Inspired by the dissipative quantum model of brain, we model the states of neural nets in terms of collective modes by the help of the formalism of Quantum Field Theory. We exhibit an explicit neural net model which allows to memorize a sequence of several informations without reciprocal destructive interference, namely we solve the overprinting problem in such a way last registered information does not destroy the ones previously registered. Moreover, the net is able to recall not only the last registered information in the sequence, but also anyone of those previously registered.The quantum model of brain by Umezawa and Ricciardi [1,2,3,4] has attracted much attention in recent years. Moreover, its extension to dissipative dynamics [5], aimed to solve the long standing problem of memory capacity, provides an interesting framework to study consciousness related mechanisms. On the other hand, computational neuroscience mostly relies on specific activity of neural cells and of their networks, thus leading to a number of models and simulations of the brain activity in terms of neural nets, mostly based on modern methods of statistical mechanics and of spin glass theory [6,7]. Besides, there is an increasing interest in the study of quantum features of network dynamics, either in connection with information processing in biological systems, or in relation with a computational strategy based on the system quantum evolution (quantum computation).Inspired thus by the papers [1, 2, 3] and [5] (see also [8,9, 10]), we explore the possibility of modeling the states of neural nets in terms of collective modes by the help of the formalism of Quantum Field Theory (QFT).We show that the classical limit of the dissipative quantum brain dynamics (DQBD)[5] provides a representation of a neural net characterized by long range correlations among the net's units. In this way we exhibit a link between DQBD and neural net dynamics [11].We present an explicit neural net model which allows to memorize a sequence of several informations without reciprocal destructive interference, namely we solve the overprinting problem, i.e. last registered information does not destroy the ones previously registered. The net is also able to recall informations registered prior to the last registered one in the sequence.In the following we will first introduce the general theoretical background on which our neural net is modeled and then we will present some of its specific features and the results, which, although preliminary, confirm our expectations.
