This article presents the design and analysis of a Compact Planar Antenna with Multi-Resonant Geometry for Broadband CubeSat Applications. The antenna features a dual-layer architecture comprising a front semi-circular radiator with strategically positioned circular and rectangular slots, and a complex ground plane etched with complementary geometries to enhance performance. The optimized geometry, with key dimensions such as an overall size of 15 mm × 15 mm × 1.5 mm, enables a wide impedance bandwidth ranging from 2.9 GHz to 11.6 GHz. The impedance bandwidth of the radiator is 120%, with an electrical size of 0.14λ × 0.14λ × 0.014λ. Confirmed through both simulation and measurement using a VNA in an anechoic chamber, the gain performance increases steadily with frequency, reaching a peak of 4.2 dBi at 9.2 GHz, while maintaining a stable gain above 3 dBi between 3.8 GHz and 10.1 GHz. Radiation efficiency peaks at 87% around 5.6 GHz and remains above 75% within the mid-band range (4-8 GHz), indicating highly effective power radiation and minimal losses. Surface current and 3D radiation pattern analysis show efficient and focused radiation behavior at 6 and 9 GHz, supporting its suitability for wideband radar and secure communication applications.

This work presents a compact single-band patch antenna designed for Near-Field Communication (NFC) based skin implant applications. The antenna features an inset-fed patch structure on FR-4 substrate and resonates at 2450 MHz. Three techniques are employed to miniaturize the antenna: a shorting pin between the patch and ground, defected ground structure (DGS), and utilization of tissue electrical properties. A polyamide insulator is used to cover the antenna for biocompatibility. Thus, the optimized antenna volume is found to be 6 × 6 × 0.46 mm³, with near-perfect impedance matching of 51.14 + j4.6 Ω. The antenna also offers enhanced impedance bandwidths of 52.24%. Compared to state-of-the-art designs, the proposed antenna exhibits significantly reduced specific absorption rate (SAR) values of 1.32 W/kg and 0.152 W/kg averaged over 1 g and 10 g of tissue, respectively, in compliance with international safety guidelines. The proposed antenna is effectively free from gain limitations due to the inherently short communication range of NFC technology. Finally, the antenna is measured for its return loss ex vivo, and it is found to be in close agreement with the simulation results. Thus, the balanced performance among the compact size, large bandwidth, and very low SAR makes the antenna a strong candidate for NFC based healthcare systems.

To address the challenge of balancing sidelobe suppression and computational efficiency in phased array random phase feeding optimization, this paper proposes a multi-objective collaborative optimization scheme based on the Dynamic Shuffled Frog Leaping Algorithm (DSFLA). By establishing a hardware-compatible binary encoding model for phase quantization errors and introducing sidelobe variance constraints, the method achieves joint optimization of peak sidelobe level (PSLL) and beam pattern flatness. Simulation results demonstrate: For 32-element Taylor-weighted arrays, optimized PSLL reaches -28.6 dB (8.8 dB improvement vs. initial) with sidelobe variance reduced from 3.5 dB² to 1.2 dB²; For Chebyshev-weighted arrays, PSLL achieves -31.2 dB. The algorithm maintains robust performance under practical imperfections including element spacing perturbations (0.02λ RMS error) where PSLL stabilizes at -27.3 dB (σ=0.9 dB), and phase quantization errors (5° RMS) yielding -27.9 dB PSLL. DSFLA significantly outperforms conventional methods - reducing convergence generations from 276 to 28 and computation time by 29.2% (85 s) versus ant colony optimization while demonstrating O(N^1.5) scalability to 128-element arrays (PSLL=-32.1 dB in 218 sec). Real-time operation is feasible with PSLL=-27 dB achievable in ≤40 ms, meeting 50 ms radar beam-switching deadlines. This approach provides a practical solution for real-time beam control in high-precision phased array radar systems.

