Deliverable D2.3 Conversion tools from external formats to
Contents
1. 4 2 EUROSTAG MODELICA CONVERTER ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccceccceccccccecccccceccceccecs 4 2 1 GENERAIOVERVIEWS Me E M 4 2 2 ANALYSIS OF THEMODELTFILE STRUCTURES Cere bea 5 2 3 CONVERTER 9 3 CIM CONVERTER UE MEE TEENS oaa 12 3 1 CIIVIEVERSION SUPPORTED 12 3 2 CONVERTER SOFEWARE ARCHITECTURE a MEME MP RM Le 13 3 3 LISING THE CONVERTER E ces E 14 4 EUROSTAG DYNAMIC DATA IMPORTER cscccccsccccccsccccansccccanscccensccccessccccsscccccsscccscsccccssccccessccccessccccsscccess 16 5 REFERENCES 17 6 ANNEX E A 18 2 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 Figures Figure 1 Eurostag to Modelica converter in the general WP2 w2. java I CIM1lImporter java I ModelConverter java L St rings2 java cim IEC61970CIM14v02 ucte extended 20090204 xml ENTSO E Boundary Set EU EQ xml ENTSO E Boundary Set EU TP xml include Editionl xml profile l1stEdition simple owl augmented xml subsets IEC61970CIM14v02 EQ TP SV xml L eu itesla project iidm import Importer platform ciml import src main java eu itesla project iidm import ciml directory contains the Java sources of the converter The most important file is ModelConverter java which contains the CIM model generated by CIM gateway to IIDM model converter platform ciml import src main resources directory contains the CIM ENTSOE V1 specification files which are used by the CIM gateway to generated the CIM in memory model 3 3 Using the converter The next diagram shows how to use the CIM to IIDM converter to create an IIDM network model from a CIM file The workflow is very simple starting from a CIM file or 3 CIM files one for each data set the converter allows us to create an in memory model of IIDM network 14 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 CIM ENTSOE network files EQ TP model Java in SV memory mode CIM to IIDM converter Figure 7 Converter run workflow Here is a Java code snippet that shows the converter Java API Using the converter is really straightforward as it only requires one line of code to c
3. Connections between blocks commect imSums 1 nl ImLeadLag i pl ecnnectipl Im5ums l pl ImLeadLag 2 nt 1 0 Insusi 1 p4 2 end guverl F Input connectors of blocks that don t have input values Figure 2 Modelica structure that is formed by several blocks and their input output connections has the 7 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 When integrating this model into a power system initialization calculations must be performed using Eurostag in order to initialize each block in the Macroblock with the appropriate values The reason for doing this is that the initial values of Macroblock regulators are closely related to the type of system to be regulated Therefore the fri file of the homologous Eurostag Macroblock cannot be taken into account until the full system converter from Eurostag to Modelica is implemented At this stage the converter is being developed with the goal of converting Macroblocks independently of the power system where they are going to be connected 2 2 3 Tools needed for the converter The first step in the converter is to match each block of a macroblock with the homologous block defined in the PowerSystems Modelica Library see Deliverable D3 1 3 to identify the dependencies between blocks and finally to rewrite the macroblock in Modelica language It will be then necessary to endow each bloc
4. IRA SAR Os 1lesla Innovative Tools for Electrica System securi within Large Aras ilesla Innovative Tools for Electrical System Security within Large Area Grant agreement number 283012 Funding scheme Collaborative projects Call identifier FP7 ENERGY 2011 1 Deliverable D2 3 Conversion tools from external formats to internal formats Dissemination level Public TSO Restricted to consortium members and TSO members of ENTSO E including the Commission Services Restricted to a group specified by the consortium including the Commission services Confidential only for members of the consortium including the Commission services m SEVENTH FRAMEWORK PROGRAMME EUROPEAN COMMISION iTesla WP2 02 3 Conversion tools from external formats to internal formats V1 0 Document Name Conversion tools from external formats to internal formats Work Package WP2 Task 2 3 Deliverable D2 3 Responsible Partner AIA Approval Marc Sabat AIA Executive Board Geoffroy Jamgotchian RTE Quinary DIFFUSION LIST For action For information DOCUMENT HISTORY I oo July 31 2013 Geoffroy Jamgotchian CIM import chapter added August 1 2013 Geoffroy Jamgotchian Eurostag data import chapter added 1 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 Table of contents 1 INTRODUCTION
