Recently, opportunistic usage of licensed frequency bands has been proposed as a solution to spectral crowding problems by using cognitive radio (CR) systems. A cognitive radio system would be able to operate in licensed bands by utilizing vacant parts of these bands. A key point for the success of cognitive radio is the ability to shape its signal spectrum to achieve minimum interference to licensed users.
Orthogonal Frequency Division Multiplexing (OFDM) has been proposed as a candidate signaling technology for cognitive radio applications. By dividing the spectrum into subbands that are modulated with orthogonal subcarriers, OFDM spectrum can be shaped more easily in comparison to other signaling techniques known in the art. However, modulated OFDM subcarriers suffer from high sidelobes, which result in adjacent channel interference (ACI). Thus, disabling a set of OFDM subcarriers to create a spectrum null may not be sufficient to avoid interference to licensed users. On the other hand, using filters to reduce the adjacent channel interference can increase the system complexity and introduce long delays. Using guard bands on both sides of used OFDM spectrum coupled with windowing of the time-domain symbols has been investigated. Other proposed methods include the use of interference cancellation carriers, subcarrier weighting, or multiple-choice sequences. While cancellation carrier techniques can significantly suppress OFDM sidelobes, they result in an increase in the system peak-to-average-power ratio (PAPR), and the performance is sensitive to the cyclic prefix (CR) size. Moreover, due to the higher power used for the cancellation carrier method, using this technique affects the spectral flatness of the transmitted signal and can increase the inter-carrier interference (ICI) in case of a Doppler spread of a frequency offset error at the receiver. On the other hand, subcarrier weighting methods cause an increase in the system bit error rate (BER), and the interference reduction is not as significant as it is with the carrier cancellation method.
In the prior art, windowing of OFDM symbols was investigated as a method to suppress OFDM sidelobes. With this process, the time domain symbols are passed through a filter (usually raised cosine (RC) filters are used), and consecutive symbols are allowed to overlap. The process smoothes the transition between OFDM symbols and thus improves the spectral characteristics of the OFDM signal. To keep the orthogonality between OFDM subcarriers, the symbols are cyclicly extended to cover the overlapping region. The advantage of this approach is its low computational complexity. The disadvantage is the reduced spectral efficiency due to the symbol extension.
Accordingly, what is needed in the art is an improved system and method to suppress OFDM sidelobes and shape the signal spectrum for use in cognitive radio applications.
The present invention provides a system and method which employs adaptive symbol transition (AST) to suppress OFDM sidelobes and shape the signal spectrum. In the present invention, the OFDM symbols are extended in time to reduce the effect of symbol transition. However, instead of using a predefined filter shape, as is known in the prior art, the transition signal is optimized adaptively based on transmitted data and detected licensed user bands to reduce the interference to licensed users.
In accordance with the present invention, a method for sidelobe suppression in an orthogonal frequency division multiplexing (OFDM) based cognitive system is provided comprising the steps of: scanning an operation band of the cognitive system to detect at least one current licensed user operating in the operation band, each of the detected current licensed users having a corresponding center frequency and a corresponding bandwidth; disabling a plurality of subcarriers associated with each of the current licensed users, the subcarriers disabled based upon the corresponding center frequency and corresponding bandwidth of each of the current licensed users; creating an index of the disabled subcarriers, the index comprising the center frequency and bandwidth for the current licensed users; receiving a current time domain OFDM symbol to be transmitted over a set of active subcarriers in the operation band, the current OFDM symbol comprising modulated data; receiving a next time domain OFDM symbol to be transmitted over the set of active subcarriers in the operation band, the next time domain OFDM symbol comprising modulated data; calculating an OFDM symbol extension to be added to the received current OFDM symbol, the OFDM symbol extension calculated based upon the set of active subcarriers, the index of the disabled subcarriers, the modulated data of the current OFDM symbol, the modulated data of the next OFDM symbol and a desired symbol extension length; and extending the current OFDM symbol using the calculated OFDM symbol extension to suppress the sidelobes of the OFDM symbols and reduce interference to the licensed users.
A cyclic prefix may be added to the OFDM symbols prior to calculating the symbol extension.
