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Phase compensation techniques based on projection method and convex optimization (phase correction only) for comparing the maximum gain of a phase-compensated conformal antenna array have been discussed. In particular, these techniques are validated with conformal phased array antenna attached to a cylindrical-shaped surface with various radii of curvatures. These phase compensation techniques are used to correct the broadside radiation pattern. It is shown that the maximum broadside gain compensated is still less than the gain of a linear flat array for any surface deformation. This fundamental maximum compensated gain limitations of the phase compensation techniques can be used by a designer to predict the maximum broadside obtainable theoretical gain on a conformal antenna array for a particular deformed surface.
Electrical and Computer Engineering Department, COMSATS University Islamabad, Pakistan
Shahid Khattak
Electrical and Computer Engineering Department, COMSATS University Islamabad, Pakistan
Benjamin D. Braaten
Electrical and Computer Engineering Department, North Dakota State University, USA
*Address all correspondence to: eengr@cuiatd.edu.pk
1. Introduction
Conformal antenna arrays are beneficial for applications that need an antenna to be placed on a non-flat surface, for example, on the fuselage of a UAV/airplane in the aerospace industry [1, 2, 3], implantable sensors in wearable networks [4, 5, 6, 7, 8], and satellite communications [9, 10, 11]. One of the main advantages of using conformal antenna is its structural integration ability on singly curved (e.g., a wedge/cylinder) [12, 13, 14, 15] and doubly curved (like a sphere) surfaces [16]. This can be very useful in applications where using definite flat surface may not be a practical design choice. Another exciting application of conformal antenna array is at the base station in a cellular mobile communication system. Today, mobile service providers are utilizing three separate antenna panels (dipole or monopole array) in a cell for a 120° sector coverage. What about, if one cylindrical array is used instead of three dipole arrays [17]? This can result in a much smaller transmitter requirement with 360° azimuthal coverage plus reduced base station size at a lower cost (specifically beneficial in crowded residential areas where cellular companies have to rent the space for base station installation).
On the other hand, these curved surfaces may be subjected to intentional (e.g., flexing wings of a UAV/aircraft) and/or unintentional (bending of aircraft wings due to severe weather conditions/vibrations) forces that change the shape of the surface [12]. As a result, the radiation pattern of the conformal antenna array is changed as shown in Figure 1. The results in [18] indicate that directivity of conformal antenna array can be reduced by 5–15 dB. In the literature, various methods have been proposed to compensate the reduction in directivity and to improve/correct the radiation pattern of a conformal antenna array. In [1, 2, 3, 11, 19, 20, 21], mechanical calibration techniques have been used to steer the main beam on a conformal surface in the desired direction. In [12, 13, 15, 16, 22, 23, 24, 25], projection method of [26] is used to correct the main beam direction of a deformed/flex surface. In [27, 28, 29, 30], various optimization algorithms have been used to control the radiation pattern of conformal antenna arrays. In summary, it has been shown that the radiation pattern of a conformal antenna array can be improved with different calibration techniques, signal processing algorithms, sensor circuitry, and phase and amplitude adjustments.
Figure 1.
Array on a conformal surface.
This chapter will focus on phase compensation of four-element conformal cylindrical antenna array using (1) projection method and (2) convex optimization method. First, a brief introduction and working principle of phase compensation is presented using projection method. Then, array factor expression will be derived to compensate the radiation pattern of conformal cylindrical array. Then, the convex optimization algorithm will be discussed to compute the array weights for pattern recovery of conformal cylindrical array. Then, compensated gain using both the methods will be compared to linear flat array to explore the gain limitations of these compensated techniques for conformal antenna arrays. Finally, conclusion and future work are presented.
