\section{INTRODUCTION}\label{sect:Introduction} The computer code DRAGON is a lattice code designed around solution techniques of the neutron transport equation.\cite{PIP2009} The DRAGON project results from an effort made at {\sl \'Ecole Polytechnique de Montr\'eal} to rationalize and unify into a single code the different models and algorithms used in a lattice code.\cite{Dragon1,Dragon2,Dragon3,Dragon4} One of the main concerns was to ensure that the structure of the code was such that the development and implementation of new calculation techniques would be facilitated. DRAGON is therefore a lattice cell code which is divided into many calculation modules linked together around the Ganlib kernel and can be called from CLE-2000.\cite{ganlib5,cle2000} These modules exchange informations only via well defined data structures. The two main components of the code DRAGON are its multigroup flux solver and its one-group collision probability (CP) tracking modules. The CP modules all perform the same task but using different levels of approximation. The SYBIL tracking option emulates the main flux calculation option available in the APOLLO-1 code,\cite{Apollo,SPH} and includes a new version of the EURYDICE-2 code which performs reactor assembly calculations in both rectangular and hexagonal geometries using the interface current method. The option is activated when the \moc{SYBILT:} module is called. The EXCELL tracking option is used to generate the collision probability matrices for the cases having cluster, two-dimensional or three-dimensional mixed rectangular and cylindrical geometries.\cite{DragonPIJI,Mtl93a} A cyclic tracking option is also available for treating specular boundary conditions in two-dimensional rectangular geometry.\cite{DragonPIJS1,Mtl93b} EXCELL calculations are performed using the \moc{EXCELT:} or \moc{NXT:} module. The MCCG tracking option activates the long characteristics solution technique. This implementation uses the same tracking as EXCELL and perform flux integration using the long characteristics algorithm proposed by Igor Suslov.\cite{mccg,suslov2,chicago2} The option is activated when both \moc{EXCELT:} (or \moc{NXT:}) and \moc{MCCGT:} modules are called. After the collision probability or response matrices associated with a given cell have been generated, the multigroup solution module can be activated. This module uses the power iteration method and requires a number of iteration types.\cite{PIM} The thermal iterations are carried out by DRAGON so as to rebalance the flux distribution only in cases where neutrons undergo up-scattering. The power iterations are performed by DRAGON to solve the fixed source or eigenvalue problem in the cases where a multiplicative medium is analyzed. The effective multiplication factor ($K_{\rm eff}$) is obtained during the power iterations. A search for the critical buckling may be superimposed upon the power iterations so as to force the multiplication factor to take on a fixed value.\cite{Buck} DRAGON can access directly standard microscopic cross-section libraries in various formats. It has the capability of exchanging macroscopic cross-section libraries with a code such as TRANSX-CTR or TRANSX-2 by the use of GOXS format files.\cite{MATXS,TRANSX2} The macroscopic cross section can also be read in DRAGON via the input data stream.