Results for the drooped microstrip, substrate permittivity 2.2.
1. Introduction
The Navigation Satellite Timing and Ranging (NAVSTAR) GPS is a space-based system designed primarily for global real-time, all-weather navigation. There are 30 GPS satellites in six nearly circular, approximately 20,000 kilometer orbital planes, with an inclination of 550 relative to the equator [1]. Each satellite transmits two unique, Right Hand Circularly Polarized (RHCP) L band signals. The L1 (1.57542 GHz) carrier is bi-phase modulated with two pseudo-random noise sequences; the P and C/A codes. The L2 (1.2276 GHz) carrier is modulated only with the P code and is used mainly to determine and correct phase advance caused by the ionosphere. Superimposed on the P and C/A codes is the navigation message which contains, among other things, satellite ephemerides, clock biases, and ionosphere correction data [1].
Due to their light weight, reduced size, low cost, conformability, robustness, and ease of integration with MMIC, tremendous research has been reported over the last three decades into the use of microstrip antennas in GPS navigation [2]-[20]. Antenna designers are often faced with interrelated, strict, and conflicting performance requirements in order to meet the accuracy, continuity, and integrity of differential GPS, relative geodetic and hydrographic surveying, ship-borne and aerospace navigation [21]-[27].
The design specifications of a GPS antenna depend on the performance requirements peculiar to the application under consideration. A GPS user antenna requires RHCP and adequate co-polarized radiation pattern coverage over almost the entire upper hemisphere to track all visible satellites. Moreover, the antenna should ideally provide a uniform response in amplitude and, more critically, in phase to the full visible satellite constellation [21]. The angle cutoff and roll-off characteristics of the radiation pattern can be altered to suit the application of interest. For example, fixed ground reference stations and relative static geodetic surveying demand a rapid fall-off near the horizon, a high cross-polarization rejection, and a front-to-back gain ratio in excess of 20 dB to mitigate deleterious effects of severe multipath [28], [29].
In real-time kinematic positioning, few if any of the above constraints may be effective [30] and it may be necessary to operate the antenna under less than optimal conditions in regard to cross polarization performance if a wide beamwidth is of precedence. Precise GPS hydrographic surveying on a vessel cruising at speeds of 10 to 20 knots in open oceans is a challenging task due to the rotational disturbances from a relatively harsh sea environment. Pitch and roll amplitudes as high as 100 to 150 may be encountered in stormy weather, which presents a major obstacle to GPS derived attitude determination [21], [22]. Another envisaged application for the drooped microstrip antennas introduced in this chapter involves normal pitch or roll maneuvers of a general aviation aircraft, which may cause loss of some satellite signals for a range of flight orientation.
There is significant interest in the commercial and military sectors to develop antennas that could cover much of the upper hemisphere, including GPS satellites at elevation angles as low as 100, and to extend the coverage to negative elevation angles [3], [4], [15], [21]. This will lead to fewer occurrences of cycle slips and loss of lock to satellites while rising or setting, will maintain the proper Dilution of Precision (DoP) by maximizing the number of satellites in view, and will reduce the RMS error in range and velocity [1]. Notably, on the negative side, undesired multipath reflections off water and conducting bodies are also strongest at low-elevation angles. Nevertheless, whatever type of antenna is chosen, multipath reception will still have to be dealt with as a common problem [30]. It is fair to say that no single antenna design in the open literature has satisfactorily fulfilled all the above-mentioned requirements on coverage, phase center stability, and multipath rejection for real-time highly dynamic GPS marine and aerospace applications.
A pedestal ground plane is reported in [31], based on a trial-and-error experimental design approach, consisting of a cylindrical structure with a flat elevated center surrounded by sloping sides, to address beam shaping of crossed dipoles. This structure was found to be successful in improving the pattern coverage of the crossed dipole at low-elevation angles. Additional elements were also examined such as folded, serrated, rolled edges, monofilar, and quadrafiliar helices [32]-[35], although none achieved the same degree of radiation pattern control as the crossed dipole. This is attributed in part to the extent of ground plane illumination produced by the different sources and serves to highlight the importance of the ground plane as a secondary source with which to produce pattern changes. Further modifications to the ground plane using choke rings [28] were investigated primarily for multipath rejection.
