X-Git-Url: http://info.iut-bm.univ-fcomte.fr/pub/gitweb/gpc2011.git/blobdiff_plain/70d6de89376491e1fefe8ef5a68591b9ce4b8773..a19006a5bab5c146c8e8841c24dc7ba9a77da00d:/gpc2011.tex

diff --git a/gpc2011.tex b/gpc2011.tex
index c9f08f8..8c7d299 100644
--- a/gpc2011.tex
+++ b/gpc2011.tex
@@ -70,12 +70,12 @@ Laboratoire d'Informatique de l'universit\'{e}
   This paper presents the design and the evaluation of the
   gridification of a radiotherapy dose computation application. Due to
   the inherent characteristics of the application and its execution,
-  we choose the architectural context of global (or volunteer)
+  we choose the architectural context of  volunteer
   computing.  For this, we used the XtremWeb-CH
-  environment. Experiments were conducted on a real global computing
+  environment. Experiments were conducted on a real volunteer computing
   testbed and show good speed-ups and very acceptable platform
-  overhead letting XtremWeb-CH be a good candidate for deploying
-  parallel applications over a global computing environment.
+  overhead, letting XtremWeb-CH be a good candidate for deploying
+  parallel applications over a volunteer computing environment.
 \end{abstract}
 
 
@@ -93,9 +93,9 @@ dose distribution during treatment planning, a compromise must be
 found between the precision and the speed of calculation. Current
 techniques, using analytic methods, models and databases, are rapid
 but lack precision. Enhanced precision can be achieved by using
-calculation codes based, for example, on Monte Carlo methods. The main
-drawback of these methods is their computation times which can be
-rapidly huge. In \cite{NIMB2008} the authors proposed a novel approach, called
+calculation codes based, for example, on the Monte Carlo methods. The main
+drawback of these methods is their computation times which can 
+rapidly become huge. In \cite{NIMB2008} the authors proposed a new approach, called
 Neurad, using neural networks. This approach is based on the
 collaboration of computation codes and multi-layer neural networks
 used as universal approximators. It provides a fast and accurate
@@ -103,32 +103,34 @@ evaluation of radiation doses in any given environment for given
 irradiation parameters. As the learning step is often very time
 consuming, in \cite{AES2009} the authors proposed a parallel
 algorithm that enables to decompose the learning domain into
-subdomains. The decomposition has the advantage to significantly
-reduce the complexity of the target functions to approximate.
+subdomains. The decomposition has the advantage of significantly
+reducing the complexity of the target functions to approximate.
 
 Now, as there exist several classes of distributed/parallel
-architectures (supercomputers, clusters, global computing...)  we have
-to choose the best suited one for the parallel Neurad application.
-The Global or Volunteer Computing model seems to be an interesting
-approach. Here, the computing power is obtained by aggregating unused
-(or volunteer) public resources connected to the Internet. For our
-case, we can imagine for example, that a part of the architecture will
-be composed of some of the different computers of the hospital. This
-approach presents the advantage to be clearly cheaper than a more
-dedicated approach like the use of supercomputers or clusters.
+architectures (supercomputers, clusters, global computing\dots{}) we
+have to choose the best suited one for the parallel Neurad
+application. The volunteer (or global) computing model seems to be an
+interesting approach. Here, the computing power is obtained by
+aggregating unused (or volunteer) public resources connected to the
+Internet. In our case, we can imagine, for example, that a part of the
+architecture will be composed of some of the different computers of
+the hospital. This approach presents the advantage of being clearly
+cheaper than a more dedicated approach like the use of supercomputers
+or clusters. Furthermore and as we will see in the remainder, the
+studied parallel algorithm corresponds very well to this computation model.
 
 The aim of this paper is to propose and evaluate a gridification of
 the Neurad application (more precisely, of the most time consuming
-part, the learning step) using a Global Computing approach. For this,
-we focus on the XtremWeb-CH environment\cite{}. We choose this environment
-because it tackles the centralized aspect of other global computing
-environments such as XtremWeb\cite{} or Seti\cite{}. It tends to a
-peer-to-peer approach by distributing some components of the
-architecture. For instance, the computing nodes are allowed to
-directly communicate. Experiments were conducted on a real Global
-Computing testbed. The results are very encouraging. They exhibit an
-interesting speed-up and show that the overhead induced by the use of
-XtremWeb-CH is very acceptable.
+part, the learning step) using a volunteer computing approach. For
+this, we focus on the XtremWeb-CH environment\cite{xwch}. We chose
+this environment because it tackles the centralized aspect of other
+global computing environments such as XtremWeb\cite{xtremweb} or
+Seti\cite{seti}. It tends to a peer-to-peer approach by distributing
+some components of the architecture. For instance, the computing nodes
+are allowed to directly communicate. Experiments were conducted on a
+real global computing testbed. The results are very encouraging. They
+exhibit an interesting speed-up and show that the overhead induced by
+the use of XtremWeb-CH is very acceptable.
 
