Your search keyword '"Cheng, Victor"' showing total 23 results

1. Optimal MIMO Precoding Under a Constraint on the Amplifier Power Consumption

Author

Cheng, Victor, Persson, Daniel, Larsson, Erik G, Cheng, Victor, Persson, Daniel, and Larsson, Erik G

Abstract

The capacity of the MIMO channel taking into account both a limitation on total consumed power, and per-antenna radiated power constraints is considered. The total consumed power takes into account the traditionally used sum radiated power, and also the power dissipation in the amplifiers. For a fixed channel with full CSI at both the transmitter and the receiver, maximization of the mutual information is formulated as an optimization problem. Lower and upper bounds on the capacity are provided by numerical algorithms based on partitioning of the feasible region. Both bounds are shown to converge and give the exact capacity when number of regions increases. The bounds are also used to construct a monotonic optimization algorithm based on the branch-and-bound approach. An efficient suboptimal algorithm based on successive convex approximation performing close to the capacity is also presented. Numerical results show that the performance of the solution obtained from the suboptimal algorithm is close to that of the global optimal solution. Simulation results also show that in the low SNR regime, antenna selection provides performance that is close to the optimal scheme while at high SNR, uniform power allocation performs close to the optimal scheme., Funding Agencies|Swedish Research Council (VR); ELLIIT; CENIIT project "Power Amplifiers and Massive MIMO"

Published

2019

2. Optimal MIMO Precoding Under a Constraint on the Amplifier Power Consumption

Author

Cheng, Victor, Persson, Daniel, Larsson, Erik G, Cheng, Victor, Persson, Daniel, and Larsson, Erik G

Abstract

The capacity of the MIMO channel taking into account both a limitation on total consumed power, and per-antenna radiated power constraints is considered. The total consumed power takes into account the traditionally used sum radiated power, and also the power dissipation in the amplifiers. For a fixed channel with full CSI at both the transmitter and the receiver, maximization of the mutual information is formulated as an optimization problem. Lower and upper bounds on the capacity are provided by numerical algorithms based on partitioning of the feasible region. Both bounds are shown to converge and give the exact capacity when number of regions increases. The bounds are also used to construct a monotonic optimization algorithm based on the branch-and-bound approach. An efficient suboptimal algorithm based on successive convex approximation performing close to the capacity is also presented. Numerical results show that the performance of the solution obtained from the suboptimal algorithm is close to that of the global optimal solution. Simulation results also show that in the low SNR regime, antenna selection provides performance that is close to the optimal scheme while at high SNR, uniform power allocation performs close to the optimal scheme., Funding Agencies|Swedish Research Council (VR); ELLIIT; CENIIT project "Power Amplifiers and Massive MIMO"

Published

2019

3. NOMA Versus Massive MIMO in Rayleigh Fading

Author

Senel, Kamil, Cheng, Victor, Björnson, Emil, Larsson, Erik G, Senel, Kamil, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper compares the sum rates and rate regions achieved by power-domain NOMA (non-orthogonal multiple access) and standard massive MIMO (multiple-input multiple-output) techniques. We prove analytically that massive MIMO always outperforms NOMA in i.i.d. Rayleigh fading channels, if a sufficient number of antennas are used at the base stations. The simulation results show that the crossing point occurs already when having 20-30 antennas, which is far less than what is considered for the next generation cellular networks., Funding Agencies|ELLIIT; Swedish Research Council (VR)Swedish Research Council

Published

2019

4. NOMA Versus Massive MIMO in Rayleigh Fading

Author

Senel, Kamil, Cheng, Victor, Björnson, Emil, Larsson, Erik G, Senel, Kamil, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper compares the sum rates and rate regions achieved by power-domain NOMA (non-orthogonal multiple access) and standard massive MIMO (multiple-input multiple-output) techniques. We prove analytically that massive MIMO always outperforms NOMA in i.i.d. Rayleigh fading channels, if a sufficient number of antennas are used at the base stations. The simulation results show that the crossing point occurs already when having 20-30 antennas, which is far less than what is considered for the next generation cellular networks., Funding Agencies|ELLIIT; Swedish Research Council (VR)Swedish Research Council

