1. Introduction
5G technology offers high channel capacity, a high data rate, and channel aggregation with low latency over MIMO fading environments. On the other hand, 5G components need to be compact to be incorporated into modern portable devices, such as smartphones and tablets, which tend to be slim and lightweight, while also requiring high processing capabilities [
1].
Beam scanning antennas play a key role in 5G communication systems to attain the desired outputs. The use of beamforming feeding networks (BFNs) is an essential technique to obtain high directivity in a particular direction and improve the connection quality as well as coverage of 5G systems [
2]. The function of BFNs is to adjust the phase and amplitude of feeding signals for phased array antenna systems [
3]. The Butler matrix (BM) is one of the most common BFNs of 5G systems owing to distinctive features such as simplicity, lower cost, and an easy fabrication process. In addition, the BM does not need external biasing in its operation. Further, the BM operates as a reciprocal feeding system for transmitting and receiving signals in phased array antenna systems. The building block of the BM is the BLC, which can be utilized as a modulator, mixer, and phase shifter as well as its basic function as part of a feeding network for phased array antenna systems [
2]. Therefore, this work focuses on the design of a compact BLC with an enhanced bandwidth. As illustrated in
Figure 1, a BLC consists of four transmission lines grouped into two pairs, with each pair consisting of parallel horizontal and vertical lines. The characteristic impedance of the horizontal lines is Z
o/√2, while for the vertical counterparts, it is Z
o, where Z
o represents the characteristic impedance of the microstrip transmission line (MSTL). Each of the four transmission lines (TL) has a length of λ
g/4, where λ
g is the guided wavelength. Thereby, the dimensions of the BLC are primarily based on the operating frequency, and thus in low frequencies, the BLC extends over a large area of the host device board and hence leads to an increased size [
4]. Another inherent issue with a conventional BLC is the limited bandwidth characteristics of no more than 50% that restrict their applications and require a large multi-sections circuit to gain wideband characteristics, which in turn increase the circuit’s area [
5].
On the other hand, in high-speed systems, microstrip lines find applications in transmitting signal pulses rather than analog microwave signals. These systems encompass various domains, including very high-speed computer logic (operating at GHz clock rates), high bit-rate digital communications, high-speed samplers for oscilloscopes or time-domain reflectometers, and radars [
6]. One crucial characteristic of microstrip lines in these scenarios is propagation delay, which depends on the effective dielectric constant. However, there are situations where it becomes necessary to extend this delay. One approach to achieve this extension in effective propagation delay is by constructing a slow-wave transmission line. This can be accomplished, for instance, by introducing capacitive loading at intervals along the microstrip. In such cases, the delay is influenced by these capacitances, leading to a reduction in
νp (velocity of propagation) and effectively slowing down the pulse when the capacitance (C) is increased [
6].
Many efforts have been reported that address the above limitations. For example, the concept of coupled line unit cells was introduced in [
4] to create a dual composite right/left-handed (D-CR/LH) unit cell, which results in a design that has a miniaturized area of ~52% of that of a conventional BLC at 1.8 GHz with a relative bandwidth of 18%. T-shaped slots and open stubs were employed in the horizontal and vertical arms of the BLC, resulting in a 30% bandwidth improvement and a 12.3% size reduction [
5].
In another study, a double-layer board with slow-wave microstrip transmission lines and blind vias was used to achieve a 43% size reduction compared to a conventional design at the same resonant frequency. However, the increased number of vias led to higher insertion losses and design complexity [
7]. A Koch fractal-shape BLC of various iterations was suggested in [
8], where the sample was designed to operate at 2.4 GHz and offered a size reduction of ~81% in combination with a relative bandwidth of 33%.
In [
9], a compact artificial transmission line was proposed for compact microwave components. The transmission line combines resonant-type composite right/left-handed transmission lines (CRLH TLs) with fractal geometry. Two sets of planar CRLH cell structures were provided: one based on a cascaded complementary single split ring resonator (CCSSRR), and the other based on complementary split ring resonators (CSRRs). A dual-band bandpass filter (BPF) and a monoband branch line coupler were designed based on the suggested artificial line.
The effectiveness of integrating CRLH TL and fractal geometry for designing compact broadband microwave devices was confirmed in [
10]. In this study, a proposal was made for a compact balun with improved bandwidth, utilizing a completely artificial fractal-shaped composite right/left-handed transmission line (CRLHTL). Chip components were employed for the left-handed contribution, and fractal microstrip lines were utilized for the right-handed part, focusing on miniaturization. This innovative technology provided an extra degree of flexibility in crafting compact devices and demonstrates superiority over alternative methods.
