Stepped-frequency waveform may be used to synthesize a wideband signal with several narrow-band pulses and achieve a high-resolution range profile without increasing the instantaneous bandwidth. Nevertheless, the conventional stepped-frequency waveform is Doppler sensitive, which greatly limits its application to moving targets. For this reason, this paper proposes a waveform design method using a staggered pulse repetition frequency to improve the Doppler tolerance effectively. First, a generalized echo model of the stepped-frequency waveform is constructed in order to analyze the Doppler sensitivity. Then, waveform design is carried out in the stepped-frequency waveform by using a staggered pulse repetition frequency so as to eliminate the high-order phase component that is caused by the target's velocity. Further, the waveform design method is extended to the sparse stepped-frequency waveform, and we also propose corresponding methods for high-resolution range profile synthesis and motion compensation. Finally, experiments with electromagnetic data verify the high Doppler tolerance of the proposed waveform.
Stepped-frequency waveform may be used to synthesize a wideband signal with several narrow-band pulses and achieve a high-resolution range profile without increasing the instantaneous bandwidth. Nevertheless, the conventional stepped-frequency waveform is Doppler sensitive, which greatly limits its application to moving targets. For this reason, this paper proposes a waveform design method using a staggered pulse repetition frequency to improve the Doppler tolerance effectively. First, a generalized echo model of the stepped-frequency waveform is constructed in order to analyze the Doppler sensitivity. Then, waveform design is carried out in the stepped-frequency waveform by using a staggered pulse repetition frequency so as to eliminate the high-order phase component that is caused by the target's velocity. Further, the waveform design method is extended to the sparse stepped-frequency waveform, and we also propose corresponding methods for high-resolution range profile synthesis and motion compensation. Finally, experiments with electromagnetic data verify the high Doppler tolerance of the proposed waveform.
Entities:
Keywords:
Doppler tolerance; radar waveform design; sparse stepped-frequency waveform (SSFW); staggered pulse repetition frequency (SPRF); synthetic wideband signal
The wideband imaging ability is one of the most important functions of modern radar that
may provide high-resolution information about targets. Wideband signals may be roughly
divided into two categories, i.e., instantaneous wideband signals and the synthetic ones
[1]. The instantaneous wideband
signal achieves a wide bandwidth within a single pulse, which has the advantages of a short
observation duration and a simple signal processing method. However, it has high
requirements for hardware, which raises the cost of the radar system or even makes it
unrealizable. The synthetic wideband signal, such as the stepped-frequency waveform (SFW),
achieves a wide bandwidth by a sequence of pulses that is called a burst. Each burst has
different carrier frequencies, and a wide bandwidth may be achieved by the synthetic
processing method. In general, a synthetic wideband signal can be realized more easily for
engineering practice due to its instantaneous narrow bandwidth.The SFW has been used in radar systems [2,3], and different intra-
and inter-sub-pulse modulation methods are applied. For instance, intra-sub-pulse modulation
includes a single-frequency signal, a linear frequency modulation signal, a phase, or a
frequency-coded signal [4,5], and inter sub-pulse modulation
includes a linear frequency-stepping signal and a random or coded frequency-hopping signal
[6,7]. In recent years, many studies on the SFW have been
presented to improve radar imaging quality and anti-jamming ability, such as the
compensation methods of system error [8,9], grating lobe
suppression [10,11], and velocity compensation [12,13]. However, the duration of the SFW burst is too long,
which leads to a reduction in detection efficiency and Doppler sensitivity, limiting its
application to various scenes [14].
Therefore, to reduce the total duration, the sparse SFW (SSFW) has been designed for sparse
target scenes [15]. Normally, the
SSFW may reduce the number of sub-pulses without changing the synthesis bandwidth.
Meanwhile, the sparse frequency band has a low probability of intercept (LPI), which
improves the anti-jamming ability [16]. The research on the SSFW mainly includes waveform optimization, which may
reduce the grating lobe caused by spectrum sparsity [17]. Further, methods of sparse basis functions’
adaptive optimization [18] as well
as motion estimation and compensation [19] are proposed to attain better reconstructed performance.Nevertheless, both the SFW and the SSFW are still Doppler sensitive. It means a small
velocity compensation deviation will lead to a serious decrease in imaging quality. Thus,
this characteristic greatly limits the application of the SFW. For this problem, the current
research is carried out from two aspects. On the one hand, the velocity measurement
compensation algorithm is studied. In [20], velocity measurement combines cross-correlation and range Doppler coupling.