2. Projection method for pattern recovery of conformal antenna array
The projection method in [26] and its further exploration in [12, 15, 22] are adopted here to describe the behavior of the conformal antenna array shown in Figure 2. For discussion, consider the problem where the flat antenna array is placed on the singly curved surface shaped as a cylinder with radius r as shown in Figure 2. The position of each antenna element on the cylinder is represented as A±n, n=1,2 (for four antenna elements on the cylindrical surface). If each antenna element on the cylindrical surface is excited with uniform amplitudes and phases, that is, if excitation weights wn=1ej0° put on all elements, then the E-fields radiated from the antenna elements will arrive at the reference plane with different phases. This phase difference is due to the different path lengths experienced by the radiated E-fields in the z direction while reaching to the reference plane. Because phases of E-fields radiated from A±1 are not the same as those radiated by A±2, the radiation may not necessarily be constructively added broadside to the array (i.e., with ϕs=90°). If the E-fields E±nejϕ±n from antenna elements are ensured to arrive at the reference plane with the same phase, then constructive interference will result in a broadside radiation pattern and therefore pattern recovery toward the broadside is possible. The delayed phase of E-fields due to free-space propagation −k∆±n from antenna elements on the conformal surface to the reference plane can be compensated (corrected) by exciting the elements with phase advance +k∆±n. This will cause the E-fields from antenna elements to arrive at the reference plane with same phase and will cause constructive broadside radiation pattern in the +z direction.
Figure 2.
Phase compensation of a conformal cylindrical antenna array.
To compute this compensated phase, the antenna elements are projected on the reference plane and then the distances from antenna elements on cylindrical surface (shown as black dots) to the projected elements on the reference plane (shown as dashed circles) are calculated. Suppose ∆−1, ∆−2, ∆2, and ∆1 denote the distances from the elementsA−1, A−2, A2, and A1, respectively, to the reference plane (or the projected elements on the reference plane).
2.1 Computing the distance to the projected elements
The distance from the antenna elements on the cylinder to the projected elements on the reference plane can be computed using:
∆±n=r−rsinϕ±nE1
wherer is the radius of the cylinder and ϕ±n is the angular position of antenna elements on the cylinder. Using the relation of L=rθ, the angular positions of antenna elements can be calculated, where L=λ/2 is the inter-element distance on the cylindrical surface.
2.2 Computing the compensated phase
The required compensated phase to correct the broadside radiation pattern of a conformal cylindrical antenna array in Figure 2 is then given by:
δ±nc=+k∆±nE2
where k is the free-space wave number.
2.3 Array factor expression
To analytically compute the corrected (compensated) radiation pattern and validate with simulation results, the following compensated array factor AFc is used [18, 31]:
AFc=AFejδ±nc,E3
where δ±nc can be computed using Eq. (2) and the array factor (AF) expression for antennas on conformal surfaces is [18]:
AF=∑n=1NFnθϕwnejkxnsinθ+zncosθ,E4
where k is the free space wave number, N is number of antenna elements, xnzn is the location of nth antenna element on the conformal surface, and Fnθϕ is the individual element pattern in Figure 2. wn=Inej∆ϕ is the complex weighting function required to drive the nth antenna element.
For this work, the phase difference ∆ϕ between adjacent antenna elements was made zero, and the amplitude tapering coefficient In was kept equal to 1 (uniform excitation). Using Eqs. (1)–(4), the expression for corrected array factor is given by:
F1θϕ=cosθ+ϕ−1 and F2θϕ=cosθ+ϕ−2 are the element patterns for the two left antenna elements and F3θϕ=cosθ−ϕ+1 and F4θϕ=cosθ−ϕ+2 are the element patterns for the two right antenna elements on the cylindrical surface in Figure 2. It should be noted that for linear array, the element pattern is cosθ as all the elements are pointing towards zenith (that is towards ϕs=0°). However on conformal surfaces, the individual element patterns become geometry dependent. For example, as can be seen in Figure 2, the look directions of antenna elements A−1 and A−2 are towards the angular directions ϕ−1 and ϕ−2 respectively, while the look directions of antenna elements A1 and A2 are towards the angular directions ϕ1 and ϕ2 respectively. Therefore, the element patterns are cosθ+ϕ−1, cosθ+ϕ−2, cosθ−ϕ1, and cosθ−ϕ2 respectively.
