Abstract
We present a design of a complete and practical scheduler for the 3GPP Long Term Evolution (LTE) downlink by integrating recent results on resource allocation, fast computational algorithms, and scheduling. Our scheduler has low computational complexity. We define the computational architecture and describe the exact computations that need to be done at each time step (1 milliseconds). Our computational framework is very general, and can be used to implement a wide variety of scheduling rules. For LTE, we provide quantitative performance results for our scheduler for full buffer, streaming video (with loose delay constraints), and live video (with tight delay constraints). Simulations are performed by selectively abstracting the PHY layer, accurately modeling the MAC layer, and following established network evaluation methods. The numerical results demonstrate that queue- and channel-aware QoS schedulers can and should be used in an LTE downlink to offer QoS to a diverse mix of traffic, including delay-sensitive flows. Through these results and via theoretical analysis, we illustrate the various design tradeoffs that need to be made in the selection of a specific queue-and-channel-aware scheduling policy. Moreover, the numerical results show that in many scenarios strict prioritization across traffic classes is suboptimal.
Highlights
The 3GPP standards’ body has completed definition of the first release of the Long Term Evolution (LTE) system
While we focus on LTE in this paper, we note that the computational framework and the insights gained via the numerical studies can be extended to other orthogonal division frequency multiple access (OFDMA) technologies such as Worldwide Interoperability for Microwave Access (WiMax) and Ultra Mobile Broadband (UMB)
We introduce the following standard 3GPP terminology to be used in the rest of the document: (i) slot: basic unit of time, 0.5 millisecond, (ii) subframe: unit of time, 1 millisecond; resources are assigned at subframe granularity, (iii) eNB: evolved Node B, refers the base station, (iv) UE, user equipment, refers to the mobile, (v) PDCCH: physical downlink control channel, physical resources in time and frequency used to transmit control information from eNB to UE, (vi) PDSCH: physical downlink shared channel, physical resources in time and frequency used to transmit data from eNB to UE, (vii) CQI: channel quality indicator, measure of the signal to noise ratio (SINR) at the UE when eNB transmits at a reference power, fed back repeatedly from the UE to the eNB
Summary
The 3GPP standards’ body has completed definition of the first release of the Long Term Evolution (LTE) system. LTE is an Orthogonal Frequency Division Multiple Access (OFDMA) system, which specifies data rates as high as 300 Mbps in 20 MHz of bandwidth. LTE can be operated as a purely scheduled system (on the shared data channel) in that all traffic including delay-sensitive services (e.g., VoIP or SIP signaling, see, e.g., [1, 2]) needs to be scheduled. Scheduler should be considered as a key element of the larger system design. The fine granularity (180 KHz Resource Block times 1 millisecond Transmission Time Interval) afforded by LTE allows for packing efficiency and exploitation of time/frequency channel selectivity through opportunistic scheduling, enabling higher user throughputs. Unlike what is typically the case in wired systems, more capacity does not translate to better user-perceived
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