Published

2019

5. Optimal MIMO Precoding Under a Constraint on the Amplifier Power Consumption

Author

Cheng, Victor, Persson, Daniel, Larsson, Erik G, Cheng, Victor, Persson, Daniel, and Larsson, Erik G

Abstract

The capacity of the MIMO channel taking into account both a limitation on total consumed power, and per-antenna radiated power constraints is considered. The total consumed power takes into account the traditionally used sum radiated power, and also the power dissipation in the amplifiers. For a fixed channel with full CSI at both the transmitter and the receiver, maximization of the mutual information is formulated as an optimization problem. Lower and upper bounds on the capacity are provided by numerical algorithms based on partitioning of the feasible region. Both bounds are shown to converge and give the exact capacity when number of regions increases. The bounds are also used to construct a monotonic optimization algorithm based on the branch-and-bound approach. An efficient suboptimal algorithm based on successive convex approximation performing close to the capacity is also presented. Numerical results show that the performance of the solution obtained from the suboptimal algorithm is close to that of the global optimal solution. Simulation results also show that in the low SNR regime, antenna selection provides performance that is close to the optimal scheme while at high SNR, uniform power allocation performs close to the optimal scheme., Funding Agencies|Swedish Research Council (VR); ELLIIT; CENIIT project "Power Amplifiers and Massive MIMO"

Published

2019

6. NOMA Versus Massive MIMO in Rayleigh Fading

Author

Senel, Kamil, Cheng, Victor, Björnson, Emil, Larsson, Erik G, Senel, Kamil, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper compares the sum rates and rate regions achieved by power-domain NOMA (non-orthogonal multiple access) and standard massive MIMO (multiple-input multiple-output) techniques. We prove analytically that massive MIMO always outperforms NOMA in i.i.d. Rayleigh fading channels, if a sufficient number of antennas are used at the base stations. The simulation results show that the crossing point occurs already when having 20-30 antennas, which is far less than what is considered for the next generation cellular networks., Funding Agencies|ELLIIT; Swedish Research Council (VR)Swedish Research Council

Published

2019

7. NOMA Versus Massive MIMO in Rayleigh Fading

Author

Senel, Kamil, Cheng, Victor, Björnson, Emil, Larsson, Erik G, Senel, Kamil, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper compares the sum rates and rate regions achieved by power-domain NOMA (non-orthogonal multiple access) and standard massive MIMO (multiple-input multiple-output) techniques. We prove analytically that massive MIMO always outperforms NOMA in i.i.d. Rayleigh fading channels, if a sufficient number of antennas are used at the base stations. The simulation results show that the crossing point occurs already when having 20-30 antennas, which is far less than what is considered for the next generation cellular networks., Funding Agencies|ELLIIT; Swedish Research Council (VR)Swedish Research Council

Published

2019

8. Optimal MIMO Precoding Under a Constraint on the Amplifier Power Consumption

Author

Cheng, Victor, Persson, Daniel, Larsson, Erik G, Cheng, Victor, Persson, Daniel, and Larsson, Erik G

Abstract

The capacity of the MIMO channel taking into account both a limitation on total consumed power, and per-antenna radiated power constraints is considered. The total consumed power takes into account the traditionally used sum radiated power, and also the power dissipation in the amplifiers. For a fixed channel with full CSI at both the transmitter and the receiver, maximization of the mutual information is formulated as an optimization problem. Lower and upper bounds on the capacity are provided by numerical algorithms based on partitioning of the feasible region. Both bounds are shown to converge and give the exact capacity when number of regions increases. The bounds are also used to construct a monotonic optimization algorithm based on the branch-and-bound approach. An efficient suboptimal algorithm based on successive convex approximation performing close to the capacity is also presented. Numerical results show that the performance of the solution obtained from the suboptimal algorithm is close to that of the global optimal solution. Simulation results also show that in the low SNR regime, antenna selection provides performance that is close to the optimal scheme while at high SNR, uniform power allocation performs close to the optimal scheme., Funding Agencies|Swedish Research Council (VR); ELLIIT; CENIIT project "Power Amplifiers and Massive MIMO"

