing atomic memory algorithms further grows, when the set of servers may be changed to ensure survivability of the service over software and hardware upgrades, while avoiding service interruptions. Atomic memory algorithms for performing server reconfiguration, in the replicated systems, are very few, complex, and are still part of an active area of research; reconfigurations of erasure-code based algorithms are non-existent. In this work, we present ARES, an algorithmic framework that allows reconfiguration of the underlying servers, and is particularly suitable for erasure-code based algorithms emulating atomic objects. ARES introduces new configurations while keeping the service available. To use with ARES we also propose a new, and to our knowledge, the first two-round erasure code based algorithm TREAS, for emulating multi-writer, multi-reader (MWMR) atomic objects in asynchronous, message-passing environments, with near-optimal communication and storage costs. Our algorithms can tolerate crash failures of any client and some fraction of servers, and yet, guarantee safety and liveness property. Moreover, by bringing together the advantages of ARES and TREAS, we propose an optimized algorithm where new configurations can be installed without the objects values passing through the reconfiguration clients.

Published

2018

25. On Simple Back-Off in Unreliable Radio Networks

Author

Gilbert, Seth, Lynch, Nancy, Newport, Calvin, and Pajak, Dominik

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

In this paper, we study local and global broadcast in the dual graph model, which describes communication in a radio network with both reliable and unreliable links. Existing work proved that efficient solutions to these problems are impossible in the dual graph model under standard assumptions. In real networks, however, simple back-off strategies tend to perform well for solving these basic communication tasks. We address this apparent paradox by introducing a new set of constraints to the dual graph model that better generalize the slow/fast fading behavior common in real networks. We prove that in the context of these new constraints, simple back-off strategies now provide efficient solutions to local and global broadcast in the dual graph model. We also precisely characterize how this efficiency degrades as the new constraints are reduced down to non-existent, and prove new lower bounds that establish this degradation as near optimal for a large class of natural algorithms. We conclude with a preliminary investigation of the performance of these strategies when we include additional generality to the model. These results provide theoretical foundations for the practical observation that simple back-off algorithms tend to work well even amid the complicated link dynamics of real radio networks.

Published

2018

26. Collaboratively Learning the Best Option, Using Bounded Memory

Author

Su, Lili, Zubeldia, Martin, and Lynch, Nancy

Subjects

Computer Science - Machine Learning, Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

We consider multi-armed bandit problems in social groups wherein each individual has bounded memory and shares the common goal of learning the best arm/option. We say an individual learns the best option if eventually (as $t \to \infty$) it pulls only the arm with the highest average reward. While this goal is provably impossible for an isolated individual, we show that, in social groups, this goal can be achieved easily with the aid of social persuasion, i.e., communication. Specifically, we study the learning dynamics wherein an individual sequentially decides on which arm to pull next based on not only its private reward feedback but also the suggestions provided by randomly chosen peers. Our learning dynamics are hard to analyze via explicit probabilistic calculations due to the stochastic dependency induced by social interaction. Instead, we employ the mean-field approximation method from statistical physics and we show: (1) With probability $\to 1$ as the social group size $N \to \infty $, every individual in the social group learns the best option. (2) Over an arbitrary finite time horizon $[0, T]$, with high probability (in $N$), the fraction of individuals that prefer the best option grows to 1 exponentially fast as $t$ increases ($t\in [0, T]$). A major innovation of our mean-filed analysis is a simple yet powerful technique to deal with absorbing states in the interchange of limits $N \to \infty$ and $t \to \infty $. The mean-field approximation method allows us to approximate the probabilistic sample paths of our learning dynamics by a deterministic and smooth trajectory that corresponds to the unique solution of a well-behaved system of ordinary differential equations (ODEs). Such an approximation is desired because the analysis of a system of ODEs is relatively easier than that of the original stochastic system., Comment: Authors's comments: This is a preliminary preprint of our work on complete graphs. New aspects of our approach on general graphs have moved to: Collaboratively Learning the Best Option on Graphs, Using Bounded Local Memory, arXiv:1811.03968

