ZTE Communications ›› 2017, Vol. 15 ›› Issue (S1): 31-40.DOI: 10.3969/j.issn.1673-5188.2017.S1.004
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YANG Shan, CHEN Peng, LIANG Lin, ZHU Jianchi, SHE Xiaoming
Received:2016-09-30
Online:2017-06-25
Published:2020-04-14
About author:YANG Shan (yangshan.bri@chinatelecom.cn) received her M.S. degree in commnuication and information system in 2012 from Beijing University of Posts and Telecommunications (BUPT), China. She works with China Telecom Technology Innvotation Center. She is now the 3GPP RAN4 and RAN1 delegate of China Telecom, and has submitted more than 200 contributions to 3GPP. Her reasearch interestes include 5G multiple access technology, baseband advacned receiver, and radio frequency requirements.|CHEN Peng (chenpeng.bri@chinatelecom.cn) received his Ph.D. degree in commnuication and information system in 2006 from BUPT, China. He is the director of China Telecom Technology Innvotation Center, and his reasearch interestes include 5G air interface, network artchitecutre, and 3GPP 5G standaridzaion work.|LIANG Lin (lianglin.bri@chinatelecom.cn) received his M.S. degree in commnuication and information system in 2013 from BUPT, China. He works with China Telecom Technology Innvotation Center. His reasearch interestes include baseband advacned receiver, channel coding, massive MIMO and 3GPP 5G standaridzaion work.|ZHU Jianchi (zhujc.bri@chinatelecom.cn) received his M.S. degree in commnuication and information system in 2007 from BUPT, China. He works with China Telecom Technology Innvotation Center. His reasearch interestes include 5G multiple access techonology, ultra dense network, massive MIMO and 3GPP 5G standaridzaion work.|SHE Xiaoming (shexm.bri@chinatelecom.cn) received his Ph.D. degree in commnuication and information system in 2004 from Tsinghua University, China. He is the vice director of China Telecom Technology Innvotation Center, and his reasearch interestes include 5G air interface, network artchitecutre, and 3GPP 5G standaridzaion work.
YANG Shan, CHEN Peng, LIANG Lin, ZHU Jianchi, SHE Xiaoming. Uplink Multiple Access Schemes for 5G: A Survey[J]. ZTE Communications, 2017, 15(S1): 31-40.
Figure 1. Multiple access technology for cellular systems.
Figure 2. Illustration of uplink NMA.
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Table 1 Categories of NMA schemes
| |
| NMA scheme | Description | Standardization impact | Receiver algorithm | |
|---|---|---|---|---|
| Category 1: Scrambling based | NOMA | •Multiple UEs with different scrambling sequences are transmitted on the same resource •NOMA can also bring in performance gain for multiple UEs with similar wideband SINR, thanks to the fast fading | •Define new scrambling sequence if needed •Power control enhancement if needed | SIC |
| RSMA | Use combination of low rate channel codes and scrambling codes (and optionally different interleavers) with good correlation properties | •Define scrambling sequence and interleaver if needed •Define single carrier based new waveform for asynchronous transmission | SIC | |
| LSSA | Each UE’s data is bit or symbol level multiplexed with UE specific signature pattern which is unknown to others | Define signature pattern | SIC | |
| Category 2: Interleaving based | IDMA | Use bit level interleavers to separate UEs | Define bit-level interleaver | ESE |
| IGMA | Use bit level interleavers and/or grid mapping pattern to separate UEs | •Define bit-level interleaver •Define sparse symbol-to-RE grid mapping pattern | ESE or chip-by-chip MAP | |
| Category 3: Spreading based | SCMA | The coded bits of a data stream are directly mapped to a codeword from a codebook built based on a multi-dimensional constellation, and low density spreading is utilized | Define LDS code and multi-dimensional constellation | MPA, or MPA with SIC |
| PDMA | A code is used to define sparse mapping from data to a group of resources, and different codes may have different diversity orders | Define LDS code matrix | BP based iterative detection and decoding | |
| LDS-SVE | For LDS spreading, consider UE signature vector extension, e.g., transforming and concatenating two element signature vectors into a larger signature vector | •Define LDS code•Define signature vector extension method | MPA | |