Published

2019

9. NOMA Versus Massive MIMO in Rayleigh Fading

Author

Senel, Kamil, Cheng, Victor, Björnson, Emil, Larsson, Erik G, Senel, Kamil, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper compares the sum rates and rate regions achieved by power-domain NOMA (non-orthogonal multiple access) and standard massive MIMO (multiple-input multiple-output) techniques. We prove analytically that massive MIMO always outperforms NOMA in i.i.d. Rayleigh fading channels, if a sufficient number of antennas are used at the base stations. The simulation results show that the crossing point occurs already when having 20-30 antennas, which is far less than what is considered for the next generation cellular networks., Funding Agencies|ELLIIT; Swedish Research Council (VR)Swedish Research Council

Published

2019

10. What Role can NOMA Play in Massive MIMO?

Author

Senel, Kamil, Cheng, Victor, Björnson, Emil, Larsson, Erik G, Senel, Kamil, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper seeks to answer a simple but fundamental question: what role can non-orthogonal multiple access (NOMA) play in massive multi-in multi-out (MIMO)? It is well established that power-domain NOMA schemes can outperform conventional orthogonal multiple access schemes in cellular networks. However, this fact does not imply that NOMA is the most efficient way to communicate in massive MIMO setups, where the base stations have many more antennas than there are users in the cell. These setups are becoming the norm in future networks and are usually studied by assuming spatial multiplexing of the users using linear multi-user beamforming. To answer the above-mentioned question, we analyze and compare the performance achieved by NOMA and multi-user beamforming in both non-line-of-sight and line-of-sight scenarios. We reveal that the latter scheme gives the highestaverage sum rate in massive MIMO setups. We also identify specific cases where NOMA is the better choice in massive MIMO and explain how NOMA plays an essential role in creating a hybrid of NOMA and multi-user beamforming that is shown to perform better than two standalone schemes do., Funding Agencies|ELLIIT; Swedish Research Council (VR)

Published

2019

11. Optimal Hybrid Beamforming for Multiuser Massive MIMO Systems With Individual SINR Constraints

Author

Zang, Guangda, Cui, Ying, Cheng, Victor, Yang, Feng, Ding, Lianghui, Liu, Hui, Zang, Guangda, Cui, Ying, Cheng, Victor, Yang, Feng, Ding, Lianghui, and Liu, Hui

Abstract

In this letter, we consider optimal hybrid beamforming design to minimize the transmission power under individual signal-to-interference-plus-noise ratio (SINR) constraints in a multiuser massive multiple-input-multiple-output (MIMO) system. This results in a challenging non-convex optimization problem. We consider two cases. In the case where the number of users is smaller than or equal to that of radio frequency (RF) chains, we propose a low-complexity method to obtain a globally optimal solution and show that it achieves the same transmission power as an optimal fully-digital beamformer. In the case where the number of users is larger than that of RF chains, we propose a low-complexity globally convergent alternating algorithm to obtain a stationary point., Funding Agencies|National Natural Science Foundation of China [61401272, 61771309, 61671301, 61420106008, 61521062]; Shanghai Key Laboratory Funding [STCSM15DZ2270400]; CETC Key Laboratory of Data Link Technology Foundation [CLDL-20162306]; Medical Engineering Cross Research Foundation of Shanghai Jiao Tong University [YG2017QN47]

Published

2019

12. Optimal MIMO Precoding Under a Constraint on the Amplifier Power Consumption

Author

Cheng, Victor, Persson, Daniel, Larsson, Erik G, Cheng, Victor, Persson, Daniel, and Larsson, Erik G