5. The Modelica PowerSystem Library is being enlarged as new models are needed for the translation of new Eurostag macroblocks We have worked on a 22 buses system that should cover the 80 of the needed devices for a large system This is the correspondence table with the dictionary between the Eurostag blocks and the existent homologous Modelica blocks in the PowerSystems library This table is a csv file read by the main module Modelica model 1 SUMMER PowerSystems Nonelectrical Math 7 LIMITED INTEGRATOR NonElectrical Continuous 1k e trv 8 LIMITED SIMPLE LAG PowerSystems NonElectrical Continuous ImLimitedSimple nStartValue DERIVATIVE LAG PowerSystems NonElectrial Continuous mDerivativelag StartVatue LEAD LAG PowerSystems Nontlectrical Continuous mLeadlag Instanta af monostasie Nontlectrical Nonlinear ImMonostable 3J Power Systems Continuous 1 fe a eS _ __ 34lN JPowerSystemsNonElectria Math mN fc 35 DIVIDR PowerSystems NonElectrical Math mDiv2 fa jnStartValue __ 36 INVERSE FUNCTION PowerSystems NonElectrica lmlnverseFuncion fa 37 SEF RESET PowerSystems NonElectrical Math ImSetReset Jo tartVatue __ 38 RESETSET JPowerSystemsNontlectrial Math mResetSet Jo startVatue 39 SECOND Omnem powe
6. Ss Sa 9s Sa Ds TE 0 02 0 02 0 03 0 03 0 025 TE 0 2 0 2 3300000 413300000 3200000 TE 2 940000 2 940000 6 600000 6 600000 6 2 0 94 0 94 4 200000 4 200000 4 TOMD 0 02 920 020 070 02 TOMSL 0 04 0 040 040 040 04 TR Ss 8 m Ba 8 2 2 2 Modelica The Modelica code of a model following structure andel govert parameter Real nit 1 parameter meal init 2 parameter Heal init 5 pararmetez init parameter Real INIMAX parameter Real KDELIAI parameter Peal PROPHP parameter Beal Fowertystems HonElactrical FowerSystaems NHonzlestrical YiaxelNiMAX 1 0 vaina nStertVelue init FowerSystanms Honzlacrtrical ai EDELTAr 0 amp 2 1 0 an 5 1 0 a0cEDELIAF StastValue 1 rowerbysctams NHonEleczzrical Kzi 0 ILSFROFHP IRH T4 IBRH n5tartValue init Fcwer5ystams HonkElectrical Initial values declaration Parameters declaration Math imdetProint ImsSetPoint i1i Veinir 1 Continucus ImtLimitedIstsgrator ImLimitedintagraroer i Math Insuas ImSums 1 Blocks declaration Tontinucus Irleadlag ImLeadLag ii Math lmserPoint ImSetroint 42 V inzr rowserbystems Coannsctors zzPin pl rcvarSystazmms Connectors equation MEI Input and output connectors of the macroblock declaration connect imetPoint_i ni ImLimitedintegrator l pi ecnnectilmSetPoint 2 n1 ImSums 1 51 connectilmLimitediIntegrator 1 nl1 ImSum5 1 p3
7. connect nl ImLeadLag 1 01 Imsaum5 1 pz 0 L CO C d Loy i up O oOo D p ip 2 oc end goverl us ko Um i du n D 1 ibs Lo g L5 d n3 1 1 I3 c Oo Figure 4 Converter GUI 2 3 3 Conversion issues At this point of the project we have found one important issue to directly translate Eurostag macroblocks to Modelica macroblocks 10 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 When a Eurostag macroblock contains one of the following blocks Terminal Voltage e Current field e Active Power e Reactive Power In these blocks the current measurement is needed to perform all the necessary calculations Therefore these particular blocks should be connected in series in order to have the current as an input value This would imply inserting blocks in the power system outside the macroblock but as explained before at this stage this converter is designed for converting Macroblocks independently of the power system where they are going to be connected Our solution for this issue is replacing these particular blocks by an input pin identified with the name of the corresponding block Then this block must be connected in series in the system outside the macroblock and connected to the Macroblock Another solution would be pe
8. any times this type of block has appeared in the macroblock before o Elements java each object of this class is a correspondence between a Eurostag block identified by its Eurostag id and its homologous Modelica block idea Integer It stores the Eurostag ID of each Eurostag block name amp u String It stores the name of the Eurostag block pathModelica String It stores the path of the homologous Modelica block in the PowerSystems Library String It stores the name of the homologous Modelica block List lt String gt It stores the name of the parameters of the Modelica block o ModelicaModel java this class uses the previous classes to implement the conversion It calculates and returns a list of lines for each section of a Modelica block code see Figure2 outputPositivePin List lt String gt It returns the input pins declaration of the Modelica model outputNegativelmPlIn List lt String gt It returns the output pins declaration of the Modelica model 9 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 outputBlocksDeclaration List lt String gt It returns the blocks declaration of the Modelica model List lt String gt It returns the declaration of the connection between blocks the input pin of the Macroblock the output pin of the Macroblock e tesla ui main amp iTesla ui util these packages contain a set of classes that define the GUI of the conv
