Pattern Diversity Based Four-Element Dual-band MIMO Patch Antenna for 5G mmWave Communication Networks

Fifth Generation (5G) technology has gathered significant attention from researchers, propelled by the relentless pursuit of enhancing both infrastructure construction and terminal installations. This heightened interest stems from the continuous exploration and refinement aimed at bolstering the capabilities of 5G networks, fostering a landscape where faster data speeds, lower latency, and increased connectivity are not only sought after but also imperative for meeting the evolving demands of our interconnected world [1]. 5G technology currently uses lower frequencies (sub-6 GHz) for wide-area coverage, while higher frequencies, or millimeter-wave (mmWave) bands, are still being developed for local area networks and short-range indoor communications [2, 3]. Because of its broadband and consequent ability to provide multigigabits per second data speed, the intended exploitation of the mmWave band will unquestionably boost the efficient communication experience compared to the sub-6 GHz band [4, 5]. To build their own standards, many nations have chosen specific frequencies for 5G mmWave applications, such as 27.5–28.8 GHz for Japan, 28 GHz for Korea, and 24.2–27.5 GHz/37–43.5 GHz for China [6]. In October 2015, the Federal Communications Commission (FCC) suggested a careful examination of the spectrum at 28 GHz, 37 GHz, 39 GHz, and 64–71 GHz. Therefore, devices for these bands are essential for 5G communication systems [7, 8].

The mmWave antenna design faces significant challenges, primarily focusing on bandwidth enhancement and size reduction while maintaining low profile, multiple resonance capabilities, and cost-effectiveness. Adhering to international standards for the mmWave band, the adoption of dual-band realization is prevalent, offering advantages such as improved signal strength, reliability amidst interference, expanded coverage in challenging terrain, and reduced interference through separate frequency bands. Dual-band antennas contribute significantly to enhancing the performance and reliability of wireless communication systems, making them indispensable in modern communication technology. In mmwave spectrum, Intelligent Reflective Surfaces (IRS) hold immense potential. In IRS through deploying reflective surfaces can overcome fading effects hurdles effectively. By manipulating and redirecting mmWave signals, IRS optimizes their propagation, extending coverage and enhancing signal strength. However, IRS technology can be expensive, particularly in large-scale deployments where numerous reflective elements are required. This cost may pose a barrier to widespread adoption, especially for smaller operators or in resource-constrained environments [9‐11]. In [12] authors presented an IMS-based pattern and beam reconfigurable antenna designed for diverse IoT applications, including V2X communication and 5G Small Cell deployment, both indoors and outdoors. This antenna system combines a wideband monopole with a programmable IMS acting as a reflector, offering versatility in radiation pattern control. Utilizing a single-layered metasurface comprising a 4 × 4 array of square ring-shaped unit cells, each controllable by four diodes, the system enables precise manipulation of the reflector's shape and size, resulting in various radiation patterns from omni-directional to broadside, with single or dual beams and beam-steering capabilities in both elevation and azimuth planes. Despite its advantages, challenges such as complexity in design and calibration, power consumption due to active components, and potential high costs associated with sophisticated IMS technology remain to be addressed for wider practical adoption in IoT and 5G applications.

Despite its appealing features, 5G faces a significant drawback of signal weakening during transmission due to low penetration power. To address this, multiple-input multiple-output (MIMO) technology is crucial, enhancing data rates and communication quality by increasing antenna components on transmitters and receivers. Efforts have been made to enhance radiation performance and propose metrics for 5G massive MIMO mmWave antennas. In [13], the authors used a complex multilayer substrate integrated waveguide (SIW) transmission line-fed coupling-based technology to get MIMO characteristics at 28 and 38 GHz frequency bands. Similarly, in [14], a dual-band MIMO antenna was designed for the microwave and mmWave bands by utilizing SIW aperture-based technology. Multilayer adaptation was used to achieve a wide impedance bandwidth with minimal coupling loss. The authors in [15] achieved dual-band resonance in the mmWave band by using LTCC-based technology. A 45⁰-polarized patch antenna fed by two pairs of differential L-type probes was used to implement the filtering antenna element. Each probe was coupled to an additional square ring and open strips, which produced radiation nulls and achieved a low and high stopband rejection level of > 24 dB with excellent selectivity. Resonant cavity antenna (RCA) technology was used by the authors in [16] to attain a high gain. To cover the 28 and 38 GHz frequency bands, the heights of the second- and third-order resonances in the RCA were optimized. Stepped rings were added to the metal ground, and a circular patch was applied to a partially reflecting surface (PRS) to increase the bandwidth and gain in both bands. In a nutshell, MIMO technology has many benefits, but it also offers many challenges. To achieve the best performance, several MIMO performance parameters must be optimized.

The presented literature study suggests that at the 28 and 38 GHz mmWave frequency bands, many researchers present phenomenal work, but it lacks simplicity as most of the discussed literature worked on utilizing multilayer designs, LTCC technology, and SIW-based structures that require precise alignments during fabrication, high costs of materials and adhesives, and time consumption due to multiple fabrication trials. To cater to this problem of multilayer designs and costly materials, in this paper, a novel planar dual-band antenna intended for operation at the 28 and 38 GHz mmWave frequency bands is presented. Notable contributions and objectives of the proposed work are as follows:

A dual-band, four-element MIMO antenna design is presented for mmWave 5G communication systems. The single element of the MIMO configuration consists of a modified rectangular patch element, while the back side consists of a slot-loaded full ground plane. It is observed from the presented results that the single antenna element offers an impedance bandwidth of 2.52 GHz ranging from 26.32 to 28.84 GHz, and 7.5 GHz varies in the range of 34–41.5 GHz. After that, a MIMO antenna system is designed and fabricated. A pattern diversity configuration is utilized for the design of MIMO antennas. The MIMO antenna system offers an impedance bandwidth of 3 GHz (27–30 GHz) and 5.46 GHz (35.54–41 GHz) with a peak realized gain of 7.4 dBi and 7.5 dBi, respectively. The proposed system is novel in terms of wide bandwidth characteristics using full ground plane, directional patterns and high achieved gain as compared to printed monopole antennas which offer low gain with wideband characteristics and narrowband patch antenna structures. In addition, the isolation between the antenna elements is noted to be > 15 dB for the 28 GHz frequency band, while for the 38 GHz frequency band, the isolation is observed to be > 25 dB. Moreover, the MIMO parameter values are within acceptable limits. According to the presented results, one can conclude that the designed dual-band MIMO antenna can be considered a valuable candidate for existing or future ka band 5G communication systems.