Meanwhile, a new algorithm was proposed based on the high-precision echo model in [21]. Based on the SSFW, the authors in
[22] divide the translational
motion into two parts, called the inter-pulse and the inter-burst translational motion, and
they jointly design the cost function and estimate of motion parameters by using particle
swarm optimization. In [23],
two-dimensional motion compensation is achieved by the auto-focus algorithm in sparse
reconstruction. On the other hand, the waveform design method is proposed. For instance, a
new modulation format of chirp radars with stepped frequency is designed synthetically in
[24] to remove range migration in
detecting high-speed targets. In [25], it is shown that the complementary code is designed to eliminate the coupling
relationship between range profile and velocity, thus improving the accuracy of velocity
measurement. Then, the SFW with a different pulse repetition frequency (PRF) is designed for
phase cancellation to eliminate the phase deviation caused by velocity [26,27]. However, the waveform design methods above focus on
improving the accuracy of velocity or processing multiple bursts jointly but not on
extending the Doppler tolerance directly in one burst of the SFW.Doppler sensitivity is a common problem existing in the radar measurement for moving
targets. Therefore, many researches are devoted to radar waveform design in order to extend
the Doppler tolerance, such as the frequency and phase-coded waveform [28,29], piecewise modulation waveform [30] and hyperbolic frequency modulation waveform with
Doppler invariance [31]. However, in
practical applications, the frequency phase-coded waveform performs poorly due to the error
in code switch, and the piecewise modulation waveform is actually an approximation of the
ideal high-Doppler-tolerance waveform. Although the hyperbolic frequency modulation waveform
has inherent Doppler invariance, the characteristic is only reflected in a single pulse. The
proposed waveform is based on the SFW for high Doppler tolerance, which has fixed the
frequency points and instead a staggered PRF (SPRF) [32,33,34,35,36]. Moreover, the modulation performance of the
proposed waveform is similar to the hyperbolic frequency modulation waveform, and it is able
to synthesize a high-resolution range profile (HRRP) with high quality.The waveform design method is extended to the SSFW and the synthetic wideband signal by
compressed sensing (CS). Nowadays, CS has developed a set of effective theories [37], which are widely used in the HRRP
[38], SAR [39], and ISAR [40]. Especially in the air scene, the radar target is
sparse relative to the observation window. Thus, we still get focusing results by CS when
the spectrum of the waveform is incomplete [41]. In addition, electromagnetic data of an unmanned aerial vehicle (UAV) are
used to verify the effectiveness of the proposed waveform design method [42]. Because the UAV has been widely
used in life, disaster relief, and even war, and has become popular in the field of radar
recognition, it is worth using these electromagnetic data to verify the proposed waveform
[43,44].
2. Signal Model and Analysis
2.1. Generalized Echo Model of the SFW and SSFW
The CPRF-SFW transmits multiple sub-pulses with a stepped carrier frequency and constant
PRF so as to improve the range resolution and synthesize wideband signals. However, the
SPRF-SFW modulates the PRF to the staggered one. If the time component is expressed as the
sum of fast time and slow time, ,
then one burst of the transmitted SPRF-SFW signal is expressed as:
where
is the waveform structure of the sub-pulse and
is the carrier frequency.
represents the linear frequency step mode. The initial carrier frequency is
,
and the step frequency is .
One burst includes M sub-pulses, and the pulse repetition interval of each sub-pulse is
,
,…,
.
Thus, the transmitting time is presented as .
Specifically, when ,
it will change to the CPRF-SFW.Further, the SSFW only selects several frequencies for transmission compared with the
SFW.
is the number of selected sub-pulses.
is the selected carrier frequencies of the sub-pulse. Thus, the degree of spectrum
integrity of the SSFW is defined as .
The higher the degree of spectrum integrity is, the more the sub-pulses are, and the
SPRF-SSFW transmission signal is expressed as follows:
where the selected carrier frequency is
and the selected mode is ,
.
Specifically, when ,
it will change to the CPRF-SSFW [15]. The waveforms of the CPRF-SFW, CPRF-SSFW, SPRF-SFW, and SPRF-SSFW based on
this model are presented in Figure
1, where
is the sub-pulse width,
is the sub-pulse bandwidth, and
is the synthetic bandwidth.
Figure 1
Time–frequency profile of (a) CPRF-SFW, (b) CPRF-SSFW,
(c) SPRF-SFW, and (d) SPRF-SSFW.
Moreover, the echo of the SPRF-SFW is analyzed. Suppose the initial distance between
target and radar is .