It is well known that a stand-alone microstrip antenna mounted on a flat ground plane suffers from a lack of pattern control and reduced gain at low-elevation angles. This may result in a loss of contact with satellites when the antenna is mounted on a highly-dynamic platform, an attractive use for this low-profile structure. Fundamental to the design of a patch antenna is the interaction with the ground plane. In fact, the size, orientation, and shape of the ground plane are among the most important parameters that have an influence on the radiation pattern [36]. However, a fundamental distinction exists in the relationship between a patch and the ground plane when compared with helical or dipole elements in that the ground plane of a microstrip antenna forms an integral part of the radiating structure and may not best be defined as a "secondary" source.
Building on our previous design experiences [28], [31]-[35], our research group at the University of New Brunswick, Fredericton, NB, Canada was the first to rigorously investigate the potential performance enhancements and limitations involved when these design modifications are applied to the more appealing microstrip antenna element [37]. The advantages associated with the microstrip antenna are such that one patent has been issued to a GPS manufacturer [38] based only on a downward drooped antenna structure. Neither the dimensions nor the performance of the proposed antennas were quantified in [38]. Later, a corner truncated square patch, partially enclosed within a flatly folded conducting wall, mounted on a pyramidal ground plane, was reported in [39]. However, neither the cross polarization performance nor the phase center stability were provided in [39].
In contrast to the antenna reported in [39], the drooped microstrip antennas introduced in this chapter have the ground plane and actual element deformed such that the corners or edges of the resonant cavity region fall away from the plane occupied by the element. A fundamental understanding of the operation and limitations of the drooped microstrip antenna is still lacking. A diffraction technique was attempted in [40] to model the effects of a sloping ground plane. This, however, was limited by the difficulty of implementing a realistic source term as well as the inclusion of finite lossy dielectric materials. A rigorous full-wave 3-D model, which incorporates the coaxial feed and detailed geometrical features of the drooped microstrip antenna, has not yet been reported.
For these reasons, we have performed the research reported in this chapter, which is the first to our knowledge that combines rigorous 3-D full-wave simulations and experimental measurements to provide a comprehensive characterization of downward and upward drooped microstrip antennas. A FDTD model has been developed, validated experimentally, and used to compute the input impedance and far-field radiation patterns. The FDTD model was used to examine the effects of a wide range of structural variations to gain an insight into the benefits and limitations of the proposed antennas. The parameters of interest include the location and angle of the bend, length of the ground plane, dielectric constant, and thickness of the substrate. Prototype structures were constructed, and their characteristics measured and then compared against simulated results. The authors wish to point out that the antennas described in this chapter are not intended to target multipath mitigation; on the contrary, they demonstrate the range of pattern modifications that could be accomplished by manipulating the orientation and size of the ground plane to suit GPS applications in marine and aerospace navigation.
The rest of the chapter is organized as follows: Section 2 summarizes the FDTD algorithm developed to perform the design and parametric studies and presents results from experimental tests performed to validate the implementation of the model and to demonstrate its ability to correctly predict the behavior of the drooped antennas. Section 3 addresses the design procedure, introduces parametric studies, and describes the drooped antennas constructed and tested for the control of the radiation patterns. Finally, Section 4 provides concluding remarks.
2. The contour path FDTD model: Experimental validation
The basic microstrip antenna, which consists of a conducting patch radiator rotated by 450 with respect to the center of the ground plane, and separated from the ground plane by a thin dielectric substrate, and the downward drooped antenna are shown in Figure1.
The element is driven by a 50 Ω coaxial cable passing through the ground plane and the substrate. The antenna operates at the L1 GPS frequency of 1.57542 GHz since the majority of commercial GPS receivers use only the L1 frequency. Due to the relatively low cost, time savings, and repeatability, computer simulations can often complement and reduce the empiricism involved in an otherwise purely experimental approach, particularly in the initial design phase, allowing the antennas to be characterized carefully prior to their construction. Because of the complex geometries involved, the task of modeling the drooped microstrip structures is by no means a simple endeavor; it better lends itself to numerical simulation techniques. The FDTD method has been adopted in this research due to its conceptual simplicity and ease of implementation. Because it is a time-domain scheme, it is straightforward to impose a pulse excitation to perform broadband analysis using the Discrete Fourier Transform (DFT).