| MUSA | Use random complex spreading codes with short length, and the real part and imaginary part of each element in the complex spreading code are drawn from a multi-level real value set uniformly, for example, {-1, 1} or {-1, 0, 1} | Define spreading code | SIC | |
| NOCA | Use LTE defined low correlation sequences as spreading codes, e.g., LTE defined sequences for uplink reference signal for 1 RB case | Reuse the LTE defined sequence as spreading code | SIC | |
| NCMA | Spreading codes are obtained by Grassmannian line packing problem | Define spreading code | PIC | |
| LCRS | Apply direct spreading of modulation symbols and to transmit the spread symbols in time-frequency resources allocated for non-orthogonal transmission | Define spreading code | SIC |
Table 2 Candidate uplink NMA schemes
| NMA scheme | Description | Standardization impact | Receiver algorithm | |
|---|---|---|---|---|
| Category 1: Scrambling based | NOMA | •Multiple UEs with different scrambling sequences are transmitted on the same resource •NOMA can also bring in performance gain for multiple UEs with similar wideband SINR, thanks to the fast fading | •Define new scrambling sequence if needed •Power control enhancement if needed | SIC |
| RSMA | Use combination of low rate channel codes and scrambling codes (and optionally different interleavers) with good correlation properties | •Define scrambling sequence and interleaver if needed •Define single carrier based new waveform for asynchronous transmission | SIC | |
| LSSA | Each UE’s data is bit or symbol level multiplexed with UE specific signature pattern which is unknown to others | Define signature pattern | SIC | |
| Category 2: Interleaving based | IDMA | Use bit level interleavers to separate UEs | Define bit-level interleaver | ESE |
| IGMA | Use bit level interleavers and/or grid mapping pattern to separate UEs | •Define bit-level interleaver •Define sparse symbol-to-RE grid mapping pattern | ESE or chip-by-chip MAP | |
| Category 3: Spreading based | SCMA | The coded bits of a data stream are directly mapped to a codeword from a codebook built based on a multi-dimensional constellation, and low density spreading is utilized | Define LDS code and multi-dimensional constellation | MPA, or MPA with SIC |
| PDMA | A code is used to define sparse mapping from data to a group of resources, and different codes may have different diversity orders | Define LDS code matrix | BP based iterative detection and decoding | |
| LDS-SVE | For LDS spreading, consider UE signature vector extension, e.g., transforming and concatenating two element signature vectors into a larger signature vector | •Define LDS code•Define signature vector extension method | MPA | |
| MUSA | Use random complex spreading codes with short length, and the real part and imaginary part of each element in the complex spreading code are drawn from a multi-level real value set uniformly, for example, {-1, 1} or {-1, 0, 1} | Define spreading code | SIC | |
| NOCA | Use LTE defined low correlation sequences as spreading codes, e.g., LTE defined sequences for uplink reference signal for 1 RB case | Reuse the LTE defined sequence as spreading code | SIC | |
| NCMA | Spreading codes are obtained by Grassmannian line packing problem | Define spreading code | PIC | |
| LCRS | Apply direct spreading of modulation symbols and to transmit the spread symbols in time-frequency resources allocated for non-orthogonal transmission | Define spreading code | SIC |
Figure 3. Comparison of orthogonal multiple access and NOMA in uplink.
Figure 4. Uplink NOMA.
Figure 5. RSMA block diagrams.
Figure 6. Example of LSSA transmitter structure.
Figure 7. Scenario for FDMA and IDMA comparison.
Figure 8. Schematic of IGMA transmitter.
Figure 9. Example of grid mapping process.
Figure 10. SCMA codebook mapping.
Figure 11. SCMA codebook bit-to-codeword mapping.
Figure 12. Multiple access with SCMA.
Figure 13. Six users sharing on four REs.
Figure 14. Elements of complex spreading sequence.
Figure 15. NOCA transmitter structure.
Figure 16. Example of transceiver structure of uplink NCMA.
Figure 17. Direct full-frequency spreading with multiple codes at the UE transmitter, assuming that OFDM waveform is used.