The radial velocity of the target is defined as , which is
positive when the target is away from the radar. The velocity of the electromagnetic wave
is .
Therefore, the two-way path delay under the initial distance is
and under the
sub-pulse is .
Therefore, the base-band echo signal of the SPRF-SFW is expressed as:The model above is actually the generalized echo model of the SFW, which is composed of
intra-pulse and inter-pulse terms. After constructing the model, the processing methods of
the synthetic HRRP and the reasons of the Doppler sensitivity for CPRF waveforms are
analyzed based on it.
2.2. Analysis of Doppler Sensitivity for CPRF Waveforms
The common signal processing method of the synthetic range profile is called twice pulse
compression: one is intra-pulse compression, and the other is inter-pulse compression. The
intra-pulse compression is to perform matched filtering on each sub-pulse, and the result
of it is related to the waveform structure of a sub-pulse that can be a single-frequency,
chirp and phase, or frequency-coded signal. Without loss of generality, we deduce the
signal processing method with chirp, and the waveform structure of sub-pulse is expressed
as:
where
is the rectangular window function and
is the slope of sub-pulse chirp. Thus, according to Equation (3), the base-band echo is
expressed as:Further, the obtained signal after intra-pulse compression is expressed as the structure
of amplitude and phase, namely:
where
and the inter-pulse phase term is .
We find that the velocity of the target makes the peak of the intra-pulse compression
shift from
to
and makes the peak value from 1 to .
The results of intra-pulse compression are different in different waveform structures.
Nevertheless, if the sub-pulse is a single-frequency signal, the bandwidth will be the
reciprocal of the time width, which is not favorable for increasing the bandwidth and time
width at the same time. Similarly, if the sub-pulse is a phase-coded signal, the result of
pulse compression will be so sensitive to velocity that motion compensation would be
difficult. Thus, the chirp signal is usually used in sub-pulse.When the spectrum is complete, the phase term of the CPRF-SFW is:The phase term, which includes the stationary phase caused by the radial distance of
static target, is ,
including only the primary phase, but the motion phase caused by the velocity of the
moving target is ,
including the primary phase and the quadratic phase. As a result, when inverse fast
Fourier transform (IFFT) is used during inter-pulse compression, imaging defocusing occurs
due to the existence of the quadratic phase term. In addition, the position of the target
is
and the broadening is
which is obtained by the use of the stationary phase method.Further, when the spectrum is incomplete, the phase term of the CPRF-SSFW
is:The stationary phase is ,
and the motion phase is .
Thus, when the CS algorithm is adopted during inter-pulse compression, the two phase terms
above cannot be expressed by a unified basis, which leads to the defocusing of the
synthetic HRRP.In conclusion, the reason for Doppler sensitivity for the conventional CPRF waveform is
the high-order phase component and filter mismatch caused by a moving target.
3. Design and Processing Method of SPRF Waveforms for High Doppler Tolerance
3.1. Waveform Design Method
After analyzing the Doppler sensitivity of CPRF waveforms, if the carrier frequencies of
sub-pulses are determined, the Doppler tolerance may be improved by staggering the PRF of
the sub-pulse.By analyzing Equation (8), the design of the SPRF-SFW with high Doppler tolerance should
meet the following two conditions.Condition 1: The PRF of the sub-pulse is modulated so that the high-order phase is
eliminated in .Condition 2: The pulse repetition interval (PRI), which is the reciprocal of the PRF,
should have physical meaning that should be greater than zero. Thus, the condition 1 is
expressed as:
where
is a constant, which represents the weighting coefficient. Thus, Equation (10) is solved
as:At this time, the modulation mode of
has met condition 1. Further, we give it physical meaning and connect it with the constant
of the CPRF-SFW. Thus, we make ,
and the transmitting time of each sub-pulse
is rewritten as:
where
is a waveform parameter, which determines the value range of the PRI.As for condition 2, it is expressed as:
where
is the minimum value of the PRI. We substitute the transmission time of each sub-pulse
into Equation (13), and condition 2 is rewritten as:The SPRF-SFW under a negative frequency modulation slope is also designed by this method.
Then, they are simplified to the following expression:In addition, further analysis shows that when the waveform parameter
,
the PRI of each sub-pulse is ,
which is a monotonic increasing function. When the waveform parameter
,
the PRI of each sub-pulse is ,
which is a monotonic decreasing function, as shown in Figure 2.
Figure 2
Pulse repetition interval of conventional CPRF-SFW and proposed SPRF-SFW with the
waveform parameters shown in Table
1.