The FDTD algorithm is implemented in a 3-D Cartesian coordinate system with the formulation allowing for different spatial increments along each coordinate direction. Provision is made for modeling symmetrical objects by applying the Neumann boundary condition along one surface of the computational space. The antenna is excited either by a sinusoidal signal at the resonant frequency of the dominant mode or by a Gaussian pulse with a specified width and delay. The excitation is applied to either the electric or magnetic field, depending on whether a voltage or current source is desired.
In order to compute the input impedance, the instantaneous voltage and current are calculated at a fixed location in the coaxial feed by integrating the radial electric field and the magnetic field components encircling the inner conductor of the coaxial cable. A Gaussian pulse is used, and a DFT is performed to obtain broadband results. The impedance is then translated into the ground plane aperture by standard transmission line methods. The far-field radiation patterns are next determined by driving the model to steady state, using a sinusoidal wave at the fundamental resonant frequency of the antenna.
With pulse excitation, the fields must settle toward zero as energy escapes through the absorbing boundary. The condition used to judge if steady state is reached requires that the energy monitored at several observation points within the computational domain remains below 1% of the peak observed value with lower values enforced for cases continuing to display periodic oscillations in the fields. For a sinusoidal excitation, the solution must converge to an oscillation. The magnitude and phase at several observation points are extracted from the DFT at each temporal cycle. A 1% variation in steady state is permitted in phase.
The methodology we followed involves extracting the antenna characteristics for a given geometry selected from a parametric study using the FDTD code; constructing a prototype; measuring the frequency response of the input impedance, far-field radiation patterns at the measured resonant frequency; and finally comparing simulated results against measurements. To validate the operation of the FDTD model, several antenna structures were simulated and measured. The first antenna used to validate the code was a flat rectangular microstrip. The 50 mm × 47 mm patch was constructed on a square ground plane, 150 mm in side length. The substrate has a relative dielectric constant,
The calculated impedance correctly predicts the resonant frequency measured using a network analyzer. Similarly, excellent agreement is observed between the amplitude and phase of the measured and simulated far-field radiation patterns.
As a progression toward the drooped structure, a microstrip antenna with two edges bent down at an angle of 450 was modeled. This structure requires special consideration in that the boundary conditions imposed by the element and ground plane do not fall along the coordinate planes. The most straightforward approach is to discretize the sloping sides with the traditional stair-stepped approximation. However, it has been observed that this can result in a slight change in the resonant frequency of high
Three different step approximations, shown in Figure 4, were used to model the sloping sides, depending upon the angle of the bend.
A rectangular microstrip with two 450 drooped edges fed by a coaxial cable was constructed and tested to compare measured and simulated input impedance,
Before progressing to the double-bend antenna, a test was conducted to verify that the FDTD model maintained continuity at the point where the stepped approximation changed from a 2:1 to a 1:1 ratio. To accomplish this, we modeled a 40 mm × 50 mm bent microstrip antenna near the change of an angle of 550 using both ratios. A comparison of the input impedance and elevation patterns depicted in Figure 8 show good agreement between results obtained from each approximation.
To duplicate the bend on the two remaining sides to achieve the full drooped structure, we constructed two drooped antennas and used them to verify the performance of the completed model. The first antenna, shown in Figure 9, consists of a 62 mm × 62 mm patch, a 40 mm square elevated section, printed on a 1.5 mm thick substrate,
3. Parametric analysis of the drooped microstrip antennas
Further parametric analyses were conducted to determine the range of structural variations that can be utilized to optimize the performance of the drooped microstrip antennas. The design process was complicated due to the several interacting parameters that must be considered in order to provide adequate low-angle coverage, uniform phase response, and polarization purity. Parameters investigated include the angle and location of the bend, length of the ground plane skirt, thickness and dielectric constant of the substrate. The results are assessed on the basis of their impact on antenna gain at bore sight, phase performance in the upper hemisphere, pattern beamwidth, cross polarization rejection, and near horizon gain reduction.