9. ata Figure 5 CIM importer in the general WP2 workflow 3 1 CIM version supported Only CIM ENTSOE profile is supported The converter is actually based on the first version of the ENTSOE profile which is a restriction on the v14 general profile The second version of the ENTSOE profile which is a restriction on the v16 general profile is not yet supported but will probably be before the end of the project 12 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 3 2 Converter software architecture CIM converter uses the RTE CIM gateway library to easily manage CIM RDF XML data This library allows us to generate Java classes of the data model and the parser from CIM UML specification Java class generation is integrated into the Maven build so that generated classes can be used and packaged with the converter The next diagram describes the build workflow of the converter CIM ENTSOE Java sources fo specifications CIM model and EA project CIM parser Compiler CIM to IIDM gateway converter jar generator Java sources of the IIDM converter Figure 6 Converter build workflow Source code of the converter can be found on the iTESLA source code repository hosted on www bitbucket org Here is the source code layout 13 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 plattorm orml rmport L itesla project I 1
10. ck in figure 1 is explained 2 2 Analysis of the model file structures 2 2 1 Eurostag A Eurostag macroblock is an assembly of elementary blocks with input output relationship integrated into a system by defining the input variables for the existing types of machines in the file editor module Each block of the macroblock performs a function for further information see 1 appendix 2 and has the following attributes block identifier A graphical block identifier within the macroblock From 0 ton inputs e Asingle output From ton parameters From 0 to 1 initial value From Oto 1 offset Three ASCII files define a Eurostag macroblock frm file corresponds to the main scheme of the macroblock fri corresponds to the initialization scheme and par corresponds to parameters 2 2 1 1 Main Scheme The frm file defines the topology of the macroblock and has the following structure for further details see D2 2 5 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 HEADER 03 10 08 4 4 Header with the date and the number of version to be used with the regulation 70 84 4 Dimensions of the graphical representation to be bypassed 5 4 Number of blocs P INTMAX KDELTAF 1 0 Blocs param 1 0 Blocs param 2 0 1 0 Blocs param 2 2 Blocs param 2 2 1 0 Blocs param 2 2 2 Blocs param 2 2 KDELTAF Blocs offs
11. e find the Eurostag to Modelica converter that translates Eurostag macroblocks to the Modelica language using as input the frm fri and par Eurostag files These files will be contained in the Dynamic database and by calling the Modelica converter from the user interface the corresponding Modelica file will be generated and stored inside the database CIM files ENTSOE RTE load flow data converter importer AIA Agora load model flow data mining a converter Data mining YAY V1 2 Contingencies database database actions feeder Eurostag data KL database converter m Modelica mining Dynamic dynamic platform database data P pito R Optimizers etc data converter 4 ay Eurostag to vini Full Modelica S Modelica mining functions converter NPA4 5 converter 3 Eurostag Dynamic Eurostag database dynamic importer UI data Figure 1 Eurostag to Modelica converter in the general WP2 workflow 4 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 This converter will also be a useful tool for WP3 WP4 and WP5 It will be used to populate the Dynamic database of the IIDM which will be then used in the Eurostag data converter and in the Full Modelica network converter see Figure 1 In this document the development of the Eurostag to Modelica converter highlighted blo
