High-Throughput LDPC-Decoder Architecture Using Efficient Comparison Techniques &amp;amp; Dynamic Multi-Frame Processing Schedule

Kumawat, Sachin; Shrestha, Rahul; Daga, Nikunj; Paily, Roy

doi:10.1109/tcsi.2015.2403032

Cited by 50 publications

(24 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The corresponding area efficiency of the proposed work is 76.81 Mbps/mm 2 , whereas the area efficiency obtained by Li et al [11], Park et al [18], Kumawat et al [19], and Lee et al [20] Table 2, it can be concluded that the proposed work is the most area-efficient among the reported LDPC decoders. Although the design from Lee et al [20] achieves the highest data rate (10.97 Gbps at 10 iterations), it suffers from a larger chip core area, compared to our proposed design.…”

Section: Throughput Area Efficiency Code Length Area =´mentioning

confidence: 66%

“…The submatrix size, z, is set to 42 for IEEE 802.11ad, to 81 for IEEE 802.11n, and to 21 for IEEE 802.15.3c applications. First of all, analysis results show that the proposed halfrow pipelined layered LDPC decoder reduces the complexity of nearly all components by half, compared to the fully parallel pipelined layer LDPC decoder design of Kumawat et al [19]. Moreover, the proposed decoder reduces the major area-consuming components, like adders, sign magnitude conversion (SMC), and min comparators, compared to flooding decoders [18,20].…”

Section: Analysis and Comparison Resultsmentioning

confidence: 93%

See 1 more Smart Citation

An Area-efficient Half-row Pipelined Layered LDPC Decoder Architecture

Ajaz¹,

Nguyen²,

Lee³

2017

JSTS

View full text Add to dashboard Cite

This paper presents an area-efficient halfrow pipelined layered low-density parity check (LDPC) decoder architecture for IEEE 802.11ad applications. The proposed decoder achieves a good tradeoff between throughput and area because of its ability to overcome the low-throughput bottleneck in conventional half-row decoders and the highcomplexity bottleneck in fully parallel decoders. Synthesis results using TSMC 40 nm CMOS technology shows much better throughput at 10.84 Gbps and superior area efficiency, compared to previously reported LDPC decoders.

show abstract

Section: Throughput Area Efficiency Code Length Area =´mentioning

confidence: 66%

Section: Analysis and Comparison Resultsmentioning

confidence: 93%

An Area-efficient Half-row Pipelined Layered LDPC Decoder Architecture

Ajaz¹,

Nguyen²,

Lee³

2017

JSTS

View full text Add to dashboard Cite

show abstract

“…Accordingly, the specific implementation characteristics of NPUs having the proposed dual-tree architecture depend on the characteristics of these subnodes. In order to facilitate a comparison and discussion in this section, we consider NPUs having subnodes which calculate the min (x, y) of two 4-bit unsigned inputs x and y, as used within fixed-point CNPUs performing the MSA 1 [14]. Since this function is non-invertible, the single binary tree structure mentioned in Section I is not viable.…”

Section: Implementation Resultsmentioning

confidence: 99%

“…Alternatively, parallel flexible NPUs may be implemented having the maximum number of inputs and outputs, namely I = D C for CNPUs or I = D V + 1 for VNPUs, where D C and D V refer to the maximum values of d c and d v within the set of supported PCMs, respectively. When used for processing nodes having lower degrees, the unused inputs may be effectively disabled by supplying them with a "null" value [12]- [14]. For the example of VNPUs processing messages in the form of binary fixed-point Logarithmic-Likelihood Ratios (LLRs), each subnode performs the addition of two LLRs.…”

Section: Flexible Npu Architecturesmentioning

confidence: 99%

“…Alternative architectures must therefore be employed when the subnode operation is not invertible, as is the case with the min operation of CNPUs performing the Min-Sum Algorithm (MSA), for example [14]. One rudimentary option, henceforth referred to as a multi-tree architecture, is to use I parallel binary trees to calculate the combination of each of the I possible sets of I − 1 inputs [12].…”

Section: Flexible Npu Architecturesmentioning

confidence: 99%

See 1 more Smart Citation

Hardware-Efficient Node Processing Unit Architectures for Flexible LDPC Decoder Implementations

Hailes

Maunder

et al. 2018

IEEE Trans. Circuits Syst. II

View full text Add to dashboard Cite

In LDPC decoder implementations, the architecture of the Node Processing Units (NPUs) has a significant impact both on the hardware resource requirements and on the processing throughput. Additionally, some NPU architectures impose limitations on the decoder's support for intra-or inter-standard LDPC code flexibility at run-time. In this paper, we present a generalised algorithmic method of constructing NPUs that support run-time flexibility whilst maintaining a low hardware resource requirement and high maximum operating frequency. FPGA-based synthesis results demonstrate that the proposed architecture offers a significantly improved hardware efficiency, when compared to two commonly-employed alternatives.

show abstract

A high‐throughput multimode low‐density parity‐check decoder for 5G New Radio

Pourjabar

Choi

2021

Circuit Theory & Apps

View full text Add to dashboard Cite

This paper presents a partially parallel low-density parity-check (LDPC) decoder for the 5G New Radio (NR) standard. The design is using a multiblock parallel architecture with a flooding schedule. The decoder can support any code rates and code lengths up to the lifting size Z max = 96. To compensate for the dropped throughput associated with the smaller Z values, the design can double and quadruple its parallelism when lifting sizes Z ≤ 48 and Z ≤ 24 are selected, respectively. Therefore, the decoder can process up to eight frames and restore the throughput to the maximum. To facilitate the design's architecture, a new variable node for decoding the extended parity bits existing in the lower code rates is proposed. The FPGA implementation of the decoder results in a throughput of 2.1 Gbps decoding the 11/12 code rate. Additionally, the synthesized decoder using the 28-nm TSMC technology achieves a maximum clock frequency of 526 MHz and a throughput of 13.46 Gbps. The core decoder occupies 1.03 mm 2 , and the power consumption is 229 mW.

show abstract

High-Throughput LDPC-Decoder Architecture Using Efficient Comparison Techniques & Dynamic Multi-Frame Processing Schedule

Cited by 50 publications

References 26 publications

An Area-efficient Half-row Pipelined Layered LDPC Decoder Architecture

An Area-efficient Half-row Pipelined Layered LDPC Decoder Architecture

Hardware-Efficient Node Processing Unit Architectures for Flexible LDPC Decoder Implementations

A high‐throughput multimode low‐density parity‐check decoder for 5G New Radio

Contact Info

Product

Resources

About