In all cases to be presented, the radiation patterns were obtained at the resonant frequency of the dominant mode. The amplitude and phase of the radiation patterns were obtained from anechoic chamber measurements in a 50× 50 grid, following the procedure described in [43]. These were then analyzed to determine the 3 dB beamwidth and near horizon gain reduction with respect to bore sight (zenith). In order to determine the absolute gain, we integrated the calculated patterns over the upper and lower hemispheres with a 50 step in azimuth and elevation. All field calculations were then referenced to the resulting isotropic power density.
Whereas an enormous volume of literature is available on patch antennas for GPS applications [2]-[20], a close scrutiny revealed that the design objectives in the majority of these studies and the performance characterization were based entirely on the amplitude of the co- and cross-polarized radiation patterns. Only few have considered the phase response as a figure of merit in the design process and/or in the analysis or measurements [28], [31]-[35], [43]. The phase response directly weighs the arriving signals and produces a phase-shaping effect, which depends on the angle of arrival of the satellite signals. The calibration of the phase response provides invaluable information regarding the level of accuracy one can ultimately achieve for sub-centimeter static geodetic positions [43].
The measured upper hemispherical phase response of the antennas under test was matched to an ideal hemisphere in a 50 × 50 grid, using equal solid angle weighting. The position of the ideal hemisphere was adjusted to minimize the RMS error between the measured and ideal phase [43]. The origin of this hemisphere is defined as the “center of best fit” or “phase center,” and the difference between the measured and ideal phase is defined as the “phase residual” or “phase error.” The RMS value of the phase error is used as a figure of merit to describe the phase distortion introduced by the antennas considered in the rest of this chapter.
3.1. Drooped microstrip with a downward bend
For the initial test, a 40 mm × 40 mm patch was placed on three different ground planes. These, in turn, were bent at three different distances from the center, forming a flat square top that was 10, 30, or 50 mm2. Simulations were carried out for bend angles, ranging from 0 to 900 in a 150 step. Figure 11 depicts the parameters and geometries used for the initial set of simulations.
Three dielectric constants were used in the course of the simulations to examine the effects of different substrate materials; values of 2.2 and 4.2 were selected because of the availability of substrates to construct the verification cases, while an
A sequence of elevation patterns is presented in Figure 12, which displays the progression of the radiated fields with the size and bend angle of the ground plane. Not unexpectedly, smaller ground planes with larger bends allow more energy to escape off the back, until it appears that the main beam is 1800 from the bore sight direction. This is made obvious by plotting the polar patterns for
Next, a prototype was constructed with adjustable bend plates, and the measured beamwidths were compared against simulated results. For construction simplicity, the antenna was excited using linear polarization with only two sloped sides. In Figure 13, the measured and computed beamwidths show a slight improvement with increasing bend angle.
Variations in bore sight gain, 3 dB beamwidth, near-horizon gain roll-off, and RMS phase error as a result of increasing the bend angle are summarized in Tables 1 to 3. The 10 mm case shows a sharp gain reduction at extreme bend angles. The results reveal a relatively minor improvement in the pattern beamwidth, even for large bend angles and varying ground plane sizes for the higher dielectric substrates. Indeed, the radiation patterns above the horizon remain virtually unchanged for bend angles up to 600.
