Antenna design

The final design of the UWB antenna with quintuple band-notched function is shown in Fig. 1. It consists of a rectangular radiating patch, a microstrip feeding line, and a notched ground plane. The notches on the ground plane are applied to optimize the electromagnetic coupling effects and improve the bandwidth of the monopole antenna.

The size of the proposed antenna is 28 mm × 25 mm. It is printed on an FR4 substrate with a thickness of 0.8 mm. The relative permittivity of the substrate is 2.65, and loss tangent is 0.036. Two rectangular slots (S1) and three inverted U-shaped slots (S2, S3, S4) are inserted into the radiating patch to realize quad band-notched characteristics.

The evolution of the proposed band-notched antenna is shown in Fig. 2, and the corresponding reflection coefficient curves are compared in Fig. 3. Figure 2(a) shows the basic structure of the rectangle monopole antenna. It can be seen from Fig. 3(a) that the impedance of antenna (a) in Fig. 2(a) is not ideal at a high frequency (8–11 GHz), and does not meet the requirements of UWB antennas. In Fig. 2(b), two notches on the ground plane are applied to optimize the electromagnetic coupling effects and improve the bandwidth of the monopole antenna. It can be seen from Fig. 3(a) that after the ground plane is modified, the high-frequency reflection coefficient of antenna (b) has been significantly improved, and the −10 dB working bandwidth of antenna (b) is 3.1–11 GHz, which meets the requirements of UWB. In [Reference Ojaroudi, Ghobadi and Nourinia3], two rectangular slots on the radiating patch and a T-shaped notch on the ground plane are used to obtain broad bandwidth for the UWB antenna. In our study, we also find that the two rectangular slots on the radiating patch can also generate band-notched characteristics when we change the length of the two slots, as shown in Fig. 4. Therefore, in Fig. 2(c), two rectangular slots are designed on both sides of the antenna to suppress C-band interference, as seen in Fig. 3(a).

Fig. 2. The evolution of the quad and quintuple band-notched antennas. (a) Monopole antenna without notched ground plane; (b) monopole antenna with notched ground plane, UWB characteristics, and without any notched bands; (c) UWB antenna with two rectangular slots; (d) UWB antenna with three inverted U-shaped slots; (e) UWB antenna with quad band-notched characteristics; (f) UWB antenna with quintuple band-notched characteristics.

Fig. 3. Simulated reflection coefficient for the six antennas shown in Fig. 2.

Fig. 4. The reflection coefficient of the antenna in Fig. 2(b) with a rectangular slot of different length.

In general, to obtain more notched bands, various slots can be added to the radiating patch, such as U-shaped, C-shaped, T-shaped, or SRR close to the feeding line. Here, as seen in Fig. 2(d), three inverted U-shaped slots are added to the radiating patch to form the other three notched bands, such as WiMAX, lower WLAN, and higher WLAN. Additionally, slots with a similar shape of the antenna can generate stronger resonance than any other shapes [Reference Han, Chen, Han, Chen, Ma and Zhang15]. It can be seen from Fig. 3(a) that, as described above, the antenna (d) has a good notch effect, and each stop band formed in the UWB antenna can be adjusted independently, and deep reflection zeros are formed between the adjacent stop bands. The formation of reflection zeros improves the band-edge selectivity of the stop band, and the notch characteristics are more prominent. Antenna (e) in Fig. 2(e) can be regarded as a combination of antenna (c) and antenna (d). Judging from the simulation results, the combined antenna (e) is getting more notches and has no negative impact on other frequency bands. The relationship between the notch frequency and the length of the slots are summarized by the following formula:

(1)$$f_{notch} = \displaystyle{{3 \times {10}^8} \over {2L_{slot}\sqrt {\varepsilon _{eff}} }}.$$

In this formula, f _notch is the center frequency of notch band, L _slot (in mm) is the total length of the slot and ɛ_eff ≈ (ɛ_r + 1)/2 is the effective dielectric constant. Based on (1), we can calculate the length of the slot at the very beginning of the design and then we can achieve quad band-notched antenna shown in Fig. 2(d). X-band as an interference frequency for the UWB systems is rejected in reference antenna [Reference Xu, Shen, Zhang and Wu34]. As we all know, C-band as an interference frequency for the UWB systems also needs to be rejected [Reference Cho, Kim, Choi, Lee and Park8]. Since the interference frequencies of C-band and X-band are adjacent, it is difficult to suppress them separately. One way to reject the two interference bands is to create a notched band with wide bandwidth, as seen in [Reference Xu, Shen, Zhang and Wu34–Reference Modak, Khan and Laskar38]. However, the notched band is usually generated by using only one resonator and cannot offer a sharp selectivity to meet the requirements of practical applications in most band-notched UWB antennas. The selectivity of the notched band is a crucial parameter in the band-notched UWB antenna design, which should be taken into consideration in the practical applications. So a wide high-selectivity notched band is formed by adding a pair of rectangular slots and a pair of symmetrical L-shaped slots. It is obvious in Fig. 3(b) that the bandwidth of the notched frequency is improved when the new slots are added near the rectangular slot S ₁. Two notched bands could be produced by the use of two slot resonators. The two notched bands are coupled together to shape a single notched band with second-order characteristics, and two reflection zeros are generated at the sides of the notched band. As a result, a wide stop band with high selectivity is achieved. Furthermore, as can be seen in Fig. 2(f), a pair of novel Rho-shaped resonators is designed near the feeding line to achieve notched function at ITU service bands (8.025–8.4 GHz) and then a compact quintuple band-notched UWB antenna is obtained, as seen in Fig. 3(b). All the parameters of the proposed antenna have been optimized by using commercial full-wave software CST Microwave Studio (http://www.cst.com). The optimal dimensions of the presented band-notched UWB antenna are summarized in Table 1.