Abstract

The capacity of the MIMO channel taking into account both a limitation on total consumed power, and per-antenna radiated power constraints is considered. The total consumed power takes into account the traditionally used sum radiated power, and also the power dissipation in the amplifiers. For a fixed channel with full CSI at both the transmitter and the receiver, maximization of the mutual information is formulated as an optimization problem. Lower and upper bounds on the capacity are provided by numerical algorithms based on partitioning of the feasible region. Both bounds are shown to converge and give the exact capacity when number of regions increases. The bounds are also used to construct a monotonic optimization algorithm based on the branch-and-bound approach. An efficient suboptimal algorithm based on successive convex approximation performing close to the capacity is also presented. Numerical results show that the performance of the solution obtained from the suboptimal algorithm is close to that of the global optimal solution. Simulation results also show that in the low SNR regime, antenna selection provides performance that is close to the optimal scheme while at high SNR, uniform power allocation performs close to the optimal scheme., Funding Agencies|Swedish Research Council (VR); ELLIIT; CENIIT project "Power Amplifiers and Massive MIMO"

Published

2019

13. Performance Analysis of NOMA in Training-Based Multiuser MIMO Systems

Author

Cheng, Victor, Björnson, Emil, Larsson, Erik G, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper considers the use of non-orthogonal-multiple-access (NOMA) in multiuser MIMO systems in practical scenarios where channel state information (CSI) is acquired through pilot signaling. A new NOMA scheme that uses shared pilots is proposed. Achievable rate analysis is carried out for different pilot signaling schemes, including both uplink and downlink pilots. The achievable rate performance of the proposed NOMA scheme with shared pilot within each group is compared with the traditional orthogonal access scheme with orthogonal pilots. Our proposed scheme is a generalization of the orthogonal scheme, and can be reduced to the orthogonal scheme when appropriate power allocation parameters are chosen. Numerical results show that when downlink CSI is available at the users, our proposed NOMA scheme outperforms orthogonal schemes. However with more groups of users present in the cell, it is preferable to use multi-user beamforming instead of NOMA., Funding Agencies|Swedish Research Council; Linkoping University Center for Industrial Information Technology; ELLIIT

Published

2018

14. Optimal Pilot and Payload Power Control in Single-Cell Massive MIMO Systems

Author

Cheng, Victor, Björnson, Emil, Larsson, Erik G, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper considers the jointly optimal pilot and data power allocation in single-cell uplink massive multiple-input-multiple- output systems. Using the spectral efficiency (SE) as performance metric and setting a total energy budget per coherence interval, the power control is formulated as optimization problems for two different objective functions: the weighted minimum SE among the users and the weighted sum SE. A closed form solution for the optimal length of the pilot sequence is derived. The optimal power control policy for the former problem is found by solving a simple equation with a single variable. Utilizing the special structure arising from imperfect channel estimation, a convex reformulation is found to solve the latter problem to global optimality in polynomial time. The gain of the optimal joint power control is theoretically justified, and is proved to be large in the low-SNR regime. Simulation results also show the advantage of optimizing the power control over both pilot and data power, as compared to the cases of using full power and of only optimizing the data powers as done in previous work., Funding Agencies|EU [ICT-619086]; ELLIIT; CENIIT

Published

2017

15. Optimal Pilot and Payload Power Control in Single-Cell Massive MIMO Systems

Author

Cheng, Victor, Björnson, Emil, Larsson, Erik G, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper considers the jointly optimal pilot and data power allocation in single-cell uplink massive multiple-input-multiple- output systems. Using the spectral efficiency (SE) as performance metric and setting a total energy budget per coherence interval, the power control is formulated as optimization problems for two different objective functions: the weighted minimum SE among the users and the weighted sum SE. A closed form solution for the optimal length of the pilot sequence is derived. The optimal power control policy for the former problem is found by solving a simple equation with a single variable. Utilizing the special structure arising from imperfect channel estimation, a convex reformulation is found to solve the latter problem to global optimality in polynomial time. The gain of the optimal joint power control is theoretically justified, and is proved to be large in the low-SNR regime. Simulation results also show the advantage of optimizing the power control over both pilot and data power, as compared to the cases of using full power and of only optimizing the data powers as done in previous work., Funding Agencies|EU [ICT-619086]; ELLIIT; CENIIT

