In this thesis, we investigate the electronic properties of fused azulene-acene system using thermally-assisted-occupation density functional theory (TAO-DFT) in local density approximation (LDA) and compare to the properties of its isomer, acenes. If we use Kohn-Sham density functional theory (KS-DFT) to calculate, we get unphysical triplet ground state because of static correlation error (SCE) causing by the strong correlated (SC) character of fused azulene-acene. On the other hand, the energy usually truncate to local minimum during the iterating process of KS-DFT, and thus it needs lots of initial guess and algorithm to find the global minimum. TAO-DFT can effectively truncate to global minimum and correct SCE under the same computational resource, therefore is used to calculate the properties of fuse azulene-acene. Negative singlet-triplet energy gap is obtained using hybrid functional B3LYP based on KS-DFT for fused azulene-acene in short length (n<8). The result is positive, namely siglet ground state, using TAO-B3LYP. In LDA, singlet-triplet gaps of fused azulene-acene are all lower than ones of acenes. We can know that fusing the 7, 5 rings will lower ST gap, and the degree of reduction decrease as the length increase. Symmetrized von Neumann entropy and orbital occupation numbers show the multi-reference character of fused azulene-acene. The slope of fused azulene-acene of symmetrized von Neumann entropy to length is the same as one of acenes and translate upward, which indicates fused azulene-acene has similar structure of orbital occupation numbers to acenes.