Home › Electrical & Power

Electrical & Power

Comparison between ARTEMIS 5th order Integration method used with the eMEGAsim Simulation Platform and the classical TUSTIN 2nd order method used in PSCAD and SimPowerSystems software

Publication date : Jul 2010
Paper File : TR10-30202-AR-1 eMEGAsim_vs_PSCAD_circuit_RLC_.pdf

Author(s)

Jean Bélanger, Amine Yamane,

Abstract

Real-time simulation requires the use of fixed step integration methods, capable of achieving accuracy with a time step range larger than 10 μs to 100 μs, to enable the use of standard processors and IO systems. Simulation accuracy increases when the time step value decrease but the processing power and number of processors increase when the time step decreases. The choice of integration techniques is also important. Simulation specialists must therefore select the best integration technique and time step that will yield to acceptable results. This document provides a comparison between simulation results obtained by using a classical 2nd order Tustin integration solver (also known as the Trapezoidal method) and the ARTEMIS 5th Order integration Method). The TUSTIN 2nd order method uses two terms of the Taylor series of the exponential function, while ARTEMIS 5th order uses five terms. Tustin is used by conventional electrical simulation software using the nodal technique such as PSCAD and EMTP while SimPowerSystems and eMEGAsim use ARTEMIS 5th order method in addition to the TUSTIN method.

Related Products

ARTEMiS
eMEGAsim
EMTP-RV
eMEGAsim
ARTEMiS
EMTP-RT

Real-time Laboratory Implementation Results of an Active Filter

Publication date : May 2010
Paper File : Active-Filter_AlirezaJAVADI_EEEIC2010.pdf

Author(s)

Guy Olivier, Frederic Sirois, Andre Youmssi, Alireza Javadi,

Abstract

- Proliferation of power electronics converters and electronic equipments has dramatically increased electric pollution in electrical distribution power systems. Active filters (capable of injecting distorted currents in order to cancel harmonics coming from non-linear loads) - Consequently, many theories have been developed to control active filters. Instantaneous power (p-q theory), an overview of the instantaneous compensation theory will be presented. -To illustrate the effectiveness of such compensation an HIL system is realized in laboratory. PHIL system with a real-time Opal-RT simulator. -The analysis of the real-time results to proven the instantaneous compensation of the controller.

Related Products

RT-LAB Professional
RT-LAB Solo
RT-LAB Professionnel
RT-LAB Solo
RT-LAB OPC Server

Opal-RT Technologies Expands Presence in the Wind Power Industry

Bookmark and Share

Use of Opal-RT PC-based Real-Time Simulators rapidly increasing for engineering research & development of wind turbines & wind farm design, control and integration.

May 25, 2010 - Dallas, TX

The Breakout Box is designed to interface with a vehicle's PCM allowing the developer to manually make or break each circuit in the harness.

   

Universidad del Pais Vasco: Our Experience using eMEGAsim Real-Time Simulator

Author(s):
Narrator:

Download Video : Vasco1(2).mp4

MPEG4 Mobile Feed :

Related Products

No Data Available

Detailed Wind Farm Simulation with Advanced Wind Modeling using eMEGAsim

Author(s): Philippe Venne,
Narrator: Philippe Venne,

Download Video : Phil1.mp4

MPEG4 Mobile Feed :

Related Products

No Data Available

Emulation of a 1500 W Motor for PHIL Simulation using eDRIVEsim

Author(s): Handy Blanchette,
Narrator: Handy Blanchette,

Download Video : Handy1.mp4

MPEG4 Mobile Feed :

Related Products

No Data Available

Real-Time Simulation Technologies in Education: a Link to Modern Engineering Methods and Practices

Publication date : Mar 2010
Paper File : 2010_Intertech_Dufour_RTLABApplications.pdf

Author(s)

Jean Bélanger, Christian Dufour, Cacilda Andrade,

Abstract

This paper discusses industrial applications of real time simulation technologies and opportunities that exist to include them in modern engineering education curricula. Real-time simulators are used extensively in many engineering fields. As a consequence, the inclusion of simulation applications in academic curricula can provide great value to the student. Statistical power grid protection tests, aircraft design and simulation, motor drive controller design methods and space robot integration are a few examples of real-time simulator technology applications to be discussed in this paper.

Related Products

DINAMO
RT-LAB Professional
EMTP-RV
DINAMO
RT-LAB Berta
EMTP-RV
EMTP-RT

Real-Time Simulation of Large-Scale Power Systems using EMTP-RV and Simulink/SimPowerSystems

Publication date : Mar 2010
Paper File : ECCE2009_paper-digest_Opal-RT_FINAL.pdf

Author(s)

Jean-Nicolas Paquin, Jean Bélanger,

Abstract

This paper presents a modern PC-based real-time simulator using the latest INTEL quad-core processors to simulate a relatively large power system. The performance of the simulator is evaluated by comparing the results of different contingencies in two different simulation environments. A large grid model built using the EMTP-RV software and simulated in real-time using the eMEGAsim platform’s EMTP-RT software tool is described. Comparisons between the off-line and the Real-Time simulations are made using superimposed steady-state and fault condition waveforms.

Related Products

RT-EVENTS
ARTEMiS
eMEGAsim
RT-LAB Professional
EMTP-RV
eMEGAsim
ARTEMiS
RT-LAB Professionnel
RT-EVENTS
RT-LAB Berta
EMTP-RV
EMTP-RT

Syndicate content