Ponderomotive laser self-focusing poses a threat to the success of the inertial confinement fusion (ICF) program: it locally enhances the laser intensity, which causes two detrimental effects: i) undermining the uniformity of the shock wave launched into the target, and ii) increasing the onset of laser-plasma instabilities. Despite several optical techniques have been implemented to smooth ponderomotive effects, they still remain a concern in case of crossing beams or in spike pulse-plasma interaction as in shock ignition.In order to ameliorate the interpretation capability of radiation-hydrodynamics simulations, the Paraxial Complex Geometrical Optics (PCGO) module has been implemented in the hydrodynamics code CHIC in two-dimensional planar geometry, and is an improved version of the standard Ray-Tracing technique. PCGO accounts for nonlinear laser-plasma interaction such as ponderomotive force and hot electrons generation and propagation, usually neglected in hydrodynamic simulations. This approach is also used for creating spatially modulated laser beams by superposing Gaussian PCGO beamlets in the far-field. Their intensity envelope generates the intensity fluctuations. Although this PCGO-based method has improved the accuracy of CHIC simulations, the superposition of PCGO beamlets produces larger and longer speckles than real ones, and their self-focusing may be overestimated.In this thesis, we develop a method for describing and controlling the excessive ponderomotive self-focusing developing in PCGO speckles while performing CHIC simulations. This study has been conducted in stationary plasmas. First, we investigate self-focusing of a single Gaussian PCGO beamlet in a homogeneous nonabsorbing plasma by comparing its behavior to a Gaussian-shaped beam modeled with the paraxial electromagnetic code HARMONY. This comparison allows to define the domain of beam power where the PCGO approximation is valid. We found that within 4 times the critical power, PCGO correctly reproduces HARMONY results.Afterwards, we consider the self-focusing of a PCGO speckle created by superposition of several beamlets, referred to as a multi-beamlet speckle. This speckle stands for a reference for any PCGO speckle created in CHIC. The reduction of the speckle intensity enhancement is quantified as a function of the number of superposed beamlets and by considering two strategies for multi-beamlet speckle shaping: random and regular.The latter configuration demonstrates better performances in controlling and reducing ponderomotive effects for a number of beamlets equal to three: our results show that the critical power of a three-beamlet speckle is twice higher compared to the critical power of a Gaussian beam with same characteristics.This novel speckle configuration has been implemented in CHIC and employed to generate multi-speckle beams whose speckle intensity distribution obeys to an exponential law. We then studied the self-focusing of a spatially modulated beam (multi-speckle beam) in a homogeneous nonabsorbing plasma and show that our configuration allows to properly treat ponderomotive effects for different laser intensities: this method describes the speckle intensity statistics modification induced by speckle self-focusing and inter-speckle interaction as observed in electromagnetic simulations.The last part of the thesis is devoted to establish a baseline towards modelling of laser self-focusing in real ICF conditions. For this purpose, our results are extended to absorbing plasmas with a linear density profile. Speckle self-focusing is investigated here for different plasma lengths, and the effect of laser absorption is discussed. It is demonstrated that the proposed method of creation of a multi-beamlet speckle pattern operates in the conditions relevant to the direct-drive ICF. It allows to control efficiently the speckle self-focusing and its effect on the speckle intensity distribution in plasma.