S-SWAP: scale-space based workload analysis and prediction

Gustavo Adolfo Campos dos Santos

04 October 2013

nÃo hà / This work presents a scale-space based approach to assist dynamic resource provisioning. The application of this theory makes it possible to eliminate the presence of irrelevant information from a signal that can potentially induce wrong or late decision making. Dynamic provisioning involves increasing or decreasing the amount of resources allocated to an application in response to workload changes. While monitoring both resource consumption and application-specic metrics is fundamental in this process since the latter is of great importance to infer information about the former, dealing with these pieces of information to provision resources in dynamic environments poses a big challenge. The presence of unwanted characteristics, or noise, in a signal that represents the monitored metrics favors misleading interpretations and is known to aect forecast models. Even though some forecast models are robust to noise, reducing its inuence may decrease training time and increase eciency. Because a dynamic environment demands decision making and predictions on a quickly changing landscape, approximations are necessary. Thus it is important to realize how approximations give rise to limitations in the forecasting process. On the other hand, being aware of when detail is needed, and when it is not, is crucial to perform ecient dynamic forecastings. In a cloud environment, resource provisioning plays a key role for ensuring that providers adequately accomplish their obligation to customers while maximizing the utilization of the underlying infrastructure. Experiments are shown considering simulation of both reactive and proactive strategies scenarios with a real-world trace that corresponds to access rate. Results show that embodying scale-space theory in the decision making stage of dynamic provisioning strategies is very promising. It both improves workload analysis, making it more meaningful to our purposes, and lead to better predictions.

Workload analysis

Forecast

Scale-space

CIENCIA DA COMPUTACAO

Examination of the Effect of Child Abuse Case Characteristics on the Time a Caseworker Devotes to a Case

Card, Christopher J.

27 October 2010

This study used an explanatory research model that determined the effect on caseworker time and therefore workload caused by specific characteristics of cases assigned after the child abuse investigation is complete. The purpose of this study was to explain the relationship between child protection case characteristics and the time an assigned caseworker devotes to a case. With this knowledge an informed methodology to assess the current workload of a caseworker could be used to assure that the caseworker is able to successfully complete the tasks required for each child assigned. Further, the knowledge of the amount of time spent on a case with specific characteristics allows supervisors to assess and properly assign cases. Utilizing focus groups and a secondary data analysis of the Florida State Automated Child Welfare Service Information System (SACWSIS) the case characteristics of race/ethnicity, living arrangement, placement, removal and prior removal were found to significantly affect caseworker time spent on a case. Additionally, the case characteristics of gender, age, type of maltreatment, and disability were not found to affect caseworker time spent on a case.

caseload

workload

child abuse

case assignment

workload analysis

American Studies

Arts and Humanities

S-SWAP: scale-space based workload analysis and prediction / S-SWAP: scale-space based workload analysis and prediction

Santos, Gustavo Adolfo Campos dos

January 2013

SANTOS, Gustavo Adolfo Campos dos. S-SWAP: scale-space based workload analysis and prediction. 2013. 99 f. Dissertação (Mestrado em ciência da computação)- Universidade Federal do Ceará, Fortaleza-CE, 2013. / Submitted by Elineudson Ribeiro (elineudsonr@gmail.com) on 2016-07-28T19:41:50Z No. of bitstreams: 1 2013_dis_gacsantos.pdf: 3910335 bytes, checksum: 15f381ec4c1d77510c3d76424bf764aa (MD5) / Approved for entry into archive by Rocilda Sales (rocilda@ufc.br) on 2016-08-01T15:38:14Z (GMT) No. of bitstreams: 1 2013_dis_gacsantos.pdf: 3910335 bytes, checksum: 15f381ec4c1d77510c3d76424bf764aa (MD5) / Made available in DSpace on 2016-08-01T15:38:14Z (GMT). No. of bitstreams: 1 2013_dis_gacsantos.pdf: 3910335 bytes, checksum: 15f381ec4c1d77510c3d76424bf764aa (MD5) Previous issue date: 2013 / This work presents a scale-space based approach to assist dynamic resource provisioning. The application of this theory makes it possible to eliminate the presence of irrelevant information from a signal that can potentially induce wrong or late decision making. Dynamic provisioning involves increasing or decreasing the amount of resources allocated to an application in response to workload changes. While monitoring both resource consumption and application-speci c metrics is fundamental in this process since the latter is of great importance to infer information about the former, dealing with these pieces of information to provision resources in dynamic environments poses a big challenge. The presence of unwanted characteristics, or noise, in a signal that represents the monitored metrics favors misleading interpretations and is known to a ect forecast models. Even though some forecast models are robust to noise, reducing its in uence may decrease training time and increase e ciency. Because a dynamic environment demands decision making and predictions on a quickly changing landscape, approximations are necessary. Thus it is important to realize how approximations give rise to limitations in the forecasting process. On the other hand, being aware of when detail is needed, and when it is not, is crucial to perform e cient dynamic forecastings. In a cloud environment, resource provisioning plays a key role for ensuring that providers adequately accomplish their obligation to customers while maximizing the utilization of the underlying infrastructure. Experiments are shown considering simulation of both reactive and proactive strategies scenarios with a real-world trace that corresponds to access rate. Results show that embodying scale-space theory in the decision making stage of dynamic provisioning strategies is very promising. It both improves workload analysis, making it more meaningful to our purposes, and lead to better predictions. / This work presents a scale-space based approach to assist dynamic resource provisioning. The application of this theory makes it possible to eliminate the presence of irrelevant information from a signal that can potentially induce wrong or late decision making. Dynamic provisioning involves increasing or decreasing the amount of resources allocated to an application in response to workload changes. While monitoring both resource consumption and application-speci c metrics is fundamental in this process since the latter is of great importance to infer information about the former, dealing with these pieces of information to provision resources in dynamic environments poses a big challenge. The presence of unwanted characteristics, or noise, in a signal that represents the monitored metrics favors misleading interpretations and is known to a ect forecast models. Even though some forecast models are robust to noise, reducing its in uence may decrease training time and increase e ciency. Because a dynamic environment demands decision making and predictions on a quickly changing landscape, approximations are necessary. Thus it is important to realize how approximations give rise to limitations in the forecasting process. On the other hand, being aware of when detail is needed, and when it is not, is crucial to perform e cient dynamic forecastings. In a cloud environment, resource provisioning plays a key role for ensuring that providers adequately accomplish their obligation to customers while maximizing the utilization of the underlying infrastructure. Experiments are shown considering simulation of both reactive and proactive strategies scenarios with a real-world trace that corresponds to access rate. Results show that embodying scale-space theory in the decision making stage of dynamic provisioning strategies is very promising. It both improves workload analysis, making it more meaningful to our purposes, and lead to better predictions.

Ciência da computação

Workload analysis

Forecast

Scale-space

Computação em nuvem

Análise de séries temporais