In [
11], open-ended stubs and transmission line meandering with a stepped impedance approach was proposed with a size reduction of ~61% and 50% compared to a conventional BLC, respectively. However, the narrow bandwidth of ~130 MHz represents a key limitation. A flexible coupler using a Teslin paper substrate was reported [
12]. It replaced the conventional quarter-wavelength transmission lines with a collective of shunt open-stubs, series transmission lines, and meandered lines, resulting in a compact design with a surface area of 0.04
and a 68% fractional bandwidth. Using a dual microstrip transmission line, the BLC size was reduced by 32% with a fractional bandwidth of 60% [
13]. However, this approach had poor return losses over the operating bandwidth. To improve matching, T-shaped transmission lines were used, reducing fractional bandwidth and size to 50% and 44%, respectively. A compact BLC class introduced a prototype using open-circuited stubs to replace traditional quarter-wavelength transmission lines [
14], resulting in a ~55.6% size reduction and achieving 11% and 50% fractional bandwidths for narrowband and wideband modes of operation, respectively.
In [
15], a new configuration, BLC, is presented. The design applies two types of trapezoid-shaped resonators on the arms of the BLC to configure a wideband branch-line coupler. The proposed design achieved a size reduction of 79% compared to conventional couplers. In addition, it offers a fractional bandwidth of 22.2%. Ref. [
16] used artificial transmission lines (ATL) for miniaturization. They replaced conventional transmission lines with right-handed transmission lines (RHTL) and constructed the branch-line coupler sides using cascaded T-Net RHTLs instead of quarter-wavelength transmission lines. This design achieved a 50% size reduction compared to the conventional BLC and a 33.3% fractional bandwidth (2.0–2.8 GHz). A simple method was used to improve bandwidth in [
17]. By adding a single transmission line element to a conventional coupler, they increased bandwidth by approximately 25%. However, the proposed structure is larger at 25.7 × 22.8 mm
2 compared to the conventional coupler’s 21.5 × 20.7 mm
2.
Triangular and trapezoidal resonators were added to the coupler for miniaturization and harmonic suppression [
18]. The design achieved an 84% size reduction and wide harmonic suppression. However, it has a complex structure with a low-frequency band around 200 MHz, representing a 26% fractional bandwidth (FBW). A bandpass filter operating in three frequency bands utilized a dual-layer structure with distinct dielectric constants, as described in [
19]. The dual-layer design was employed to diminish the overall size and enhance the isolation between the passbands. Consequently, the suggested configuration offers benefits such as a nearly 50% reduction in physical size and the alleviation of design constraints by utilizing the two substrates within a unified structure.
The majority of the aforementioned prototypes were based on composite right/left-handed structures to create branch lines, which might result in unfavorable characteristics that are associated with miniaturization such as shallow return losses for input ports, poorly isolated ports, and narrow bandwidths in some cases [
3,
4,
6,
8]. In addition, the structures of right/left-handed transmission lines probably increase the structure’s complexity, which results in a challenging practical realization despite the overall size reduction.
In this study, a quasi-twisted shape branch line coupler is proposed, which is the longitudinal bisection of a conventional BLC into two sections and twisting each over the other. The structure is designed based on the microstrip double-layered TL (MDL-TL). The input/output transmission lines and horizontal arms of the BLC are built based on a Z-shape meandered section with round blend edges, while the λg/4 vertical arms of the BLC are adopted for the slow wave structure. The MDL-TLs are placed on two layers and connected using four conductive vias. A common ground plane is placed between the layers of the MDL-TLs, which incorporate circular slots around the vias to avoid shorting them to the common ground plane. The described configuration reduced the size of the conventional BLC by 49.9% and improved the relative bandwidth to 75.8%. The novel design is modelled and simulated using a computer simulation technology (CST) microwave studio and then fabricated and tested on a low-cost FR-4 substrate material demonstrating promising S-parameter results.
This paper is organized as follows:
Section 2 explains the theoretical analysis and design procedures of developing a wideband MDL-TL and compares the achieved performance with that of a conventional microstrip line;
Section 3 presents the analysis and design of a branch line coupler based on MDL-TL; finally,
Section 4 presents the simulated and measured results demonstrating the novel BLC performance.
4. Fabrication and Measurements
The proposed novel miniaturized BLC, shown in
Figure 10, was fabricated on an FR4 substrate with a dielectric constant of 4.4 and a thickness of 0.8 mm, where a thin ground plane of 70 µm thickness was inserted between the two FR4 substrates, forming a sandwich-like structure. Both substrates were truncated at their corners using cross-sectional areas of 2 × 5 mm
2 each to expose the ground plane and enable the SMA connector to be easily connected, as illustrated in
Figure 10b.
The fabricated novel BLC was measured using an HP 8720B vector network analyzer (VNA) from Test Equipment Center, Inc., Gainesville, FL, USA, as shown in
Figure 10c. The reflection coefficient and isolation coefficient between input ports 1 and 3 as well as the transmission and coupling coefficients were measured by connecting the relevant ports to the VNA, while the remaining ports were terminated by a 50 Ω load to prevent additional mismatching and increase the measurements’ reliability, as illustrated in
Figure 10d.
