The exact wave function of helium atom has not been fully determined yet. Formulating an efficient way of describing and computing the wave functions of two-electron systems is important. Solving this fundamental problem can be useful for accurate treatment of many-electron systems. Using homogeneity expansion of the wave function to solve the Schrödinger equation is the main topic in this thesis. In order to solve the Schrödinger equation to helium atom, we assume that the wave function can be expanded as , where is the component of the total wave function homogeneous of order . By substituting the expansion into Schrödinger equation, the working equation of our method, , is produced. We attempt to solve this equation to find with 0, 1, 2 and 3. The first equation is and its solution is . For , we give a short discussion of homogeneous solutions for the kinetic energy operator ( ) in interparticle coordinates (IC). Next, we discuss two methods of finding , separately for terms independent of and terms dependent on . By solving the equation , we can find that . The equation defining is ; its solution is too complicated to quote it here. The solution found by our method is a particular solution. This solution has singularities at some special points. In order to make our particular solution well-behaving, we need to find homogeneous solutions to remove the singularities of when and . A detailed discussion of found by Abbott et al. leads us to find homogeneous solutions we need. We also make a plot of and prove that is a well-behaving wave function successfully. Application of for solving is another important issue studied in this thesis. An inversion table for monomial terms of homogeneity one is created for finding a particular solution of . Enough terms in monomial tables of every homogeneity have the ability to generate particular solutions of with every value of . This discovery shows that using inversion table to solve the Schrödinger equation is feasible and valuable.