In this paper, a novel miniaturized broadband dielectric waveguide (DW) bandpass filter (BPF) with wide stopband response is proposed. The proposed BPF is composed of two square DW resonators operating in TM₁₀₁ mode. By etching a coplanar waveguide (CPW) resonator on a silver-plated metal surface in the middle of the two DW resonators, an additional resonant mode is introduced, thereby broadening the bandwidth of the filter while retaining the inherent advantages of the DW structure. Simultaneously, the CPW resonator creates a new coupling path that enables cross-coupling and introduces a controlled transmission zero (TZ). The position of the TZ can be adjusted to suppress the second harmonic of the filter, ensuring effective stopband performance. For verification, a DW BPF with center frequency of 5 GHz and a fractional bandwidth of 11.4% was designed, fabricated, and measured. The measured results are in excellent agreement with the simulated ones. Specifically, the upper stopband of the filter extends to twice of the center frequency (10 GHz), demonstrating the wide stopband characteristics of the filter.

Aiming at the crosstalk problem between multiple coupled transmission lines in high-speed interconnection, a crosstalk cancellation method based on the inverse matrix of the Coupled Transmission Lines-Transfer Function Matrix (CTL-TFM) is proposed. The method first constructs the transfer function matrix of multiple coupled microstrip lines, and then designs the corresponding circuit for the inverse matrix of the transfer function matrix at the output ports. This ensures that the transfer function matrix of the entire system is reduced to a unit matrix, effectively reducing the crosstalk between transmission lines. Simulation results show that the quality of the signal eye diagrams at the outputs of all three coupled microstrip lines is significantly improved after using this method, and the crosstalk amplitude and jitter are substantially reduced.

A 2D flat, 2D curved, and 3D finite element method (FEM) implementation of the spatially-variant lattice (SVL) algorithm is presented. This powerful algorithm is used in electromagnetics to preserve the electromagnetic properties and geometry of periodic structures that are bent, twisted, conformed, or otherwise spatially varied. Applications of the SVL algorithm include photonic crystals, metamaterials, conformal frequency selective surfaces, cloaking devices, and volumetric circuits over complex geometries. The present work shows examples of SVLs over a planar surface lattice, a doubly-curved surface lattice, and a volumetric lattice.

This paper presents the design and development of a miniaturized Multiple-Input Multiple-Output (MIMO) antenna for sub-6 GHz 5G applications, featuring reduced cross polarization and enhanced isolation between antenna elements. Utilizing characteristics mode analysis, slots are introduced in the patch to achieve orthogonal mode separation, effectively minimizing cross polarization. Further bandwidth enhancement is achieved by incorporating slot loading in the ground plane. To improve isolation between antenna elements, spiral decoupling (SD) and aperture spiral decoupling (ASD) structures are employed. The proposed MIMO antenna, with dimensions 0.32λ_o*0.32λ_o*0.01λ_o where λ_o is the wavelength at the lower band frequency of 3.5 GHz, was fabricated and experimentally tested to validate its performance. Measurement results indicate significant compactness, low envelope correlation coefficient (ECC), high gain, minimal channel capacity loss, and very low mutual coupling between elements. The measured results are in good agreement with simulated results, confirming that the proposed antenna is a promising candidate for advanced MIMO applications in next-generation wireless communication systems.

To address internal parameter ingress and external load perturbations in the speed loop of a permanent magnet synchronous motor (PMSM) and enhance the dynamic performance and robustness of its speed control system, this study proposes a novel adaptive sliding mode reaching law-based controller integrated with a global non-singular fast terminal sliding mode observer (GNFTSMO). The proposed reaching law incorporates system state variables as power functions, thereby minimizing steady-state errors and resolving the inherent trade-off between chatter suppression and rapid response. To further enhance the dynamic and steady-state performance of the PMSM control system, a GNFTSMO is designed. This observer reduces the switching gain of the convergence law while incorporating feed-forward compensation for perturbations, thereby improving the system's anti-disturbance capability. The feasibility and effectiveness of the proposed sliding mode control method are empirically validated through both simulation and experimental studies.