Further, when the spectrum is incomplete, the design of the SPRF-SSFW with high Doppler
tolerance should also meet two conditions. Condition 2 remains unchanged, but Condition 1
changes to the following: the PRF of the sub-pulse is modulated so that the motion phase
and the stationary phase
are expressed by a unified basis. Then, the transmitting time of each sub-pulse
is expressed as:
where is the coding law
of the transmission frequency. When the waveform parameter ,
, which is equal to
the spectrum selection of positive frequency modulation coding. When the waveform
parameter ,
, which is equal to
the spectrum selection of negative frequency modulation coding. The time–frequency
profiles of waveforms designed by the proposed method using the SPRF are shown in Figure 3.
Figure 3
Time–frequency profile of (a) SPRF-SFW and (b)
SPRF-SSFW designed by the proposed waveform method.
In conclusion, the waveform design method of SPRF waveforms with high Doppler tolerance
is proposed. At the same time, as one of the staggered PRF waveforms, the SPRF-SSFW also
has the characteristics of improving blind speed: the minimum blind velocity is increased
from the constant PRF to the least-common-multiple PRF of each sub-pulse.In addition, Doppler tolerance is defined as the corresponding value when the pulse
compression gain drops to the minimum allowable level, which is expressed as:
where
is the peak amplitude after pulse compression and
is the minimum allowable gain. Thus, the imaging results for different velocities and the
curve of pulse compression gains versus velocities are shown in Figure 4.
Figure 4
Comparison of imaging results under different waveforms at different velocities:
(a) 20 m/s and (b) 100 m/s. (c) Curve of pulse
compression gains versus velocities with the waveform parameters shown in Table 1.
Furthermore, by analyzing the echo model of the CPRF-SFW and SPRF-SFW, we get the
ambiguity function of the synthetic wideband signal by twice pulse compression
as:The contour maps of the ambiguity function for the two kinds of SFW, which have the same
waveform parameters, after wideband synthesis are shown in Figure 5. Figure 5a is the ambiguity function of the CPRF-SFW,
and Figure 5b is the ambiguity
function of the SPRF-SFW. Both of them have range velocity coupling. However, when the
velocity deviates, the broadening of the ambiguity function of the CPRF-SFW is obvious,
which is the reason for the defocusing synthetic HRRP. In contrast, the ambiguity function
of the proposed SPRF-SFW has no broadening, which means high Doppler tolerance.
Figure 5
Ambiguity functions of (a) conventional CPRF-SFW and (b)
proposed SPRF-SFW.
3.2. Synthetic HRRP and Motion Compensation Process
The synthetic HRRP for the proposed SPRF-SSFW with high Doppler tolerance is also
processed by twice pulse compression, as shown in Figure 6. Because the SPRF is only one inter-pulse
modulation way, the intra-pulse compression is still the same for CPRF waveforms.
Figure 6
The flowchart of processing the proposed waveform.
First, when the spectrum is complete, the phase term of the proposed SPRF-SFW is
expressed as:The phase term includes the stationary phase
and the motion phase .
Thus, none of them contains a quadratic or high-order phase term. The inter-pulse
compression by IFFT is expressed as:In this case, the range profiles without defocusing are obtained, and the target position
is .Then, when the spectrum is incomplete, the phase term of the proposed SPRF-SSFW is
expressed as:The phase term includes the stationary phase
and the motion phase .
Thus, the two phase-terms above are expressed by a unified basis.The sparse characteristics of the target are used in processing of the SPRF-SSFW, and the
CS algorithm is proposed to transform the target imaging into a parameter estimation
optimization problem. The measurement process is expressed as:
where the matrix is expressed in bold, is the
measurement value vector, and
is the echo of the i-th sub-pulse.
represents the target to be reconstructed, and
is the amplitude of the i-th resolution unit. is
the sensing matrix with ,
is the measurement matrix with ,
and
denotes the basis matrix with .
The target is sparse, which means that most of the elements in matrix
are
zero or minimum. Thus, the solution of the measurement process is transformed into the
norm optimization problem as follows:The
norm optimization problem is a nondeterministic polynomial problem. Thus, in the process
of optimization, it is usually relaxed to an
norm optimization problem. At the same time, considering the influence of weak scattering
points and noise, the final optimization problem is expressed as follows:
where
represents one minimum value, the sensing matrix ,
and the measurement matrix
is usually set as a Gaussian random matrix, which expresses the influence of thermal noise
in a single channel of the radar receiver. According to Equation (21), the elements of the
basis matrix designed for the SPRF-SSFW, ,
are as follows: where
is the synthetic
range resolution and
is the synthetic bandwidth.As for the optimization method, greedy algorithms, such as orthogonal matching pursuit,
are used to solve this problem. CS methods have made great progress, and to improve the
reconstruction efficiency, we use the joint-block sparse method for reconstruction [37,38]. The flowchart of the joint-block sparse CS
algorithm is shown in Figure
7.
