Elliptical Ring Antenna Excited by Circular Disc Monopole for UWB Communications

*is research proposes a compact elliptical ring antenna excited by a circular disc monopole (CDM) for ultra-wideband (UWB) communications. In the study, timeand frequency-domain pulse distortions of the antenna in the transmission mode were characterized by magnitude and phase of the antenna transfer function (Hrad). *e results showed that the gain and magnitude of Hrad in the boresight direction are sufficiently flat with linear phase response. *e average antenna gain is 3.9 dBi over the UWB spectrum. *e antenna also exhibits low pulse distortion with the correlation factors (ρ) of 0.98 and 0.93 for the fifth-order derivative Gaussian pulse and modulated Gaussian pulse with 6GHz band rejection. *e CDM-excited elliptical ring antenna possesses several attractive features, including wide bandwidth, flat gain, compactness, low cost, and low distortion.


Introduction
Ultra-wideband (UWB) is a radio technology with a spectrum that occupies a fractional bandwidth greater than 20 percent of the center frequency, or a bandwidth of at least 500 MHz when the center frequency is higher than 6 GHz. UWB emits less than − 41.3 dBm/MHz within the 3.1-10.6 GHz operating band. ere are two UWB signal implementation schemes: impulse UWB (I-UWB) using the full spectrum of a single band for low-data-rate applications and multicarrier UWB (MC-UWB) using multiple subbands with a bandwidth larger than 500 MHz in combination with orthogonal frequency-division multiplexing (OFDM) modulation for high-data-rate applications [1,2]. e advantages of I-UWB include low complexity, low power consumption, and good time-domain resolution, allowing for location and tracking applications. I-UWB has also been incorporated in IEEE 802. 15.4a standard for a lowrate wireless personal area network (LR-WPAN).
In impulse radio-based ultra-wideband communication, minimum impulse signal distortion is imperative because UWB antennas transmit very short pulses on the order of nanosecond in duration without carrier and occupies a very large bandwidth of 7.5 GHz. erefore, UWB antennas should possess a clean impulse response (constant magnitude and linear phase) where the radiating signal is a time derivative of the input signal [2]. Most UWB antennas have an omnidirectional radiation pattern for applications in mobile devices.
Antennas with planar monopoles protruding from a perpendicular ground plane have been proposed in [3][4][5][6][7][8][9]. e antenna with a consistent monopole-like radiation characteristic was proposed [3]. e bandwidth is extremely larger than conventional monopole whip antenna. Next, the monocone antenna with a dielectric loading and a monocone quasi-Yagi antenna was subsequently investigated [4,5]. e very wideband operation could be achieved with a reasonable gain. In [6,7], the UWB antennas with a reflector were presented for high gain and steerable beam purpose. e UWB patch antenna with a top loading was also designed for the WBAN system [8]. In [9], the UWB monopole-like radiation characteristic was introduced for high isolation between transmit and receive ports. Despite low profile structure, these antennas lack a compact size because of its extended ground plane structure. To obtain a more compact structure, the modified biconical antenna [10] and the coplanar waveguide (CPW)-feeding antennas [11][12][13][14] have been reported for some specific applications. In addition, the printed antennas with different structures in both sides had been realized for bandwidth enhancement size miniaturizations [15][16][17][18][19]. e main advantage of these antennas is that the flat structure could be readily integrated into electronic circuits. However, they suffer from bulkiness because of the presence of the planar ground plane.
is study proposes an elliptical ring antenna excited by a circular disc monopole (CDM) for radiation over the UWB spectrum. e antenna is compact and consists of a simple feeder and low-cost components. In the antenna development, simulations were carried out using CST Studio Suite [20], and a prototype antenna was fabricated. To validate the antenna performance, time-and frequencydomain pulse distortions in the transmission mode in terms of magnitude and phase of the antenna transfer function (H rad ) were characterized by manipulating the angular positions. e fifth-order derivative Gaussian pulse and modulated Gaussian pulse with 6 GHz band rejection were used as the exciting signals in the simulation. e correlation factors between input and radiated pulses were also determined. Figure 1 illustrates the proposed antenna, consisting of an elliptical ring and a CDM, where a, b, d, and l are the semimajor axis, semiminor axis, thickness, and length of the elliptical ring, respectively; and c and t are the radius and thickness of the CDM, respectively, with a feeding gap of h between the elliptical ring and the CDM. e CDM radiates omnidirectionally with wideband characteristics, and the elliptical ring transforms the omnidirectional into bidirectional radiation pattern. A hole was centrally drilled at the base of the elliptical ring, whose radius is identical to the dielectric radius of an SMA connector to connect the antenna to the connector.

