We studied the assembly of nanoparticles (NPs) with oppositely charged linear and periodic copolymers (CPs), alternating ionic and polar sequences, in the dilute range of polymer concentration. For the first time, we considered CPs displaying a contour length much higher than the gold NP (AuNP) perimeter. We assumed that such CPs will enable the collection of a finite number of NPs into linear nanostructures with a gain of colloidal stability and a better structural control compared to electrostatic complexes obtained with homopolyelectrolytes. As a case study, we synthesized anionic AuNPs and CPs consisting of alternated cationic poly-l-lysine (PLL) blocks and polar sequences of poly(ethylene glycol) (PEG). We showed that complexation of AuNPs with CPs is quite similar to that observed with homo PLL. In that respect, finite size nanometric clusters, of less than 30 NPs, are formed outside the electroneutrality domain and a fast phase separation occurs at the electroneutrality. Nevertheless, the presence of PEG blocks allowed us to highlight some specific effects. First, the global charge of the positively charged clusters was found to be always lower for CP-based clusters than for homo PLL with a dependence of the charge with the number and the mass of the PEG blocks. Second, in spite of this effect which should have promoted the formation of a dense structure, the fractal dimension characterizing the structure of the clusters in bulk was found to be always below 1.8. Finally, we showed that PEG blocks influence the interparticle distance by disfavoring plasmon delocalization when the clusters are dispersed in water and collapse around the NPs when the clusters are deposited on the substrate.