The present invention generally relates to a method to optimize the power assignment of user streams transmitted from base stations in coordinated base station transmission systems, said CBST systems, employing block diagonalization techniques in order to remove the interference among users and being deployed in MIMO-OFDM scenarios. More particularly it relates to a method that employs a new waterfilling technique which provides a performance very close to the theoretical ideal but with a reduced computational complexity.
During the last years, the use of OFDM (Orthogonal Frequency Division Multiplexing), a multicarrier transmission technique of transmitting information in parallel over multiple subcarriers, has become a solution to the problem of transmitting data over wireless channels with large delay spread [1]. For this reason, it has been adopted in several wireless standards such as digital audio broadcasting (DAB), digital video broadcasting (DVB-T), IEEE 802.11a/g/n (Wi-Fi), IEEE 802.16e/m (WiMAX), and 3GPP LTE (Long Term Evolution) and LTE-Advanced.
OFDM may be combined with antenna arrays at the transmitter and receiver to increase the diversity gain and/or to enhance the system capacity in time-variant and frequency selective channels. Multiple Input-Multiple Output (MIMO) techniques have been proposed as a means to take advantage of the possible gain and capacity increase [2]. However, MIMO processing in actual cellular networks faces a significant problem: achieving gain and capacity increase through MIMO techniques requires significant Signal-to-Noise-plus-Interference Ratios (SINR) values, of the order of 15 dB [3], and these SINR values can be found only in the proximity of base stations.
As a result, in mobile broadband systems that use these technologies, a considerable gap between cell-edge and cell-centre performance is observed due to intercell interference, especially when frequency reuse one is employed, which poses the main limitation of state-of-the art mobile networks. Therefore it is key for true ubiquity of mobile broadband to bridge this gap by introducing innovative techniques.
Several technological solutions have been proposed to solve the identified problems based on cooperative base station transmission. On one hand, cooperative BS techniques allow a user to benefit from the communication from multiple BSs, especially at the cell border. Diversity is increased, the quality of communication is increased, and in general, the overall link budget is more favourable, leading to less energy consumption at the system level. On the other hand, the use of relays decreases the distance seen by the user (at cell border) and the infrastructure. As a result, the user can reach the relay with less power, saving battery life and simultaneously decreasing its contribution to the interference.
Recently some work has been devoted to manage interference in cellular systems with reuse one. In [4] a Block Diagonalization (BD) algorithm that accounts for the presence of other-cell interference (OCI) is proposed for a multiuser MIMO downlink. It uses a whitening filter for interference suppression at the receiver and a precoder using the interference-plus-noise covariance matrix for each user in the transmitter at the base station. In this proposal the transmitter has perfect Channel State Information (CSI) and perfect knowledge of the whitening filter. So far, this technique has been usually employed over flat fading channels.
In
where the interference of other users is eliminated using the precoder Bk. The matrix Wk is a whitening or an interference-suppression filter that is only determinate by the interference plus noise covariance matrix independent of each user's channel. On the other hand, the precoder Mk is a cascade of two precoding matrices Bk and Dk for block diagonalization (Mk=BkDk) where Bk removes the intra-cell interference and Dk is used for parallelizing and power allocation by means of the standard waterfilling technique. The transmit precoder Mk requires the Singular Value Descomposition (SVD) of
So each receiver has to inform Wk to the transmitter.
In [5] the authors analyze several approaches for overcoming interference in MIMO cellular networks. If the interference is known by the transmitters, cooperative encoding among base stations using Dirty Paper Coding (DPC) can suppress OCI. This scheme has been shown to achieve the (maximum theoretical) capacity of the multiuser MIMO downlink channel. However, it has a high computational complexity.
In [6] [7] several strategies are proposed to perform Coordinated Base Station Transmission (CBST). Interference is eliminated by jointly and coherently coordinating the transmission from the base stations in the network, assuming that base stations know all downlink signals.
In a Coordinated Base Station Transmission (CBST) scheme, the transmitted signal from a particular BS may eventually arrive, depending on the propagation conditions, to a certain number of adjacent users in the cellular system that are served by other BSs. Under this assumption, the channel may be modelled by a N·r×M·t matrix H where each matrix coefficient represents the fading from each transmit antenna in the BS to each receive antenna at the user side. The received signal model is as follows:
y=Hx+n
where y is the received N·r×1 signal vector, x is the M·t×1 signal vector transmitted from all the BSs, and n is the Nr×1 independent and identically distributed complex Gaussian noise vector with variance σ2.
If Hk, with k=1 . . . N, is defined as the r×M·t channel matrix seen by user k, then
H=[H1TH2T . . . HTN]
where the superscript T means transposed.