 The paper is organized as follows. In Section 2 we present the Neurad
 application and particularly its most time consuming part, i.e. the
@@ -150,13 +152,13 @@ The \emph{Neurad}~\cite{Neurad} project presented in this paper takes place in a
 multi-disciplinary project, involving medical physicists and computer scientists
 whose goal is to enhance the  treatment planning of cancerous tumors by external
 radiotherapy.   In our  previous works~\cite{RADIO09,ICANN10,NIMB2008},  we have
-proposed  an  original approach  to  solve  scientific  problems whose  accurate
+proposed  an  original approach  to  solving  scientific  problems whose  accurate
 modeling and/or  analytical description are  difficult. That method is  based on
 the collaboration of  computational codes and neural networks  used as universal
 interpolator. Thanks to that method,  the \emph{Neurad} software provides a fast
 and accurate  evaluation of radiation  doses in any given  environment (possibly
 inhomogeneous) for  given irradiation  parameters. We have  shown in  a previous
-work (\cite{AES2009}) the interest to use a distributed algorithm for the neural
+work (\cite{AES2009}) the interest of using a distributed algorithm for the neural
 network learning. We  use a classical RPROP~\footnote{Resilient backpropagation}
 algorithm with a  HPU~\footnote{High order processing units} topology  to do the
 training of our neural network.
@@ -186,7 +188,7 @@ criterion is that the result must be obtained in an homogeneous environment.
 % \end{figure}
 
 The secondary stage  of the {\it{Neurad}} project is the  learning step and this
-is  the most time  consuming step.  This step  is performed  off-line but  it is
+is  the most time  consuming step.  This step  is performed  offline but  it is
 important to  reduce the time used for  the learning process to  keep a workable
 tool. Indeed, if the learning time is  too huge (for the moment, this time could
 reach one week for a limited domain), this process should not be launched at any
@@ -194,8 +196,7 @@ time,  but only  when a  major modification  occurs in  the environment,  like a
 change  of  context for  instance.  However, it  is  interesting  to update  the
 knowledge of the neural network, by  using the learning process, when the domain
 evolves (evolution in material used for  the prosthesis or evolution on the beam
-(size, shape or energy)). The learning time is related to the volume of data who
-could be  very important in  a real  medical context.  A  work has been  done to
+(size, shape or energy)). The learning time is related to the volume of data which could be  very important in  a real  medical context.  Some work has been  done to
 reduce this  learning time with the  parallelization of the  learning process by
 using a partitioning method of the global dataset. The goal of this method is to
 train  many neural networks  on sub-domains  of the  global dataset.  After this
@@ -214,7 +215,7 @@ response for the global domain of study.
 % j'ai relu mais pas vu le probleme 
  
 However, performing the learning on  sub-domains constituting a partition of the
-initial domain is  not satisfying according to the quality  of the results. This
+initial domain may  not be satisfying depending on  the chosen quality  of the results. This
 comes from the fact that the accuracy of the approximation performed by a neural
 network is not constant over the learned domain. Thus, it is necessary to use an
 overlapping  of   the  sub-domains.  The   overall  principle  is   depicted  in
@@ -222,13 +223,10 @@ Figure~\ref{fig:overlap}.  In this  way,  each sub-network  has an  exploitation
 domain  smaller than its  training domain  and the  differences observed  at the
 borders  are  no  longer  relevant.   Nonetheless,  in  order  to  preserve  the
 performance  of the parallel  algorithm, it  is important  to carefully  set the
-overlapping  ratio $\alpha$.  It  must be  large  enough to  avoid the  border's
+overlapping  ratio $\alpha$.  It  must both be  large  enough to  avoid the  border's
 errors,  and as  small  as  possible to  limit  the size  increase  of the  data
 subsets~\cite{AES2009}.
 