|
Boresight gain (dBi) |
3 dB Beamwidth (deg) |
Near horizon gain Roll-off (dB) |
RMS phase error (deg) |
|||||||||
Width-mm | 60 | 80 | 100 | 60 | 80 | 100 | 60 | 80 | 100 | 60 | 80 | 100 | |
Bend angle (10 mm top) |
0 15 30 45 60 70 90 |
7.2 7.1 6.9 5.5 0.9 0.8 -24 |
7.5 7.5 7.1 6.5 5.6 3.3 -25 |
7.7 7.7 7.1 6.4 6.2 5.4 -26 |
88 88 90 96 100 119 354 |
83 84 86 95 94 91 356 |
80 80 86 96 97 95 356 |
-11. -10. -9.7 -9.0 -7.9 -5.5 22 |
-12. -11. -10. -9.1 -9.5 -9.3 23 |
-13. -13. -11. -9.1 -9.0 -9.0 24 |
3.0 2.5 1.5 2.2 4.3 12. 11.9 |
2.6 3.3 1.8 1.6 6.5 4.4 2.7 |
2.0 3.4 1.7 2.0 2.6 2.8 2.8 |
Bend angle (30 mm top) |
0 15 30 45 60 70 90 |
7.2 7.1 6.9 6.6 5.5 5.2 0.1 |
7.5 7.5 7.4 7.1 6.7 6.4 2.3 |
7.7 7.8 7.4 7.0 6.5 6.2 3.78 |
88 88 89 90 91 92 97 |
83 83 83 87 90 92 84 |
80 78 82 87 93 96 85 |
-11. -11. -9.6 -10. -10. -10. -9.6 |
-12. -11. -11. -10. -10. -9.9 -11 |
-13. -13. -11. -11. -9.7 -9.1 -12 |
2.9 2.4 1.5 1.9 2.3 1.6 8.2 |
2.6 3.3 1.8 1.6 6.5 4.4 2.7 |
2.0 3.4 1.7 2.0 2.6 2.8 2.8 |
Bend angle (50 mm top) |
0 15 30 45 60 70 90 |
7.2 7.0 7.1 6.9 6.8 7.1 6.4 |
7.5 7.7 7.5 7.2 7.2 7.2 6.9 |
7.7 7.9 7.4 7.1 7.0 6.8 6.9 |
88 89 87 89 89 87 91 |
83 81 82 86 87 87 89 |
80 77 83 87 88 91 89 |
-11. -10. -9.9 -9.6 -9.7 -10. -9.4 |
-12. -12. -11. -10. -10. -10. -9.7 |
-13. -13. -11. -10. -10. -9.4 -10. |
2.9 2.4 1.5 1.9 2.3 1.6 8.2 |
2.6 3.3 1.8 1.6 6.5 4.4 2.7 |
2.0 3.4 1.7 2.0 2.6 2.8 2.8 |
|
Boresight gain (dBi) |
3 dB Beamwidth (deg) |
Near horizon gain Roll-off (dB) |
RMS phase error (deg) |
|||||||||
Width-mm | 60 | 80 | 100 | 60 | 80 | 100 | 60 | 80 | 100 | 60 | 80 | 100 | |
Bend angle (10 mm top) |
0 15 30 45 60 70 90 |
4.7 4.5 4.8 3.4 0.9 -1.1 -27 |
5.8 5.7 5.9 5.2 4.3 1.5 -28 |
6.2 6.0 6.0 6.5 6.1 3.3 -29 |
106 106 106 149 360 360 360 |
100 103 100 107 129 360 360 |
100 100 101 108 115 144 360 |
-11.6 -9.9 -8.6 -3.7 2.5 6.5 - |
-13.5 -10.8 -11.0 -9.0 -5.7 0.8 - |
-14.5 -10.9 -10.7 -9.7 -8.4 -3.8 - |
1.6 2.2 1.5 2.0 3.6 12.8 - |
1.2 3.6 1.0 1.5 2.7 2.9 - |
1.1 4.3 1.0 1.2 2.6 3.3 - |
Bend angle (30 mm top) |
0 15 30 45 60 70 90 |
4.7 4.5 4.6 4.9 3.5 3.0 1.0 |
5.8 6.0 5.9 5.8 4.4 4.3 1.5 |
6.2 6.0 6.0 5.9 5.3 4.8 2.4 |
114 119 113 107 106 116 121 |
106 103 104 104 109 114 110 |
100 103 102 106 112 115 103 |
-11.6 -10.6 -11.1 -12.2 -11.3 -9.2 -6.7 |
-13.5 -13.8 -13.3 -13.4 -11.4 -10.9 -8.2 |
-14.5 -13.7 -13.5 -13.4 -12.0 -11.3 -10.1 |
1.6 1.2 0.9 1.2 1.6 0.9 1.6 |
1.2 1.1 0.5 0.8 1.9 0.9 1.5 |
1.1 0.9 0.5 0.7 1.3 0.8 1.4 |
Bend angle (50 mm top) |
0 15 30 45 60 70 90 |
4.8 4.9 5.3 5.0 4.7 5.2 4.4 |