For the CBST scenario x can be defined as follows
where bki represents the i-th symbol for user k transmitted with power Pki, and wki=[wki1, . . . , wki(m-1)t+j, . . . wkiMt]T are the precoding vectors being wki(m-1)t+j the weight of j-th transmit antenna (j=1 . . . t) of the m-th base station for the i-th symbol of the user k transmitted.
The precoding matrix
W=└w11, . . . , w1r, . . . , wk1, . . . , wkr, . . . , wN1, . . . , wNr┘
will be obtained under a Zero-Forcing criteria to guarantee that
where Uk is a unitary matrix and Sk=diag{(λk1)1/2, (λk2)1/2, . . . , (λkr)1/2} is a diagonal matrix that contains the square roots of the nonzero eigenvalues of the matrix QkQkT, being Qk the part of the channel matrix Hk orthogonal to the subspace spanned by other users' channels Hq (q≠k).
Then, the received signal can be expressed as
Each user may independently rotate the received signal and decouple the different streams
where the noise ñk remains white with the same covariance because of the unitary transformation.
Thus, the signal obtained by k-th user can be expressed as:
Thus, under an ideal Block Diagonalization strategy, the overall system can be seen as a set of parallel noninterfering channels. The problem lies in determining the powers involved in this parallel system (“Power allocation” as it will be shown in
It is necessary to offer an alternative to the state of the art which covers the gaps found therein, particularly related to the lack of proposals which allows reducing the heavy computational complexity associated to convex optimization, which is the optimal technique used to solve the power assignment problem in CBST systems.
To that end, the present invention provides a method to optimize the power assignment of user streams transmitted from base stations in coordinated base station transmission systems, said CBST systems, employing block diagonalization techniques in order to remove the interference among users and being deployed in MIMO-OFDM scenarios, wherein said optimization is subject to a plurality of constraints on the maximum available power transmission from each base station.
On contrary to the known proposals, in the method of the invention, in a characteristic manner it comprises solving said optimization of power assignment with a single constraint considering an equivalent base station among said base stations, wherein said single constraint is the most stringent of said plurality of constraints.
The method of the invention comprises using a new waterfilling technique which provides a performance very close to the theoretical ideal but with a reduced computational complexity.
Other embodiments of the method of the first aspect of the invention are described according to appended claims 2 to 7, and in a subsequent section related to the detailed description of several embodiments.
The previous and other advantages and features will be more fully understood from the following detailed description of embodiments, with reference to the attached drawings (some of which have already been described in the Prior State of the Art section), which must be considered in an illustrative and non-limiting manner, in which:
The present invention is addressed to methods and apparatus for enhancing overall throughput in the LTE Advanced (LTE-A) mobile communications system that supports cooperative base station transmission in the downlink. The invention proposes a method to optimize the power assignment to the user streams to be transmitted from different base stations. A BD scheme is employed to remove interference among users, using a new waterfilling technique which provides a performance very close to the theoretical ideal but with a reduced computational complexity.
Coordinated multi-point (CoMP) transmission and reception has been considered for LTE-Advanced as a tool to improve the coverage of high data rates, the cell-edge throughput, and also to increase system throughput.
The 3GPP has been working on LTE-A since early 2008. In March 2010 a Study Item on Coordinated Multiple Point (CoMP) was closed and a Work Item on extended Inter-Cell Interference Coordination for co-channel deployments of heterogeneous networks was started. The first decisions have been taken and will form the basis for LTE-Advanced standardization in Release 10 that are being reflected in the 3GPP Technical Report TR 36.814.
At the moment, CoMP is being analyzed in 3GPP as a Study Item. The framework of the CoMP study shall cover both intra-eNodeB as well as inter-eNodeB CoMP, and include investigation of spatial domain cooperation, e.g., spatial domain inter-cell scheduling and/or interference coordination, and other cooperation methods. Some objectives are: evaluate the performance benefits of CoMP operation and the required specification support for certain proposed scenarios, identify potential enhancements for DL-CoMP operation, evaluate applicability of X2 interface for different CoMP modes/schemes, and identify potential standardization impact for UL-CoMP operation and evaluate its performance benefit.
