Auxiliary Beam Pair Enabled AoD Estimation for Large-scale mmwave MIMO Systems

Similar documents
Compressed-Sensing Based Multi-User Millimeter Wave Systems: How Many Measurements Are Needed?

PROGRESSIVE CHANNEL ESTIMATION FOR ULTRA LOW LATENCY MILLIMETER WAVE COMMUNICATIONS

Estimating Millimeter Wave Channels Using Out-of-Band Measurements

Next Generation Mobile Communication. Michael Liao

Millimeter Wave Wireless Communications Workshop #1: 5G Cellular Communications

Millimeter-Wave Communication and Mobile Relaying in 5G Cellular Networks

Reconfigurable Hybrid Beamforming Architecture for Millimeter Wave Radio: A Tradeoff between MIMO Diversity and Beamforming Directivity

WHITE PAPER. Hybrid Beamforming for Massive MIMO Phased Array Systems

Beamforming for 4.9G/5G Networks

On the Security of Millimeter Wave Vehicular Communication Systems using Random Antenna Subsets

Millimeter Wave MIMO Precoding/Combining: Challenges and Potential Solutions

Wideband Channel Tracking for mmwave MIMO System with Hybrid Beamforming Architecture

5G, WLAN, and LTE Wireless Design with MATLAB

Performance Analysis of Beam Sweeping in Millimeter Wave Assuming Noise and Imperfect Antenna Patterns

Vehicle-to-X communication for 5G - a killer application of millimeter wave

NR Physical Layer Design: NR MIMO

A Practical Channel Estimation Scheme for Indoor 60GHz Massive MIMO System. Arumugam Nallanathan King s College London

Low-Complexity Beam Allocation for Switched-Beam Based Multiuser Massive MIMO Systems

5G System Concept Seminar. RF towards 5G. Researchers: Tommi Tuovinen, Nuutti Tervo & Aarno Pärssinen

What is the Role of MIMO in Future Cellular Networks: Massive? Coordinated? mmwave?

mm Wave Communications J Klutto Milleth CEWiT

Millimeter wave communication: From Origins to Disruptive Applications

Multiple Antenna Processing for WiMAX

2015 The MathWorks, Inc. 1

Vehicle-to-X communication using millimeter waves (just in time for 5G)

Discussion Points for HW-CSP Breakout Session. July 19, 2017 Jeyanandh Paramesh, Subhanshu Gupta, Greg LaCaille, Vishal Saxena, Sarah Yost

Full-Duplex Millimeter-Wave Communication. Zhenyu Xiao, Pengfei Xia, Xiang-Gen Xia. Abstract

An adaptive channel estimation algorithm for millimeter wave cellular systems

Millimeter Wave Cellular Channel Models for System Evaluation

5G Positioning for connected cars

Analysis of massive MIMO networks using stochastic geometry

Millimeter Wave: the future of commercial wireless systems

ADC Bit Optimization for Spectrum- and Energy-Efficient Millimeter Wave Communications

MIllimeter-wave (mmwave) ( GHz) multipleinput

What s Behind 5G Wireless Communications?

Hybrid Beamforming Based mmwave for Future Generation Communication

High-Resolution Angle Tracking for Mobile Wideband Millimeter-Wave Systems with Antenna Array Calibration

Millimeter Wave communication with out-of-band information

Vehicle-to-X communication using millimeter waves

Modeling and Simulating Large Phased Array Systems

2015 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media,

Hybrid Transceivers for Massive MIMO - Some Recent Results

Ten Things You Should Know About MIMO

MIMO Systems and Applications

Principles of Millimeter Wave Communications for V2X

Millimeter Wave MIMO Communication

Index Modulation with PAPR and Beamforming for 5G MIMO-OFDM

Multi-Aperture Phased Arrays Versus Multi-beam Lens Arrays for Millimeter-Wave Multiuser MIMO

Millimeter Wave MIMO Channel Estimation Based on Adaptive Compressed Sensing

Wideband Channel Estimation for Hybrid Beamforming Millimeter Wave Communication Systems with Low-Resolution ADCs