Published

2017

16. NOMA in Multiuser MIMO Systems with Imperfect CSI

Author

Cheng, Victor, Björnson, Emil, Larsson, Erik G, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper considers the use of NOMA in multiuser MIMO systems in practical scenarios where CSI is acquired through pilot signaling. A new NOMA scheme that uses shared pilots is proposed. Achievable rate analysis is carried out for a pilot signaling scheme including both uplink and downlink pilots. The achievable rate of the proposed NOMA scheme with shared pilots in each NOMA group is compared with the traditional orthogonal access scheme with orthogonal pilots. Numerical results show that when estimated downlink CSI is available at the users, our proposed NOMA scheme outperforms orthogonal schemes. With increasing number of antennas at the base station, the gain from our proposed NOMA scheme is also increasing. This shows that there is a benefit of applying the proposed NOMA scheme in massive MIMO systems., Funding Agencies|Swedish Research Council (VR); Linkoping University Center for Industrial Information Technology (CENIIT); ELLIIT

Published

2017

17. NOMA in Multiuser MIMO Systems with Imperfect CSI

Author

Cheng, Victor, Björnson, Emil, Larsson, Erik G, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper considers the use of NOMA in multiuser MIMO systems in practical scenarios where CSI is acquired through pilot signaling. A new NOMA scheme that uses shared pilots is proposed. Achievable rate analysis is carried out for a pilot signaling scheme including both uplink and downlink pilots. The achievable rate of the proposed NOMA scheme with shared pilots in each NOMA group is compared with the traditional orthogonal access scheme with orthogonal pilots. Numerical results show that when estimated downlink CSI is available at the users, our proposed NOMA scheme outperforms orthogonal schemes. With increasing number of antennas at the base station, the gain from our proposed NOMA scheme is also increasing. This shows that there is a benefit of applying the proposed NOMA scheme in massive MIMO systems., Funding Agencies|Swedish Research Council (VR); Linkoping University Center for Industrial Information Technology (CENIIT); ELLIIT

Published

2017

18. Optimal Pilot and Payload Power Control in Single-Cell Massive MIMO Systems

Author

Cheng, Victor, Björnson, Emil, Larsson, Erik G, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper considers the jointly optimal pilot and data power allocation in single-cell uplink massive multiple-input-multiple- output systems. Using the spectral efficiency (SE) as performance metric and setting a total energy budget per coherence interval, the power control is formulated as optimization problems for two different objective functions: the weighted minimum SE among the users and the weighted sum SE. A closed form solution for the optimal length of the pilot sequence is derived. The optimal power control policy for the former problem is found by solving a simple equation with a single variable. Utilizing the special structure arising from imperfect channel estimation, a convex reformulation is found to solve the latter problem to global optimality in polynomial time. The gain of the optimal joint power control is theoretically justified, and is proved to be large in the low-SNR regime. Simulation results also show the advantage of optimizing the power control over both pilot and data power, as compared to the cases of using full power and of only optimizing the data powers as done in previous work., Funding Agencies|EU [ICT-619086]; ELLIIT; CENIIT

Published

2017

19. NOMA in Multiuser MIMO Systems with Imperfect CSI

Author

Cheng, Victor, Björnson, Emil, Larsson, Erik G, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper considers the use of NOMA in multiuser MIMO systems in practical scenarios where CSI is acquired through pilot signaling. A new NOMA scheme that uses shared pilots is proposed. Achievable rate analysis is carried out for a pilot signaling scheme including both uplink and downlink pilots. The achievable rate of the proposed NOMA scheme with shared pilots in each NOMA group is compared with the traditional orthogonal access scheme with orthogonal pilots. Numerical results show that when estimated downlink CSI is available at the users, our proposed NOMA scheme outperforms orthogonal schemes. With increasing number of antennas at the base station, the gain from our proposed NOMA scheme is also increasing. This shows that there is a benefit of applying the proposed NOMA scheme in massive MIMO systems., Funding Agencies|Swedish Research Council (VR); Linkoping University Center for Industrial Information Technology (CENIIT); ELLIIT

