Patent Abstract:
A novel folded Clos switch apparatus and method therefore for reducing the number of unemployed I/O terminals of a multistage Clos switching network by partitioning a crossbar switch to provide both the first (yth) and last (x−y+1th) stage of a multistage Clos switch where x is the total number of stages in the general case.

Full Description:
FIELD OF THE INVENTION 
     This invention pertains to non-blocking switching networks, and more particularly, to Clos switch architectures. 
     BACKGROUND OF THE INVENTION 
     Modern high-capacity communication channels have alleviated a number of communication bottlenecks, namely limitations in data transfer rate and channel bandwidth. However, the recent increase in channel bandwidth has also given rise to the need for switching networks capable of maintaining not only high data rates, but also large numbers of separate I/O channels. 
     Historically, the driving force behind the development of switching networks has been the need to provide a non-blocking telephone switching architecture capable of connecting any pair of user terminals under arbitrary traffic conditions. Early on, it was recognized that a crossbar switch with n input terminals, n output terminals and n 2  crosspoints as shown in FIG. 1 is capable of providing the required non-blocking performance, only at a prohibitive cost in large systems. For a square crossbar switch, the number of crosspoints grows by n 2 , making the crossbar switch too complex to implement for a large number of inputs. 
     In a seminal paper entitled “A Study of Non-blocking Switching Networks,” Bell Syst. Tech. J., vol. 32, 3/53, pp. 406-424, published in 1953, Charles Clos proposed a scheme to partition the large crossbar into a number of stages, thus reducing the complexity of the network by decreasing the number of crosspoints. 
     FIG. 2 shows a square three-stage Clos switch architecture. The first (input) stage includes N/n crossbar switches, each having n inlets and k outlets. The second (center) stage consists of k crossbar switches of size (N/n)×(N/n). Similar to the first stage, the third (output) stage also consists of N/n crossbar switches. However, each individual crossbar switch of the third stage has k inlets and n outlets. 
     According to Clos&#39; space-division technique, there are k possible paths for an inlet to reach an outlet. The worst case scenario occurs when for a given inlet and outlet, (n−1) inlets of the first stage are used by other sources, and (n−1) other sources use (n−1) outlets of the third stage. As a result, a minimum of (n−1)+(n−1)+1 routes must be available between the inlet and the outlet. The three stage switch is therefore non-blocking if k≦(n−1)+(n−1)+1, or simply k≦(2n−1). 
     In contrast to the crossbar switch of FIG. 1, the three stage Clos switch configuration has nk(N/n) crosspoints for each first and last stages, and k(N/n) 2  crosspoints for the middle stage, for a total of S=2kN+k(N/n) 2  [Equation S] crosspoints. The optimum number of crosspoints can be obtained by substituting the total number of crosspoints into equation S and differentiating with respect to n then equating to zero. For large values of N, the optimum value of crosspoints is n opt ≈(N/2)½, a definite improvement over the single stage crossbar matrix. Nonetheless, the use of generic square crossbar switches to build a multistage switch results in waste of I/O ports at the input and output stages of the Clos switch. Although rectangular (asymmetrical) crossbar switches can be used in each switching stage of a multistage crossbar switch to reduce the number of idle I/O ports, rectangular crossbar switches are application-specific and unlike their generic square counterparts, cannot be readily used in a wide variety of applications. 
     Switch complexity can be somewhat ameliorated by rearranging an existing connection through a different set of switching interconnections by means of control systems. However, rearrangeable switching networks require data synchronization and employ complex control systems for managing and rerouting large numbers of existing connections. This need for synchronizing the incoming data often requires an additional processing layer at the input and output stages. Furthermore, even though a rearrangeable switch may provide non-blocking behavior, a connection may still suffer from unacceptable performance in terms of delay and data loss if the wrong path is chosen by the control system. 
     There is therefore a need for a non-blocking switching network that fully utilizes the input and output terminals at various stages of the switching architecture. Preferably, such a system can be implemented using off-the-shelf square crossbar switches having a fixed number of I/O terminals, such that the need for using custom-made rectangular crossbars is avoided. 