| [1] | IMT Vision -Framework and Overall Objectives of the Future Development of IMT for 2020 and Beyond, ITU-R M .2083-0, Sept. 2015. |
| [2] | NTT DOCOMO , “New SID proposal: study on new radio access technology,” RP-160671, 3GPP TSG RAN Meeting #71, Göteborg, Sweden, Mar. 2016. |
| [3] | IMT-2020 (5G) Promotion Group, “White paper on 5G vision and requirements,” May 2014. |
| [4] | METIS, “Components of a new air interface-building blocks and performance,” ICT-317669-METIS/D2.3, Apr. 2014. |
| [5] | IMT-2020 (5G) Promotion Group , “White paper on 5G wireless technology architecture,” May 2015. |
| [6] | T. M. Cover and J. A. Thomas , Elements of Information Theory, 2nd ed. Hoboken, USA: Wiley, 2006. |
| [7] | Q. Bi, L. Liang, S. Yang, P. Chen , “Non-orthogonal multiple access technology for 5G systems,” Telecommunication Science, vol. 31, no. 5, article ID 2015137, May 2015. |
| [8] | ETSI, “Final report of 3GPP TSG RAN1 #84bis v1.0.0,” R1-165448, 3GPP TSG RAN WG1 Meeting #84bis, Busan, Korea, Apr. 2016. |
| [9] | ETSI, “Final report of 3GPP TSG RAN1 #86 v1.0.0,” R1-1608562, 3GPP TSG RAN WG1 Meeting #86, Gothenburg, Sweden, Aug. 2016. |
| [10] | NTT DOCOMO , “Initial views and evaluation results on non-orthogonal multiple access for NR,” R1-165175, 3GPP TSG RAN WG1 Meeting #85, Nanjing, China, May 2016. |
| [11] | Qualcomm, “RSMA,” R1-164688, 3GPP TSG RAN WG1 Meeting #85, Nanjing, China, May 2016. |
| [12] | ETRI, “Low code rate and signature based multiple access scheme for New Radio,” R1-164869, 3GPP TSG RAN WG1 Meeting #85, Nanjing, China, May 2016. |
| [13] | Nokia, Alcatel-Lucent Shanghai Bell, “Performance of Interleave Division Multiple Access (IDMA) in combination with OFDM family waveforms,” R1-165021, 3GPP TSG RAN WG1 Meeting #85, Nanjing, China, May 2016. |
| [14] | Samsung, “Non-orthogonal multiple access candidate for NR,” R1-163992, 3GPP TSG RAN WG1 Meeting #85, Nanjing, China, May 2016. |
| [15] | Huawei and HiSilicon, “LLS results for uplink multiple access,” R1-164037, 3GPP TSG RAN WG1 Meeting #85, Nanjing, China, May 2016. |
| [16] | CATT, “Candidate solution for new multiple access,” R1-163383, 3GPP TSG RAN WG1 Meeting #84bis, Busan, Korea, Apr. 2016. |
| [17] | Fujitsu, “Initial LLS results for UL non-orthogonal multiple access,” R1-164329, 3GPP TSG RAN WG1 Meeting #85, Nanjing, China, May 2016. |
| [18] | ZTE, “Contention-based non-orthogonal multiple access for UL mMTC,” R1-164269, 3GPP TSG RAN WG1 Meeting #85, Nanjing, China, May 2016. |
| [19] | Nokia and Alcatel-Lucent Shanghai Bell, “Non-orthogonal multiple access for new radio,” R1-165019, 3GPP TSG RAN WG1 Meeting #85, Nanjing, China, May 2016. |
| [20] | LG Electronics , “Considerations on DL/UL multiple access for NR,” R1-162517, 3GPP TSG RAN WG1 Meeting #84bis, Busan, Korea, Apr. 2016. |
| [21] | Intel Corporation , “Multiple access schemes for new radio interface,” R1-162385, 3GPP TSG RAN WG1 Meeting #84bis, Busan, Korea, Apr. 2016. |
| [22] | L. Ping, L. Liu, K. Wu, W.K. Leung , “Interleave-division multiple-access,” IEEE Transactions on Wireless Communications, vol. 5, no. 4, pp. 938-947, Apr. 2006. doi: 10.1109/TWC.2006.1618943. |
| [23] | H. Nikopour, H. Baligh , “Sparse code multiple access,” in IEEE 24th International Symposium on Personal Indoor and Mobile Radio Communications (PIMRC), London, UK, 2013. doi: 10.1109/PIMRC.2013.6666156. |
| [24] | M. Taherzadeh, H. Nikopour, A. Bayesteh, H. Baligh , “SCMA codebook design,” in IEEE 80th Vehicular Technology Conference (VTC Fall), Vancouver, Canada, 2014. doi: 10.1109/VTCFall.2014.6966170. |
| [25] | Huawei and HiSilicon, “Applying multi-dimensional modulation to non-orthogonal multiple access,” R1-162163, RAN1#84bis, Busan, South Korea, Apr. 2016. |
| [26] | Evolved Universal Terrestrial Radio Access (E-UTRA) : Physical Channels And Modulation, 3GPP TS 36.211 V12.2.0 TS 36.211 V12.2.0, Jun. 2014. |
| [27] | A. Medra and T. N. Davidson , “Flexible codebook design for limited feedback systems via sequential smooth optimization on the grassmannian manifold,” IEEE Transactions on Signal Processing, vol. 62, no. 5, pp. 1305-1318, Mar. 2014. doi: 10.1109/TSP.2014.2301137. |
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