Low-Complexity Multi-size Cyclic-Shifter for QC-LDPC Codes

Abstract: The decoding process of a quasi-cyclic low-density parity check code requires a unique type of rotator. These rotators, called multi-size cyclic-shifters (MSCSs), rotate input data with various sizes, where the size is the amount of data to be rotated. This paper proposes a lowcomplexity MSCS structure for the case when the sizes have a nontrivial common divisor. By combining the strong points of two previous structures, the proposed structure achieves the smallest area. The experimental results show that the … Show more

“…The delay times of the RIP structure and the BN + F3 structure are and , respectively. The FC structure in [9] combined the BN + F3 structure and the pre‐rotator structure, achieving the smallest number of MUXs, , and the moderate delay time, .…”

“…In the proposed structure, the sub‐MSCS block in the coarse part uses the RIP structure instead of the BN + F3 structure exploited in [9]. The 2‐input MUX number of the proposed coarse part can be calculated by substituting for N in the second row of Table 1.…”

“…Because of the delay, the BN structure generates a larger circuit than the RIP structure after synthesis. In the experimental results of [9], the RIP structure was found to be the smallest and almost the fastest one among the above structures. The fine‐coarse (FC) structure proposed in [9] combined the BN structure and the pre‐rotator structure, leading to an even smaller MSCS block.…”

“…The above structures were compared in [9], where the BN structure was theoretically found to have the lowest complexity but a longer delay. Because of the delay, the BN structure generates a larger circuit than the RIP structure after synthesis.…”

“…The kth sub-MSCS block gathers the kth outputs of the pre-rotators and rotates them by s c with the rotation size of z g = z/g. The cross-group movement, the make-up for the inside-group rotation at the pre-rotators, is performed by the s c + 1 rotation in the kth sub-MSCS block of k + s f ≥ g. In the proposed structure, the sub-MSCS block in the coarse part uses the RIP structure instead of the BN + F3 structure exploited in [9]. The 2-input MUX number of the proposed coarse part can be calculated by substituting N g for N in the second row of Table 1.…”

Low‐complexity, high‐speed multi‐size cyclic‐shifter for quasi‐cyclic LDPC decoder

“…The delay times of the RIP structure and the BN + F3 structure are and , respectively. The FC structure in [9] combined the BN + F3 structure and the pre‐rotator structure, achieving the smallest number of MUXs, , and the moderate delay time, .…”

“…In the proposed structure, the sub‐MSCS block in the coarse part uses the RIP structure instead of the BN + F3 structure exploited in [9]. The 2‐input MUX number of the proposed coarse part can be calculated by substituting for N in the second row of Table 1.…”

“…Because of the delay, the BN structure generates a larger circuit than the RIP structure after synthesis. In the experimental results of [9], the RIP structure was found to be the smallest and almost the fastest one among the above structures. The fine‐coarse (FC) structure proposed in [9] combined the BN structure and the pre‐rotator structure, leading to an even smaller MSCS block.…”

“…The above structures were compared in [9], where the BN structure was theoretically found to have the lowest complexity but a longer delay. Because of the delay, the BN structure generates a larger circuit than the RIP structure after synthesis.…”

“…The kth sub-MSCS block gathers the kth outputs of the pre-rotators and rotates them by s c with the rotation size of z g = z/g. The cross-group movement, the make-up for the inside-group rotation at the pre-rotators, is performed by the s c + 1 rotation in the kth sub-MSCS block of k + s f ≥ g. In the proposed structure, the sub-MSCS block in the coarse part uses the RIP structure instead of the BN + F3 structure exploited in [9]. The 2-input MUX number of the proposed coarse part can be calculated by substituting N g for N in the second row of Table 1.…”

Low‐complexity, high‐speed multi‐size cyclic‐shifter for quasi‐cyclic LDPC decoder

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