3. Convex optimization for pattern recovery of conformal antenna array
The broadside gain maximization problem of a conformal antenna array in Figure 2 can be formulated as a linear constrained quadratic programming problem [32], i.e.,
Minimizewn,Subject toAFtarget=1,E6
where wn∈ℂN×1 is the complex weighing vector, which gives the objective function 2N degrees of freedom. In Figure 3(a) the objective function plotted for the two component dimensions of the first antenna weight w1 clearly indicates its convex form in the vicinity of the origin. The contour plots in the considered two dimensions are also presented in Figure 3(b). The aspect of the contour lines along these two dimensions suggests low condition number. This well condition behavior also exists among the other degrees of freedom and results in a reduced convergence time to find the minimum within the search space.
Figure 3.
(a) 3D plot of the objective function plotted as a function of real w1 and imaginary w1. (b) the contour plot of the objective function with illustration of gradient descent method.
Iterative optimization algorithms are normally adopted to find this minimum. Although second-order Newton method is able to find the solution in fewer steps, it requires evaluation of complex quadratic norm defined as the Hessian matrix ∇2wn, which is quite complex. Since the problem is well-conditioned, even the low complexity first-order Gradient decent method can find the solution quickly. If the iteration number is represented as superscript k, then the weights update in the kth iteration for Gradient descent method is given as
wk+1=wk+tk∆wk,E7
where tk is the scalar step size obtained through backtracking method which reduces as one gets closer to the global minimum. ∆wk is the step direction, which is chosen to maximize the negative gradient ∇wnk at each step. The method descends in each step such that wnk+1≤wnk, until the optimum minimum is reached, and the slope becomes positive. Since the objective function is trying to minimize the norm, the number of steps required for convergence is reduced if the starting point is chosen close to the origin. It should be noted that in this work, the algorithm was used to calculate the required compensated phases only (with uniform amplitudes). Computing the weights for phase correction using Eq. (7) to maximize the broadside gain of conformal antenna array in Figure 2 are used in Eq. (5) to plot the corrected radiation pattern.
To analytically compute the corrected (compensated) radiation pattern and validate with simulation results, the compensated array factor AFc in Eq. (5) was used for different radii of curvatures of the cylindrical surface in Figure 2. The compensated (corrected) weights were computed using projection method in Section 2 and convex optimization in Section 3. The analytical results using Eq. (5) and CST simulation results using Figure 2 are discussed next.
4.1 Cylindrical surface with radius of curvature r=8 cm
The four-element microstrip patch antenna array on a cylindrical surface with radius r=8 cm in Figure 2 was simulated in CST simulator. The inter-element spacing was L=λ/2 at f=2.45 GHz. The compensated phases for broadside pattern recovery were computed using Eq. (2) for projection method, and are tabulated in Table 1. For uncorrected pattern, the complex weights wn=1∠0° were applied on all antenna elements in CST simulator. Next, the weights (phase correction only) for broadside pattern recovery were calculated using the optimization algorithm in Section 3 and are also tabulated in Table 1. The analytical and CST simulation results for r=8 cm are shown in Figure 4. Next, the difference in gain (Gref) between flat array and compensated gain of conformal array were calculated and are also given in Table 1. It can be seen from Figure 4 and Table 1 that the broadside compensated gain Gc of conformal antenna array is greater than the uncorrected gain and is less than the gain of flat array using both projection and convex optimization (phase correction only) methods. This is the fundamental limitation of both the compensation methods for broadside pattern recovery of conformal antenna arrays and should be kept in mind while designing conformal antenna array. It should be noted that convex optimization has more degrees of freedom than projection method in the sense that convex optimization gives complex weights (amplitude tapering plus phase correction), while projection method gives only phase correction (one degree of freedom). However, for broadside pattern recovery, convex optimization gives uniform amplitudes (equal to 1) and compensated phases and thus its performance is equal to projection method for broadside pattern recovery.
r (cm)
Parameter
Projection method
Convex optimization
8
δc (deg)
[121.67,0,0,121.67]
[−89.49,146.95,146.95,-89.49]
Gc (dB)
6.17
6.17
Gref (dB)
0.8
0.8
10
δc (deg)
[101.84,0,0,101.84]
[−170.44,85.95,85.95,−170.44]
Gc (dB)
4
Gref (dB)
0.53
12
δc (deg)
[86.95,0,0,86.95]
[114.61,26.05,26.05,114.61]
Gc (dB)
2.74
Gref (dB)
0.4
15
δc (deg)
[70.95,0,0,70.95]
[9.66,−62.66,−62.66,9.66]
Gc (dB)
1.765
Gref (dB)
0.24
30
δc (deg)
[36.42,0,0,36.42]
[−102.2,−139.3,−139.3,−102.2]
Gc (dB)
0.5
Gref (dB)
0
Table 1.