Published

2018

27. Neuro-RAM Unit with Applications to Similarity Testing and Compression in Spiking Neural Networks

Author

Lynch, Nancy, Musco, Cameron, and Parter, Merav

Subjects

Computer Science - Neural and Evolutionary Computing, Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Data Structures and Algorithms, Quantitative Biology - Neurons and Cognition

Abstract

We study distributed algorithms implemented in a simplified biologically inspired model for stochastic spiking neural networks. We focus on tradeoffs between computation time and network complexity, along with the role of randomness in efficient neural computation. It is widely accepted that neural computation is inherently stochastic. In recent work, we explored how this stochasticity could be leveraged to solve the `winner-take-all' leader election task. Here, we focus on using randomness in neural algorithms for similarity testing and compression. In the most basic setting, given two $n$-length patterns of firing neurons, we wish to distinguish if the patterns are equal or $\epsilon$-far from equal. Randomization allows us to solve this task with a very compact network, using $O \left (\frac{\sqrt{n}\log n}{\epsilon}\right)$ auxiliary neurons, which is sublinear in the input size. At the heart of our solution is the design of a $t$-round neural random access memory, or indexing network, which we call a neuro-RAM. This module can be implemented with $O(n/t)$ auxiliary neurons and is useful in many applications beyond similarity testing. Using a VC dimension-based argument, we show that the tradeoff between runtime and network size in our neuro-RAM is nearly optimal. Our result has several implications -- since our neuro-RAM can be implemented with deterministic threshold gates, it shows that, in contrast to similarity testing, randomness does not provide significant computational advantages for this problem. It also establishes a separation between feedforward networks whose gates spike with sigmoidal probability functions, and well-studied deterministic sigmoidal networks, whose gates output real number sigmoidal values, and which can implement a neuro-RAM much more efficiently.

Published

2017

28. Beeping a Maximal Independent Set Fast

Author

Holzer, Stephan and Lynch, Nancy

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

We adapt a recent algorithm by Ghaffari [SODA'16] for computing a Maximal Independent Set in the LOCAL model, so that it works in the significantly weaker BEEP model. For networks with maximum degree $\Delta$, our algorithm terminates locally within time $O((\log \Delta + \log (1/\epsilon)) \cdot \log(1/\epsilon))$, with probability at least $1 - \epsilon$. The key idea of the modification is to replace explicit messages about transmission probabilities with estimates based on the number of received messages. After the successful introduction (and implicit use) of local analysis, e.g., by Barenboim et al. [JACM'16], Chung et al. [PODC'14], Ghaffari [SODA'16], and Halldorsson et al. [PODC'15], we study this concept in the BEEP model for the first time. By doing so, we improve over local bounds that are implicitly derived from previous work (that uses traditional global analysis) on computing a Maximal Independent Set in the \beep model for a large range of values of the parameter $\Delta$. At the same time, we show that our algorithm in the \beep model only needs to pay a $\log(1/\epsilon)$ factor in the runtime compared to the best known MIS algorithm in the much more powerful \local model. We demonstrate that this overhead is negligible, as communication via beeps can be implemented using significantly less resources than communication in the LOCAL model. In particular, when looking at implementing these models, one round of the \local model needs at least $O(\Delta)$ time units, while one round in the BEEP model needs $O(\log\Delta)$ time units, an improvement that diminishes the loss of a $\log(1/\epsilon)$ factor in most settings., Comment: Full version of a brief announcement with the same title that appeared at the 30th International Symposium on Distributed Computing (DISC), Paris, France, September 2016. 17 pages

