Phylogenetic trees are widely applied in evolutionary biology. They provide graphical representation of historical relations between operational taxonomic units (OTUs), in particular the evolutionary relationships. From a graph theoretic point of view, a phylogenetic tree is a rooted binary tree. The balance of a phylogenetic tree is probably one of the most widely studied tree shape properties. One can regard the balance of a rooted tree as its overall asymmetry, or the degree to which both children of each internal node tend to have the same number of descendant. This property can be quantified by balance indices. A balance index satisfies a recursive relation. When computing such an index of a tree, one can compute those of its two subtrees, and sum the results as well as the value of a specified function that depends on the property of the index. If a tree is generated by random models, then the balance indices can be regarded as random variables. Two of the most popular random models will be discussed. One is the Yule-Harding model, which randomly selects an extant leaf and replaces it with a cherry until the required number of leaves are obtained. Another one is the uniform model, which assigns the same probability to all trees with the same number of leaves. In fact, balance indices are equivalent to additive parameters in theoretical computer science. Such parameters have been studied for decades. For example, M. Sackin suggested the Sackin's index (S_{n}) in 1972, which is the sum of the depth of all leaves of a tree. Under the Yule-Harding model, this is equivalent to the number of comparison used by quicksort to sort a random input, or the total path length of a random binary search tree. The exact formula of the mean of S_{n} was given by the biologists M. Kirkpatrick and M. Slatkin in 1993. However, its exact formula as well as asymptotic solution has been mentioned in D. Knuth's book in 1973. Also, its limit law was given by M. R{'e}gnier and U. R{"o}sler in 1989 and 1991, respectively. Analysis on several structures and random models, as well as general analytic approaches, are already developed in the literature. For instance, H.-K. Hwang and R. Neininger published a systematic study of additive parameters on quicksort-liked structures in 2002. \ In 2013, A. Mir et al. defined a new balance index---the total cophenetic index (Phi_{n}), and provided the exact formulas of its mean under the Yule-Harding model and the uniform model. This index is the sum over all pairs of leaves, of the depth of their least common ancestor. Soon after, G. Cardona el al. published the second moment as well as the variance of Phi_{n} under the Yule-Harding model. The above studies are all done by arithmetic computation. As the order of moments grows, computation will become more complicated. Also, for large tree size n, it might be more suitable to consider asymptotic formulas. In fact, we can consider the generating function of Phi_{n}. Computer scientists P. Flajolet and Odlyzko A. introduced the method of singularity analysis to deal with generating functions in 1990. This method uses complex analysis to solve combinatorial problems. It is also one of the most important contents in the 2009 book---the first book-length material on this topic written by Flajolet, who is known as the father of analytic combinatorics, together with R. Sedgewick. One of the goal of this thesis is to apply the methods of analytic combinatorics to the generating function of Phi_{n} and find the main terms of all moments under the Yule-Harding model and the uniform model. Also, we prove limit laws by the method of moments. Moreover, we define a generalized total cophenetic index, Phi_{alpha, n}, which is the sum over all set of size alpha of leaves, of the depth of their least common ancestor. In this way, S_{n} is the special case when alpha=1 and Phi_{n} is alpha=2. We also provide the asymptotics of all moments under the Yule-Harding model and the uniform model for this generalized total cophenetic index. This thesis aims to review literature and display our results. Literature arrangement is mainly in Chapter 1, 2, Appendix B and C, while the results are presented in Chapter 3, 4, 5, 6 and Appendix A. In Chapter 1, we give the background of our research problem, including the definition of phylogenetic trees, the properties of balance indices and random models. Previous results on Phi_{n},S_{n} and Colless' index, C_{n} are also provided. Chapter 2 focuses on introducing our methods, such as singularity analysis, an elementary approach and the method of moments. We not only give the theorems we need, but also explain the motivations with examples. In Chapter 3, the limit law of Phi_{n} will be discussed under the Yule-Harding model and the uniform model by singularity analysis. Rules of operations on generating functions will be introduced in Appendix B. Furthermore, Chapter 4 includes the joint distribution of Phi_{n},S_{n} and C_{n} for the Yule-Harding model by an elementary approach, which is also an extension of the joint limit law of S_{n} and C_{n} given by M. Blum. et al. (2006). We also recompute covariances that appeared in previous papers, with the computation details presented in Appendix A. Chapter 5 considers variations of Phi_{n}. The first part is about the index overline{Phi}_{n}=S_{n}+Phi_{n} that was mentioned in A. Mir et al. (2013). We apply Slutsky's theorem in this section and include its proof in Appendix C. The second part will discuss the generalized total cophenetic index Phi_{alpha,n}. We give the asymptotics of its moments under the Yule-Harding model and the uniform model, where for the Yule-Harding model we use an elementary approach. Finally, we conclude this thesis by Chapter 6, which contains a summation of our work as well as several numerical results.