5.8 5.9 6.0 5.8 5.6 5.5 5.2 |
6.2 6.3 6.2 6.0 5.8 5.4 5.4 |
114 119 113 107 106 116 121 |
106 103 104 104 109 114 110 |
100 103 102 106 112 115 103 |
-11.6 -11.5 -12.5 -12.4 -11.7 -12.2 -11.6 |
-13.5 -13.6 -13.6 -13.4 -12.8 -12.5 -12.6 |
-14.5 -14.6 -14.1 -13.4 -13.3 -12.0 -12.8 |
0.8 0.7 0.6 0.7 0.6 0.4 0.8 |
0.9 0.7 0.5 0.6 0.6 0.4 0.6 |
1.2 0.9 0.6 0.6 1.0 0.5 0.6 |
|
Boresight gain (dBi) |
3 dB Beamwidth (deg) |
Near horizon gain Roll-off (dB) |
RMS phase error (deg) |
|||||||||
Width-mm | 60 | 80 | 100 | 60 | 80 | 100 | 60 | 80 | 100 | 60 | 80 | 100 | |
Bend angle (10 mm top) |
0 15 30 45 60 70 90 |
3.1 3.4 3.8 2.5 3.3 2.4 -38 |
4.7 4.4 4.4 3.6 2.6 3.0 -40 |
5.3 5.2 5.1 4.5 3.6 3.5 -43 |
114 116 117 123 139 134 360 |
108 115 113 117 120 122 360 |
104 111 111 116 118 120 360 |
-9.4 -9.3 -9.7 -7.8 -8.2 -7.4 - |
-11.5 -10.4 -10.7 -9.5 -8.3 -8.5 - |
-12.5 -11.4 -11.3 -10.6 -9.5 -9.3 - |
0.80 0.89 0.59 0.41 3.0 2.0 - |
0.49 1.0 0.46 0.41 0.80 0.72 - |
0.53 0.87 0.42 0.38 0.86 0.97 - |
Bend angle (30 mm top) |
0 15 30 45 60 70 90 |
3.1 3.8 3.8 2.9 2.7 2.3 1.5 |
4.7 4.5 5.0 4.1 3.6 2.9 1.4 |
5.3 4.9 5.4 4.7 4.3 3.5 1.5 |
114 119 116 116 119 122 134 |
108 108 106 114 104 119 132 |
104 106 106 114 104 119 127 |
-9.4 -9.6 -9.8 -8.9 -8.6 -7.8 -6.0 |
-11.5 -11.3 -12.1 -10.3 -11.1 -8.6 -6.1 |
-12.5 -11.9 -12.5 -10.9 -12.0 -9.3 -6.6 |
0.80 0.40 0.25 0.39 0.56 0.24 0.29 |
0.49 0.46 0.33 0.32 1.2 0.21 0.31 |
0.53 0.48 0.36 0.30 1.2 0.18 0.34 |
Bend angle (50 mm top) |
0 15 30 45 60 70 90 |
3.1 2.9 3.2 3.4 3.0 3.7 2.0 |
4.7 4.6 4.9 4.5 3.7 3.6 2.6 |
5.3 5.4 5.5 4.8 4.9 4.5 3.2 |
114 133 121 119 122 117 113 |
108 114 110 112 124 123 110 |
104 109 109 117 119 107 108 |
-9.4 -7.6 -8.7 -9.0 -8.4 -9.5 -8.3 |
-11.5 -10.7 -12.4 -10.7 -8.9 -9.1 -9.2 |
-12.5 -11.7 -11.8 -10.4 -11.8 -10.3 -10.0 |
0.80 0.34 0.46 0.37 0.51 0.28 2.1 |
0.49 0.70 0.90 0.56 0.51 2.2 2.4 |
.53 0.80 0.32 0.41 0.90 1.5 2.2 |
The phase of the elevation cuts shown in Figure 14 shows a remarkable change in the below-horizon phase. For small bend angles, the phase diminishes from the bore sight value when approaching the horizon, while at higher bends the phase increases from the bore sight value. At about 150 to 300 of bend, a region exists where the elevation phase remains relatively constant above the horizon. Bending of the structure in this manner could provide an additional beamwidth and, more importantly, the phase stability necessary to achieve a design specification, particularly if further modification of the substrate is not feasible.