A Complete MIMO System Built on a Single RF Communication Ends

Claudio Fiandrino, IMDEA Networks, Madrid, Spain

Energy Harvested and Achievable Rate of Massive MIMO under Channel Reciprocity Error

at 1 The simulation codes are provided to reproduce the results in this paper

FEASIBILITY STUDY ON FULL-DUPLEX WIRELESS MILLIMETER-WAVE SYSTEMS. University of California, Irvine, CA Samsung Research America, Dallas, TX

5G: Opportunities and Challenges Kate C.-J. Lin Academia Sinica

Muhammad Nazmul Islam, Senior Engineer Qualcomm Technologies, Inc. December 2015

Application Note. StarMIMO. RX Diversity and MIMO OTA Test Range

Massive MIMO for the New Radio Overview and Performance

What s Behind 5G Wireless Communications?

Implications of Millimeter Wave for 5G System Design

IEEE Broadband Wireless Access Working Group < Per Stream Power Control in CQICH Enhanced Allocation IE

Low RF-Complexity Technologies for 5G Millimeter-Wave MIMO Systems with Large Antenna Arrays

Low Complexity Energy Efficiency Analysis in Millimeter Wave Communication Systems

Beyond 4G: Millimeter Wave Picocellular Wireless Networks

5G Antenna Design & Network Planning

On the Value of Coherent and Coordinated Multi-point Transmission

Context Information Based Initial Cell Search for Millimeter Wave 5G Cellular Networks

Bit Allocation for Increased Power Efficiency in 5G Receivers with Variable-Resolution ADCs

Coverage and Capacity Analysis of mmwave Cellular Systems

Channel Estimation for Hybrid Architecture Based Wideband Millimeter Wave Systems

Energy Efficient Hybrid Beamforming in Massive MU-MIMO Systems via Eigenmode Selection

Hierarchical Codebook Design for Beamforming Training in Millimeter-Wave Communication

Multiple Antennas. Mats Bengtsson, Björn Ottersten. Basic Transmission Schemes 1 September 8, Presentation Outline

Analysis and Improvements of Linear Multi-user user MIMO Precoding Techniques

Challenges of 5G mmwave RF Module. Ren-Jr Chen M300/ICL/ITRI 2018/06/20

Hybrid MMSE Precoding for mmwave Multiuser MIMO Systems

Experimental mmwave 5G Cellular System

Space-Time Block Coded Spatial Modulation Aided mmwave MIMO with Hybrid Precoding

Full-duplex Wireless: From Experiments to Theory

UNEQUAL POWER ALLOCATION FOR JPEG TRANSMISSION OVER MIMO SYSTEMS. Muhammad F. Sabir, Robert W. Heath Jr. and Alan C. Bovik

Dictionary-free Hybrid Precoders and Combiners for mmwave MIMO Systems

Design of Analog and Digital Beamformer for 60GHz MIMO Frequency Selective Channel through Second Order Cone Programming

MU-MIMO with Fixed Beamforming for

LTE Transmission Modes and Beamforming White Paper

Massive MIMO a overview. Chandrasekaran CEWiT

University of Bristol - Explore Bristol Research. Peer reviewed version. Link to published version (if available): /MC-SS.2011.

Potential Throughput Improvement of FD MIMO in Practical Systems

Vehicular mmwave Communication: Opportunities and Challenges

3G Evolution. Outline. Chapter: Multi-antenna configurations. Introduction. Introduction. Multi-antenna techniques. Multiple receiver antennas, SIMO

Channel Measurements for Evaluating Massive MIMO Precoding

Channel Modelling ETIN10. Directional channel models and Channel sounding

Channel Capacity Estimation in MIMO Systems Based on Water-Filling Algorithm

Technical challenges for high-frequency wireless communication

Impact of mm-wave Range and Large Bandwidth on RF System Design. R&S Taiwan Feiyu Chen

Merging Propagation Physics, Theory and Hardware in Wireless. Ada Poon

University of Bristol - Explore Bristol Research. Peer reviewed version. Link to published version (if available): /ICCE.2012.

