In DFA we can do the intersection of two automata by doing the cross product of the states of the two automata and accepting those states that are accepting in both the initial automata. Union is performed similarly. How ever although i can do union in NFA easily using epsilon transition how do i do their intersection?
You can use the crossproduct construction on NFAs just as you would DFAs. The only changes are how you'd handle εtransitions. Specifically, for each state (q_{i}, r_{j}) in the crossproduct automaton, you add an εtransition from that state to each pair of states (q_{k}, r_{j}) where there's an εtransition in the first machine from q_{i} to q_{k} and to each pair of states (q_{i}, r_{k}) where there's an εtransition in the second machine from r_{j} to r_{k}. Alternatively, you can always convert the NFAs into DFAs and then compute the cross product of those DFAs. Hope this helps! 


there is a huge mistake in the templatetypedef 's answer . the product automaton of L1 and L2 which are NFAs : new states Q = product of the states of L1 and L2 . now the transition function : a is a symbol in the union of both automatons alphabets delta( (q_1,q_2) , a) = delta_L1(q_1 , a) X delta_L2(q_2 , a) which means you should multiply the set that is the resualt of delta_L1(q_1 , a) with the set that results from delta_L2(q_1 , a). the problem in the templatetypedef's answer is that the product result (qk ,rk) is not mentioned . 


An alternative to constructing the product automaton is allowing more complicated acceptance criteria. Ordinarily, an NFA accepts an input string when it has reached any one of a set of accepting final states. That can be extended to boolean combinations of states. Specifically, you construct the automaton for the intersection like you do for the union, but consider the resulting automaton to accept an input string only when it is in (what corresponds to) accepting final states in both automata. 


We can also use De Morgan's Laws: A intersection B = (A' U B')' Taking the union of the compliments of the two NFA's is comparatively simpler, especially if you are used to the epsilon method of union. 