The present invention provides a system for sidelobe suppression in a cognitive transmitter employing orthogonal frequency division multiplexing (OFDM), the system comprises: a cognitive engine for scanning an operation band of the cognitive transmitter to detect at least one current licensed user operating in the operation band, each of the detected current licensed users having a corresponding center frequency and a corresponding bandwidth and to disable a plurality of subcarriers associated with each of the current licensed users, the subcarriers disabled based upon the corresponding frequency and corresponding bandwidth of each of the current licensed users, and an adaptive symbol transition unit coupled to the cognitive engine, the adaptive symbol transition unit for creating an index of the disabled subcarriers, the index comprising the center frequency and bandwidth for the current licensed users; receiving a current time domain OFDM symbol to be transmitted over a set of active subcarriers in the operation band, the current OFDM symbol comprising modulated data; receiving a next time domain OFDM symbol to be transmitted over a set of active subcarriers in the operation band, the next OFDM symbol comprising modulated data; calculating an OFDM symbol extension to be added to the received current OFDM symbol, the OFDM symbol extension calculated based upon the set of active subcarriers, the index of the disabled subcarriers, the modulated data of the current OFDM symbol, the modulated data of the next OFDM symbol and a desired symbol extension length; and extending the current OFDM symbol using the calculated OFDM symbol extension to suppress the sidelobes of the OFDM symbols and reduce interference to the licensed users.
The system may be a cognitive radio system or a broadband wireless system.
The present invention introduces a further reduction of interference with less power consumption and more robustness to different system and channel parameters.
The present invention introduces a new method for OFDM signals sidelobe suppression. The proposed method can reduce the interference caused by OFDM systems to adjacent users operating in the same channel Using the invention presented here results in the increase of spectral efficiency of the system and thus increasing the data rates.
The present invention can reduce interference caused by OFDM systems (e.g. WiFi and WiMAX systems) to users operating in adjacent bands. By minimizing interference, users can send at higher powers and thus achieve higher data rates.
For a fuller understanding of the invention, reference should be made to the following detailed description, taken in connection with the accompanying drawings, in which:
A cognitive radio system employing OFDM as the signaling technique is provided in accordance with the present invention. The cognitive radio is assumed to be aware of the surrounding environment and the radio channel characteristics. After scanning the channel, the cognitive radio should be able to identify licensed users operating within the same band. The goal of cognitive radio is to exploit available spectrum opportunities and achieve the highest possible spectral efficiency while keeping the interference to the licensed users at a minimum.
The system is accordance with the present invention is illustrated with reference to
The time domain signal at the output of the IFFT 30 is
where (m) is the symbol index, N is the IFFT size, (.)* is the complex conjugate operator,
is the inverse Fourier transform matrix, and X(m)=[X1(m), X2(m), . . . , XN(m)]T is the modulated data vector. The signal is then extended with a cyclic prefix 40 consisting of G samples and the extended symbols y(m) are fed to an adaptive signal transition block 45. Meanwhile, the cognitive engine 50 passes required information regarding licensed users operating in the same band to both the subcarrier mapper 25 and the adaptive signal transition block 45. This information is used to disable subcarriers operating in the licensed user's bands to suppress the interference to the licensed users caused by OFDM sidelobes.
The adaptive symbol transition technique in accordance with the present invention suppresses OFDM sidelobes by extending OFDM symbols and thus using the extensions to smooth the transition between consecutive symbols. However, instead of using a predefined window shape (e.g., raised cosine filter) to determine the value of the symbol extension, the present invention proposes an adaptive method that calculates the value of the symbol extension based on licensed user's center frequency and bandwidth.
Assume the cognitive system detects a licensed user signal spanning over K subcarriers (Xi+1, Xi+2, . . . Xi+K), where iΔf is the licensed signal offset with respect to the OFDM signal, KΔf is the licensed signal bandwidth, and Δf is the frequency subcarrier spacing. In the present invention, the above subcarrier set is disabled to avoid interfering with the licensed user. In addition, to further suppress the interference, the adaptive symbol transition block adds an extension a(m)=[a1(m), a2(m), . . . aC(m)]T to every OFDM symbol y(m) as shown in
First, the interference to the licensed user is examined. The signal is upsampled by a factor of ξ or in other words, ξ points per subcarrier are considered. The signal spectrum of two consecutive symbols can be obtained as,
where β=2N+2G+C. The interference to the licensed user is then,
IL=FKz
where FK is a subset of Fξ, N, β containing only the rows that correspond to the licensed user band (rows ξ(i+1) to ξ(i+K)) and zK(m) is the same as z(m) but with a(m)=[0]c×1. To minimize interference power, the adaptive symbol transition block chooses a(m) such that,
where FI is a subset of FK containing only the columns that correspond to a(m); columns N+G to N+G+C−1.