Antenna Design and Parametric Study
To overcome bulkiness, the feeding gap (h), the CDM thickness (t), and the ring length (l) were 1 mm. Based on the length of quarter-wave monopole operating at 3 GHz, the initial CDM diameter was 25 mm (c � 12.5 mm).
Initially, the simulation was carried out using a circular ring, where a � b. e feeding gap (h) was optimized to prevent electrical short circuit. As a result, h was 1 mm and the radius of the circular ring was 14 mm. e parameters of the circular ring antenna are tabulated in Table 1. However, these parameters failed to achieve |S 11 | < − 10 dB across the UWB spectrum, as shown in Figure 2. In the figure, with the circular ring, the impedance matching (|S 11 |) was achieved slightly above 7 GHz and again 10.66 GHz, failing to cover the entire UWB spectrum. As shown in Figure 2, to cover the UWB spectrum with the circular ring, a large ground plane of 100 mm × 100 mm was required. To achieve size compactness, the large ground plane is undesirable. e CDMexcited elliptical ring is proposed to accomplish UWB operation without using a large ground plane. e radius of CDM (c) and the dimension of elliptical ring axes (a and b) are varied to cover the UWB frequency range.
To realize the size compactness with UWB characteristics, the parameters were individually varied and simulated |S 11 | determined. Figure 3 shows the simulated |S 11 | under varying a (11-15 mm), given the other antenna refined parameters remaining constant.              International Journal of Antennas and Propagation remaining unchanged (Table 1).
e results validate the elliptical ring antenna parameters.

Antenna Characteristics
A prototype antenna was fabricated according to the elliptical ring antenna refined parameters in Table 1. Figures 9(a)-9(b) show the prototype antenna and the coordinate system. In Figure 10, the simulated and measured results showed that the bandwidth of the antenna covered the entire UWB spectrum. Instead of using the CDM with the ground plane size 100 mm × 100 mm, the proposed antenna using the CDM-excited elliptical ring can also cover UWB with a compact size. e discrepancy could be attributed to the coupling effects of the connecting cable.
Ideally, the antenna gain is flat under the distortionless condition [21]. Figure 11 shows the simulated gain in the boresight direction, varying between 3.1 and 4.8 dBi (<3 dBi), indicating flat gain. e average simulated gain is 3.9 dBi along the UWB spectrum. Because the proposed antenna contained no dielectric materials, it achieved very high radiation efficiency (almost 100%) along the UWB spectrum.
e CDM-excited elliptical ring antenna radiated bidirectionally over 3.1-10.6 GHz. e measurement setup for the radiation pattern are shown in Figure 12. e standard horn antenna ETS model 3115 is used as the transmitting antenna, and the antenna under test (AUT) is used as the receiving antenna. e distance between the antennas are maximized for closed to uniform plane wave. e position of the AUT is located by line-of-sight alignment. e radiation pattern measured results at a frequency of 3.1 GHz, 6.8 GHz, and 10.6 GHz were carried out by E-and H-planes. e comparison between simulated and measured radiation patterns are shown in Figures 13(a)-13(c). Table 2 presents the main beam direction and half-power beamwidth (HPBW) of the antenna. A plus sign indicates that the main beam is tilting upward from z to + y axis, and a minus sign indicates that the main beam is tilting downward in the direction of − y axis. e main beam direction is influenced by the induced electric fields from various antenna components. Figure 14 shows the contour with color map and excitation levels of electric fields on the z-plane (5 mm) at the boresight of the antenna aperture. From 3.1 GHz to 6.8 GHz, the induced electric fields in the direction perpendicular to the z axis (between the top of the CDM and the top of the ring) continually increased, resulting in a downward tilted main beam (Figure 14(a)). At 6.8 GHz (the center frequency), the electric fields mostly radiated without induced electromagnetic fields at the top and bottom of the elliptical ring, as shown in Figure 14(b). erefore, the main beam was in the boresight direction. At 10.6 GHz, stronger induced electric fields near the feeding point and the connector were observed in the direction perpendicular to the z axis, resulting in an upward tilted main beam (Figure 14(c)). e main beam in E-plane was tilted upward as the frequency increased from 6.8 GHz to 10.6 GHz.  International Journal of Antennas and Propagation e boresight direction, however, remained in the HPBW region, resulting in bidirectional radiation over the UWB spectrum. e cross polarization is also very low in the boresight direction. Table 3 provides a comparison between the performance of this antenna with the current state of the art in UWB antennas. ese antennas were designed to meet the application requirements with a very wideband frequency range and desirable radiation characteristics. Furthermore, the low profile and size compactness are important features for actual applications. e antennas with a flat ground plane or reflector are low profile at the expense of a large planar dimension [3][4][5][6][7][8][9]. e modified biconical antenna [10] without a flat ground plane can overcome the bulky ground plane. However, the antenna volume is relatively huge. e patch antennas using a printed circuit board (PCB) [11][12][13][14][15][16][17][18][19] that can accommodate the radiator and ground plane within the single structure such as coplanar waveguide (CPW), strip line, and partial ground plane can reduce the overall antenna size with the suffered gain limitation. Apparently, the antenna presented in this work is compact with a very wide impedance bandwidth and efficient gain.

