Cooperative relaying has been envisioned as a promising technique for improving spectral efficiency in wireless networks. One way to increase the data rate of todays dense wireless networks is by utilizing the proximity of the nearby terminals. When a wireless terminal is allowed to cooperate with the nearby wireless terminals, it can utilize this proximity gain to “borrow” the antennas from these devices and form a virtual multiple-antenna transceiver. This is the basic principle of cooperative Multiple-Input Multiple-Output (MIMO) transmission, the technique that resembles that of the standard MIMO systems found in modern wireless standards, such as Wifi 802.11n and 4G LTE.
In this project we are exploring physical-layer cooperation in the uplink scenario (mobile station to base station) from a system design perspective. The project focusses on the network configuration presented on Figure 1, with one single-antenna transmit mobile terminal (source), one multiple-antenna access point (AP) or base station (BS) (destination), and many single-antenna mobile terminals (relays) close to the source and available for physical-layer cooperation. The relays are assumed to be half-duplex, i.e. they can either be in the transmit (Tx) or the receive (Rx) mode.
We have looked into several aspects of how to design such cooperative network. First, we simulated what is the capacity gain for a different number of relays and typical channel conditions. We demonstrated around 3x increase in QMF achievable rate with up to 5 relays. Second, we looked at efficient relay scheduling (when relays should be in Tx and when in Rx mode) algorithms. We have suggested a simple local scheduling algorithm that can operate in real-time and achieve an optimal rate for small number of relays, Figure 2. Third, we are looking into relay interference issue. With other nearby relays transmitting at the same time, some amount of interference from other relays is inevitable. We have suggested an efficient algorithms that can mitigate the effect of relay interference. Lastly, we would like to show proof-of-concept with a hardware implementation of the simplified version of this cooperative network. The hardware prototype has a single source, a single relay, and a two-antenna destination. We are building the complete baseband using the National Instruments (NI) platform for design and testing of wireless communication systems. The system will run on FPGA chips and use standard radio boards supplied by NI, Figure 3.Read more
Milos Jorgovanovic received his Dipl. Ing. degree in Electrical Engineering from University of Belgrade, Serbia in 2007 and MSc degree from University of California at Berkeley in 2010. He is currently working towards his PhD degree at University of California at Berkeley under guidance of Prof. Borivoje Nikolic.
In summer 2006 he held an internship position at Kodak European Research Center in Cambridge, UK, working on Dye-Sensitized Solar Cells and their application as a light detector. After graduation in 2007/2008, he spent eight months designing digital communication systems at Signum Concepts Inc. in Belgrade, Serbia. In summer 2010 he held an internship position with Samsung Telecommunications America in Richardson, TX, where he worked on MIMO detection algorithms for LTE-Advanced. He did another internship on LTE-Advanced with Qualcomm Inc. in 2012. He was working on downlink channel estimation algorithms and CQI feedback computation.
His research interests include wireless communication systems design, signal processing for digital communications and digital integrated circuit design.Read more