Published

2017

29. A Layered Architecture for Erasure-Coded Consistent Distributed Storage

Author

Konwar, Kishori M., Prakash, N., Lynch, Nancy, and Medard, Muriel

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Information Theory

Abstract

Motivated by emerging applications to the edge computing paradigm, we introduce a two-layer erasure-coded fault-tolerant distributed storage system offering atomic access for read and write operations. In edge computing, clients interact with an edge-layer of servers that is geographically near; the edge-layer in turn interacts with a back-end layer of servers. The edge-layer provides low latency access and temporary storage for client operations, and uses the back-end layer for persistent storage. Our algorithm, termed Layered Data Storage (LDS) algorithm, offers several features suitable for edge-computing systems, works under asynchronous message-passing environments, supports multiple readers and writers, and can tolerate $f_1 < n_1/2$ and $f_2 < n_2/3$ crash failures in the two layers having $n_1$ and $n_2$ servers, respectively. We use a class of erasure codes known as regenerating codes for storage of data in the back-end layer. The choice of regenerating codes, instead of popular choices like Reed-Solomon codes, not only optimizes the cost of back-end storage, but also helps in optimizing communication cost of read operations, when the value needs to be recreated all the way from the back-end. The two-layer architecture permits a modular implementation of atomicity and erasure-code protocols; the implementation of erasure-codes is mostly limited to interaction between the two layers. We prove liveness and atomicity of LDS, and also compute performance costs associated with read and write operations. Further, in a multi-object system running $N$ independent instances of LDS, where only a small fraction of the objects undergo concurrent accesses at any point during the execution, the overall storage cost is dominated by that of persistent storage in the back-end layer, and is given by $\Theta(N)$., Comment: To appear in ACM PODC 2017

Published

2017

30. Lack of Quorum Sensing Leads to Failure of Consensus in Temnothorax Ant Emigration

Author

Zhao, Jiajia, Su, Lili, Lynch, Nancy, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Johnen, Colette, editor, Schiller, Elad Michael, editor, and Schmid, Stefan, editor

Published

2021

31. How to Color a French Flag : Biologically Inspired Algorithms for Scale-Invariant Patterning

Author

Ancona, Bertie, Bajwa, Ayesha, Lynch, Nancy, Mallmann-Trenn, Frederik, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Kohayakawa, Yoshiharu, editor, and Miyazawa, Flávio Keidi, editor

Published

2020

32. Learning hierarchically-structured concepts

Author

Lynch, Nancy and Mallmann-Trenn, Frederik

Published

2021

33. Computational Tradeoffs in Biological Neural Networks: Self-Stabilizing Winner-Take-All Networks

Author

Lynch, Nancy, Musco, Cameron, and Parter, Merav

Subjects

Computer Science - Neural and Evolutionary Computing, Computer Science - Distributed, Parallel, and Cluster Computing, Quantitative Biology - Neurons and Cognition

Abstract

We initiate a line of investigation into biological neural networks from an algorithmic perspective. We develop a simplified but biologically plausible model for distributed computation in stochastic spiking neural networks and study tradeoffs between computation time and network complexity in this model. Our aim is to abstract real neural networks in a way that, while not capturing all interesting features, preserves high-level behavior and allows us to make biologically relevant conclusions. In this paper, we focus on the important `winner-take-all' (WTA) problem, which is analogous to a neural leader election unit: a network consisting of $n$ input neurons and $n$ corresponding output neurons must converge to a state in which a single output corresponding to a firing input (the `winner') fires, while all other outputs remain silent. Neural circuits for WTA rely on inhibitory neurons, which suppress the activity of competing outputs and drive the network towards a converged state with a single firing winner. We attempt to understand how the number of inhibitors used affects network convergence time. We show that it is possible to significantly outperform naive WTA constructions through a more refined use of inhibition, solving the problem in $O(\theta)$ rounds in expectation with just $O(\log^{1/\theta} n)$ inhibitors for any $\theta$. An alternative construction gives convergence in $O(\log^{1/\theta} n)$ rounds with $O(\theta)$ inhibitors. We compliment these upper bounds with our main technical contribution, a nearly matching lower bound for networks using $\ge \log\log n$ inhibitors. Our lower bound uses familiar indistinguishability and locality arguments from distributed computing theory. It lets us derive a number of interesting conclusions about the structure of any network solving WTA with good probability, and the use of randomness and inhibition within such a network.