The mean-squared-error (MSE) solution to (5) can result in very high values for a(m). This leads to an increase in the extension power. As a result, the useful symbol energy is reduced compared to the total symbol energy, resulting in an increase in the system BER (bit error ratio). The mitigate this effect, the present invention adds a constraint on the minimization in (5) such that the symbol extension power is below a given level α2,
∥a(m)∥2≦α2 (6)
The optimization in (5) and (6) is known as linear least squares problem with a quadratic inequality constraint. Using singular value decomposition (SVD), we get,
and,
DF
where (.)H is the Hermitian transpose, [U]Ψ×Ψ and [V]C×C are unitary, and Ψ=ξ(K−1)+1. Using the method of Lagrange multipliers, we get the following equation,
where ĨL=UHIL=[ĨL−1, . . . ĨL,Ψ]T. If a solution exists to the optimization problem, the function ƒ(λ) will have a unique positive root and it has been shown that this is the desired root. The solution can be obtained as,
a(m)=V[−v1ĨL−1/(v12+{tilde over (λ)}), . . . , −vCĨL,C/(vc2+{tilde over (λ)})]T, (10)
where {tilde over (λ)} is the unique positive root of (9). Fortunately, for a given spectrum shape FI is fixed and thus, only IL needs to be updated for every OFDM symbol. The computational complexity of the optimization problem is reduced significantly due to this fact.
An important parameter of OFDM systems is the peak-to-average power ratio (PAPR) which affects the dynamic range over which the system should be linear. By choosing α2 such that,
α2=C/(N+G)ES, (11)
the signal average power is kept at the same level, where ES is the symbol energy prior to the adaptive symbol transition block. Since the adaptive symbol transition signal is optimized to smooth the symbol transition, it does not introduce any peaks to the signal (confirmed by simulations results) and, thus, the PAPR of the system does not increase. Nevertheless, the adaptive symbol transition of the present invention reduces the useful symbol energy. Using (11) the maximum signal-to-noise ratio (SNR) loss γ is,
By controlling the number of samples, C, and for a fixed PAPR, the system of the present invention provides a tradeoff between reducing γ (by reducing C), or improving the interference suppressing (by increasing C).
It is noteworthy that since the adaptive symbol transition technique in accordance with the present invention is performed on time-domain symbols, the performance is not sensitive to the cyclic prefix size. In addition, the adaptive symbol transition does not introduce any inter-symbol interference (ISI) to the system as the leakage from the symbol extension is contained in the cyclic prefix. The intended receiver can remove the adaptive symbol transition extension along with the cyclic prefix to maintain an ISI-free signal.
The performance of the method in accordance with the present invention is investigated using computer simulations. In a particular embodiment of the present invention is provided an OFDM-based cognitive radio system with N=256 and G=16. The AST method is accordance with the present invention is used with C=16, ξ=16, and, based on (11), α2=0.06ES. The DC subcarrier is disabled. Data subcarriers are modulated with a QPSK signal. All results shown are averaged over 10,000 OFDM symbols. Two cases were considered for performance evaluation. In the first case, a licensed user is detected spanning 24 OFDM subcarriers. The system disables 32 subcarriers leaving a guard band of 4 subcarriers on each side of the licensed user band. The guard bands are to allow the signal power to decay while the adaptive symbol transition block performs the optimization over the 24-subcarrier band. The normalized power spectral density (PSD) of the signal at the output of the adaptive symbol transition block is measured and the results are shown in
In an additional embodiment the adaptive symbol transition method in accordance with the present invention is used to reduce the number of disabled subcarriers used as guard bands in current OFDM systems. For example, a WiMAX system employing a 256 subcarriers OFDM system disables 55 subcarriers (28 and 27 on the left and right sides, respectively) to limit out-of-band radiations.
Using sidelobe suppression techniques, the required guard band can be reduced for an increase in system complexity. In an embodiment using 24 subcarriers (12 on each side) as guard bands, N, G, C, ξ and α2 are the same as in the previous embodiment. The normalized PSD of the left side of the signal is shown in
With reference to
In accordance with the present invention, a new system and method are provided to suppress OFDM sidelobes and shape the spectrum of OFDM signals. The proposed adaptive symbol transition method of the present invention extends OFDM symbols and uses the extension to reduce adjacent channel interference (ACI) to other users operating in the same band. Simulation results shown that the adaptive symbol transition method in accordance with the present invention can achieve a significant gain over conventional sidelobe suppression techniques. Moreover, the adaptive symbol transition method in accordance with the present invention does not increase the signal peak-to-average power ratio (PAPR) and keeps a low signal-to-noise ratio (SNR) loss.
It will be seen that the advantages set forth above, and those made apparent from the foregoing description, are efficiently attained and since certain changes may be made in the above construction without departing from the scope of the invention, it is intended that all matters contained in the foregoing description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
It is also to be understood that the following claims are intended to cover all of the generic and specific features of the invention herein described, and all statements of the scope of the invention which, as a matter of language, might be said to fall therebetween. Now that the invention has been described,
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Number | Date | Country | |
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