A) OFDM and SC signal classification algorithm

Considering an OFDM signal with N _S transmission subcarriers be denoted by $\{ {s(t_1 ),s(t_2 ),\ldots ,s({t_{N_S } })}\}$, according to the definition of fractal box dimension of digital communication signal, the fractal box dimension of the OFDM signal D(s) can be defined as [Reference Li, Li and Lin14]:

(5)$$D(s)=1+\displaystyle{{lgd(\Delta )-lgd(2\Delta )}\over{lg2}}$$

with

(6)$$d(\Delta )=\sum\limits_{i=1}^{N_S } {\left\vert {s(t_i )-s(t_{i+1} )} \right\vert}=LE\vert s_i -s_{i+1} \vert,$$

(7)$$d(2\Delta )=\sum\limits_{i=1}^{N_S /2} {\{s_{max} (t_{2i} )-s_{min} (t_{2i})\}},$$

and

(8)$$s_{max} (t_{2i} ) = max[s(t_{2i-1} ),s(t_{2i} ),s(t_{2i+1} )],$$

(9)$$s_{min} (t_{2i} )=min[s(t_{2i-1} ),s(t_{2i} ),s(t_{2i+1} )].$$

The modulation of OFDM signal's every carrier is different and these carriers are assumed to be independent and orthogonal. According to the central limit theorem, the instantaneous amplitude of OFDM signal can be assumed to have a Gaussian distribution when the number of OFDM carrier is large enough. So, when N _S → ∞, the probability density function of the OFDM signal can be written as:

(10)$$f_s (s)=\displaystyle{{1}\over{\sigma \sqrt {2\pi}}}e^{-(s-\eta )/2\sigma ^2},$$

where σ and η are the variance and mean value of the OFDM signal. Let F _s (s) be the distribution function of OFDM signal, P = s _max (t _2i), Q = s _min (t _2i), and the distribution function of P and Q is $F_P (p)=F^3_S (p)$, F _Q (q) = 1 − (1 − F _S (q))³, then we can get the first-order derivative with respect to P and Q, so the probability density function of P and Q is $f_P (p)=3F^2_s (p)f_s (p)$, $f_Q (q)=3f_s (q)-6F_S (q)f_s (q)+3F^2_s (q)f_s (q)$. Then the expectation of P and Q can be expressed as follows:

(11)$$E(P)=\int_{-\infty }^{+\infty } {pf_P (p)dp} =\int_{-\infty }^{+\infty }{3pF^2_s (p)f_s (p)dp},$$

(12)$$\eqalign{E(Q) & = \int_{-\infty }^{+\infty } {qf_Q (q)dq}, \cr & = \int_{-\infty }^{+\infty } {q[3f_s (q)} -6F_S (q)f_s (q) \cr & \quad + 3F^2_s (q)f_s(q)]dq}$$

and

(13)$$\eqalign{& E(P)-E(Q) \cr & \quad = 6\int_{-\infty }^{+\infty } {nF_S (n)f_s (n)}dn-3\int_{-\infty }^{+\infty } {nf_s (n)} dn \cr & \quad = 3E(max(s_i ,s_{i+1} ))-3E(s_i) \cr & \quad =\displaystyle{{3}\over{2}}(E(s_i )+E(s_{i+1} )+E(\vert s_i -s_{i+1} \vert ))-3E(s_i )\cr & \quad =\displaystyle{{3}\over{2}}E(\vert s_i -s_{i+1} \vert)}$$

this leads to

(14)$$d(2\Delta )=\displaystyle{{N_S}\over{2}}[E(P)-E(Q)]=\displaystyle{{3N_S}\over{4}}E(\vert s_i -s_{i+1}\vert).$$

By replacing equations (6) and (14) into equation (5), we can get:

(15)$$\eqalign{D(s) & = 1+\displaystyle{{lg(d(\Delta )/d(2\Delta ))}\over{lg2}} \cr & = 1+\displaystyle{{1}\over{lg2}}lg \displaystyle{{LE\vert s_i -s_{i-1} \vert }\over{(3L/4)E\vert s_i-s_{i-1}\vert}} \cr & =1+\displaystyle{{lg(4/3)}\over{lg2}}=1.415.}$$

By analyzing the fractal box dimension of the OFDM signal, we get the fractal box dimension of OFDM signal's amplitude as 1.415. For a SC signal, the shaping filter of every symbol has no difference, the instantaneous amplitude of samples is restricted by each other; thus, the fractal box dimension of a SC signal is smaller than the OFDM signal. Next, we will demonstrate that the fractal box dimension of SC signal's amplitude among adjacent three samples. We are considering the three adjacent samples can be divided into two cases based on the monotonicity of the samples.