Published

2016

34. Information-Theoretic Lower Bounds on the Storage Cost of Shared Memory Emulation

Author

Cadambe, Viveck R., Wang, Zhiying, and Lynch, Nancy

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Information Theory, 68P30, 68W15, C.2.4, D.4.2

Abstract

The focus of this paper is to understand storage costs of emulating an atomic shared memory over an asynchronous, distributed message passing system. Previous literature has developed several shared memory emulation algorithms based on replication and erasure coding techniques. In this paper, we present information-theoretic lower bounds on the storage costs incurred by shared memory emulation algorithms. Our storage cost lower bounds are universally applicable, that is, we make no assumption on the structure of the algorithm or the method of encoding the data. We consider an arbitrary algorithm $A$ that implements an atomic multi-writer single-reader (MWSR) shared memory variable whose values come from a finite set $\mathcal{V}$ over a system of $N$ servers connected by point-to-point asynchronous links. We require that in every fair execution of algorithm $A$ where the number of server failures is smaller than a parameter $f$, every operation invoked at a non-failing client terminates. We define the storage cost of a server in algorithm $A$ as the logarithm (to base 2) of number of states it can take on; the total-storage cost of algorithm $A$ is the sum of the storage cost of all servers. Our results are as follows. (i) We show that if algorithm $A$ does not use server gossip, then the total storage cost is lower bounded by $2 \frac{N}{N-f+1}\log_2|\mathcal{V}|-o(\log_2|\mathcal{V}|)$. (ii) The total storage cost is at least $2 \frac{N}{N-f+2} \log_{2}|\mathcal{V}|-o(\log_{2}|\mathcal{V}|)$ even if the algorithm uses server gossip. (iii) We consider algorithms where the write protocol sends information about the value in at most one phase. We show that the total storage cost is at least $\nu^* \frac{N}{N-f+\nu^*-1} \log_2( |\mathcal{V}|)- o(\log_2(|\mathcal{V}|),$ where $\nu^*$ is the minimum of $f+1$ and the number of active write operations of an execution.

Published

2016

35. RADON: Repairable Atomic Data Object in Networks

Author

Konwar, Kishori M., Prakash, N., Lynch, Nancy, and Medard, Muriel

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Information Theory

Abstract

Erasure codes offer an efficient way to decrease storage and communication costs while implementing atomic memory service in asynchronous distributed storage systems. In this paper, we provide erasure-code-based algorithms having the additional ability to perform background repair of crashed nodes. A repair operation of a node in the crashed state is triggered externally, and is carried out by the concerned node via message exchanges with other active nodes in the system. Upon completion of repair, the node re-enters active state, and resumes participation in ongoing and future read, write, and repair operations. To guarantee liveness and atomicity simultaneously, existing works assume either the presence of nodes with stable storage, or presence of nodes that never crash during the execution. We demand neither of these; instead we consider a natural, yet practical network stability condition $N1$ that only restricts the number of nodes in the crashed/repair state during broadcast of any message. We present an erasure-code based algorithm $RADON_C$ that is always live, and guarantees atomicity as long as condition $N1$ holds. In situations when the number of concurrent writes is limited, $RADON_C$ has significantly improved storage and communication cost over a replication-based algorithm $RADON_R$, which also works under $N1$. We further show how a slightly stronger network stability condition $N2$ can be used to construct algorithms that never violate atomicity. The guarantee of atomicity comes at the expense of having an additional phase during the read and write operations., Comment: To be presented at OPODIS 2016

Published

2016

36. Storage-Optimized Data-Atomic Algorithms for Handling Erasures and Errors in Distributed Storage Systems

Author

Konwar, Kishori M., Prakash, N., Kantor, Erez, Lynch, Nancy, Medard, Muriel, and Schwarzmann, Alexander A.