The system of the invention applies to an OFDM wireless system where the whole channel is known to transmitter and receiver. This is usually the case for a bidirectional transmission system where CSI is available at the receiver side after channel estimation and a signalling channel can be used to forward the CSI to the transmitter, like LTE. The system is intended to implement coordinated transmission for the downlink, where M base stations (BS) serve N UEs. Each base station has t transmit antennas and each UE has r receive antennas. The operational conditions are characterized by a linear block fading channel with frequency selective fading and additive Gaussian noise. Provided that the length of the cyclic prefix is chosen longer than the longest impulse response, the channel seen by each user can be decomposed into NOFDM independent flat subcarriers (at the same time, a set of subcarriers may be grouped in subchannels). An example of the system analyzed was represented in
Extending the previous equations to OFDM signals, the achievable rates per user in a MIMO-OFDM scenario based on CBST with Block Diagonalization technique are as follows
In order to maximize a weighted sum of the rates Rk for the set of users, it is required to solve the following optimization problem in terms of the power PkiP allocated to the i-th stream of user k:
subject to a constraint on the maximum available power for transmission from each base station Pmax:
In (2) the values αk∈[0,1], Σk=1Nαk=1, can be seen as indicating the priorities of the users: the closer αk is to 1, the higher the priority given to user k. In the particular case of αk=1/N, for all k, the solution of the above problem maximizes the sum rate.
The problem above is convex since the logarithmic function is concave in the power assignments, the addition operation preserves concavity and the constraints (3) are linear. Therefore it can be solved by standard convex optimization techniques [8]. This optimum solution is given by:
which resembles the well-known waterfilling distribution. However, here the waterlevel is different for each symbol i to be transmitted to each user k on each subcarrier p. Even though the values of the waterlevels can be found again by convex optimization techniques, it still has a similar computational complexity. So, closed-form solutions, even if suboptimal, would be desirable in order to reduce this computational time and resources required for the optimization.
This invention proposes a new method for solving the power allocation problem described above which makes it possible to be implemented in computational effective way without significant performance degradation.
By considering the most stringent of the constraints in (3), the problem can be reduced to an “equivalent” base station m0 having for each symbol transmitted to each user the precoding weights whose sum of squared values is maximum among all the BSs, that is:
So the problem reduces to:
subject to:
The resultant problem is equivalent to finding a constant value K such that, for all the power levels Pkip, the following equations hold
where [·]+ denotes the maximum between zero and the argument and μ is the Lagrange multiplier used to maximize the weighted sum rate of the users. This corresponds again to a waterfilling distribution with variable waterlevel. However, for given user priorities αk and channel realization determining λkip and Ωkip, the problem reduces to finding a constant K that can be solved with the same algorithms that solve standard waterfilling [9].
In order to further simplify the solution to the optimization problem, it may be considered that in a practical realizations the values of Ωkip are close to each other for all k, i and p. Then the solution (6) can be simplified to give:
which corresponds to a waterfilling distribution with the waterlevel modified only by the user priorities. In particular for equal priorities αk=1/N it corresponds to a standard waterfilling.
To sum up, the proposed solutions for this power assignment problem can be summarized through the following equations:
The invention allows for the practical implementation of a cooperative multipoint transmission technique that may help to provide the capacity required to meet the future traffic demand for mobile broadband services. The invention proposed provides a solution for the power allocation in a CBST environment with a much lower complexity with respect to other possible solutions like Dirty Paper Coding without a significant loss of performance. This reduced complexity may allow supporting the technique with a lower cost, due to the use of hardware with lower processing capabilities. The technique will also allow for the support of higher bit rates for those users located in the cell edges, with low SINR operating conditions, and providing them with a better Quality of experience.
Numerical Results of the Invention
Next, it will be performed a comparison of the performance in terms of achievable rates of the proposed waterfilling (WF), modified waterfilling (MWF) and the optimum solution found by convex optimization (CVX). For the sake of comparison the rates achieved when using a uniform power distribution (UP) are also included.
A simple two-BS, two-user scenario is considered. Here a simplified frequency-selective channel model with Npath paths and an exponential power-delay profile (PDP) are employed. Therefore, the channel matrix of the n-th path is
where β is the factor which indicates the decreasing speed of the power, and HG is a matrix whose entries are independent and identically distributed complex Gaussian random variables with zero mean and variance 1. Due to a high computational complexity of the CVX, an OFDM system with 8 subcarriers will be considered, although the results can be extended to more subcarriers.
In
In
A person skilled in the art could introduce changes and modifications in the embodiments described without departing from the scope of the invention as it is defined in the attached claims.
3GPP Third Generation Partnership Project
BD Block Diagonalization
BS Base Station
CBST Coordinated Base Station Transmission
CSI Channel State Information
DAB Digital Audio Broadcasting
DPC Dirty Paper Coding
DVB-T Digital Video Broadcasting-Terrestrial
LTE Long Term Evolution
LTE-A Long Term Evolution-Advanced
MIMO Multiple Input Multiple Output
OCI Other-Cell Interference
OFDM Orthogonal frequency Division Multiplexing
SINR Signal-to-Noise-plus-Interference Ratio
UE User Equipment
WF Waterfilling
ZF Zero-Forcing
Number | Date | Country | Kind |
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P201131183 | Jul 2011 | ES | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2012/063212 | 7/6/2012 | WO | 00 | 9/8/2014 |