Table 1. Final dimensions of the proposed design

Parametric study

In order to avoid repeated discussion, we chose the quintuple band-notched UWB antenna as the object of studying the parametric. Table 2 illustrates the calculated values and optimal dimensions of the slots obtained from the CST simulation. It is found that there are slight differences between them. As shown in Fig. 1, the length of the rectangular slot S ₁ is $L_{S_1} = L_2 = 16\,{\rm mm}$, which is about half of the guide wavelength (0.49 λ_g), where the guide wavelength is $\lambda _g = \lambda /\sqrt {\varepsilon _{eff}}$. λ is the free space wavelength. The width of the slot S ₁ is $W_{S_1} = W_3-W_2 = 1.5\,{\rm mm}$. The wide bandwidth notched frequencies for C-band and X-band are generated by using the two rectangular slots and a pair of symmetrical L-shaped slots. So both slots are used for studies. Figure 5(a) shows the length of rectangular slots and L-shaped slots have an obvious influence on the center of the notch frequency. It is found that by decreasing the length of rectangular slots (by changing L ₂) from 17.5 to 16.5 mm and decreasing the length of L-shaped slots (by changing L ₃) from 6.65 to 6.15 mm, the notch frequency shifts toward the higher frequency clearly, and have slight effects on other notch frequencies. When the lengths of the rectangular slots are fixed, by changing the L-shaped slots, we can alter the bandwidth of the notch frequencies at C-band and X-band as seen in Fig. 5(b). In Fig. 5(b), it is observed that as the length of the L-shaped slots increased from 5.9 to 6.9 mm while fixing the rectangular slots length at 17 mm, the bandwidth of the notch frequency is changed from 6.8–7.5 GHz to 6.8–8 GHz.

Fig. 5. The rectangular slot and L-shaped slot lengths on wide band-notched frequencies at C-band and X-band. (a) Changing L ₂ and L ₃, (b) fixing L ₂ and changing L ₃.

Table 2. The calculated correlation factors of three configurations in different cases

The effects of lengths and widths of three inverted U-shaped slots on the notched frequencies are also analyzed where only one parameter is changed each time, with the other parameters fixed, as shown in Fig. 6. Figures 6(a)–6(c) display that the length of the three inverted slots has a decisive influence on the center of the notched frequencies. It is found that by decreasing the lengths of three inverted U-shaped slots, respectively, the center of notch frequencies shifts to the higher frequency apparently. Figure 6(d) shows the effect of one of the inverted U-shaped slots. It is found that the thinner the width of U-shaped slots, the narrower the bandwidth of the notch frequency (WiMAX). Similarly, the notched frequency bandwidth of lower WLAN and higher WLAN can also be changed by changing the width of inverted U-shaped slots, respectively.

Fig. 6. The inverted U-shaped slot length and width effect on notched frequencies. (a) The slot length effect on the center frequency of WiMAX band by changing L ₉. (b) The slot length effect on the center frequency of lower WLAN band by changing L ₁₀. (c)The slot length effect on the center frequency of higher WLAN band by changing L ₁₁. (d) The slot width effect on the bandwidth of WiMAX band by changing W ₁₅.

The fifth notch frequency is achieved by a pair of Rho-shaped resonators, as shown in Fig. 7. The main effects of the Rho-shaped resonators are its size and the distance from the feeding line. The equivalent-circuit model of the Rho-shaped resonator and the antenna is shown in Fig. 7. Therefore, the notch frequency generated by the Rho-shaped structure is obtained and can be calculated by $F_{Rho} = 1/\left({2\pi \sqrt {L_P( C_0 + C_P) } } \right)$. The capacitance C ₀ denotes coupling between the resonators and feeding line. The capacitance C_p is caused by the voltage gradients between the patch and ground plane, whereas the inductance L_p is generated by the current flowing through the Rho-shaped structure. In this design, the Rho-shaped structure can be referred as a half/one-wavelength resonator. To achieve the desired band-notched function, the band-notched frequency is given approximately by the expression

(2)$$f_{Rho} = \displaystyle{c \over {2L_{Rho} \times \sqrt {\varepsilon _{eff}} }}, \;$$

(3)$$L_{Rho} = L_6 + W_5 + \displaystyle{{360-\varphi } \over {360}} \times 2\pi r.$$

Fig. 7. The equivalent-circuit model of the Rho- shaped resonator.

In this formula, f_Rho is the resonant frequency at 8.2 GHz, c is the speed of light in free space, L_Rho is the total length of the Rho-shaped structure, which can be calculated through (2) and ɛ_eff ≈ (ɛ_r + 1)/2 is the effective dielectric constant. The value of the inductor L_p mainly depends on the length of the Rho-shaped structure, so when the angle of the φ is changed, the corresponding inductance and resonant frequency will also change and the corresponding reflection coefficient with different φ is shown in Fig. 8(a). As can be seen from Fig. 8(a), the notched frequency is shifted from 8.3 to 7.9 GHz as the angle of the gap (φ) range from 74 to 86°. The effect of the Rho-shaped distance from the feeding line on the notch frequency (ITU service bands) is shown in Fig. 8(b). It is observed that as the Rho-shaped resonators are moved from the feeding line from 0.1 to 0.4 mm, the bandwidth of the ITU service bands is narrowed apparently.

Fig. 8. The simulated return loss at ITU bands with different Rho-shaped size and distance from the feeding line. (a) Changing the size of Rho-shaped resonators by changing φ, (b) changing the distance from the feeding line by changing W ₇.