     SUMMARY OF THE INVENTION 
     The above problems and other similar shortcomings of the existing systems are solved by partitioning a crossbar switch to provide both the first (yth) and last (x−y+1th) stage of a multistage Clos switch architecture where x is the total number of stages in the general case. By aggregating each input stage having n inlets and its corresponding output stage also having n outlets into a single device, a non-blocking crossbar building block of (3n−1)×(3n−1) dimensions is obtained, thereby reducing the number of unused I/O terminals or the need for asymmetrical custom-made switching devices. In the general case of an output stage having a different number of outlets m than the first stage number of inlets n, we encounter the following two cases, as the dilation of the middle stages becomes a function of the greater of n and m: 
     a) if n≧m, then the non-blocking crossbar building block is of size (3n−1)×(2n+m−1); 
     b) if n&lt;m, then the non-blocking crossbar building block is of size (2m+n−1)×(3m−1). 
     This invention arises from the realization that the use of conventional square crossbar devices to build multistage Clos switches results in waste of input and output terminals on all stages except the middle stage, making the cost penalties for implementing large switching systems prohibitive. The architectural complexity and loss of I/O terminals can be obviated by means of a novel method for combining the input and output stages of thp Clos switch network into a single device, thus allowing for an advantageous grouping of functional elements of the Clos switch architecture that minimizes the number of inactive inputs and outputs without loss of non-blocking behavior. The invention departs from a mere replacement of prior art elements with larger size switching devices, and instead focuses on grouping of the input and output stages of a Clos switching architecture into a single device in order to significantly reduce size, complexity and cost of integrated switching networks. Additionally, another benefit of aggregating the first and last stages in the same device is that loopbacks come in for free, be it directly form the switch to I/O port side or from the middle stages. 
    
    
     Other aspects and features of the present invention will become apparent to those ordinarily skilled in the art upon review of the following description of specific embodiments of the invention in conjunction with the accompanying figures. 
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a representation of a non-blocking nxn square crossbar matrix; 
     FIG. 2 is a schematic diagram of an exemplary three stage Clos switch architecture; 
     FIG. 3 is a representation of a 64×64 crossbar matrix; 
     FIG. 4 is a representation of the three stage Clos switch architecture of FIG. 2 as applied to the crossbar matrix of FIG. 3; 
     FIG. 5 is a schematic diagram of the connection arrangements for a folded Clos switch architecture of FIG. 3 in accordance with the present invention; and 
     FIG. 6 is a schematic diagram of a generalized folded Clos architecture switch embodying the features of the current invention. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     A preferred embodiment of the present invention is hereafter described with reference to FIGS. 3 to  6 . FIG. 3 shows a square crossbar switch  100  having a plurality of inlets  110  for accepting an incoming signals and outlets  120  for outputting a signal, wherein any one inlet  111  may be selectively connected to any one of outlets  121  by means of crosspoints  130 . It should be noted that the inlets  110 , outlets  120  and crosspoints  130  are nomenclature common to all crossbar switches hereafter referred to in the ensuing description, regardless of their shape or dimension. 
     The particular switching matrix of FIG. 3 has sixty-four inlets  110 , sixty-four outlets  120 , and a total number of four thousands ninety-six crosspoints  130  allowing an incoming signal (for example an electrical signal or an optical signal) from an inlet  111  to be routed to a particular outlet  121  without blocking. The crosspoints  130  may consist of optical or monolithic switching devices. For instance, a state-of-the-art monolithic IC equivalent of the switching matrix of FIG. 3 operates at speeds of up to 2.5 Gbps, for a total throughput of 160 Gbps. 