Figure 7
The flowchart of the joint-block sparse CS algorithm.
According to the analysis, the proposed SPRF waveform has high Doppler tolerance and has
a focusing range profile of the moving target. However, the migration of the range profile
still appears, which is not conducive to the accumulation of multi-frame imaging.
Therefore, it is necessary to carry on the correlation velocity measurement and motion
compensation.The echo motion compensation of the SPRF waveform is similar to that of the CPRF [21,22], which usually consists of two steps: intra-pulse
range alignment and inter-pulse phase compensation, as shown in Figure 6. It is necessary to go on the intra-pulse
range alignment when the echo envelope movement cannot be ignored in a single frame. It
effectively accumulates the intra-pulse compression results in the burst, reduces the loss
of amplitude, and obtains the synthetic HRRP effectively. The envelope alignment step
should ensure that the envelope movement caused by the residual velocity error is less
than half of the sub-pulse resolution, which is expressed as ,
namely:The requirement of intra-pulse range alignment is not high, which is called coarse motion
compensation. Generally, intra-pulse range alignment is attained by system measurement or
intra-pulse correlation velocity measurement [21]. After intra-pulse envelope alignment, the target
is located in the same range resolution cell, and inter-pulse compression is
performed.In inter-pulse phase compensation, we obtain the motion parameters by the difference in
the range profile. In the radar system, the difference in the synthetic range profile is
obtained by the adjacent correlation method, and the velocity of the target is further
obtained as .
The velocity measurement error should meet the requirement that the range difference is
not greater than the resolution of the synthetic range profile ,
and then the velocity measurement error is expressed as:The requirement of inter-pulse phase compensation is high, which is called fine-motion
compensation [22]. Furthermore,
the difference in the proposed SPRF waveform is more accurate than the CPRF waveform due
to the synthetic range profile without defocusing. After processing, the estimated motion
parameters of the target are obtained.Furthermore, it is necessary to consider the influence of the target’s
acceleration on motion compensation [23]. If the acceleration of the target is defined as and the
two-way path delay is ,
the base-band signal with uniform acceleration is presented as:Further, the motion compensation term is expressed as:
where
represents the estimated velocity,
represents the estimated acceleration, and
denotes the peak position after intra-pulse compression, used as the reference time delay.
Thus, the SPRF-SSFW base-band echo after accurate motion compensation is expressed
as:
where
represents the residual velocity,
represents the residual acceleration after motion compensation, and
is the two-way delay of the difference between the reference point and each scattering
point. The result shows that to ensure that the defocusing caused by acceleration is
ignored, it is necessary to meet the following requirements:In addition,
is small and the phase term related to
is approximately constant, so the results of the SPRF-SSFW base-band echo after motion
compensation are consistent with the results for a stationary target.
4. Experiment and Discussion
In this section, three simulation experiments combined with the electromagnetic data of the
UAV are presented to verify the effectiveness of the proposed waveform design method. First,
the proposed SPRF-SFW is compared with the conventional CPRF-SFW in order to verify the
high-Doppler tolerance of the staggered PRF waveform. Second, the proposed SPRF-SSFW is
designed and processed. On the one hand, it is compared with the CPRF-SSFW to verify the
high Doppler tolerance. On the other hand, it verifies the effectiveness of the processing
algorithm based on CS. Third, the velocities of target and waveform parameters are changed
to verify the effectiveness of the waveform design method for high Doppler tolerance under
different conditions.In addition, the ideal HRRP and ISAR images obtained from the electromagnetic data of the
UAV at a certain angle are shown in Figure
8 and are used as benchmarks to compare with the imaging results of the designed
waveform.
Figure 8
Ideal radar image using UAV electromagnetic data: (a) HRRP and
(b) ISAR.