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Information Theory

Abstract

Erasure codes are increasingly being studied in the context of implementing atomic memory objects in large scale asynchronous distributed storage systems. When compared with the traditional replication based schemes, erasure codes have the potential of significantly lowering storage and communication costs while simultaneously guaranteeing the desired resiliency levels. In this work, we propose the Storage-Optimized Data-Atomic (SODA) algorithm for implementing atomic memory objects in the multi-writer multi-reader setting. SODA uses Maximum Distance Separable (MDS) codes, and is specifically designed to optimize the total storage cost for a given fault-tolerance requirement. For tolerating $f$ server crashes in an $n$-server system, SODA uses an $[n, k]$ MDS code with $k=n-f$, and incurs a total storage cost of $\frac{n}{n-f}$. SODA is designed under the assumption of reliable point-to-point communication channels. The communication cost of a write and a read operation are respectively given by $O(f^2)$ and $\frac{n}{n-f}(\delta_w+1)$, where $\delta_w$ denotes the number of writes that are concurrent with the particular read. In comparison with the recent CASGC algorithm, which also uses MDS codes, SODA offers lower storage cost while pays more on the communication cost. We also present a modification of SODA, called SODA$_{\text{err}}$, to handle the case where some of the servers can return erroneous coded elements during a read operation. Specifically, in order to tolerate $f$ server failures and $e$ error-prone coded elements, the SODA$_{\text{err}}$ algorithm uses an $[n, k]$ MDS code such that $k=n-2e-f$. SODA$_{\text{err}}$ also guarantees liveness and atomicity, while maintaining an optimized total storage cost of $\frac{n}{n-f-2e}$., Comment: Accepted for Publication at IEEE IPDPS, 2016

Published

2016

37. Dynamic Input/Output Automata: a Formal and Compositional Model for Dynamic Systems

Author

Attie, Paul C. and Lynch, Nancy A.

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Formal Languages and Automata Theory, C.2.4, D.1.3, D.2.4, F.3.2

Abstract

We present dynamic I/O automata (DIOA), a compositional model of dynamic systems. In DIOA, automata can be created and destroyed dynamically, as computation proceeds, and an automaton can dynamically change its signature, i.e., the set of actions in which it can participate. DIOA features operators for parallel composition, action hiding, action renaming, a notion of automaton creation, and a notion of behavioral subtyping by means of trace inclusion. DIOA can model mobility, using signature modification, and is hierarchical: a dynamically changing system of interacting automata is itself modeled as a single automaton. We also show that parallel composition, action hiding, action renaming, and (subject to some technical conditions) automaton creation are all monotonic with respect to trace inclusion: if one component is replaced by another whose traces are a subset of the former, then the set of traces of the system as a whole can only be reduced., Comment: 65 pages, 11 figures, Information and Computation, Available online 21 March 2016

Published

2016

38. Ant-Inspired Density Estimation via Random Walks

Author

Musco, Cameron, Su, Hsin-Hao, and Lynch, Nancy

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Data Structures and Algorithms

Abstract

Many ant species employ distributed population density estimation in applications ranging from quorum sensing [Pra05], to task allocation [Gor99], to appraisal of enemy colony strength [Ada90]. It has been shown that ants estimate density by tracking encounter rates -- the higher the population density, the more often the ants bump into each other [Pra05,GPT93]. We study distributed density estimation from a theoretical perspective. We prove that a group of anonymous agents randomly walking on a grid are able to estimate their density within a small multiplicative error in few steps by measuring their rates of encounter with other agents. Despite dependencies inherent in the fact that nearby agents may collide repeatedly (and, worse, cannot recognize when this happens), our bound nearly matches what would be required to estimate density by independently sampling grid locations. From a biological perspective, our work helps shed light on how ants and other social insects can obtain relatively accurate density estimates via encounter rates. From a technical perspective, our analysis provides new tools for understanding complex dependencies in the collision probabilities of multiple random walks. We bound the strength of these dependencies using $local\ mixing\ properties$ of the underlying graph. Our results extend beyond the grid to more general graphs and we discuss applications to size estimation for social networks and density estimation for robot swarms.

