In distributed cloud storage systems, inevitably there exist multiple node failures at the same time. The existing methods of regenerating codes, including minimum storage regenerating(MSR) codes and minimum bandwidth...In distributed cloud storage systems, inevitably there exist multiple node failures at the same time. The existing methods of regenerating codes, including minimum storage regenerating(MSR) codes and minimum bandwidth regenerating(MBR) codes, are mainly to repair one single or several failed nodes, unable to meet the repair need of distributed cloud storage systems. In this paper, we present locally minimum storage regenerating(LMSR) codes to recover multiple failed nodes at the same time. Specifically, the nodes in distributed cloud storage systems are divided into multiple local groups, and in each local group(4, 2) or(5, 3) MSR codes are constructed. Moreover, the grouping method of storage nodes and the repairing process of failed nodes in local groups are studied. Theoretical analysis shows that LMSR codes can achieve the same storage overhead as MSR codes. Furthermore, we verify by means of simulation that, compared with MSR codes, LMSR codes can reduce the repair bandwidth and disk I/O overhead effectively.展开更多
In distributed storage systems,file access efficiency has an important impact on the real-time nature of information forensics.As a popular approach to improve file accessing efficiency,prefetching model can fetches d...In distributed storage systems,file access efficiency has an important impact on the real-time nature of information forensics.As a popular approach to improve file accessing efficiency,prefetching model can fetches data before it is needed according to the file access pattern,which can reduce the I/O waiting time and increase the system concurrency.However,prefetching model needs to mine the degree of association between files to ensure the accuracy of prefetching.In the massive small file situation,the sheer volume of files poses a challenge to the efficiency and accuracy of relevance mining.In this paper,we propose a massive files prefetching model based on LSTM neural network with cache transaction strategy to improve file access efficiency.Firstly,we propose a file clustering algorithm based on temporal locality and spatial locality to reduce the computational complexity.Secondly,we propose a definition of cache transaction according to files occurrence in cache instead of time-offset distance based methods to extract file block feature accurately.Lastly,we innovatively propose a file access prediction algorithm based on LSTM neural network which predict the file that have high possibility to be accessed.Experiments show that compared with the traditional LRU and the plain grouping methods,the proposed model notably increase the cache hit rate and effectively reduces the I/O wait time.展开更多
Thermal Energy Storage(TES)systems are pivotal in advancing net-zero energy transitions,particularly in the energy sector,which is a major contributor to climate change due to carbon emissions.In electrical vehicles(E...Thermal Energy Storage(TES)systems are pivotal in advancing net-zero energy transitions,particularly in the energy sector,which is a major contributor to climate change due to carbon emissions.In electrical vehicles(EVs),TES sys-tems enhance battery performance and regulate cabin temperatures,thus improving energy efficiency and extend-ing vehicle range.The enhanced efficiency reduces overall energy consumption in EVs.Consequently,this reduc-tion in energy demand can lead to decreased infrastructure needs,minimising the scale and investment required in energy production and distribution systems.Furthermore,the integration of TES with existing infrastructure allows for the simultaneous charging of thermal and electrical energy,leveraging waste heat or renewable energy sources.This not only cuts costs by optimizing resource use but also bolsters sustainability by minimising reliance on non-renewable energy sources.The widespread adoption of TES in EVs could transform these vehicles into nodes within large-scale,distributed energy storage systems,thus supporting smart grid operations and enhancing energy security.Strategic investments and regulatory updates are essential to realise a sustainable,carbon-neutral transporta-tion future,underpinned by robust,cost-efficient infrastructure.展开更多
基金supported in part by the National Natural Science Foundation of China (61640006, 61572188)the Natural Science Foundation of Shaanxi Province, China (2015JM6307, 2016JQ6011)the project of science and technology of Xi’an City (2017088CG/RC051(CADX002))
文摘In distributed cloud storage systems, inevitably there exist multiple node failures at the same time. The existing methods of regenerating codes, including minimum storage regenerating(MSR) codes and minimum bandwidth regenerating(MBR) codes, are mainly to repair one single or several failed nodes, unable to meet the repair need of distributed cloud storage systems. In this paper, we present locally minimum storage regenerating(LMSR) codes to recover multiple failed nodes at the same time. Specifically, the nodes in distributed cloud storage systems are divided into multiple local groups, and in each local group(4, 2) or(5, 3) MSR codes are constructed. Moreover, the grouping method of storage nodes and the repairing process of failed nodes in local groups are studied. Theoretical analysis shows that LMSR codes can achieve the same storage overhead as MSR codes. Furthermore, we verify by means of simulation that, compared with MSR codes, LMSR codes can reduce the repair bandwidth and disk I/O overhead effectively.
基金This work is supported by‘The Fundamental Research Funds for the Central Universities(Grant No.HIT.NSRIF.201714)’‘Weihai Science and Technology Development Program(2016DXGJMS15)’‘Key Research and Development Program in Shandong Provincial(2017GGX90103)’.
文摘In distributed storage systems,file access efficiency has an important impact on the real-time nature of information forensics.As a popular approach to improve file accessing efficiency,prefetching model can fetches data before it is needed according to the file access pattern,which can reduce the I/O waiting time and increase the system concurrency.However,prefetching model needs to mine the degree of association between files to ensure the accuracy of prefetching.In the massive small file situation,the sheer volume of files poses a challenge to the efficiency and accuracy of relevance mining.In this paper,we propose a massive files prefetching model based on LSTM neural network with cache transaction strategy to improve file access efficiency.Firstly,we propose a file clustering algorithm based on temporal locality and spatial locality to reduce the computational complexity.Secondly,we propose a definition of cache transaction according to files occurrence in cache instead of time-offset distance based methods to extract file block feature accurately.Lastly,we innovatively propose a file access prediction algorithm based on LSTM neural network which predict the file that have high possibility to be accessed.Experiments show that compared with the traditional LRU and the plain grouping methods,the proposed model notably increase the cache hit rate and effectively reduces the I/O wait time.
基金Funded by EPSRC(grant number EP/W027372/1,EP/T022981/1,and EP/S032622/1).
文摘Thermal Energy Storage(TES)systems are pivotal in advancing net-zero energy transitions,particularly in the energy sector,which is a major contributor to climate change due to carbon emissions.In electrical vehicles(EVs),TES sys-tems enhance battery performance and regulate cabin temperatures,thus improving energy efficiency and extend-ing vehicle range.The enhanced efficiency reduces overall energy consumption in EVs.Consequently,this reduc-tion in energy demand can lead to decreased infrastructure needs,minimising the scale and investment required in energy production and distribution systems.Furthermore,the integration of TES with existing infrastructure allows for the simultaneous charging of thermal and electrical energy,leveraging waste heat or renewable energy sources.This not only cuts costs by optimizing resource use but also bolsters sustainability by minimising reliance on non-renewable energy sources.The widespread adoption of TES in EVs could transform these vehicles into nodes within large-scale,distributed energy storage systems,thus supporting smart grid operations and enhancing energy security.Strategic investments and regulatory updates are essential to realise a sustainable,carbon-neutral transporta-tion future,underpinned by robust,cost-efficient infrastructure.
