In this study, the self-aggregation process is identified in shallow-to-deep transition of convection during MJO suppressed phase. An idealized experiment is performed using the Vector Vorticity cloud resolving Model (VVM). The initial soundings and subsidence profiles are adopted from the suppressed phase of CINDY/DYNAMO campaign in 2011. The self-aggregation process is identified by the cloud size distribution. The cloud size is calculated using Depth-First Search (DFS) algorithm which treats connected cloudy points as a single cloud object. In addition, the life cycle of the cloud object in discrete model output can also be estimated using a searching algorithm. The result shows that the convective cloud self-aggregation can be identified by the increasing of number and averaged volume during diurnal cycles in the SDT process. The average size of convective clouds increases about 100% during the SDT process and the number of convective clouds becomes 2:5 times larger as well. Our results also show that the ratio of cloud that contains relative larger mass flux and longer life-cycle increase during the SDT process. The results also suggest the importance of convective moistening contributed by self-aggregation of the convective clouds.