Published

2016

39. A Geometry-Sensitive Quorum Sensing Algorithm for the Best-of-N Site Selection Problem

Author

Cai, Grace, primary and Lynch, Nancy, additional

Published

2022

40. Computing in Additive Networks with Bounded-Information Codes

Author

Censor-Hillel, Keren, Kantor, Erez, Lynch, Nancy, and Parter, Merav

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Information Theory, Computer Science - Networking and Internet Architecture

Abstract

This paper studies the theory of the additive wireless network model, in which the received signal is abstracted as an addition of the transmitted signals. Our central observation is that the crucial challenge for computing in this model is not high contention, as assumed previously, but rather guaranteeing a bounded amount of \emph{information} in each neighborhood per round, a property that we show is achievable using a new random coding technique. Technically, we provide efficient algorithms for fundamental distributed tasks in additive networks, such as solving various symmetry breaking problems, approximating network parameters, and solving an \emph{asymmetry revealing} problem such as computing a maximal input. The key method used is a novel random coding technique that allows a node to successfully decode the received information, as long as it does not contain too many distinct values. We then design our algorithms to produce a limited amount of information in each neighborhood in order to leverage our enriched toolbox for computing in additive networks.

Published

2015

41. A Local Broadcast Layer for the SINR Network Model

Author

Halldorsson, Magnus M., Holzer, Stephan, and Lynch, Nancy

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

We present the first algorithm that implements an abstract MAC (absMAC) layer in the Signal-to-Interference-plus-Noise-Ratio (SINR) wireless network model. We first prove that efficient SINR implementations are not possible for the standard absMAC specification. We modify that specification to an "approximate" version that better suits the SINR model. We give an efficient algorithm to implement the modified specification, and use it to derive efficient algorithms for higher-level problems of global broadcast and consensus. In particular, we show that the absMAC progress property has no efficient implementation in terms of the SINR strong connectivity graph $G_{1-\epsilon}$, which contains edges between nodes of distance at most $(1-\epsilon)$ times the transmission range, where $\epsilon>0$ is a small constant that can be chosen by the user. This progress property bounds the time until a node is guaranteed to receive some message when at least one of its neighbors is transmitting. To overcome this limitation, we introduce the slightly weaker notion of approximate progress into the absMAC specification. We provide a fast implementation of the modified specification, based on decomposing a known algorithm into local and global parts. We analyze our algorithm in terms of local parameters such as node degrees, rather than global parameters such as the overall number of nodes. A key contribution is our demonstration that such a local analysis is possible even in the presence of global interference. Our absMAC algorithm leads to several new, efficient algorithms for solving higher-level problems in the SINR model. Namely, by combining our algorithm with known high-level algorithms, we obtain an improved algorithm for global single-message broadcast in the SINR model, and the first efficient algorithm for multi-message broadcast in that model.

Published

2015

42. Distributed House-Hunting in Ant Colonies

Author

Ghaffari, Mohsen, Musco, Cameron, Radeva, Tsvetomira, and Lynch, Nancy

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

We introduce the study of the ant colony house-hunting problem from a distributed computing perspective. When an ant colony's nest becomes unsuitable due to size constraints or damage, the colony must relocate to a new nest. The task of identifying and evaluating the quality of potential new nests is distributed among all ants. The ants must additionally reach consensus on a final nest choice and the full colony must be transported to this single new nest. Our goal is to use tools and techniques from distributed computing theory in order to gain insight into the house-hunting process. We develop a formal model for the house-hunting problem inspired by the behavior of the Temnothorax genus of ants. We then show a \Omega(log n) lower bound on the time for all n ants to agree on one of k candidate nests. We also present two algorithms that solve the house-hunting problem in our model. The first algorithm solves the problem in optimal O(log n) time but exhibits some features not characteristic of natural ant behavior. The second algorithm runs in O(k log n) time and uses an extremely simple and natural rule for each ant to decide on the new nest., Comment: To appear in PODC 2015

Published

2015

43. Consensus using Asynchronous Failure Detectors

Author

Lynch, Nancy and Sastry, Srikanth

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

The FLP result shows that crash-tolerant consensus is impossible to solve in asynchronous systems, and several solutions have been proposed for crash-tolerant consensus under alternative (stronger) models. One popular approach is to augment the asynchronous system with appropriate failure detectors, which provide (potentially unreliable) information about process crashes in the system, to circumvent the FLP impossibility. In this paper, we demonstrate the exact mechanism by which (sufficiently powerful) asynchronous failure detectors enable solving crash-tolerant consensus. Our approach, which borrows arguments from the FLP impossibility proof and the famous result from CHT, which shows that $\Omega$ is a weakest failure detector to solve consensus, also yields a natural proof to $\Omega$ as a weakest asynchronous failure detector to solve consensus. The use of I/O automata theory in our approach enables us to model execution in a more detailed fashion than CHT and also addresses the latent assumptions and assertions in the original result in CHT.