1. (a) When the samples of a SC signal are monotonic, the maximum value and minimum value located in the two endpoints of samples spacing, so, |s(t _2i−1) − s(t _2i)| + |s(t _2i) − s(t _2i+1)| and |s(t _2i−1) − s(t _2i+1)| are equal, in this case, d(Δ) = 2d(2Δ), and the fractal box dimension of SC signal is D(s) = 1.

2. (b) When the samples of a SC signal are not monotonic, according to the relation of three points in the same plane, we can get P − Q < |s(t _2i−1) − s(t _2i)| + |s(t _2i) − s(t _2i+1)| ≤ 2(P − Q) and the equality holds for one particular condition that s(t _2i−1) = s(t _2i+1). Similarly, in this case, d(2Δ) ≤ d(Δ) < 2d(2Δ), so the fractal box dimension of a SC signal is 1 < D(s) ≤ 2.

Under normal circumstances, when the oversampling ratio q is large enough, the number of SC signal's samples in case (a) is more than the samples in case (b); thus, the fractal box dimension of SC signal could be assumed to be a little larger than 1. So, the fractal box dimension of a SC signal and OFDM signal has an apparent difference, it could be used for the classification of a signal as a SC or OFDM signal. We set the classification threshold of the fractal box dimension D _J as 1.4 to discriminate OFDM signal and SC signal. By comparing the fractal box dimension of income signal ς to the threshold D _J, the received signal is classified as OFDM signal if $\varsigma >D_J $ or SC signal if $\varsigma <D_J $. The performance of the algorithm depends on the SNR. If SNR is relatively high, the algorithm will have a good performance. However, if SNR is very low, the Gaussian noise power is large enough, and the Gaussian noise distribution is random, its fractal box dimension is close to OFDM signal, thus we cannot identify OFDM signal in the Gaussian noise using this algorithm. In such a case, a new method to detect an OFDM signal in the Gaussian noise with a wide range of SNR value is proposed.

B) Detect OFDM signal in the Gaussian noise

Now we assume the transmitted OFDM signal to be s(t), and P _OFDM (w) is the power spectrum of an OFDM signal. In order to detect an OFDM signal in the Gaussian noise, we use a novel feature named PIS, which is defined as the power spectrum of an OFDM signal's power spectrum. The technique fully uses quasi-period characteristics in the signal frequency domain and tests OFDM signal components submerged in the Gaussian noise, thus realize OFDM signal detection. The PISPIS of OFDM is given as:

(16)$$S(t\prime )=\vert FFT[P_{OFDM} (w)]\vert ^2=\vert FFT[\vert FFT[s(t)]\vert^2]\vert^2.$$

The autocorrelation function of the OFDM signal can be obtained by inverse Fourier transformation of the power spectrum, so the PIS of OFDM can be rewritten as:

(17)$$S(t\prime )=K\vert R_{OFDM} (-\tau )\vert ^2=K\vert R_{OFDM} (\tau )\vert^2,$$

where K is a constant, R _OFDM (τ) is the autocorrelation function of an OFDM signal under the given time delay and has even symmetry. The autocorrelation function of an OFDM signal would appear as a periodical peak induced by cyclic prefix, and the PIS of an OFDM signal represents modulus square of autocorrelation function and has higher periodic characteristics than the autocorrelation function.

When OFDM signal is mixed with Gaussian noise, the received OFDM signal can be expressed as:

(18)$$x(t)=s(t)+w(t).$$

The power spectrum of the Gaussian noise w(t) is P _n (w) = N ₀, and the noise and signal are assumed to be independent, thus the power spectrum of the received signal is:

(19)$$ P_x (w)=P_{OFDM} (w)+P_n (w). $$

By replacing equation (19) into equation (16), we can get the PIS of the received signal:

(20)$$\eqalign{S(t\prime) & = \vert FFT[P_x (w)]\vert ^2=\vert FFT[P_{OFDM} (w)+N_0 ]\vert^2 \cr & = \vert FFT[N_0 ]\vert ^2+\vert FFT[P_{OFDM} (w)]\vert ^2 \cr & \quad +2\vert FFT[N_0]FFT[P_{OFDM} (w)]\vert \cr & = \vert N_0 2\pi \delta (t\prime )\vert ^2+K\vert R_{OFDM} (t\prime)\vert ^2 \cr & \quad +\vert 2N_0 2\pi R_{OFDM} (0)\delta (t\prime )\vert.}$$