Another consideration for GPS antennas is the cross polarization behavior. Odd reflections from nearby objects tend to be orthogonally polarized. Hence, it is important that the antenna be able to reject these, particularly near the horizon. To demonstrate the effect of bending the structure on the polarization performance, we examined the ratio of the right- to the left-hand circular components for several bend angles. Almost without exception, the bend degraded the cross polarization rejection near the horizon as shown in Figure 15, making the antenna more susceptible to spurious signals.
3.2. Drooped microstrip with an upward bend
The modification of the FDTD model to accommodate upward bends was accomplished by interchanging the positions of the ground plane and the element. The structure would then be upside down in the computational space but would have an upward bend. Initially, we considered the antenna shown in Figure16, which has a 30 mm flat top on a substrate with
A prototype antenna was constructed and tested to allow comparison against experimental results. The antenna is identical to the one shown in Figure 13; only two variable upward bends were used in this case. For measurement purposes, a linearly polarized excitation was used. The initial dip in the beamwidth did not occur in the simulated and measured results shown in Fig. 18.
With the completion of the initial set of simulations and measurements, we pursued the model with additional parameter variations. Bend locations at the 10 and 50 mm positions were tested for the
A changing upward bend produced little effect on the phase in the upper hemisphere. All phase curves above 900 elevation fell within 300 of each other over the full range of bend angles. Like the downward bend, the RMS phase error over the hemisphere did not vary substantially with bend angle, although a slightly greater differentiation is evident between different ground plane sizes. The elevation gain and cross polarization rejection for various upward bend angles are displayed in Figs. 19 and 20, respectively. When compared to Figure 15, it is apparent that the rejection is better by 2 dB near the horizon for upward bends, but the opposite is true below the horizon. In both cases, bending the ground plane reduces the cross-polarization discrimination near the horizon.
|
Boresight gain (dBi) |
3 dB Beamwidth (deg) |
Near horizon gain Roll-off (dB) |
RMS phase error (deg) |
|||||||||
Width-mm | 60 | 80 | 100 | 60 | 80 | 100 | 60 | 80 | 100 | 60 | 80 | 100 | |
Bend angle (10 mm top) | 0 15 30 45 60 70 90 |
7.2 4.0 4.7 5.1 4.1 2.5 -1.5 |
7.5 6.2 6.5 3.5 -.8 -4.4 -6.1 |
7.7 6.4 1.3 3.5 2.6 -.42 -6.4 |
88 158 143 137 142 127 188 |
83 134 122 170 302 327 360 |
80 118 120 106 214 300 360 |
-11. -14. -9.4 -7.2 -3.8 0.44 -2.3 |
-12. -11. -10. -7.6 -6.7 5.8 -6.6 |
-13. -11. -12. -9.4 -7.1 5.7 0.93 |
3.0 6.2 3.6 4.5 6.6 35.8 11.0 |
2.6 6.8 3.5 3.3 5.2 6.5 69.9 |
2.0 9.1 5.5 3.3 4.6 11.2 80.1 |
Bend angle (30 mm top) |
0 15 30 45 60 70 90 |
7.2 7.7 7.1 6.6 6.0 4.9 5.1 |
7.5 8.4 7.6 7.0 6.2 4.9 0.6 |
7.7 8.7 7.7 7.3 6.0 4.9 3.7 |
88 75 81 89 95 104 112 |
83 69 75 83 91 110 176 |
80 63 73 79 91 114 142 |
-11. -12. -11. -9.1 -8.3 -6.7 -6.1 |
-12. -13. -12. -9.8 -7.8 -5.8 -2.1 |
-13. -15. -13. -11. -7.9 -5.3 -3.9 |
3.0 1.8 2.8 2.3 2.2 4.4 6.8 |
2.6 1.6 2.4 1.5 1.3 2.8 4.7 |
2.0 3.9 4.0 2.0 1.5 1.9 1.5 |
Bend angle (50 mm top) |
0 15 30 45 60 70 90 |
7.2 7.3 7.0 7.3 7.1 6.9 6.5 |
7.5 7.6 7.4 7.5 6.8 6.8 5.8 |