Codeword Selection and Hybrid Precoding for Multiuser Millimeter Wave Massive MIMO Systems

Interference in Finite-Sized Highly Dense Millimeter Wave Networks

5G India Demystifying 5G, Massive MIMO and Challenges

Transcription:

Auxiliary Beam Pair Enabled AoD Estimation for Large-scale mmwave MIMO Systems Dalin Zhu, Junil Choi and Robert W. Heath Jr. Wireless Networking and Communications Group Department of Electrical and Computer Engineering The University of Texas at Austin This work is funded by a research gift from Huawei Technologies, Inc. www.profheath.org

Hybrid precoding in mmwave MIMO DAC 1-bit ADC RF Chain RF Chain 1-bit ADC ADC Baseband Precoding RF Precoding RF Combining Baseband Combining F BB F RF channel RF W RF W BB 1-bit DAC ADC RF Chain Chain 1-bit ADC ADC Effective channel at baseband A combination of digital and analog beamforming/combining Most prior work assumes a channel estimate is available for configuration 2

Prior work on channel estimation in mmwave MIMO u Compressed sensing based approaches * ª Assumes sparsity in the angular domain of the channel ª Requires a prior knowledge of the number of the propagation paths u Subspace based methods ** ª Echo-based subspace estimation between the transmitter and receiver ª Requires a lot of training between the transmitter and receiver u Exhaustive search based approaches *** ª Searches for the best pairs of analog transmit and receive steering vectors ª Training overhead is high Feasible channel estimation method is required Low training and feedback overhead High-resolution estimate of channel information Contributions: Path-based channel estimator based on auxilary beam pairs (ABPs) * A. Alkhateeb, O. E. Ayach, G. Leus, and R. W. Heath Jr., ``Channel estimation and hybrid precoding for millimeter wave cellular systems,'' in IEEE J. Sel. Top. Signal Process, vol. 8, pp. 831-846, Oct. 2014 ** H. Ghauch, T. Kim, M. Bengtsson, and M. Skoglund, `` Subspace estimation and decomposition for large millimeter-wave MIMO systems,'' submitted to IEEE J. Sel. Top. Signal Process., arxiv preprint arxiv:1507.00287, Jul. 2015 *** C. Kim, T. Kim, and J.-Y. Seol, `` Muti-beam transmission diversity with hybrid beamforming for MIMO-OFDM systems,'' in IEEE Global Telecomm. Conf. (GLOBECOM 13), pp. 61-65, Dec. 2013. 3

Exhuastive search via grid of beams True AoD Each beam is probed Quantization error Quantized AoD Receiver determines which beams have the strongest signals Index of preferred beams are sent to the transmitter Transmitter Receiver The resolution for AoD angle is limited by grid size 4

Angle estimation in monopulse radar systems Projections of on and Echo signal Custom designed analog receive beams Beams distinguished by sending with different polarization, code, or time Receive beam pair Angle estimation Amplitude comparison Signal detection S. M. Sherman, ``Monopulse principles and techniques,'' Artech House, 1984 5

Basic design principle of auxiliary beam pairs (1/2) Pairs of analog transmit beams are formed to cover a given angular range Exact AoD can be extracted from the ABP that covers the AoD...... System setup : boresight angle of n-th ABP : steering angle of : steering angle of scatter : dominant path s AoD : n-th ABP Transmit array response vector: Auxiliary beam pair that covers the AoD: 6

Basic design principle of auxiliary beam pairs (2/2)...... Quantized version of Amplitude comparison Calculate received signal strengths Angle estimation If is invertible with respect to 7

Quantization options Distribution of the ratio metric Distribution of the estimated AoD More codewords can be allocated in densely distributed portions Uniformly distributed codewords Quantizing the ratio metric provides more quantization resolution 8

Procedure for estimating the AoD using ABP Auxiliary beam pairs are probed A set of ratio metrics are calculated, each corresponds to a ABP The ratio metric with the highest received signal strength is quantized Transmitter Receiver The AoD is estimated using the quantized ratio metric 9

Deployment scenarios using ABP-based method (1/3) Beamforming range for the next layer is optimized using the estimated AoD Beam finding for control channels UE UE UE UE UE UE Base station Base station Base station Layer-1: system-specific information Layer-2: cell-specific information Layer-3: user-specific information Beam finding process for control channels is facilitated via ABP design 10