Published

2015

44. How to Color a French Flag : Biologically Inspired Algorithms for Scale-Invariant Patterning

Author

Ancona, Bertie, Bajwa, Ayesha, Lynch, Nancy, Mallmann-Trenn, Frederik, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Censor-Hillel, Keren, editor, and Flammini, Michele, editor

Published

2019

45. A Coded Shared Atomic Memory Algorithm for Message Passing Architectures

Author

Cadambe, Viveck R., Lynch, Nancy, Médard, Muriel, and Musial, Peter

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Information Theory

Abstract

This paper considers the communication and storage costs of emulating atomic (linearizable) multi-writer multi-reader shared memory in distributed message-passing systems. The paper contains three main contributions: (1) We present a atomic shared-memory emulation algorithm that we call Coded Atomic Storage (CAS). This algorithm uses erasure coding methods. In a storage system with $N$ servers that is resilient to $f$ server failures, we show that the communication cost of CAS is $\frac{N}{N-2f}$. The storage cost of CAS is unbounded. (2) We present a modification of the CAS algorithm known as CAS with Garbage Collection (CASGC). The CASGC algorithm is parametrized by an integer $\delta$ and has a bounded storage cost. We show that in every execution where the number of write operations that are concurrent with a read operation is no bigger than $\delta$, the CASGC algorithm with parameter $\delta$ satisfies atomicity and liveness. We explicitly characterize the storage cost of CASGC, and show that it has the same communication cost as CAS. (3) We describe an algorithm known as the Communication Cost Optimal Atomic Storage (CCOAS) algorithm that achieves a smaller communication cost than CAS and CASGC. In particular, CCOAS incurs read and write communication costs of $\frac{N}{N-f}$ measured in terms of number of object values. We also discuss drawbacks of CCOAS as compared with CAS and CASGC., Comment: Part of the results to appear in IEEE Network Computing and Applications (NCA), Aug 2014. This report supersedes MIT CSAIL technical report MIT-CSAIL-TR-2013-016

Published

2014

46. Trade-offs between Selection Complexity and Performance when Searching the Plane without Communication

Author

Lenzen, Christoph, Lynch, Nancy, Newport, Calvin, and Radeva, Tsvetomira

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

We consider the ANTS problem [Feinerman et al.] in which a group of agents collaboratively search for a target in a two-dimensional plane. Because this problem is inspired by the behavior of biological species, we argue that in addition to studying the {\em time complexity} of solutions it is also important to study the {\em selection complexity}, a measure of how likely a given algorithmic strategy is to arise in nature due to selective pressures. In more detail, we propose a new selection complexity metric $\chi$, defined for algorithm ${\cal A}$ such that $\chi({\cal A}) = b + \log \ell$, where $b$ is the number of memory bits used by each agent and $\ell$ bounds the fineness of available probabilities (agents use probabilities of at least $1/2^\ell$). In this paper, we study the trade-off between the standard performance metric of speed-up, which measures how the expected time to find the target improves with $n$, and our new selection metric. In particular, consider $n$ agents searching for a treasure located at (unknown) distance $D$ from the origin (where $n$ is sub-exponential in $D$). For this problem, we identify $\log \log D$ as a crucial threshold for our selection complexity metric. We first prove a new upper bound that achieves a near-optimal speed-up of $(D^2/n +D) \cdot 2^{O(\ell)}$ for $\chi({\cal A}) \leq 3 \log \log D + O(1)$. In particular, for $\ell \in O(1)$, the speed-up is asymptotically optimal. By comparison, the existing results for this problem [Feinerman et al.] that achieve similar speed-up require $\chi({\cal A}) = \Omega(\log D)$. We then show that this threshold is tight by describing a lower bound showing that if $\chi({\cal A}) < \log \log D - \omega(1)$, then with high probability the target is not found within $D^{2-o(1)}$ moves per agent. Hence, there is a sizable gap to the straightforward $\Omega(D^2/n + D)$ lower bound in this setting., Comment: appears in PODC 2014