-%(Qu'en est-il pour nos test ?).
-% Ce paramètre a deja été etudié dans un précédent papier, il a donc choisi d'être fixe
-% pour ces tests-ci.
 
 
 \section{The XtremWeb-CH environment}
@@ -247,14 +245,21 @@ density. This part is out of the scope of this paper.
 %Multiple ``views'' can be
 %superposed in order to obtain a more accurate learning. 
 
-The second step of the application, and the most time consuming, is
-the learning itself. This is the one which has been parallelized,
-using the XWCH environment. As exposed in the section 2, the
-parallelization relies on a partitionning of the global
-dataset. Following this partitionning all learning tasks are executed
-in parallel independently with their own local data part, with no
-communication, following the fork/join model. Clearly, this
-computation fits well with the model of the chosen middleware.
+The second step of the application, and the most time consuming, is the learning
+in  itself.  This  is the  one  which  has  been  parallelized, using  the  XWCH
+environment.  As  exposed  in  section   2,  the  parallelization  relies  on  a
+partitioning  of the global  dataset. Following  this partitioning  all learning
+tasks are  independently executed  in parallel with  their own local  data part,
+with no communication, following  the fork/join model. Clearly, this computation
+fits well with the model of the chosen middleware.
+
+\begin{figure}[ht]
+  \centering
+  \includegraphics[width=8cm]{figures/neurad_gridif}
+  \caption{The proposed Neurad gridification}
+  \label{fig:neurad_grid}
+\end{figure}
+
 
 The execution scheme is then the following (see Figure
 \ref{fig:neurad_grid}):
@@ -265,21 +270,15 @@ The execution scheme is then the following (see Figure
 \item When a worker (W) is ready to compute, it requests a task to
   execute to the coordinator (Coord.);
 \item The coordinator assigns the worker a task. This last one retrieves the
-application and its assigned data and so can start the computation. 
+application and its assigned data and so can start the computation;
 \item At the end of the learning process, the worker sends the result to a warehouse.
 \end{enumerate}
 
 The last step of the application is to retrieve these results (some
 weighted neural networks) and exploit them through a dose distribution
-process. This latter step is out of the scope of this paper.
+process.
 
 
-\begin{figure}[ht]
-  \centering
-  \includegraphics[width=8cm]{figures/neurad_gridif}
-  \caption{The proposed Neurad gridification}
-  \label{fig:neurad_grid}
-\end{figure}
 
 \section{Experimental results}
 \label{sec:neurad_xp}
@@ -287,40 +286,41 @@ process. This latter step is out of the scope of this paper.
 The aim of this section is to describe and analyze the experimental
 results we have obtained with the parallel Neurad version previously
 described. Our goal was to carry out this application with real input
-data and on a real global computing testbed.
+data and on a real volunteer computing testbed.
 
 \subsubsection{Experimental conditions}
 \label{sec:neurad_cond}
 
-The size of the input data is about 2.4Gb. In order to avoid that data
-noise appears and disturbs the learning process, these data can be
+The size of the input data is about 2.4Gb. In order to avoid 
+noises to appear and disturb the learning process, these data can be
 divided into, at most, 25 parts. This generates input data parts of
 about 15Mb (in a compressed format). The output data, which are
-retrieved after the process, are about 30Kb for each
-part. Unfortunately, the data decomposition limitation does not allow
-us to use more than 25 computers (XWCH workers). Nevertheless, we used two
+retrieved after the process, are about 30Kb for each part. We used two
 distinct deployments of XWCH:
 \begin{enumerate} 
 
-\item In the first one, called ``distributed XWCH'' in the following,
+\item In the first one, called ``distributed XWCH'',
   the XWCH coordinator and the warehouses were located in Geneva,
   Switzerland while the workers were running in the same local cluster
   in Belfort, France.
 
 \item The second deployment, called ``local XWCH'' is a local
-  deployment where both coordinator, warehouses and workers were in
-  the same local cluster.  
+  deployment where  coordinator, warehouses and workers were, in
+  the same local cluster, at the same time.  
 