Further, the evaluation factors are set as the signal-to-noise ratio (SNR) and the main
lobe width
for the HRRP image and the image entropy
and the image contrast
for the ISAR image. The SNR is defined as the ratio of the peak power of the
pulse-compression-result-to-noise variance, which is expressed as:
where
is the peak amplitude,
is the amplitude of the starting point,
is the amplitude of the ending point,
is the number of the protecting points around the target, and
represents the variance function. Thus, the higher the SNR is, the higher the imaging
quality is.The main lobe width was defined as the corresponding broadening at half of the peak, which
is expressed as:
where
is the amplitude of the range profile. Thus, the narrower the main lobe width is, the higher
the imaging quality is.The image entropy is expressed as:
where
is the amplitude of the imaging point. Thus, the lower the image entropy is, the higher the
imaging quality is. In addition, according to [45], the image contrast is expressed as:Thus, the higher the image contrast is, the higher the imaging quality is.
4.1. Experiment I: SPRF-SFW
This subsection shows the HRRP and ISAR images to verify that the proposed SPRF-SFW has
high Doppler tolerance. The design of the SPRF-SFW is carried out under the condition that
the carrier frequencies obey the linear law with ,
and the same parameters of the SPRF-SFW and CPRF-SFW are shown in the Table 1. In addition, the target is
the UAV electromagnetic data.
Table 1
The same parameters of the SPRF-SFW and CPRF-SFW.
Parameters
Symbols
Value
Initial carrier
frequency
f0
9 GHz
Sub-pulse
bandwidth
Bp
20 MHz
Sub-pulse
width
Tp
20 µs
Synthesis
bandwidth
Ω
2 GHz
Number of
sub-pulses
M
100
Burst
duration
TM
20 ms
Sampling rate
fs
40 MHz
Azimuth
bandwidth
Ba
750 MHz
We further obtain the range resolution as 0.075 m, and the azimuth resolution is 0.2 m.
To compare the SPRF-SFW with the CPRF-SFW, their burst durations are equal, that is,
.
Then,
is satisfied, and the waveform parameter
is represented as:Therefore, the PRI of the CPRF-SFW is ,
and the PRI of the SPRF-SFW is obtained according to Equation (15), among which the
maximum repetition interval is ,
the minimum repetition interval is ,
and other PRIs are shown in Figure
2. The time–frequency curves of the CPRF-SFW and the proposed SPRF-SFW
under the designed parameters are presented in Figure 9.
Figure 9
Time–frequency curves of conventional CPRF-SFW and proposed SPRF-SFW with
simulation data.
The base-band signal of the SRPF-SFW with acceleration is discussed in the above waveform
parameters. According to Equation (31), to ensure that the defocusing caused by
acceleration is ignored, the residual acceleration after motion compensation should meet
.
It is easy to be satisfied for aerodynamic targets. The residual velocity after coarse
motion compensation is set as 20 m/s, which is far away from the radar direction, in order
to better reflect the advantage of the proposed waveform. The received signal is
contaminated by additive white complex Gaussian noise. Then, the SNR after intra-pulse
compression is set as 16 dB, and the theoretical SNR is 26 dB after inter-pulse
compression with 100 pulses. Therefore, the synthetic HRRPs of the conventional CPRF-SFW
and the proposed SPRF-SFW are shown in Figure 10, and the ISAR images are shown in Figure 11.
Figure 10
HRRP synthesis with conventional CPRF-SFW and proposed SPRF-SFW.
Figure 11
ISAR images with (a) conventional CPRF-SFW and (b) proposed
SPRF-SFW.
As shown in Figure 10, the blue
solid line is the synthesis HRRP of the CPRF-SFW and the red solid line is the synthesis
HRRP of the SPRF-SFW. The imaging offset of the SPRF-SFW caused by the target motion is 2
m, which is consistent with the theoretical analysis. Additionally, compared with Figure 8a, it is observed that the
CPRF-SFW imaging has both offset and defocusing caused by the target motion, with the SNR
as 16.58 dB and the main lobe width as 0.71 m, while the SPRF-SFW imaging only has offset
without broadening, with the SNR as 25.93 dB and the main lobe width as 0.08 m. For
comparison, the SNR for the HRRP of the SPRF-SFW is higher and the main lobe width is
narrower than that of the CPRF-SFW, which means that the imaging quality of the SPRF-SFW
is higher than that of the CPRF-SFW for the same moving target.The ISAR images of the CPRF-SFW and the SPRF-SFW are shown in Figure 11a,b, respectively. Compared with Figure 8b, the target motion causes
defocusing of CPRF-SFW imaging, with the image entropy as 2484.08 bits and the image
contrast as 2.32, while the proposed SPRF-SFW imaging is focused, with the image entropy
as 1811.15 bits and the image contrast as 3.13. For comparison, the image entropy for ISAR
images of the SPRF-SFW is lower and the image contrast is higher than that of the
CPRF-SFW, which means that the imaging quality of the SPRF-SFW is higher than that of the
CPRF-SFW for the same moving target.Consequently, the above simulation results verify the high Doppler tolerance of the
proposed SPRF-SFW, which makes up for the Doppler sensitivity of the CPRF-SFW, and has
more practical value in complex scenes, especially in an imaging scene with multiple
velocity targets such as target separation due to the difficulty in accurate motion
compensation.