Published

2014

47. Multi-Message Broadcast with Abstract MAC Layers and Unreliable Links

Author

Ghaffari, Mohsen, Kantor, Erez, Lynch, Nancy, and Newport, Calvin

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

We study the multi-message broadcast problem using abstract MAC layer models of wireless networks. These models capture the key guarantees of existing MAC layers while abstracting away low-level details such as signal propagation and contention. We begin by studying upper and lower bounds for this problem in a {\em standard abstract MAC layer model}---identifying an interesting dependence between the structure of unreliable links and achievable time complexity. In more detail, given a restriction that devices connected directly by an unreliable link are not too far from each other in the reliable link topology, we can (almost) match the efficiency of the reliable case. For the related restriction, however, that two devices connected by an unreliable link are not too far from each other in geographic distance, we prove a new lower bound that shows that this efficiency is impossible. We then investigate how much extra power must be added to the model to enable a new order of magnitude of efficiency. In more detail, we consider an {\em enhanced abstract MAC layer model} and present a new multi-message broadcast algorithm that (under certain natural assumptions) solves the problem in this model faster than any known solutions in an abstract MAC layer setting.

Published

2014

48. Bounded-Contention Coding for Wireless Networks in the High SNR Regime

Author

Censor-Hillel, Keren, Haeupler, Bernhard, Lynch, Nancy, and Médard, Muriel

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Data Structures and Algorithms, Computer Science - Information Theory

Abstract

Efficient communication in wireless networks is typically challenged by the possibility of interference among several transmitting nodes. Much important research has been invested in decreasing the number of collisions in order to obtain faster algorithms for communication in such networks. This paper proposes a novel approach for wireless communication, which embraces collisions rather than avoiding them, over an additive channel. It introduces a coding technique called Bounded-Contention Coding (BCC) that allows collisions to be successfully decoded by the receiving nodes into the original transmissions and whose complexity depends on a bound on the contention among the transmitters. BCC enables deterministic local broadcast in a network with n nodes and at most a transmitters with information of l bits each within O(a log n + al) bits of communication with full-duplex radios, and O((a log n + al)(log n)) bits, with high probability, with half-duplex radios. When combined with random linear network coding, BCC gives global broadcast within O((D + a + log n)(a log n + l)) bits, with high probability. This also holds in dynamic networks that can change arbitrarily over time by a worst-case adversary. When no bound on the contention is given, it is shown how to probabilistically estimate it and obtain global broadcast that is adaptive to the true contention in the network.

Published

2012

49. Bounds on Contention Management in Radio Networks

Author

Ghaffari, Mohsen, Haeupler, Bernhard, Lynch, Nancy, and Newport, Calvin

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Distributed, Parallel, and Cluster Computing, Mathematics - Combinatorics

Abstract

The local broadcast problem assumes that processes in a wireless network are provided messages, one by one, that must be delivered to their neighbors. In this paper, we prove tight bounds for this problem in two well-studied wireless network models: the classical model, in which links are reliable and collisions consistent, and the more recent dual graph model, which introduces unreliable edges. Our results prove that the Decay strategy, commonly used for local broadcast in the classical setting, is optimal. They also establish a separation between the two models, proving that the dual graph setting is strictly harder than the classical setting, with respect to this primitive.

Published

2012

50. How to Color a French Flag

Author

Ancona, Bertie, primary, Bajwa, Ayesha, additional, Lynch, Nancy, additional, and Mallmann-Trenn, Frederik, additional

Published

2020