     FIG. 4 illustrates how the 64×64 crossbar switch of FIG. 3 may be implemented using a Clos switch architecture having fewer crosspoints per elements. The Clos switch architecture  200  includes a first stage  202  having eight 8×15 input crossbar switches three of which,  208 ,  218  and  228  are shown, a second stage  204  having fifteen 8×8 center crossbar switches four of which,  210 ,  220 ,  230  and  240  are shown, and a third stage  206  having eight 15×8 output crossbar switches three of which,  212 ,  222  and  232  are shown. The first outlet  219  belonging to first input crossbar switch  208  is connected to the first inlet  205  of the first center crossbar switch  210 . The second outlet  229  of the first input crossbar switch  208  is connected to the first inlet  221  of the second center crossbar switch  220 . In like fashion, the remaining outlets of the first stage  202  crossbar switches are sequentially connected to the corresponding inlets of the second stage  204  crossbar switches. In a similar fashion, the first outlet  215  of the first center crossbar switch  210  is connected to the first inlet  207  of the first output crossbar switch  212 . The second outlet  216  of the first center crossbar switch  210  is connected to the first inlet  223  of the second output switch  222 , and so on. As a result, non-blocking behavior is achieved as each inlet is sequentially interconnected to only one outlet. 
     Although the three stage Clos switch architecture  200  of FIG. 4 has more components, modest gains in cost and complexity are achieved as the three stage Clos switch architecture  200  uses components having fewer number of crosspoints than the single crossbar switch  100  of FIG.  3 . Nonetheless, most off-the-shelf crossbar switches are square devices, and the use of square 16×16 crossbar switches to implement the first and third stage crossbar switches  202  and  206  results in waste of one hundred forty-four inlets and outlets, which translates into a total waste of 28% of I/O terminals per crossbar switch. As described in the following section, the present invention streamlines the Clos switching architecture by folding the first stage  202  and third stage  206  crossbar switches into single devices in order to reduce the number of unemployed I/O terminals. 
     There is shown in FIG. 5 a preferred embodiment of a folded Clos switch architecture  300  for implementing the 64×64 crossbar matrix  100  of FIG. 3 in accordance with the teaching of the current invention. The folded Clos switch architecture  300  consists of eight first stage switches three of which,  310 ,  320  and  330  are shown, and fifteen second stage switches  340  four of which,  350 ,  360  and  370  are shown. The first stage switches are each sized 23×23 and the second stage switches are each sized 8×8. More particularly, the first stage crossbar switches  310 ,  320 ,  330  each have twenty-three inlets that are selectively connected to any twenty-three outlets by means of electrical or optical switching elements, in such a manner that any connection request between a particular set of inlets and outlets can be routed from its inlet to its targeted outlet without being blocked. Similarly, the second stage switches  340 ,  350 ,  360 ,  370  each consist of eight inlets selectively coupled to eight outlets via non-blocking optical or electrical switching devices. 
     Pursuant to the teaching of the invention, each first stage crossbar switch  310 ,  320 ,  330  is further partitioned into an input stage  311 ,  321 ,  331  and its corresponding output stage  312 ,  322 ,  332  relating to the input and output stages  202 ,  206  in the Clos switch architecture  200  of FIG.  4 . In other words, the input  202  and output  206  stages of the conventional three stage Clos switch architecture  200  of FIG. 4 are folded together to constitute a single first stage crossbar device  310 ,  320 ,  330 . For instance, the input stage crossbar switch  311  and its corresponding output stage crossbar switch  312  are combined together to form a first stage crossbar switch  310 . Likewise, the input stage crossbar switch  321  and its corresponding output stage crossbar switch  322  are combined together to form a first stage crossbar switch  320 . In similar fashion, successive input and output stage crossbar switches are aggregated together, so that the input stage crossbar switches  331  and its relating output stage crossbar switches  332  form the final first stage crossbar switch  330 . As a result, instead of two separate crossbar switches of 8×15 and 15×8 for each input  311 ,  321 ,  331  and output  312 ,  322 ,  332  stages of the three stage Clos switch architecture, each crossbar switch pairs are each gathered together to form individual 23×23 crossbar switches, therefore significantly reducing the number of unused I/O terminal per device. 