 \end{enumerate}
-For both deployments, during the day these machines were used by
-students of the Computer Science Department of the IUT of Belfort.
-
-In order to evaluate the overhead induced by the use of the platform
-we have furthermore compared the execution of the Neurad application
-with and without the XWCH platform. For the latter case, we mean that the
-testbed consists only in workers deployed with their respective data
-by the use of shell scripts. No specific middleware was used and the
-workers were in the same local cluster.
+For both deployments, the local cluster is a campus cluster and during
+the day these machines were used by students of the Computer Science
+Department of the IUT of Belfort.  Unfortunately, the data
+decomposition limitation does not allow us to use more than 25
+computers (XWCH workers).
+
+In order  to evaluate the overhead  induced by the  use of the platform  we have
+furthermore compared  the execution of  the Neurad application with  and without
+the XWCH platform. For  the latter case, we want to insist  on the fact that the
+testbed consists only in workers deployed  with their respective data by the use
+of shell  scripts. No specific middleware was  used and the workers  were in the
+same local cluster.
 
 Finally, five computation precisions were used: $1e^{-1}$, $0.75e^{-1}$,
 $0.50e^{-1}$, $0.25e^{-1}$, and $1e^{-2}$.
@@ -329,12 +329,13 @@ $0.50e^{-1}$, $0.25e^{-1}$, and $1e^{-2}$.
 \subsubsection{Results}
 \label{sec:neurad_result}
 
+
 Table \ref{tab:neurad_res} presents the execution times of the Neurad
 application on 25 machines with XWCH (local and distributed
 deployment) and without XWCH. These results correspond to the measures
-of the same steps for both kinds of execution, i.e. sending of local
+of the same steps for both kinds of execution, i.e. the sending of local
 data and the executable, the learning process, and retrieving the
-results. Results represent the average time of $?? x ??$ executions.
+results. Results represent the average time of $5$ executions.
 
 
 \begin{table}[h!]
@@ -374,16 +375,16 @@ results. Results represent the average time of $?? x ??$ executions.
 As we can see, in the case of a local deployment the overhead induced
 by the use of the XWCH platform is about $7\%$. It is clearly a low
 overhead. Now, for the distributed deployment, the overhead is about
-$34\%$. Regarding to the benefits of the platform, it is a very
+$34\%$. Regarding  the benefits of the platform, it is a very
 acceptable overhead which can be explained by the following points.
 
 First, we point out that the conditions of executions are not really
-identical between with and without XWCH contexts. For this last one,
-though the same steps were done, all transfer processes are inside a
+identical between, with and without, XWCH contexts. For this last one,
+though the same steps were achieved out, all transfer processes are inside a
 local cluster with a high bandwidth and a low latency. Whereas when
 using XWCH, all transfer processes (between datawarehouses, workers,
 and the coordinator) used a wide network area with a smaller
-bandwidth. In addition, in executions without XWCH, all the machines
+bandwidth. In addition, in the executions without XWCH, all the machines
 started immediately the computation, whereas when using the XWCH
 platform, a latency is introduced by the fact that a computation
 starts on a machine, only when this one requests a task.
@@ -393,6 +394,8 @@ coordinator and one or more warehouses near a cluster of workers can
 enhance computations and platform performances. 
 
 
+
+
 \section{Conclusion and future works}
 
 In this paper, we have presented a gridification of a real medical
@@ -400,16 +403,21 @@ application, the Neurad application. This radiotherapy application
 tries to optimize the irradiated dose distribution within a
 patient. Based on a multi-layer neural network, this application
 presents a very time consuming step, i.e. the learning step. Due to the
-computing characteristics of this step, we choose to parallelize it
-using the XtremWeb-CH global computing environment. Obtained
+computing characteristics of this step, we have chosen to parallelize it
+using the XtremWeb-CH volunteer computing environment. Obtained
 experimental results show good speed-ups and underline that overheads
 induced by XWCH are very acceptable, letting it be a good candidate
-for deploying parallel applications over a global computing environment.
+for deploying parallel applications over a volunteer computing environment.
 
-Our future works include the testing of the application on a more
-large scale testbed. This implies, the choice of a data input set
+Our future works include the testing of the application on a 
+larger scale testbed. This implies, the choice of a data input set
 allowing a finer decomposition. Unfortunately, this choice of input
-data is not trivial and relies on a large number of parameters
+data is not trivial and relies on a large number of parameters.
+
+We are also planning to test XWCH with parallel applications where
+communication between workers occurs during the execution. In this
+way, the use of the asynchronous iteration model \cite{bcl08} may be
+an interesting perspective.
 
 %(demander ici des précisions à Marc).
 % Si tu veux parler de l'ensembles des paramètres que l'on peut utiliser pour caractériser les conditions d'irradiations