Orthogonality and boundary conditions in quantum mechanics

One-dimensional particle states are constructed according to orthogonality conditions, without requiring boundary conditions. Free particle states are constructed using Dirac's delta function orthogonality conditions. The states (doublets) depend on two quantum numbers: energy and parity ("+" or "-"). With the aid of projection operators the particles are confined to a constrained region, in a way similar to the action of an infinite well potential. From the resulting overcomplete basis, only the mutually orthogonal states are selected. Four solutions arte found, corresponding to different non-commuting Hamiltonians. Their energy eigenstates are labeled with the main quantum number n and parity "+" or "-". The energy eigenvalues are functions of n only. The four cases correspond to different boundary conditions: (I) The wave function vanishes on the boundary (energy levels: 1(+),2(-),3(+),4(-),...), (II) the derivative of the wavefunction vanishes on the boundary (energy levels 0(+),1(-),2(+),3(-),...), (III) periodic boundary conditions (energy levels: 0(+),2(+),2(-),4(+),4(-)6(+),6(-),...), (IV) periodic boundary conditions (energy levels: 1(+),1(-),3(+),3(-),5(+,)5(-),...). Among the four cases, only solution (III) forms a complete basis in the sense that any function in the constrained region, can be expanded with it. By extending the boundaries of the constrained region to infinity, only solution (III) converges uniformly to the free particle states. Orthogonality seems to be a more basic requirement than boundary conditions. By using projection operators, confinement of the particle to a definite region can be achieved in a conceptually simple and unambiguous way, and physical operators can be written so that they act only in the confined region.