7.7 7.9 7.9 7.8 7.1 6.9 5.1 |
88 82 79 83 87 83 89 |
83 75 77 79 81 87 99 |
80 73 69 73 87 81 110 |
-11. -12. -12. -10. -9.7 -9.4 -8.9 |
-12. -13. -12. -11. -9.4 -5.4 -7.2 |
-13. -14. -13. -12. -10. -4.5 -6.4 |
3.0 1.2 1.6 1.1 1.0 2.5 5.6 |
2.6 1.5 2.4 1.5 1.1 2.9 12.6 |
2.0 2.5 3.4 1.9 1.3 2.0 10.3 |
|
Bore-sight gain (dBi) |
3 dB Beamwidth (deg) |
Near horizon gain Roll-off (dB) |
RMS phase error (deg) |
|||||||||
Width-mm | 60 | 80 | 100 | 60 | 80 | 100 | 60 | 80 | 100 | 60 | 80 | 100 | |
Bend angle (30 mm top) |
0 15 30 45 60 70 90 |
4.7 6.6 5.1 5.6 4.5 3.4 4.7 |
5.8 7.0 5.4 6.0 4.9 4.2 4.7 |
6.2 7.5 5.6 6.4 5.1 4.3 4.4 |
114 89 106 91 102 114 102 |
106 81 102 89 104 110 100 |
100 75 93 83 100 118 110 |
-11. -8.4 -7.8 -7.1 -7.7 -7.2 -6.7 |
-14. -9.4 -8.6 -7.4 -7.3 -6.1 -6.0 |
-14. -11. -9.4 -8.1 -7.3 -5.0 -5.1 |
1.6 0.8 4.2 2.1 5.2 5.0 2.5 |
1.2 1.0 3.8 2.0 3.9 2.7 2.1 |
1.1 1.7 4.7 2.6 3.8 1.6 1.4 |
4. Concluding remarks
In this chapter, we have presented numerical simulations and experimental measurements to analyze downward and upward drooped microstrip antennas with the intent of modifying the radiation pattern of the basic planar patch to accommodate the coverage requirements of GPS marine navigation and positioning. Magnitude and phase of the simulated and measured far-field radiation patterns are presented to reveal the tradeoffs in performance between patch geometry, ground plane size, and orientation. Results reported for the wide range of structural variations applied to the base antenna along with changes in the substrate material should be valuable to designers seeking to achieve a specific coverage performance.
It has been found that an accurate and stable phase center can be obtained over the entire hemisphere for moderate upward bends. Numerical simulations and measurements demonstrate that the 3-dB beamwidth of the flat microstrip patch can be increased by at least 15% and 60% for the downward and upward bends, respectively. The phase stability demonstrated by the slightly bent structures may be viewed as advantageous in cases where circumstances require distorting the element but where a significant alteration in the pattern is not desired. These were accomplished, however, at the expense of some loss of the low-profile character of the antenna.
Although not dramatically affected, the cross polarization discrimination of the bent antennas is reduced by 3 dB at the horizon compared to the equivalent flat case. Calculations of the RMS error in the spherical phase fit over the upper hemisphere showed little change with bend angle or position. In general, there is a tradeoff in achieving broad-beam pattern coverage, and maintaining high cross polarization discrimination.
The crossed dipole source, when used with the pedestal ground plane, demonstrated significant pattern improvements which inspired our interest in the drooped microstrip structure. It should be noted, however, that the crossed dipole is fundamentally different from the microstrip antenna, being itself a stand-alone radiator which operates in the presence of secondary sources created by the ground plane image. For the microstrip antenna, the ground plane is an integral part of the structure. The interior field distribution of the fundamental mode remains essentially unchanged with ground plane manipulation, and pattern modification can come about only by repositioning of the radiating edges in space.
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