Computed parameters of conformal cylindrical array for various radii of curvatures.
Figure 4.
(a) Analytical results for phase compensation of a conformal cylindrical antenna array with r=8 cm. (b) CST simulation results for phase compensation of a conformal cylindrical antenna array with r=8 cm.
4.2 Cylindrical surface with radii of curvatures r=10,12,15 cm
When radii of curvatures of cylindrical surface array increase (less deformation), both the projection and convex optimization (phase correction only) methods recover the broadside radiation pattern with decreasing gap between corrected and uncorrected gains as shown in Figures 5–7 and are also tabulated in Table 1. The gain Gc (between uncorrected and corrected) and Gref (between corrected and linear) decreases with increase in r. However, it is obvious that in all cases, the compensated gain is less than the ideal gain (linear array) for both projection and convex optimization methods. This is an important finding and must be kept in design stages of conformal antenna arrays.
Figure 5.
(a) Analytical results for phase compensation of a conformal cylindrical antenna array with r=10 cm. (b) CST simulation results for phase compensation of a conformal cylindrical antenna array with r=10 cm.
Figure 6.
(a) Analytical results for phase compensation of a conformal cylindrical antenna array with r=12 cm. (b) CST simulation results for phase compensation of a conformal cylindrical antenna array with r=12 cm.
Figure 7.
(a) Analytical results for phase compensation of a conformal cylindrical antenna array with r=15 cm. (b) CST simulation results for phase compensation of a conformal cylindrical antenna array with r=15 cm.
4.3 Cylindrical surface with radii of curvatures r=30 cm
In the limiting case, when the radius of curvature of conformal cylindrical array increases up to 30 cm and above (approaching flat array), the compensated gains achieved from both projection and convex optimization methods nearly reaches the linear flat array gain, which is demonstrated in Figure 8 and is shown in Table 1.
Figure 8.
(a) Analytical results for phase compensation of a conformal cylindrical antenna array with r=30 cm. (b) CST simulation results for phase compensation of a conformal cylindrical antenna array with r=30 cm.
In this chapter, phase compensation techniques based on projection method and convex optimization (phase correction only) have been discussed for recovery of broadside radiation pattern on a conformal cylindrical-shaped antenna array. The compensated gains of both the methods have been compared with linear flat antenna array. It is shown that the maximum broadside gain recovered with both the methods is less than the linear antenna array for severe deformation cases and approaches the gain of linear antenna array for less conformal deformation surfaces. The analytical expressions and convex optimization algorithm used can be used by a designer to predict the maximum possible compensated gain of conformal antenna array.
The proposed techniques can be extended for broadside pattern correction of conformal antenna arrays on other deformed surfaces (spherical nose of plane, flexing wings of UAV, etc.). Another interesting research can be to extend these techniques for beamforming on conformal deformed surfaces (e.g., on base station/tower of cellular companies) to improve the signal-to-noise ratio (SNR) and its capacity. In this work, convex optimization is used to compute the compensated phases (with uniform amplitudes constraint) for recovery of broadside radiation pattern only. In practice, the technique is robust and can be used to calculate complex weights (amplitude tapering as well as phase correction), which can be further explored for beamforming applications and side lobe level control of conformal antenna arrays.
This work is supported by Ignite (NTF), Ministry of IT & Telecom, Government of Pakistan via project no. ICTRDF/TR&D/2015/04.
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Written By
Irfan Ullah, Shahid Khattak and Benjamin D. Braaten
Submitted: 25 November 2019Reviewed: 24 December 2019Published: 22 January 2020
Open access peer-reviewed chapter