Antenna Performance for UWB Communications
e performance of the UWB antenna could be assessed by pulse distortion attributable to the effect of the propagation path. In this research, the magnitude and phase of the antenna transfer function (H rad ) were characterized at different angular positions of a receiving probe in E-plane and H-plane. e angular position (θ) and probe direction (+ and − ) along E-plane and H-plane were illustrated in Figure 9(b). Figure 15 shows the simulated magnitude and phase of H rad in the boresight direction, given an antenna/probe propagation distance of 9.7 cm (in the far-field region). |H rad | was normalized to remove the effect of the propagation distance. e normalized |H rad | is sufficiently flat with 1.9 dB variation over the UWB spectrum. e phase of H rad is of linear phase response, independent of propagation distance and time as the cycles of phase variation are proportionate to distance and time. Figures 16-18 illustrate |H rad | at various angular positions in E-plane and H-plane. e E-plane of the antenna is nonsymmetrical, so the plus and minus signs are used to indicate the direction.   International Journal of Antennas and Propagation Meanwhile, the H-plane is symmetrical. e flat magnitude and linear phase were observed over the UWB spectrum in the boresight direction but deteriorated outside the boresight direction. In Figure 16, the pulse distortion in H-plane evidently increased beyond 6 GHz and became more pronounced with larger angles. is could be attributed to the fact that beyond 6 GHz, the electric fields in the area between the CDM and the elliptical ring were induced.
e simulation was carried out by positioning the probe 3 meters away from the transmitting antenna. e electric fields received by the probe were measured in the boresight direction. In general, variations in the propagation distance affect the signal amplitude and time delay. However, since the amplitude was normalized, the propagation distance could be ignored. Figures 19(a) and 19(b) illustrate the input pulses in the time domain and the normalized electric fields for the fifth-order derivative Gaussian pulse and modulated Gaussian pulses with 6 GHz band rejection, with the corresponding correlation factors (ρ) tabulated in Table 4. e small discrepancies between the input and radiated pulses correspond to the simulated |H rad | in the boresight direction ( Figure 15).

Conclusions
is study proposes an elliptical ring antenna excited by a circular disc monopole. e proposed antenna could achieve ultra-wideband and bidirectional radiation characteristics in the 3.1-10.6 GHz frequency range. e antenna gain and |H rad | are sufficiently flat with linear phase response over the UWB spectrum. In addition, the correlation factors (ρ) between the input and radiated pulses for the fifth-order derivative Gaussian pulse and modulated Gaussian pulse with 6 GHz band rejection are 0.98 and 0.93, respectively. e CDM-excited elliptical ring antenna possesses several attractive characteristics, including economy, compactness, and ease of fabrication with a gain of 3.9 dBi. e antenna is suitable for UWB communications.

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e authors declare that there are no conflicts of interests regarding the publication of this paper.