In this paper, we propose a technique for reducing asynchronous transfer mo
de (ATM) call blocking which is achieved by splitting wide-band connections
into multiple low-bandwidth subconnections and routing them independently
through the network. The essence of the mechanism is to use fragmented netw
ork bandwidth for supporting calls which are otherwise blocked by conventio
nal routing. ATM bandwidth fragmentation may take place in a situation when
a connection occupies a part of a link bandwidth and the rest of it is not
sufficient for another connection. The unused bandwidth becomes fragmented
, We provide a detailed cell-level design for the split-scheduling algorith
ms, which use a special type of ATM resource management cell for maintainin
g cell ordering. The analysis and simulation of the scheduling algorithms s
how that connection splitting is capable of delivering acceptable cell-leve
l quality of service to multiple traffic classes. We also deliver a solutio
n for implementing splitting without requiring any protocol changes within
the network, We show that it is sufficient to modify the data and control p
lane protocols only within the end stations. Finally, a set of routing-leve
l simulations for splitting demonstrate that splitting can reduce blocking
by up to 45% for high-bandwidth calls in a moderately loaded network, Consi
dering that it does not incur any network expenses or protocol changes, we
propose splitting as an efficient means for reducing connection blocking.