Journal of Systems Engineering and Electronics ›› 2022, Vol. 33 ›› Issue (6): 1208-1223.doi: 10.23919/JSEE.2022.000143
• SYSTEMS ENGINEERING • Previous Articles
Hui CHE1,2(
), Dingxiang PENG2(), Fachang GUO2(), Yong BAI3,*()
Received:2020-04-07
Online:2022-12-18
Published:2022-12-24
Contact:
Yong BAI
E-mail:xmutch@163.com;pengdx@ruijie.com.cn;guofachang@ruijie.com.cn;bai@hainanu.edu.cn
About author:Supported by:Hui CHE, Dingxiang PENG, Fachang GUO, Yong BAI. Faster-than-Nyquist signaling based on filter bank multicarrier modulation with joint optimization[J]. Journal of Systems Engineering and Electronics, 2022, 33(6): 1208-1223.
Fig 1
Coded modulation MFTN system model"
Fig 2
Time domain compression of MFTN"
Fig 3
Frequency domain compression of MFTN"
Fig 4
Effect of K on spectral efficiency with β= 0.2, ${\boldsymbol{\tau}} = {\boldsymbol{0.83}}$ , v = 0.93 "
Fig 5
${{\boldsymbol{\eta}} _{\boldsymbol{G}}}$ versus ${{\boldsymbol{E}}_{\boldsymbol{b}}}/{{\boldsymbol{N}}_{\boldsymbol{0}}}$ for TFP-MFTN with the same FPR (0.93) and different TPRs ( ${\boldsymbol{\tau }} =$ 0.85, 0.83, 0.81), where ${\boldsymbol{\beta }} = {\boldsymbol{0.2}}$ "
Fig 6
${{\boldsymbol{\eta}} _{\boldsymbol{G}}}$ versus ${{\boldsymbol{E}}_{\boldsymbol{b}}}/{{\boldsymbol{N}}_{\boldsymbol{0}}}$ for TFP-MFTN with the same TPR (0.83) and different FPRs ( ${\boldsymbol{\nu}} =$ 1.0, 0.93, 0.85), where ${\boldsymbol{\beta}} = {\boldsymbol{0.2}}$ "
Fig 7
MFTN transmitter with ${\boldsymbol{\tau \nu}} = {\boldsymbol{0.5}}/\left( {{\boldsymbol{1}} + {\boldsymbol{\beta}} } \right)$ "
Table 1
Number of complex multiplications per output of MFTN with 16, 32, 64, 128, and 256 subcarriers"
| Subcarrier | Direct | Efficient implementation |
| L=16 | 520 | 98.5 |
| L=32 | 1040 | 99.5 |
| L=64 | 2080 | 110.5 |
| L=128 | 4160 | 101.5 |
| L=256 | 8320 | 102.5 |
Fig 8
MFTN receiver with ${\boldsymbol{\tau \nu}} = {\boldsymbol{0.5}}/\left( {{\boldsymbol{1 }}+ {\boldsymbol{\beta}} } \right)$ "
Fig 9
Per subcarrier equalization based on channel shortening"
Fig 10
PIC for MFTN"
Fig 11
Soft ICI estimator"
Fig 12
${{\boldsymbol{\eta}} _{\boldsymbol{F}}}$ versus ${{\boldsymbol{E}}_{\boldsymbol{b}}}/{{\boldsymbol{N}}_{\boldsymbol{0}}}$ for TFP-MFTN with different FPRs ${\boldsymbol{\nu}}$ and ${\boldsymbol{\beta }} = {\boldsymbol{0.2}}$ , subject to ${\boldsymbol{ \tau \nu}} = {\boldsymbol{0.5}}/\left( {{\boldsymbol{1}} + {\boldsymbol{\beta}} } \right)$ "
Fig 13
${{\boldsymbol{\eta}} _{\boldsymbol{F}}}$ versus ${{\boldsymbol{E}}_{\boldsymbol{s}}}/{{\boldsymbol{N}}_{\boldsymbol{0}}}$ for TFP-MFTN in this paper and TFP-MFTN in [15], [16] and [19] "
Table 2
Parameters for coded modulation MFTN"
| Parameter | Value |
| Prototype filter | RRC, |
| Number of subcarriers | |
| Packing ratio pair | ( |
| Constellation cardinality | M=4 |
| Doping rate | |
| Code rate | r=0.5 |
| Code length | 32000 |
| Degree distribution | |
| ISI taps | |
| Spectrum efficiency | |
| Minimal | 2.5 dB |
| | 30 |
| Dimension of | 8 |
| Maximum iterations | |
Table 3
LDPC parameters"
| Base matrix | Degree distribution | Sliding-window girth [ | Expanding factor |
| | 2(48), 3(1), 19(1) | 12 | 640 |
Fig 14
Doping effects on the EXIT chart of TFP-MFTN inner decoders and ${{\boldsymbol{E}}_{\boldsymbol{b}}}/{{\boldsymbol{N}}_{\boldsymbol{0}}}$ = 3 dB "
Fig 15
EXIT chart prediction for joint MFTN and LDPC optimization"
Fig 16
Impact of doping and PIC on BER"
Fig 17
BER performance of MFTN and Nyquist system"
Table 4
Gain for TP/TFP-MFTN dB "
| Type | TP gain | TFP gain | Coding gain |
| Theoretical | 0.2 | 0.55 | 2.7 |
| Simulation | 0.1 | 0.9 | 2.9 |
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