An experimental power profile of Energy Efficient Ethernet switches

Sivaraman, Vijay; Reviriego, Pedro; Zhi, Zhao; Sánchez‐Macian, Alfonso; Vishwanath, Arun; Maestro, Juan Antonio; Russell, Craig

doi:10.1016/j.comcom.2014.02.019

Cited by 6 publications

(5 citation statements)

References 19 publications

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“…For example, an on-cable with 1% load and another with 100% load consume the same amount of energy. Note that in practice, each port of energy-efficient switches continues to consume the maximum power even with 10% traffic load [30]. Let ε t be the energy saving in stage t. Formally, it is computed as…”

Section: Preliminariesmentioning

confidence: 99%

Multi-Path Routing in Green Multi-Stage Upgrade for Bundled-Links SDN/OSPF-ECMP Networks

et al. 2021

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This paper considers the novel problem of upgrading a legacy network into a Software Defined Network (SDN) over multiple stages and saving energy in the upgraded network or hybrid SDN. That is, in each stage, the problem at hand is to select and replace legacy switches with SDN switches, and reroute traffic to power off as many unused cables as possible to save energy. The operator has to also consider (i) the available budget at each stage, (ii) maximum path delays, (iii) maximum link utilization, (iv) per-stage increase (decrease) in traffic size (upgrade cost), and (v) the Open Shortest Path First -Equal Cost Multi-Path protocol. This paper addresses two multi-path routing scenarios: 1) non link-disjoint, and 2) linkdisjoint. It outlines a Mixed Integer Program and a heuristic algorithm for each scenario. The experimental results show that (i) both solutions for scenario-1 produce only up to 0.63% higher energy saving than those for scenario-2, (ii) the mixed integer program (heuristic algorithm) for both scenarios give an energy saving of up to 71.93% (71.64%), (iii) using a larger budget and/or number of stages increases the energy saving, and (iv) the saving achieved by the heuristic solution for each scenario is within 4% from the optimal saving.

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Section: Preliminariesmentioning

confidence: 99%

Multi-Path Routing in Green Multi-Stage Upgrade for Bundled-Links SDN/OSPF-ECMP Networks

et al. 2021

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“…To simulate the results of the power profile unaware algorithms we eliminated all but the most used outgoing link for each node when using SPF routing. 5 Then, we calculated the global power usage in the modified graph. We found that energy usage increases 9.5 % for links with logarithmic cost function when compared with the unmodified network using SPF as a routing algorithm.…”

Section: Cost Functionmentioning

confidence: 99%

“…These high energy demands have spurred successful research on all areas of networking, from the link level [3][4][5][6][7] to the networking layer adapting the routing decisions, as suggested in Gupta's seminal paper [8]. However, these traffic engineering proposals were initially constrained to the mere aggregation of traffic during low activity periods to power off some devices, as that was the only way a non-power aware device could be made to draw less power.…”

Section: Introductionmentioning

confidence: 99%

An ant colonization routing algorithm to minimize network power consumption

Rodríguez-Pérez

Herrería-Alonso

Fernández‐Veiga

et al. 2015

Journal of Network and Computer Applications

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Rising energy consumption of IT infrastructure concerns have spurred the development of more power efficient networking equipment and algorithms. When old equipment just drew an almost constant amount of power regardless of the traffic load, there were some efforts to minimize the total energy usage by modifying routing decisions to aggregate traffic in a minimal set of links, creating the opportunity to power off some unused equipment during low traffic periods. New equipment, with power profile functions depending on the offered load, presents new challenges for optimal routing. The goal now is not just to power some links down, but to aggregate and/or spread the traffic so that devices operate in their sweet spot in regards to network usage. In this paper we present an algorithm that, making use of the ant colonization algorithm, computes, in a decentralized manner, the routing tables so as to minimize global energy consumption. Moreover, the resulting algorithm is also able to track changes in the offered load and react to them in real time.

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“…D-Link DGS-1100-16 [15] 0 0 Level-One GEU-0820 [15] 0 0 SMC GS801 [15] 0 0 hysteresis and coalescing timers of some popular EEE devices. Note that the last three devices feature 1 Gbit/s ports, but we added them for completeness, as they have been thoroughly analyzed in [15]. This paper analyzes the energy efficiency limits of actual networking devices.…”

Section: Introductionmentioning

confidence: 99%

Leveraging energy saving capabilities of current EEE interfaces via pre-coalescing

Rodríguez-Pérez

Herrería-Alonso

Rodríguez-Rubio

et al. 2020

Journal of Network and Computer Applications

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The low power idle mode implemented by Energy Efficient Ethernet (EEE) allows network interfaces to save up to 90 % of their nominal energy consumption when idling. There is an ample body of research that recommends the use of frame coalescing algorithms-that enter the low power mode as soon as there is no more traffic waiting to be sent, and delay the exit from this mode until there is an acceptable amount of traffic queued-to minimize energy usage while maintaining an acceptable performance. However, EEE capable hardware from several manufactures delays the entrance to the low power mode for a considerable amount of time (hysteresis). In this paper we augment existing EEE energy models to account for the hysteresis delay and show that, using the configuration ranges provided by manufacturers, most existing EEE networking devices are unable to obtain significant energy savings. To improve their energy efficiency, we propose to implement frame coalescing directly at traffic sources, before reaching the network interface. We also derive the optimum coalescing parameters to obtain a given target energy consumption at the EEE device when its configuration parameters are known in advance.

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An experimental power profile of Energy Efficient Ethernet switches

Cited by 6 publications

References 19 publications

Multi-Path Routing in Green Multi-Stage Upgrade for Bundled-Links SDN/OSPF-ECMP Networks

Multi-Path Routing in Green Multi-Stage Upgrade for Bundled-Links SDN/OSPF-ECMP Networks

An ant colonization routing algorithm to minimize network power consumption

Leveraging energy saving capabilities of current EEE interfaces via pre-coalescing

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