Deployment scenarios using ABP-based method (2/3) An example of control channels beamforming using ABP Beam finding for control channels Layer-I beam-b The UE decodes system-specific control information from beam-a 1 UE Base station beam-a UE The UE calculates a ratio metric with respect to the ABP formed by beam-a and beam-b Base station The UE quantizes the ratio metric and sends it back to the base station 2 3 4 beam-b beam-a UE UE UE Base station Using the quantized ratio metric, the base station estimates the AoD Base station The probing range for layer-ii beamforming is determined around the estimated AoD Base station Layer-II 11

Deployment scenarios using ABP-based method (3/3) Hybrid precoding for data channels PA... Baseband Precoder DAC... DAC Mixers Phase shifters Antenna array... Antenna array Multi-path s AoDs/AoAs can be estimated via ABP Phase shifters... Mixers ADC... ADC Baseband Combiner... Analog and digital precoder and combiner are optimized using the high resolution estimates of AoDs/AoAs via ABP design 12

Numerical results (1/2) MSE of AoD estimation ª ª Channel assumption AoDs/AoAs take continuous values AoDs/AoAs are uniformly distributed Parameters : total # of transmit antennas : total # of receive antennas : total # of transmit RF chains : total # of receive RF chains : total # of data streams : total # of channel paths (6) Performance metric: MSE of AoD estimation In radians With increase in the number of antennas, more and narrower auxiliary beams are probed, which improves the estimation performance Promising MSE performance of AoD estimation can be obtained 13

Numerical results (2/2) Spectral efficiency performance ª ª Channel assumption AoDs/AoAs take continuous values AoDs/AoAs are uniformly distributed Parameters : total # of transmit antennas : total # of receive antennas : total # of transmit RF chains : total # of receive RF chains : total # of data streams : total # of channel paths (6) Multi-path s AoDs/AoAs estimation performance via ABP design is promising Assume, the performance gap is marginal 14

Conclusions u High-resolution AoD/AoA estimation method via ABP is possible ª Suited for mmwave MIMO with directional beamforming ª Quantizing the ratio metric results in better performance ª Applicable to beamformed control channels and data channels design in practice u Future work ª ABP-based AoD/AoA estimation assuming arbitrary antenna array geometry ª Exploiting TDD channel s reciprocity to enable mmwave MIMO precoding ª Simultaneously employing multiple RF chains to facilitate the estimation 15

Questions? 16

Backup Slides 17

System model for hybrid precoding baseband combiner, baseband precoder, transmit signal vector, Complex Gaussian noise vector analog precoder: similarly defined to analog combiner Steering angle Analog precoder and combiners are simple spatial matched filters 18

Spatial channel model Total number of propagation paths channel matrix Path-r s gain AoD (spatial frequency) to be estimated Assuming ULA AoA (spatial frequency) to be estimated 19

Detailed derivations of ABP design principle u Received signal with respect to each beam in the ABP (noiseless) u Received signal strength with respect to each beam in the ABP u A ratio metric via the difference and sum of and If is invertible with respect to 20

Performance evaluation of quantization options MSE of quantizing the estimated AoD: MSE of quantizing the ratio metric: In radians The performance gap between two quantization options is marginal The receiver requires knowledge of ABP parameters from the transmitter to estimate and quantize the AoD 21

Estimation of multiple angles using multiple RF chains (1/2) An example of multiple AoDs estimation Beam finding for control channels u Multiple analog beams can be simultaneously probed by the TX and RX Total number of transmit probings Total number of receive probings u Consider noiseless reception and a given receive probing, u Assume that path-r s AoD, and Desired transmit ABP that covers path-r s AoD Their positions in 22

Estimation of multiple angles using multiple RF chains (2/2) An example of multiple AoDs estimation Beam finding for control channels u The ratio metric that characterizes path-r s AoD is calculated as u The quantized version of the ratio metric is fed back to the transmitter u Path-r s AoD is estimated by the transmitter using the ratio metric u The above process iterates until all paths AoDshave been estimated 23

2024 © hobbydocbox.com Privacy Policy | Terms of Service | Feedback