Published

2017

20. NOMA in Multiuser MIMO Systems with Imperfect CSI

Author

Cheng, Victor, Björnson, Emil, Larsson, Erik G, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper considers the use of NOMA in multiuser MIMO systems in practical scenarios where CSI is acquired through pilot signaling. A new NOMA scheme that uses shared pilots is proposed. Achievable rate analysis is carried out for a pilot signaling scheme including both uplink and downlink pilots. The achievable rate of the proposed NOMA scheme with shared pilots in each NOMA group is compared with the traditional orthogonal access scheme with orthogonal pilots. Numerical results show that when estimated downlink CSI is available at the users, our proposed NOMA scheme outperforms orthogonal schemes. With increasing number of antennas at the base station, the gain from our proposed NOMA scheme is also increasing. This shows that there is a benefit of applying the proposed NOMA scheme in massive MIMO systems., Funding Agencies|Swedish Research Council (VR); Linkoping University Center for Industrial Information Technology (CENIIT); ELLIIT

Published

2017

21. Optimal Pilot and Payload Power Control in Single-Cell Massive MIMO Systems

Author

Cheng, Victor, Björnson, Emil, Larsson, Erik G, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper considers the jointly optimal pilot and data power allocation in single-cell uplink massive multiple-input-multiple- output systems. Using the spectral efficiency (SE) as performance metric and setting a total energy budget per coherence interval, the power control is formulated as optimization problems for two different objective functions: the weighted minimum SE among the users and the weighted sum SE. A closed form solution for the optimal length of the pilot sequence is derived. The optimal power control policy for the former problem is found by solving a simple equation with a single variable. Utilizing the special structure arising from imperfect channel estimation, a convex reformulation is found to solve the latter problem to global optimality in polynomial time. The gain of the optimal joint power control is theoretically justified, and is proved to be large in the low-SNR regime. Simulation results also show the advantage of optimizing the power control over both pilot and data power, as compared to the cases of using full power and of only optimizing the data powers as done in previous work., Funding Agencies|EU [ICT-619086]; ELLIIT; CENIIT

Published

2017

22. NOMA in Multiuser MIMO Systems with Imperfect CSI

Author

Cheng, Victor, Björnson, Emil, Larsson, Erik G, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper considers the use of NOMA in multiuser MIMO systems in practical scenarios where CSI is acquired through pilot signaling. A new NOMA scheme that uses shared pilots is proposed. Achievable rate analysis is carried out for a pilot signaling scheme including both uplink and downlink pilots. The achievable rate of the proposed NOMA scheme with shared pilots in each NOMA group is compared with the traditional orthogonal access scheme with orthogonal pilots. Numerical results show that when estimated downlink CSI is available at the users, our proposed NOMA scheme outperforms orthogonal schemes. With increasing number of antennas at the base station, the gain from our proposed NOMA scheme is also increasing. This shows that there is a benefit of applying the proposed NOMA scheme in massive MIMO systems., Funding Agencies|Swedish Research Council (VR); Linkoping University Center for Industrial Information Technology (CENIIT); ELLIIT

Published

2017

23. Optimal Pilot and Payload Power Control in Single-Cell Massive MIMO Systems

Author

Cheng, Victor, Björnson, Emil, Larsson, Erik G, Cheng, Victor, Björnson, Emil, and Larsson, Erik G

Abstract

This paper considers the jointly optimal pilot and data power allocation in single-cell uplink massive multiple-input-multiple- output systems. Using the spectral efficiency (SE) as performance metric and setting a total energy budget per coherence interval, the power control is formulated as optimization problems for two different objective functions: the weighted minimum SE among the users and the weighted sum SE. A closed form solution for the optimal length of the pilot sequence is derived. The optimal power control policy for the former problem is found by solving a simple equation with a single variable. Utilizing the special structure arising from imperfect channel estimation, a convex reformulation is found to solve the latter problem to global optimality in polynomial time. The gain of the optimal joint power control is theoretically justified, and is proved to be large in the low-SNR regime. Simulation results also show the advantage of optimizing the power control over both pilot and data power, as compared to the cases of using full power and of only optimizing the data powers as done in previous work., Funding Agencies|EU [ICT-619086]; ELLIIT; CENIIT

Published

2017