12. eds to initialize a macroblock i e to give initial values to all the state variables of the macroblock within the simulation of a power system with Eurostag However when a power system that contains a macroblock is simulated with Modelica initialization calculations are previously performed with Eurostag and the initial resulting values for the state variables of the macroblock are taken to initialize the Modelica macroblock Hence for the moment the fri file will not be taken into account when converting a Eurostag macroblock to Modelica code 2 2 1 3 Parameters scheme The par file provides all the parameters of the macroblock In case there is more than one occurrence of the macroblock in the system where it is integrated the par file also provides all the necessary sets of parameter values corresponding to each occurrence of the macroblock The set used in the simulation will be specified into the dynamic data file 6 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats HEADER 17 04 12 4 5 RTE comment __ FLR 1 2 3 4 5 ALPHATR 1 700000 2 400000 1 700000 2 400000 2 DEUXPINU 314 1593 314 1593314 1593314 1593314 1593 K1 5 10000 5 10000 3 40000 3 40000 2 64000 K2 18 LO 1 LG 22 K3 18 70000 18 70000 125 m 8 K4 123 9 13 5 11 70000 11 70000 14 40000 KE 4900000 4900000 L Le 3 300000 MESU 0 02 0 020 020 020 02 PLEXM c4 3 46 3 46 3 46 PLEXP 4 600000 4 600000 4 4 4 IE
13. erter 2 3 2 GUI The converter s GUI has two panels and a browser After selecting the Eurostag macroblock which is meant to be converted to Modelica code the frm fri and par files are printed on each tab of the left panel and after converting it to Modelica code the result is printed on the right panel and it is saved as a mo file dn Eurostag description model quveri 53 _ TA Parameter init i 0 parameter Real init z Parameter Real init 5 parameter Real init 6 0 parameter Real INIMEZX parameter Heal EDELTAY parameter Real Parameter Real Powersyatems NonElectrical Math ImSerPoint imsetPoint_1 PowerSystema NonElectrical Continuous ImLimitedintegrat Fowersysatemna NonElectrical Math ImSums 1 al Kl gwerSgystems NonElecutrical Continugcus ImLeadLag ImLeadl nwersSyartems NonElectrical Math ImserBPolrnt ImSserEninr 2 werg3ystema3 CGConnectara imPin pl OMEGE Eunwersyatems Conpecrn rasa ImPin ni equation pa bo i L be c rp Hd Li un nnect ImserPolinr 1 n1 ImLimitedintegrator 1 1 connect ImsetFoint 2 n1 Imsum5 1 p5 H imos Go m io dme dj RM n econnect ImLimitendIntegrator 1 n1 ImsSums5 1 p3 nnect Imsums 1 1 ImLeadLag 1 pl RODA i p 1 i 2 a 9 9 ImsSums5 i pli
14. et 0 V1 2 XI 0 Blocs init value 2 OMEGA Blocs entries 2 2 Blocs entries Blocs entries 2 2 Blocs entries 2 Blocs entries 5 amp SCM Blocs output 1 2 4 5 6 Graphical Blocks numbers 3741 3930 4153 4382 3930 Location on the graphical representation to be bypassed X axis 3948 394839483948 4152 Location on the graphical representation to be bypassed Y axis 26 7 1 10 26 Type of the bloc need of a table of correspondence 0 0000 Orientation of the bloc graphical to be bypassed 1 2 4 5 6 Graphical Blocks numbers again 4 Number of links 3822 40114011 4234 Location on the graphical representation to be bypassed M Location on the graphical representation to be bypassed 3990 0 004 Location on the graphical representation to be bypassed 1 5 2 3 Starting block of link blocs are 1 2 3 4 5 graphical numbers are 1 2 4 5 96 3 3 4 Ending block of a link 1 5 3 1 i Number of entry in the extremity bloc 10 3 1 to bypassed O to be bypassed to be bypassed to be bypassed 0 to be bypassed 0 to be bypassed This scheme will be the most important one for the conversion from Eurostag to Modelica language It defines the topology of the macroblock which blocks appear in the macroblock their parameters and their connections 2 2 1 2 Initialization Scheme The fri file indicates that the Computation Module ne
15. k of the Modelica library with the same attributes of the homologous Eurostag block On the other hand the frm file provides the Eurostag identifiers of the blocks used in the macroblock the parameters of each block the offset and the initial values if they exist Therefore a sort of dictionary identifying each Eurostag block to the homologous Modelica model is needed for this purpose a correspondence table has been created see Annex It identifies each block coming from Eurostag with the correspondent Modelica block and it also provides if they exist the parameters names the initial values names and the offset names of the Modelica block n i ELI nun Eurostag Nar Modelica model param 1 param 2 param 3 param 4 param 5 param 6 offset init value WOTES l SUMMER PowersSystemas lms5ums5 2 at a5 2 MULTIPLIER Powertyvstems imMult2 a1 a2 3 INTESRATO Powersystems imintegrator K nStartValue Eurostag Modelica block name Name of parameters offset and init Code amp name Figure 3 Correspondence table Since the parameters in the frm file are provided in a specific order the parameters in the correspondence table must follow the same order In addition for the correct compilation of the translated Modelica model correct paths for the Modelica blocks have to be provided In each new version of the library some blocks might change their location within the packages Thereby after each