4.2. Experiment II: SPRF-SSFW
In this subsection, the following simulation experiments are carried out when the
spectrum is incomplete to verify that the SPRF-SSFW has high Doppler tolerance and obtains
the wideband synthetic image by the CS algorithm. Therefore, the degree of the
transmission spectrum integrity is set to 0.6. As a result, when compared with simulation
experiment I, the number of sub-pulses is reduced from 100 to 60, the burst duration is
reduced from 20 ms to 12 ms, and the carrier frequency of each sub-pulse is selected by
random coding. Further, the PRI of the sub-pulse is calculated according to Equation (16),
and other parameters are the same as those given in Table 1. The time–frequency curves of the
CPRF-SSFW [15] and the proposed
SPRF-SSFW under the designed parameters are presented in Figure 12.
Figure 12
Time–frequency curves of conventional CPRF-SSFW and proposed SPRF-SSFW with
simulation data.
Due to the incomplete spectrum, the burst duration of the SRPF-SSFW is lower than that of
the SRPF-SFW in experiment I. Thus, the acceleration compensation tolerance of the
SPRF-SSFW is higher. According to Equation (31), the residual acceleration after motion
compensation should meet .
The residual velocity after coarse motion compensation is also set as 20 m/s. Meanwhile,
the synthetic HRRP and ISAR images of the CPRF-SSFW and the SPRF-SSFW are shown in Figure 13 and Figure 14, respectively.
Figure 13
HRRP synthesis with conventional CPRF-SSFW and proposed SPRF-SSFW.
Figure 14
ISAR images with (a) conventional CPRF-SSFW and (b) proposed
SPRF-SSFW.
As shown in Figure 13, the blue
solid line is the HRRP of the CPRF-SSFW and the red solid line is the HRRP of the
SPRF-SSFW. The imaging offset caused by the target motion is 1.2 m, which is consistent
with the theoretical analysis. Moreover, comparing these results with Figure 8a, we observe that the CPRF-SSFW imaging has
both offset and defocusing caused by the target motion, with the SNR as 15.98 dB and the
main lobe width as 0.39 m, while the SPRF-SSFW imaging only has offset without broadening,
with the SNR as 23.95 dB and the main lobe width as 0.08 m. For comparison, the SNR for
the HRRP of the SPRF-SSFW is higher and the main lobe width is narrower than that of the
CPRF-SSFW, which means that the imaging quality of the SPRF-SSFW is higher than that of
the CPRF-SSFW for the same moving target.The ISAR images of the CPRF-SSFW and the SPRF-SSFW are shown in Figure 14a,b, respectively. Compared with Figure 8b, the target motion causes
serious defocusing of CPRF-SSFW images, which is caused by the mismatch of the sensing
basis, with the image entropy as 2712.49 bits and the image contrast as 2.05, while the
SPRF-SSFW imaging has better focusing, and the sensing basis matches well, with the image
entropy as 1947.65 bits and the image contrast as 2.96. For comparison, the image entropy
for ISAR images of the SPRF-SSFW is lower and the image contrast is higher than that of
the CPRF-SSFW, which also means that the imaging quality of the SPRF-SSFW is higher than
that of the CPRF-SSFW for the same moving target.Consequently, the above simulation results verify that the proposed SPRF-SSFW ha high
Doppler tolerance and is processed by the CS algorithm well. Clearly, the SPRF-SSFW has a
shorter burst duration and it is more suitable for a complex electromagnetic
environment.
4.3. Experiment III: Different Conditions
In this subsection, the velocities of target and waveform parameters are changed, and the
evaluation factors for ISAR images of conventional CPRF waveforms [15] (blue star line), optimized CPRF waveforms [11,17] (green cross line), and proposed SPRF waveforms
(red diamond line) are further compared under different conditions in order to verify the
effectiveness of the waveform design method for high Doppler tolerance.First, when the spectrum is complete, the waveform parameters are fixed, as shown in
experiment I, and the residual velocity of target changes. The imaging qualities of the
conventional CPRF-SFW, optimized CPRF-SFW [11], and proposed SPRF-SFW are compared in Figure 15. The image entropy of the
conventional CPRF-SFW increases and the image contrast decreases with velocity, which
corroborates the decrease in imaging quality. The optimized CPRF-SFW increases the imaging
quality in a certain velocity tolerance but decreases significantly when the velocity is
too high. In addition, all evaluation factors of the proposed SPRF-SFW change little,
which verifies the high Doppler tolerance for different velocities.
