Energy Scalability of On-Chip Interconnection Networks in Multicore Architectures

On-chip interconnection networks (OCNs) such as point-to-point networks and buses form the communication backbone in systems-on-a-chip, multicore processors, and tiled processors. OCNs can consume significant portions of a chip's energy budget, so analyzing their energy consumption early in the design cycle becomes important for architectural design decisions. Although numerous studies have examined OCN implementation and performance, few have examined energy. This paper develops an analytical framework for energy estimation in OCNs and presents results based on both analytical models of communication patterns and real network traces from applications running on a tiled multicore processor. Our analytical framework supports arbitrary OCN topologies under arbitrary communication patterns while accounting for wire length, switch energy, and network contention. It is the first to incorporate the effects of communication locality and network contention, and use real traces extensively. This paper compares the energy of point-to-point networks against buses under varying degrees of communication locality. The results indicate that, for 16 or more processors, a one-dimensional and a two-dimensional point-to-point network provide 66% and 82% energy savings, respectively, over a bus assuming that processors communicate with equal likelihood. The energy savings increase for patterns which exhibit locality. For the two-dimensional point-to-point OCN of the Raw tiled microprocessor, contention contributes a maximum of just 23% of the OCN energy, using estimated values for channel, switch control logic, and switch queue buffer energy of 34.5pJ, 17pJ, and 12pJ, respectively. Our results show that the energy-delay product per message decreases with increasing processor message injection rate

Energy scalability of OCN

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2007.This electronic version was submitted by the student author. The certified thesis is available in the Institute Archives and Special Collections.Page 198 blank.Includes bibliographical references (p. 191-197).On-chip interconnection networks (OCN) such as point-to-point networks and buses form the communication backbone in multiprocessor systems-on-a-chip, multicore processors, and tiled processors. OCNs consume significant portions of a chip's energy budget, so their energy analysis early in the design cycle becomes important for architectural design decisions. Although innumerable studies have examined OCN implementation and performance, there have been few energy analysis studies. This thesis develops an analytical framework for energy estimation in OCNs, for any given topology and arbitrary communication patterns, and presents OCN energy results based on both analytical communication models and real network traces from applications running on a tiled multicore processor. This thesis is the first work to address communication locality in analyzing multicore interconnect energy and to use real multicore interconnect traces extensively. The thesis compares the energy performance of point-to-point networks with buses for varying degrees of communication locality. The model accounts for wire length, switch energy, and network contention. This work is the first to examine network contention from the energy standpoint.(cont.) The thesis presents a detailed analysis of the energy costs of a switch and shows that the estimated values for channel energy, switch control logic energy, and switch queue buffer energy are 34.5pJ, 17pJ, and 12pJ, respectively. The results suggest that a one-dimensional point-to-point network results in approximately 66% energy savings over a bus for 16 or more processors, while a two-dimensional network saves over 82%, when the processors communicate with each other with equal likelihood. The savings increase with locality. Analysis of the effect of contention on OCNs for the Raw tiled microprocessor reports a maximum energy overhead of 23% due to resource contention in the interconnection network.by Theodoros K. Konstantakopoulos.Ph.D

Analysis and implementation of charge recycling for deep sub-micron buses

ABSTRACT : Charge recycling has been proposed as a strategy to reduce the power dissipation in data buses. Previous work in this area was based on simplified bus models that ignored the coupling between the lines. Here we propose a new Charge Recycling Technique (CRT) appropriate for sub-micron technologies. CRT is analyzed mathematically using a bus energy model that captures the energy loss due to strong line to line capacitive coupling. In theory CRT can result to energy reduction of a factor of 2. It becomes even more energy efficient when combined with Bus Invert coding (Stan '97

Implementation of delay and power reduction in deep sub-micron buses using coding

Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2002.Includes bibliographical references (p. 73-74).by Theodoros K. Konstantakopoulos.S.M

Energy Scalability of On-Chip Interconnection Network

On-chip interconnection networks (OCNs) such as point-to-point networks and buses form the communication backbone in systems-on-a-chip, multicore processors, and tiled processors. OCNs can consume significant portions of a chip’s energy budget, so analyzing their energy consumption early in the design cycle becomes important for architectural design decisions. Although numerous studies have examined OCN implementation and performance, few have examined energy. This paper develops an analytical framework for energy estimation in OCNs and presents results based on both analytical models of communication patterns and real network traces from applications running on a tiled multicore processor. Our analytical framework supports arbitrary OCN topologies under arbitrary communication patterns while accounting for wire length, switch energy, and network contention. It is the first to incorporate the effects of communication locality and network contention, and use real traces extensively. This paper compares the energy of point-to-point networks against buses under varying degrees of communication locality. The results indicate that, for 16 or more processors, a one-dimensional and a two-dimensional point-to-point network provide 66 % and 82 % energy savings, respectively, over a bus assuming that processors communicate with equal likelihood. The energy savings increase for patterns which exhibit locality. For the two-dimensional point-to-point OCN of the Raw tiled microprocessor, contention contributes a maximum of just 23 % of the OCN energy, using estimated values for channel, switch control logic, and switch queue buffer energy of 34.5pJ, 17pJ, and 12pJ, respectively. Our results show that the energy-delay product per message decreases with increasing processor message injection rate. I

Investigation of the health effects on workers exposed to respirable crystalline silica during outdoor and underground construction projects

Chronic exposure of workers to powder containing crystalline silica (Silicon dioxide; SiO2) can lead to chronic lung diseases (lung cancer, silicosis, etc.). Aim of this study was to evaluate the exposure of Greek construction workers to SiO(2)and describe their pulmonary function. The study involved 86 outdoor and underground workers. Medical and professional history was obtained, and breath samples were collected at morning hours through a mask for the determination of SiO(2)levels. Pulmonary function tests, radiological examination and evaluation of radiographs were also performed. Pulmonary function examination showed that the majority of the workers were within normal range (61.4%) while the rest were diagnosed with mild (26.5%) and more severe impairment (7.24%). Working conditions (underground-outdoor) were statistically significantly related to the categorization of pulmonary function (P=0.038). During radiological examination, the type of working activity/ conditions (underground-outdoor) were statistically significantly related to the categorization of these findings (P=0.044). Of the 69 employees, 52 did not present findings (75.4%) and 5 were diagnosed with findings specific to occupational diseases (7.23%). Environmental exposure to respirable crystalline silica (RCS) was detected at 0.0125 mg/m(3)in the workplace, which is not beyond the legal limits. Underground workers with more than 15 years of exposure to SiO(2)are more likely to present chronic silicosis compared to the workers of outdoor activities