16. nformation 11 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 On the other hand this translator will be integrated in a larger converter that will transform the Eurostag dynamic data of a system into a Modelica system It will be adapted to be executed from an automatic call generated in the iTESLA platform in order to insert the generated file in the Dynamic database Finally error codes will be defined with the aim of having warning messages when trying to convert blocks or components that do not exist in the PowerSystems library 3 CIM To IIDM CONVERTER CIM files will be used in the iTESLA platform to provide network static data As shown in the following diagram a converter has been developped to convert a CIM file to the iTESLA internal network data model CIM files ENTSOE RTE load flow CIM data converter eT importer Network data AIA Agora load model flow data Data mining a converter 5 _ Data mining N onting neies EEREN and actions Eurostag data database converter a Modelica Dynamic dynamic database data V1 2 database feeder mining platform P pito R etc Optimizers data converter 4 Complementary Eurostag to mining Full Modelica database C functions network converter 4 5 converter 3 Eurostag Dynamic Eurostag DD database dynamic importer UI d
17. orkflow eee 4 Figure 2 Modelica StrUCTUG sce tatu oa sb senatum eee M DEM M ME 7 Fere 3 Correspondence tables eee ned attt beue eme ld obi aue 8 PISULe CONVEIMEr GU lk aise cause 10 Figure 5 CIM importer in the general WP2 workflow eese nennen 12 Figure 6 Converter build workflow 13 Figure 7 Converter run essa nnns serene aane nns 15 Figure 8 Eurostag dynamic data importer in the WP2 general 16 3 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 1 INTRODUCTION Deliverable D2 3 is of the Prototype type It consists of three conversion tools from external data formats to the iTesla internal data model IIDM Import of data in the Eurostag format Eurostag to Modelica data converter Import of data in the CIM format Source codes of theses conversion tools can be found on the iTESLA source code Git repository hosted at www bitbucket org The present document is an accompanying document that describes the main characteristics of these tools 2 EUROSTAG TO IVIODELICA CONVERTER 2 1 General overview Within the iTesla project WP2 provides common services for WP3 WP4 and WP5 Among them w
18. rSystemsNanledricaConimuousimtecondOrder pstervalue __ 40 INTEGRATOR FOLLOWER PowerSystems NonElectrial Continuous ImIntegratorFolldK TE a 22 COSINE_____ PawerSystems Non lectrisalMath imCosing EL 43 SNE PowerSystemsNonElectrica Math mSine o 4 OO 45 ARC TANGENT PowerSystems NonElectrial Math mArcTangent a1 fae AARCCOSINE LO AARCSINE 4 4 4 sofro current Sa uiiTeD LEAD LAG S2 RELAY DELAY psa 4 4 Jd wq d SZSTATORSTATUS OS8FUNCTION XY o Eo E po Po oo 4 4 S9 VOLTAGEANGEE _ sofcurrenT __ SNCURRENTANGEE 4 4 18 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 19 20
19. reate the IIDM network model variable n import eu itesla_project iidm import_ Importers import eu itesla_project iidm network Network public class Demo public static void main String args Network m Impottetrs import CIMI tmp myvoimfile null 15 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 4 EUROSTAG DYNAMIC DATA IMPORTER A Eurostag dynamic data importer has been developed so that a TSO which has its dynamic data in the Eurostag format can easily feed the iTESLA platform with dynamic data and then run dynamic simulations on its perimeter CIM files ENTSOE RTE load flow data converter importer V1 2 AIA Agora load flow data sana database Datamining atabase actions feeder Eurostag data L 54 database converter Data JA Se Modelica mining Dynamic dynamic un pito R Optimizers database data data converter AN 4 aZ FS Complementary Data Eurostag to ome Full Modelica database Modelica mining function network a converter aN 24 5 converter Eurostag Dynamic Eurostag database dynamic importer Ul data Figure 8 Eurostag dynamic data importer in the WP2 general workflow The previous diagram explains how the converter works Starting from a dd Eurostag file dta chunks and a dictionary CSV file containing the mapping between E