As per the design specifications of the proposed BLC, the required phase difference between the output signals is 90°. This phase difference can be verified by measuring the phases of the transmission coefficients, S
21 and S
43, and coupling coefficients, S
41 and S
23, at the output ports 2 and 4. Once these measurements are carried out, the phase difference can be determined as follows:
The performance of the proposed BLC is evaluated by observing the four-port S-parameters’ magnitudes and phase differences as shown in
Figure 11. The four principal scattering parameters considered in the analysis are as follows: the reflection coefficient (RC) S
11, transmission coefficient (TC) S
21, isolation coefficient (IC) S
31, and coupling coefficient (CC) S
41, when port 1 is excited as the input port. On the other hand, when port 3 is excited, the required scattering parameters, S
13, S
23, S
33, and S
43, are considered. Ports 1 and 3 were chosen as they are located on opposite sides of the coupler and are designated as input ports. In addition, from
Figure 11a, it is evident that a good agreement was accomplished between the simulated and measured reflection coefficients. For example, the measured −10 dB S
11 bandwidth extends from 4.6 GHz to 10 GHz, which corresponds to a relative bandwidth of 73.9% compared to a typical bandwidth of ~40% from an identical traditional branch line coupler. As a result, the proposed configuration offers a substantial bandwidth enhancement.
The transmission and coupling coefficients, S
21 and S
41, respectively, are presented in
Figure 11b with good agreement between measurements and simulations. From these results, it can be observed that both the transmission and coupling coefficients are −3.9 dB at the desired frequency of 6 GHz, which is close to the ideal value of −3 dB. Notably, S
21 remains higher than −3.5 dB for the entire operating band ranging from 5.8 GHz to 10 GHz. However, the coupling coefficient, S
41, gradually degrades with increasing frequency, possibly due to vias and substrate losses since the input port and coupled ports are located on opposite sides of different substrates. Despite this degradation, the power delivered to port 4 remains greater than −7.5 dB up to a frequency of 8 GHz.
Furthermore, the isolation coefficient between the input ports, S
31, as shown in
Figure 11c demonstrates a magnitude of less than −13 dB throughout the operating band, signifying a good isolation between the input ports. This ensures that the proposed BLC meets the necessary design specifications for optimal performance.
Finally,
Figure 11d presents the difference between the phases at the output ports 2 and 4 for input excitations from port 1. A 90° phase difference is required between the output signals. At a design frequency of 6 GHz, the phase difference between the output ports for inputs from port 1 is (∠S
21 − ∠S
41 = 90.50°), which satisfies the required phase difference for typical BLC design specifications. In addition, the phase difference error (PDE) is 0.5° for the designed frequency of 6 GHz, which is marginal.
Figure 12 presents the proposed BLC performance when port 3 is excited. From
Figure 12a, it is evident that the −10 dB S
33 bandwidth extends from 4.5 GHz to 10 GHz, which corresponds to a relative bandwidth of 75.8% compared to ~40% for the traditional branch line coupler based on the same design specifications and operating frequency of 6 GHz. It should be noted that a marginal difference of 1.9% occurs between the reflection coefficients’ bandwidths of S
11 and S
33. The transmission coefficient, S
23, and the coupling coefficient, S
43, for port 3 excitations are illustrated in
Figure 12b. At the target band, i.e., at 6 GHz, the transmission and the coupling coefficients of the proposed BLC design are −3.9 dB, which is close to the ideal value of −3 dB. Notably, the transmission coefficient, S
43, remain higher than −3.5 dB for the entire operating band ranging from 5.8 GHz to 10 GHz, and this behavior is consistent throughout this wide operating frequency range. However, the coupling coefficient, S
23, gradually degrades with increasing frequency, and this is due to the use of vias as well as losses inherited from the lossy FR4 substrates, as the input port and coupled ports are located on opposite sides of different substrates. Despite this degradation, the power delivered to port 4 remains greater than −7.5 dB up to a frequency of 8 GHz. In
Figure 12c, the isolation coefficient between input ports, S
13, is depicted. It is evident that S
13 remains less than –14 dB throughout the operating band. It can be concluded that the proposed miniaturized BLC has excellent performance in terms of scattering parameters (S-parameters) compared to a traditional BLC design. Additionally, based on the obtained results, it can also be confirmed that the ports are reciprocal and have the same S-parameters characteristics for all ports. This consolidates the principle that the proposed miniaturized BLC can be used as a unit cell for constructing a Butler matrix, which in turn has potential use in the development of phased array antenna systems.
Figure 12d illustrates the phase difference between output ports 2 and 4 for input excitations from port 3. At a frequency of 6 GHz, the phase difference between output ports for input from port 3 (∠S
43 − ∠S
23 = 94.8°) meets the requirements of a BLC coupler for good performance. However, a slight discrepancy between the simulated and measured phases is observed for input port 3. This difference may be attributed to fabrication tolerance and the lump solder for SMA feeders. Nevertheless, the phase difference error (PDE) at a design frequency of 6 GHz is 4.8° for input port 3 excitation.
Table 2 provides a comparison between the performance of the proposed BLC and those of previously published BLC designs. Most of the designs presented in
Table 2 were focused on either improving the bandwidth or reducing the size of the BLC. The proposed work, however, achieves both bandwidth enhancement and size reduction, which is crucial for the design of a 5G system. Furthermore, when compared to the literature, the proposed miniaturized wide band BLC offers other advantages such as design simplicity, ease of fabrication, smaller phase difference errors, and equal power distribution among output ports at a design frequency of 6 GHz.