Hamed Omidvar scite author profile

Hamed Omidvar

5Publications

71Citation Statements Received

81Citation Statements Given

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154

Affiliations

University of California, San Diego, Sharif University of Technology

Publications

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Self-organized Segregation on the Grid

Omidvar

Franceschetti

2017

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We consider an agent-based model with exponentially distributed waiting times in which two types of agents interact locally over a graph, and based on this interaction and on the value of a common intolerance threshold τ , decide whether to change their types. This is equivalent to a zero-temperature Ising model with Glauber dynamics, an Asynchronous Cellular Automaton (ACA) with extended Moore neighborhoods, or a Schelling model of self-organized segregation in an open system, and has applications in the analysis of social and biological networks, and spin glasses systems. Some rigorous results were recently obtained in the theoretical computer science literature, and this work provides several extensions. We enlarge the intolerance interval leading to the expected formation of large segregated regions of agents of a single type from the known size > 0 to size ≈ 0.134. Namely, we show that for 0.433 < τ < 1/2 (and by symmetry 1/2 < τ < 0.567), the expected size of the largest segregated region containing an arbitrary agent is exponential in the size of the neighborhood. We further extend the interval leading to expected large segregated regions to size ≈ 0.312 considering "almost segregated" regions, namely regions where the ratio of the number of agents of one type and the number of agents of the other type vanishes quickly as the size of the neighborhood grows. In this case, we show that for 0.344 < τ ≤ 0.433 (and by symmetry for 0.567 ≤ τ < 0.656) the expected size of the largest almost segregated region containing an arbitrary agent is exponential in the size of the neighborhood. This behavior is reminiscent of supercritical percolation, where small clusters of empty sites can be observed within any sufficiently large region of the occupied percolation cluster. The exponential bounds that we provide also imply that complete segregation, where agents of a single type cover the whole grid, does not occur with high probability for p = 1/2 and the range of intolerance considered.

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Shape of diffusion and size of monochromatic region of a two-dimensional spin system

Omidvar

Franceschetti

2018

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An energy-efficient multi-sensor scheduling mechanism with QoS support for WBANs

Omidvar

Ashtiani

Javidi

et al. 2014

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Self-organized Segregation on the Grid

Omidvar¹,

Franceschetti²

2017

J Stat Phys

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We consider an agent-based model in which two types of agents interact locally over a graph and have a common intolerance threshold $\tau$ for changing their types with exponentially distributed waiting times. The model is equivalent to an unperturbed Schelling model of self-organized segregation, an Asynchronous Cellular Automata (ACA) with extended Moore neighborhoods, or a zero-temperature Ising model with Glauber dynamics, and has applications in the analysis of social and biological networks, and spin glasses systems. Some rigorous results were recently obtained in the theoretical computer science literature, and this work provides several extensions. We enlarge the intolerance interval leading to the formation of large segregated regions of agents of a single type from the known size $\epsilon>0$ to size $\approx 0.134$. Namely, we show that for $0.433 < \tau < 1/2$ (and by symmetry $1/2<\tau<0.567$), the expected size of the largest segregated region containing an arbitrary agent is exponential in the size of the neighborhood. We further extend the interval leading to large segregated regions to size $\approx 0.312$ considering "almost segregated" regions, namely regions where the ratio of the number of agents of one type and the number of agents of the other type vanishes quickly as the size of the neighborhood grows. In this case, we show that for $0.344 < \tau \leq 0.433$ (and by symmetry for $0.567 \leq \tau<0.656$) the expected size of the largest almost segregated region containing an arbitrary agent is exponential in the size of the neighborhood. The exponential bounds that we provide also imply that complete segregation, where agents of a single type cover the whole grid, does not occur with high probability for $p=1/2$ and the range of tolerance considered

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Gamma rays transmutation of Palladium by bremsstrahlung and laser inverse Compton scattering

Irani

Omidvar

Sadighi‐Bonabi

2014

Energy Conversion and Management

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Hamed Omidvar

Self-organized Segregation on the Grid

Shape of diffusion and size of monochromatic region of a two-dimensional spin system

An energy-efficient multi-sensor scheduling mechanism with QoS support for WBANs

Self-organized Segregation on the Grid

Gamma rays transmutation of Palladium by bremsstrahlung and laser inverse Compton scattering

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