20. rforming all the calculations of this block inside the machine and inserting an additional output pin on the machine that connects directly to the macroblock We will not use this option here for the moment 2 3 4 Results So far we have tested the converter on the voltage regulators and voltage governors supplied in the Eurostag tutorial and we have validated them in some simple test systems e GOVER1 e AVR2 GOVER2 AVR3 e GOVER3 The converter has also been tested on the excitation system of 64 blocks built in Modelica during the Pegase project see 4 in order to make the necessary improvements for the conversion of this type of complex macroblocks 2 3 5 Next steps Among the different steps that will be taken to enhance the converter an important one involves the graphical part of the translated Macroblock So far when the converter translates a Macroblock to the Modelica code it only generates the code without generating the part concerning the graphical information of the model If this translated model has to be eventually used by a user then it would be appropriate to have this information in order to make the model more user friendly As it can be seen in the structure of a frm file there exists graphical information about the layout of the blocks in the Eurostag model editor Therefore it would be necessary to determine the necessary transformations to map this Eurostag graphical information to Modelica graphical i
21. update a text file will be automatically created with the correct paths of all the Modelica models in the PowerSystems library 8 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 2 3 Converter This chapter describes the Eurostag to Modelica converter The source code is available on the iTESLA Git repository stored at www bitbucket com in the folder itesla Modelica Eurostag to Modelica Converter The converter was built in Java and it consists of a set of Java classes that implement the converter and a GUI mainly used for debugging and demonstration purposes In the integrated platform the output of the converter is only a mo file stored in a preconfigured folder 2 3 1 Packaging The following modules are part of the converter iTESLA o iTesla java it is the top level class of the converter It is the entry point to open the GUI and to make the conversion e tesla conversor this package contains the following classes o M Block java each object of this class is a Eurostag block with the information contained in the frm file String 8 It stores the parameters the offset and the init value of each Eurostag block String It stores the output of each block GraphicalNumber Integer It stores the Eurostag ID of each Eurostag block Entries 11 String 5 It stores the entries of each block Integer It stores the Eurostag ID of each Eurostag block Integer It stores how m
22. urostag equipment identifiers and IIDM equipment identifiers based on CIM ID it is possible to automatically fill the dynamic database see deliverable 2 2 for more detail on the dynamic database This tool is callable from command line and only requires providing the directory where dd files are stored the identifiers dictionary and connection information to the JBoss application server which is responsible to manage the access to the dynamic database The source code is available on the iTESLA repository at www bitbucket com It is made of Java classes grouped within iidm ddb eurostag import export Maven module You will find next a dump of the source code tree The main class is eu itesla project iidm ddb eurostag imp exp DdbDtalmpExp java and contains most of the code that makes the conversion 16 20 iTesla WP2 D2 3 Conversion tools from external formats to internal formats V1 0 platform iidm ddb iidm ddb eurostag import export L Lees La project L iidm L ddb L eurostag imp exp DdbDtaImpExp java DtaParser java EurostagRecord java FortranFormat java MemoryBufferedReader java utils L Utils java resources L log4j xml 5 REFERENCES 1 Tractebel RTE MODEL EDITOR USER S MANUAL 2 iTESLA Deliverable D2 2 WP2 3 iTESLA Deliverable D 3 1 annex WP3 2 4 Pegase Project Deliverable D5 2 17 20 iTesla WP2 02 3 Conversion tools from external formats to internal formats V1 0 6 ANNEX
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