ENERGY-AWARE RESOURCE
ALLOCATION STRATEGIES FOR LTE UPLINK WITH SYNCHRONOUS HARQ CONSTRAINTS
ABSTRACT:
In this paper we propose a
framework for energy efficient resource allocation in multiuser localized
SC-FDMA with synchronous HARQ constraints. Resource allocation is formulated as
a two-stage problem where resources are allocated in both time and frequency. The
impact of retransmissions on the time-frequency problem segmentation is handled
through the use of a novel block scheduling interval specifically designed for
synchronous HARQ to ensure uplink users do not experience ARQ blocking. Using
this framework, we formulate the optimal margin adaptive allocation problem,
and based on its structure, we propose two sub-optimal approaches to minimize
average power allocation required for resource allocation while attempting to
reduce complexity. Results are presented for computational complexity and
average power allocation relative system complexity and data rate, and comparisons
are made between the proposed optimal and suboptimal approaches.
EXISTING SYSTEM:
General radio resource allocation problems,
particularly for systems such as orthogonal frequency division multiplexing
(OFDM) fall in to two major classifications, namely the rate and margin
adaption (RA and MA) problems. RA problems try to allocate resources to maximize
system throughput for a given power constraint, while MA problems try to
minimize transmission power and maintain a minimum throughput guarantee. The
latter of which is essential for energy efficient scheduling. In recent years,
MA problems have been well-studied for a general OFDMA transmission system.
However, more modern systems, such as 3GPP-LTE, utilize localized Single
Carrier Frequency Division Multiple Access (SC-FDMA) at the physical layer for
uplink transmissions. With localized SC-FDMA, subcarriers can only be allocated
contiguously in frequency. The use of localized SC-FDMA has been shown to offer
improved peak to average power ratio (PAPR) compared to OFDM. This however imposes
a limitation of contiguous frequency block assignment, and thus eliminates
direct application of traditional MA framework as described above. Furthermore,
the finite set of modulation and coding schemes (MCS) used in modern
communication systems dramatically increases the optimal allocation complexity.
DISADVANTAGES OF
EXISTING SYSTEM:
· The
objective function in this case is to maximize the cell transmission rate
rather than minimize transmission power.
· Mobile battery resources are not efficiently
utilized.
PROPOSED SYSTEM:
We propose a method of performing resource
allocation that exploits the periodicity of the HARQ process in scheduler
design. We propose the use of a block time-frequency domain packet scheduler (BTFDPS).
This approach reduces the amount of scheduling decisions required for uplink
traffic in addition to simplifying incorporation of synchronous HARQ into the
framework. At each block time-frequency frame, resources are allocated
dynamically relative to the required throughput, priority, and number of
on-going transmissions. Power allocation is minimized per unit time to meet
constraints resulting in minimizing energy expended for transmission.
ADVANTAGES OF PROPOSED
SYSTEM:
· Power
allocation is minimized.
· It
reduces the amount of scheduling decisions required for uplink traffic.
SYSTEM ARCHITECTURE:
SYSTEM CONFIGURATION:-
HARDWARE REQUIREMENTS:-
ü Processor - Pentium –IV
ü Speed - 1.1 Ghz
ü RAM - 512 MB(min)
ü Hard
Disk - 40 GB
ü Key
Board - Standard Windows Keyboard
ü Mouse - Two or Three Button Mouse
ü Monitor - LCD/LED
SOFTWARE
REQUIREMENTS:
•
Operating system : Windows XP
•
Coding Language : Java
•
Data Base : MySQL
•
Tool : Net Beans IDE
REFERENCE:
Dan J. Dechene and Abdallah Shami, “Energy-Aware Resource
Allocation Strategies for LTE Uplink with Synchronous HARQ Constraints”IEEE TRANSACTIONS ON
MOBILE COMPUTING, VOL. 13, NO. 2, FEBRUARY 2014.
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