Jinseok Choi, Brian L. Evans and *Alan Gatherer

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Presentation transcript:

ADC Bit Allocation under a Power Constraint For MmWave Massive MIMO Communication Receivers Jinseok Choi, Brian L. Evans and *Alan Gatherer Embedded Signal Processing Laboratory Wireless Networking & Communications Group The University of Texas at Austin, Austin, Texas USA *Huawei Technologies, Plano, Texas, USA http://www.wncg.org

Millimeter Wave Communications [1] Massive MIMO Carrier frequency 3-300 GHz Small antenna sizes Bandwidths on order of 1 GHz Multi-Gigabit data rates possible Large pathloss Large antenna arrays Large beamforming gain Challenges in mmWave Massive MIMO Large number of RF processing chains with ADCs High-resolution ADCs primary power consumer [2] Put a dotted circle to 28GHz band / Take the mmWave graph -> backup slide(Hyperlink) Goal: Reduce ADC resolution to reduce power consumption [1] Z. Pi and F. Khan. "An introduction to millimeter-wave mobile broadband systems," IEEE Comm. Mag. vol. 49. no. 6, 2011, pp. 101-107. [2] F. Boccardi, R. Heath and A. Lozano . "Five disruptive technology directions for 5G," IEEE Comm. Mag., vol. 52, no. .2, 2014, pp. 74-80. 2

Reduction of ADC Power Consumption Intuition Channels are sparse in beamspace (on next two slides) Exploit sparsity for efficient bit allocation Approach Apply analog beamforming for beamspace projection Minimize quantization error subject to power constraint Contributions Low-complexity and near-optimal ADC bit allocation technique Numerical validation using error vector magnitude 3

Multiuser Massive MIMO Uplink System Model: M users, each with a single Tx antenna Base station with N Rx antennas (N >> M) Narrowband channel Known channel state information Received signals in vector form and WHY SINGLE TX ANTENNA AT THE MOBILE PLATFORM – A VALID ASSUMPTION? 4

Millimeter Wave Channel Channel Model: p major scattering paths (limited scattering) Virtual channel representation under ULA* assumption p major elements N-p minor DFT matrix Beamspace channel matrix for M users where : array response vector with : beamspace channel vector of i-th user (p major elements + N-p minor elements) In our network model, In our signal model, 5 *Uniform linear array

ADC Quantization Model: Linear Gain Plus Noise ADC Quantization Model: Assumes optimal scalar minimum mean square error quantizer Best fit linear gain for input yi and output yqi Apply linear gain plus noise model for ADC quantization where In our network model, In our signal model, where : quantization noise 6

RF Preprocessing: Analog Beamforming Reveals channel sparsity Analog beamforming output ADC output (quantization) model : DFT matrix (Recall ) p major elements N-p minor 7

Bit Allocation: Problem Formulation Mean square quantization error (MSQE) Model beamforming output as complex Gaussian distribution* where Under Gaussian model for , MSQE becomes Quantization bits for i-th ADC 8 * Due to the Central Limit Theorem

Bit Allocation: Problem Formulation Relax MSQE minimization problem i) Relax non-negative integer problem to a real number problem ii) Relax power consumption model to be where c = energy consumption per conversion step (e.g. 494 fJ) W = sampling rate Relaxation (ii) removes 9

Bit Allocation: Relaxed Minimization and Solution Relaxed MSQE minimization problem Subject to power constraint (total power of N -bit ADCs) Convex optimization Closed-form solution by using Karush-Kuhn-Tucker conditions Global optimal solution Log term can be minus where 10

Bit Allocation: Mapping Relaxed Solution Map real-valued bit allocations to non-negative integers Map to 0 because Map using and If power constraint is not met then, compute MSQE vs. ADC power consumption tradeoff For the set of , i) iteratively pick bit allocation with smallest tradeoff function value ii) perform until power constraint met increase of quantization error per unit power saving 11

Validation: Link-Level Simulation Settings Performance measures QPSK modulation N = 256 Rx antennas elements M = {8, 16} users Channel: 1 cluster with 4 subpaths [3] Carrier frequency: 73 GHz Antenna spacing: Error vector magnitude (EVM) Signal-to-noise ratio (SNR) SNR We performed link-level simulation for the validation of our algorithm for 10MHz case the simulation is set as 64QAM Modulation with 8, 16, 32 and 64 antenna cases. And the number of users is fixed as 4. Assigned Resource blocks per user is 12 block, total 48 block out of 50 blocks (which is 96% of full usage). Compression Block Length is 1096 and Pedestrian A channel model is used. 12 [3] T. A. Thomas, H. C. Nguyen, G. R. MacCartney, and T. S. Rappaport, “3D mmWave channel model proposal,” Proc. IEEE Veh. Tech. Conf. , Sep. 2014,.

Error Vector Magnitude Bit allocation vs. Uniform bit ADC 13

Error Vector Magnitude Bit allocation vs. Uniform bit ADC 14

Error Vector Magnitude Bit allocation vs. Uniform bit ADC 15

ADC Configuration 0-bit ADCs represent deactivated ADCs 256 Rx Antennas 0-bit ADCs represent deactivated ADCs 16

Conclusion Near Optimal Bit Allocation Technique Reduces EVM for all cases of and Consumes lower or equal amount of power Has low complexity Develop Future Bit Allocation Algorithms Wideband channels & imperfect channel state information Multiple Tx antennas & basestation planar array Impact of interference & hybrid beamforming 17

Thank you

References [1] Z. Pi and F. Khan. "An introduction to millimeter-wave mobile broadband systems.” IEEE Communications Magazine, vol. 49, no. 6, 2011, pp. 101-107. [2] F. Boccardi, R. Heath and A. Lozano, "Five disruptive technology directions for 5G," IEEE Communications Magazine, vol. 52, no. 2, 2014, pp. 74-80. [3] T. A. Thomas, H. C. Nguyen, G. R. MacCartney, and T. S. Rappaport, “3D mmWave channel model proposal,” in Proc. IEEE Vehicular Technology Conference , Sep. 2014. 19

Millimeter Wave Communications Millimeter Wave Spectrum [Pi11] Carrier frequency 3-300 GHz Small antenna sizes Bandwidths on order of 1 GHz Multi-Gigabit data rates possible Large pathloss Put a dotted circle to 28GHz band / Take the mmWave graph -> backup slide(Hyperlink) [1] Z. Pi and F. Khan. "An introduction to millimeter-wave mobile broadband systems." IEEE Comm. Mag. ,vol. 49. no. 6, 2011, pp. 101-107. 20

Proposed Near Optimal Bit Allocation Algorithm Step 1) Maps to Step 2) Maps to Step 3-1) If violates the constraint, compute Step 3-2) bi with the smallest Trel(i): Minimum error increase/unit power saving Step 3-3) Repeat until satisfies the constraint

Error Vector Magnitude Bit allocation vs. Uniform bit ADC 22