TY  - JOUR
T1  - Attainable throughput of an interference-limited multiple-input multiple-output (MIMO) cellular system.
JF  - IEEE Transactions on communications
A1  - Catreux, S.
LA  - English
UL  - https://tuklas.up.edu.ph/Record/UP-99796217609484328
AB  - We investigate the high spectral efficiency capabilities of a cellular data system that combines the following: 1) multiple transmit signals, each using a separately adaptive modulation; 2) adaptive array processing at the receiver; and 3) aggressive frequency reuse (reuse in every cell). We focus on the link capacity between one user and its serving base station, for both uncoded and ideally coded transmissions. System performance is measured in terms of average data throughput, where the average is over user location, shadow fading, and fast fading. We normalize this average by the total bandwidth, call it the mean spectral efficiency, and show why this metric is a useful representation of system capability. We then quantify it, using simulations, to characterize multiple-input multiple-output systems performance for a wide variety of channel conditions and system design options
KW  - MIMO cellular system.
KW  - Adaptive array processing.
KW  - Adaptive modulation.
KW  - Aggressive frequency reuse.
KW  - Attainable throughput.
KW  - Bandwidth.
KW  - Base station.
KW  - Cellular data system.
KW  - Channel conditions.
KW  - Fast fading.
KW  - Ideally coded transmission.
KW  - Interference-limited multiple-input multiple-output cellular system.
KW  - Link capacity.
KW  - Mean spectral efficiency.
KW  - Multiple transmit signals.
KW  - Receiver.
KW  - Shadow fading.
KW  - Spectral efficiency capabilities.
KW  - System design options.
KW  - System performance.
KW  - Uncoded transmission.
KW  - User location.
ER  -