From equation (20), it is known that the signal additive noise PIS result is linked with autocorrelation function of signal and average power of noise. For OFDM signal, its autocorrelation function contains narrow pulse periodically appearing. Narrow pulse is a Sa function compressed from an OFDM signal with T _S width and its width is about 1/B, B is the bandwidth of OFDM signal, then it has T _S B times of gain. But the noise after spectrum reprocessing has not processed gain except for zero point. Therefore, the PIS-based detecting method improves the output SNR, and has higher detecting capability. So the PIS can add the non-linear operation to the power spectrum (such as logarithm, evolution, etc.) to suppress multiplicative interference and strengthen the characteristic of the spectrum line, and extract signal feature parameters more accurately. Then we can definite a new detection characteristic to detect OFDM signal in the Gaussian noise according to the periodical peak of OFDM signal's PIS:

(21)$$J=\displaystyle{{J_1 +J_2 +\cdots +J_Y }\over{J_{12} +J_{23} +\cdots +J_{Y-1} J_Y}},$$

where {J ₁, J ₂, …, J _Y} represents the periodical peak sequence of OFDM signal's PIS, {J ₁₂, J ₂₃, …, J _Y−1 J _Y} is the mean value sequence between adjacent periodical peak. Through the theory analysis, we could know that the detection characteristic of OFDM signal is much larger than the noise's, then we could set a reasonable detection threshold J _D to detect OFDM signal in the Gaussian noise by comparing the detection characteristic of incoming signal γ to the threshold J _D. If γ > J _D, we could conclude that the received signal exists OFDM signal. Otherwise, the received signal is considered as Gaussian noise.

C) OFDM signal detection algorithm flow

This section describes the algorithm flow of the identification for OFDM signal as below.

1. (1) Replacing the received signal into equations (6) and (14), we can get d(Δ) and d(2Δ), then according to equation (5), we compute the fractal box dimension of the received signal using d(Δ) and d(2Δ).

2. (2) Setting the classification threshold D _J to discriminate the OFDM signal and SC signal. By comparing the fractal box dimension of incoming signal ς to the threshold D _J, the received signal is classified as OFDM signal if $\varsigma >D_J $ or SC signal if $\varsigma <D_J $.

3. (3) Judging the received signal as OFDM signal with Gaussian noise, we could substitute the received OFDM signal into equation (20) to calculate the PIS of an OFDM signal.

4. (4) Detecting the location of periodical peak of the received signal first and then compute the periodical peak sequence of OFDM signal's PIS thanks to the peak location. Replacing the sequence into equation (21), we can get the classification feature J.

5. (5) Setting the detection threshold J _D to detect OFDM signal with Gaussian noise by comparing the detection characteristic of incoming signal γ to the threshold J _D. If γ > J _D, we could conclude that the received signal exists OFDM signal. Otherwise, the received signal is considered as Gaussian noise.

A) The fractal box dimension of OFDM and SC signal

In this section, in order to demonstrate the difference between the fractal box dimension of OFDM and SC signal, we compare the fractal box dimension of OFDM with six modulation types of SC, including BPSK, QPSK, 8PSK, 16QAM, 64QAM, and 256QAM. The range of SNR is [ − 20, 20]dB, step is 5 dB, we consider a perfect time and frequency synchronization context, and the fractal box dimension of OFDM and SC (SC) is presented in Fig. 1.

Fig. 1. The fractal box dimension of OFDM and SC.

Figure 1 illustrates the fractal box dimension of OFDM and SC. As shown in the figure, the fractal box dimension of the two types of signal is easy to be affected by noise, and the fractal box dimension of OFDM and SC is aliasing together and not easy to distinguish when the SNR is lower than −5 dB, this result was caused by Gaussian noise. High Gaussian noise in the signal would lead to the fractal box dimension of the received signal to be close to that of the Gaussian noise, and the fractal box dimension of the Gaussian noise is close to OFDM's fractal box dimension. Thus, in this scenario, it is difficult to classify the OFDM signal and SC signal. When the SNR rises to 5 dB, the two types of signal have obvious difference. With the SNR rising up, the fractal box dimension of the two types of signal is settled out, the fractal box dimension of OFDM signal is nearly close to 1.415, and the fractal box dimension of SC signal is nearly close to 1, and the experimental result is in accordance with the theoretical analysis.

