DFE Error Propagation and FEC Interleaving for 400GbE PAM4 Electrical Lane

Zhan, Yongzheng; Hu, Qingsheng; Zhang, Yinhang

doi:10.1587/transele.2019ecp5016

Cited by 2 publications

(4 citation statements)

References 11 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Moreover, there are some mathematical operations, such as convolution and Fourier transform, in the signal transmission process. Through simulation, it can be obtained that, compared with the non-interleaving scheme in reference [15], PBM can achieve an interleaving gain of 0.35 dB at the BER of 10 −7 , as shown in Figure 9a. This shows that PBM can reduce more error symbols caused by the same burst errors than FOM, but fewer than PSM.…”

Section: Architecture and Analysismentioning

confidence: 99%

“…Then, these interleaved data are aggregated through the multiplexer to further discrete errors and double the transmission rate. We have provided and theoretically explored the use of FEC Orthogonal bit Multiplexing (FOM), symbol Pre-interleaving Bit MUX (PBM) and symbol Pre-interleaving Symbol MUX (PSM) in detail [15]. The error-mitigation processes of non-interleaving and PBM are shown in Figure 7a,b, respectively.…”

Section: Architecture and Analysismentioning

confidence: 99%

“…This requires some optimization technologies at the circuit level. Further, focusing on the memory capacity for buffer codewords, MUX and the latency of interleaving, a performance comparison of these three FEC interleaving schemes is given in Table 1 [15]. In order to prepare all 16 symbols well before they are sent to MUX, PBM needs a 1500-bit memory, which consists of 150 bit, 300 bit, 450 bit and 600 bit to buffer 16 symbols from the first FEC lane to the fourth one, respectively.…”

Section: Architecture and Analysismentioning

confidence: 99%

“…To achieve our objectives, we propose and implement a high-speed high-depth preinterleaver of symbol pre-interleave bit muxing (PBM) to mitigate DFE error propagation. The theoretical level focuses on developing a cumulative probability distribution model to theoretically analyze the error probability and interleaving gain of PBM [15]. Due to the compensate constraint, the model is subject to a limit to the SerDes configuration with DFE.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

41.6 Gb/s High-Depth Pre-Interleaver for DFE Error Propagation in 65 nm CMOS Technology

Zhan,

Li,

Zou

et al. 2023

Electronics

View full text Add to dashboard Cite

A high-speed, high-depth pre-interleaver in the proposed symbol pre-interleaving Bit MUX (PBM) was implemented to mitigate decision feedback equalizer (DFE) error propagation in a 400 G Ethernet Serializer–Deserializer (SerDes) interface. Based on the SerDes interface link architecture with 5-tap DFE, the performance of the PBM under DFE error propagation was simulated theoretically, which could obtain an interleaving gain of 0.35 dB. In the pre-interleaver, in order to significantly increase the transmission rate while keeping the larger interleaving depth, characteristic polynomial parallelization with the logic expansion method and register-based memory with interleaving technology were adopted. Finally, the pre-interleaver was fabricated with 65 nm CMOS technology, with a total area of 0.615 mm2, including the I/O pad. The measurement results show that the horizontal opening degree of the output signal can reach 0.925 UI at the data rate of 41.6 Gb/s. The total power consumption is 38.52 mW at the supply voltage of 1.2 V and frequency of 1.3 GHz.

show abstract

Section: Architecture and Analysismentioning

confidence: 99%

Section: Architecture and Analysismentioning

confidence: 99%

Section: Architecture and Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

41.6 Gb/s High-Depth Pre-Interleaver for DFE Error Propagation in 65 nm CMOS Technology

Zhan,

Li,

Zou

et al. 2023

Electronics

View full text Add to dashboard Cite

show abstract

DFE Error Propagation Mitigation Using Feed Forward Equalizer and Forward Error Correction in 25 Gb/s NRZ Transceiver

Zhan,

Li,

et al. 2024

J CIRCUIT SYST COMP

View full text Add to dashboard Cite

In order to mitigate DFE error propagation to reduce bit error rate (BER), a 25[Formula: see text]Gb/s Non-Return-To-Zero (NRZ) transceiver including a five-tap decision feedback equalizer (DFE) combined with a dedicated feed forward equalizer (FFE) was first constructed and was found to be helpful in improving signal integrity and reduce errors in high-speed data transmission, which can lead to more reliable and efficient communication. In this transceiver, the effect of multi-tap FFE on error probability with different burst error run lengths was evaluated through a cumulative-probability distribution model. Then, forward error correction (FEC) with different correction capabilities can be also employed to correct burst errors for a better BER performance. Probability-based BER with single/double burst error correcting FEC was derived and a joint optimization of FFE and FEC can be further explored to achieve the target BER. Results show that compared with two-tap FFE, FFE with a post-cursor tap can obtain a BER improvement of 1.5[Formula: see text]dB at the BER of [Formula: see text], and also enlarge the horizontal opening degree of DFE, which is 0.74 unit interval (UI). Double burst error correcting FEC obtaining 2.2[Formula: see text]dB coding gain at the BER of [Formula: see text] outperforms single one. When the FEC error correcting capability is 16, the combination of double burst error correcting FEC and three-tap FFE can reduce BER from [Formula: see text] to approximately [Formula: see text]. FEC with a larger error correction capability is more likely to achieve the target BER and reduce the complexity of the combination equalizer while ensuring a better equalization performance. The proposed NRZ transceiver, as a part of the physical interface, can be applied to high-speed interconnection scenarios, such as Ethernet, PCIe, and Chiplet.

show abstract

DFE Error Propagation and FEC Interleaving for 400GbE PAM4 Electrical Lane

Cited by 2 publications

References 11 publications

41.6 Gb/s High-Depth Pre-Interleaver for DFE Error Propagation in 65 nm CMOS Technology

41.6 Gb/s High-Depth Pre-Interleaver for DFE Error Propagation in 65 nm CMOS Technology

DFE Error Propagation Mitigation Using Feed Forward Equalizer and Forward Error Correction in 25 Gb/s NRZ Transceiver

Contact Info

Product

Resources

About