Figure 15
(a) Image entropy and (b) image contrast for ISAR images
versus different velocities with conventional CPRF-SFW, optimized CPRF-SFW, and proposed
SPRF-SFW.
Then, when the degree of spectrum integrity is set to 0.6, the waveform parameters are
fixed, as shown in experiment II, and the residual velocity of target also changes. The
imaging qualities of the conventional CPRF-SSFW [15], optimized CPRF-SSFW [17], and proposed SPRF-SFW are compared in Figure 16. The image entropy of the
conventional CPRF-SSFW increases and the image contrast decreases with velocity, which
corroborates the decrease in imaging quality. The change is more rapid than that in Figure 15, because the imaging quality
decreases more obviously when the echo of the moving target does not match the CS basis.
The optimized CPRF-SSFW is similar to the conventional one, and the imaging focuses only
when the velocity is low. In addition, all evaluation factors of the proposed SPRF-SSFW
change little, and the imaging quality is stable, which also verifies the high Doppler
tolerance for different velocities.
Figure 16
(a) Image entropy and (b) image contrast for ISAR images
versus different velocities with conventional CPRF-SSFW, optimized CPRF-SSFW, and
proposed SPRF-SSFW.
Next, when the spectrum is complete, the residual velocity of target is fixed as 20 m/s
and the burst duration changes. The imaging qualities of the conventional CPRF-SFW,
optimized CPRF-SFW [11], and
proposed SPRF-SFW are compared in Figure
17. The image entropy of the conventional CPRF-SFW increases and the image
contrast decreases with the burst duration, which verifies that the longer the burst
duration, the lower the Doppler tolerance of the conventional CPRF-SFW. The optimized
CPRF-SFW increases the imaging quality in a certain burst duration but decreases
significantly when the burst duration is too long. In addition, all evaluation factors of
the proposed SPRF-SFW change little, which verifies the high Doppler tolerance for
different burst durations.
Figure 17
(a) Image entropy and (b) image contrast for ISAR images
versus different burst duration with conventional CPRF-SFW, optimized CPRF-SFW, and
proposed SPRF-SFW.
Finally, when the spectrum is incomplete, the residual velocity of the target is fixed as
20 m/s and the degree of spectrum integrity changes. The imaging qualities of the
conventional CPRF-SSFW [15],
optimized CPRF-SSFW [17], and
proposed SPRF-SFW are compared in Figure
18. The image entropy of the conventional CPRF-SSFW is always higher and the
image contrast is always lower, which indicates that the images of the moving targets
defocus under various degrees of spectrum integrity. The optimized CPRF-SSFW has higher
imaging quality than the conventional CPRF-SSFW but also has imaging defocusing. As a
comparison, the image entropy of the proposed SPRF-SSFW increases slowly and the image
contrast decreases slowly when the degree of spectrum integrity is bigger than 0.5. The
main reason for the decrease in imaging quality is the decrease in the SNR, which is
caused by the decrease in the accumulated pulse number. However, when the degree of
spectrum integrity is smaller than 0.5, image entropy increases and image contrast
decreases rapidly, which indicates that the degree of spectrum integrity should not be too
low, otherwise the imaging quality will be affected. The experiment verifies the high
Doppler tolerance of the proposed SPRF-SSFW for a high degree of spectrum integrity.
Figure 18
(a) Image entropy and (b) image contrast for ISAR images
versus different degrees of spectrum integrity with conventional CPRF-SSFW, optimized
CPRF-SSFW, and proposed SPRF-SSFW.
5. Conclusions
In this paper, we proposed a waveform design and a corresponding processing method using
the SPRF to improve the Doppler tolerance of the SFW and the SSFW. Theoretical analysis and
experiments verified that both the SPRF-SFW and the SPRF-SSFW designed by the proposed
method have high Doppler tolerance and a focusing synthetic range profile. In addition, the
SPRF-SSFW processed by CS has not only high Doppler tolerance but also a short burst
duration and low probability of intercept, which improves the anti-jamming ability. Further
work can expand the sub-pulse optimization design to improve the adaptability to maneuvering
targets in a complex electromagnetic environment.
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