     The first stage crossbar switches  310 ,  320 ,  330  are identical to one another and are each sized to include twenty-three inlets and twenty-three outlets. It should however be noted that the implementation of this preferred embodiment is not necessarily limited to this particular size of square crossbar switch. To achieve high scaleability while reducing the prohibitive cost of manufacturing rectangular crossbar switches, it is more advantageous to employ square crossbar switches preferably sized in binary increments as such devices are readily available in the industry. 
     Reference is now made to FIG. 6 wherein a generalized three stage folded Clos architecture switch showing the features of the current invention is illustrated. There is shown in FIG. 6 a folded Clos switch architecture  400  having a total number of N input terminals and M output terminals, wherein M is at most equal to N. In a preferred embodiment of the invention, M is set equal to N in order to obtain a square Clos switch structure. The folded Clos switch  600  includes a plurality of first stage crossbar switches three of which,  402 ,  404  and  408  are shown. A given first stage crossbar switch  402  is partitioned into an input crossbar switch  408  comprising n inlets  414  for receiving an incoming signal and an output crossbar switch  420  having m outlets  415  selectively coupled to any of the n inlets for routing the incoming signal. 
     In order to achieve the overall switching function of connecting any particular inlet and outlet, each input  408  and output  420  crossbar switches also comprise at least K=m+n−1 outlets  426  and inlets  427  respectively such that an incoming signal can be successfully routed from any one of n inlets  414  to any one of m outlets  415  without blocking. In total, there are N/n first stage crossbar switches. 
     The folded Clos switch architecture  400  also includes K second stage crossbar switches three of which,  430 ,  432  and  434  are shown. Each second stage crossbar switch  430 ,  432 ,  434  is of size (N/n)×(N/n) wherein each inlet  436  is connected to its corresponding outlet  426  of the input stage crossbar switch  408 . Similarly, the second inlet  438  is interconnected to the second outlet  428  of the input stage crossbar switch  408 . In identical manner, successive outlets of the input stage crossbar switches are interconnected to their corresponding inlets of the second stage crossbar switches in an attempt to build the input part of the folded Clos switch architecture  400 . In order to construct the output part of the folded Clos switch architecture  400 , inlet  427  of the output crossbar switch  402  is connected to outlet  437  of the second stage crossbar switch  430 . Inlet  429  of the output crossbar switch  402  is connected to outlet  437  of the second stage crossbar switch  432 . In like fashion, successive inlets of the output crossbar switches are interconnected to their corresponding outlets of the second stage switches in a sequential manner as described above. 
     Considered together, the first and second stage crossbar switches fashion an interconnected three stage folded Clos switch architecture  400  that substantially reduces the number of wasted I/O terminals by combining two stages into a single device. Aggregating the input  408  and output  420  stages together yields first stage cross bar switches of size (3n−1)×(2n+m−1) for n≧m, (2m+n−1)×(3m−1) for n&lt;m in the general case, and (3n−1)×(3n−1) in a square Clos switch implementation where m=n. This in turn translates into a significant economy in the total number of inlets and outlets of the state-of-the-art Clos switch structure. 
     Although the forgoing implementation is described with respect to a three stage Clos switch network, it should be noted that the teaching of the invention is not intended to be limited in scope only to three stage Clos switching structures. In fact, the folded Clos switch structure can also be realized by means of any stage-wise Clos switch structure having three or larger odd number of stages. Thus, in the general case of a square Clos switch architecture having x number of stages where x is an odd integer greater than or equal to three, the crossbar switch at a given yth input stage having a 2:2n−1 fan-out and its corresponding crossbar switch at the x−y+1th stage having 2n−1:n fan-in are physically united to create a single crossbar switch of size (3n−1)×(3n−1), partitioned into a (n)×(2n−1) and (2n−1)×(n) portions respectively. 
     What has been described is merely illustrative of the application of the principles of the invention. Other arrangements and methods can be implemented by those skilled in the art without departing from the spirit and scope of the present invention.

Technology Classification (CPC): 7