B) Performance of classification method for OFDM and SC signal

In order to test the robustness of our identification method based on fractal box dimension (denoted by FDB) to short cyclic prefix OFDM signal and the performance under different SNR, we present the correct detection probability for the autocorrelation-based method (denoted by AC) versus SNR when short cyclic prefix OFDM lengths have been employed $(\hbox {CP ratio}=\{1/8, /16, 1/32\})$ and the average correct probability under different CP ratio been evaluated as the number of correct detection. The range of SNR is [ − 10, 10] dB, step is 2 dB.

Figure 2 illustrates the detection probability versus SNR for short CP of two algorithms. From the figure, we can remark that the FDB algorithm provides a better performance under $\hbox {CP ratio}={\{}1/8, /16, 1/32{\}}$. The correct detection probability of the FDB algorithm is nearly reached 100% at SNR equal to 2 dB. In contrast, the correct detection probability of AC algorithm under $\hbox {CP ratio} = {\{}1/8, /16, 1/32{\}}$ is lower than 60, 40, and 10%, respectively. So, the FDB algorithm is more robust than short cyclic prefix OFDM identification algorithm. Actually, this can be easily explained as follows: the identification method for OFDM is based on the correlation of signal symbol induced by cyclic prefix, when the cyclic prefix becomes short, the correlation between OFDM symbols is degrading, and the performance of AC algorithm based on correlation fails down while the FDB algorithm still works well. Notice that standard CP differs from 1/32 (DVB-T in France) to 1/4 (WiFi); consequently, the FDB algorithm is more appropriate for the cognitive radio than the autocorrelation-based method.

Fig. 2. The correct detection probability versus SNR for short CP of two algorithms.

C) Complexity analysis of the FDB algorithm

In this section, the computation reduction of the proposed algorithm is shown in detail. Let L be the total number of OFDM signal samples, the computational load needed for the FDB algorithm and the other two identification algorithms are shown in Table 1.

Table 1. Computational load of three algorithms.

The comparison of the computational complexity between the proposed algorithm and the other two identification algorithms is listed in Table 1; we can remark from Table 1 that the cyclostationary detecting OFDM signal method (the method of [Reference Cao, Peng, Dong and Wang6]) requires the exploration of a wide range of time delay and computational load is a little high. The method of [Reference Guo and Yu11] used the high-order cumulants of OFDM signal and SC signal to achieve the classification. But the method brings in the eighth cumulants, whose mathematics model is very complex. By analyzing the complexity of above mentioned algorithms, we can discover that the proposed algorithm has lower computational complexity than the other two algorithms.

D) The PIS classification feature of OFDM signal and the Gaussian noise

In this section, we present the PIS classification feature of OFDM signal and the Gaussian noise. The range of SNR is [ − 20, 20] dB, step is 5 dB.

Figure 3 describes the classification feature of OFDM signal and the Gaussian noise at different SNR, from the figure we can know that the classification feature of OFDM signal and Gaussian noise show subtler difference when the SNR is below −15 dB, in this case, it is hard to detect OFDM signal in the Gaussian noise. With the improvement of SNR, the difference between the classification feature of OFDM signal and the Gaussian noise becomes larger. When the SNR rise to −5 dB, the classification feature of OFDM signal and the Gaussian noise can be separated from each other, at this time we can detect OFDM signal in the Gaussian noise.

Fig. 3. The classification feature of OFDM signal and the Gaussian noise.

E) Recognition probability of classification method for OFDM signal in the Gaussian noise

In this section, we present the recognition probability of the proposed algorithm for OFDM signal in the Gaussian noise and compare the result with the algorithm proposed in [Reference Punchihewa, Zhang, Dobre, Spooner, Rajan and Inkol7]. The range of SNR is [0, 10]dB, step is 2 dB.

Table 2 illustrates the recognition probability of the proposed algorithm and the algorithm proposed in [Reference Punchihewa, Zhang, Dobre, Spooner, Rajan and Inkol7]. It is clear that under the SNR given in Table 2, the proposed algorithm can correctly detect OFDM signal in the Gaussian noise, and the recognition probability almost reached 100% when $\hbox {SNR}=0\,\hbox {dB}$. If we compare these results with the algorithm proposed in [Reference Cao, Peng, Dong and Wang6], we could find that the recognition probability of the algorithm proposed by [Reference Punchihewa, Zhang, Dobre, Spooner, Rajan and Inkol7] is lower than the proposed algorithm at every SNR. Thus, it can be concluded that the proposed algorithm is more suitable for detecting OFDM signal in the Gaussian noise than the conventional method.

Table 2. Recognition probabilities under different SNR.