This paper investigates a new, simple, fast, and broadband procedure to extract the material intrinsic parameters through new mathematical modeling. It only uses the transmission coefficient of two identical lines. The method is based on the mathematical reformulation of the two transmission lines, taking into account the effects of discontinuities at the interface connecting the trapper and the connector, as well as the included S-parameters. These test cells have different lengths, so the sample under test (SUT) complex relative permittivity is determined after fixing the vacuum structure's electric length. At the same time, the mathematical formulation of the telecommunications equation, which links transmission and reflection coefficients, was used to determine the loss tangent parameter by combining the attenuation and phase coefficients. The correction of the electric length difference of the transmission coefficients resulting from the measurement of the vacuum-filled test cells is done using an affine function. The frequency is the variable parameter, and the slope (rate of variation) and the initial value (ordered at the origin) are computed according to the test cell used. On the one hand, the suggested principle has the advantage of extracting the relative permittivity of the sample under test beyond the limit set by the appearance of higher-order modes (propagated by considering the test fixture's transverse dimensions). On the other hand, the use of the reflection coefficient, although it improves the attenuation coefficient extraction, limits the characterization band of the loss tangent. A circular coaxial test fixture has been used in the 1-20 GHz frequency range to validate the proposed method with samples of various materials, including semolina, polenta, Q-Cell 5020 (ceramic powder), aquarium stone, distilled water, and phantom gel. The results are compared with those from the two transmission lines technique, as defined in its popular form.

The lightning channel is a rapidly evolving transient plasma that radiates intense electromagnetic (EM) fields and emits broadband optical radiation. This paper presents a theoretical and experimental investigation into the correlation between electromagnetic fields generated during lightning events and the corresponding optical spectra observed during various phases of the discharge. Using advanced EM field modelling and high-speed optical spectroscopy, we demonstrate that key plasma parameters such as temperature, electron density, and ionization state can be inferred from combined electromagnetic-optical datasets. This multidisciplinary analysis not only reveals the underlying physical characteristics of the lightning channel but also provides insights for future atmospheric diagnostics, lightning modelling, and protective technologies.

In this paper, a novel multiple-input multiple-output (MIMO) antenna for 5G applications in n77, n78, n79 and 6 GHz bands is proposed. The antenna structure is compact, measuring 30×50×1.5 mm³. The antenna is composed of two microstrip antenna units, which are formed of two hexagonal rings with lotus and small human, with the floor partially removed. The antenna functions in a frequency range of 3.3 to 9 GHz. The flow of coupling currents is impeded, and the isolation of the antenna is improved by the use of stepped rectangular slots and the floor of the projecting T-shaped structure, resulting in the antenna having an isolation of less than -20 dB over the entire operating bandwidth. Furthermore, the envelope correlation coefficient (ECC) is less than 0.008, the diversity gain (DG) greater than 9.95, the total active reflectance coefficient (TARC) less than -30 dB, and the channel capacity loss (CCL) less than 0.32 bit/s/Hz. The simulations and measurements of the antenna demonstrate its reliability and stability, thus indicating its potential for significant applications in 5G wireless communications.

This paper introduces a novel wideband antenna composed of fabric materials, suitable for wearable and flexible applications and a straightforward single-unit Metamaterial (MTM). The antenna design employs ShieldIT Super as the conductive fabric and Felt as the dielectric substrate, creating a lightweight and adaptable solution with dimensions of 58 mm × 34 mm × 2 mm. Operating over a frequency range of 1.88 to 6.88 GHz, the proposed antenna achieves a peak gain of 4.72 dBi and a radiation efficiency of 94%. The antenna has wide measured bandwidth from 1.2 to 3.5 GHz (97%) and 4.0 to 5.9 GHz (38%) with average measured gain of 3 dBi in the lower band and 4.6 dBi in the upper band. The MTM-inspired design features a double rectangular complementary split-ring resonator at the center of the radiating patch, which enhances bandwidth. The MTM structure exhibits epsilon-near-zero (ENZ) and Mu-negative (MNG) properties were proposed. This novel design illustrates significant advancements in wideband antenna performance and is suitable for fabric-based S band, C band, 5G, Wireless Body Area Network (WBAN), and microwave imaging applications.

The late-phase electromagnetic pulse (E3) of high-altitude nuclear explosions induces DC bias currents in power transformers via geomagnetically induced currents (GICs), threatening grid stability. Existing studies lack consensus on failure thresholds under HEMP E3 conditions. This paper addresses this gap by developing a multiphysics model of an SSZ10-40000/110 transformer exposed to simulated HEMP E3 environments. Our results demonstrate that DC currents exceeding 16.5A cause tank wall displacement (100 μm limit) and noise levels (>90 dB), with insulation breakdown occurring at 19A DC. These thresholds provide critical benchmarks for transformer protection strategies.

This paper proposes a lumped parameter microwave dual frequency filter implemented using surface mount technology (SMT), which has low-pass and band-pass characteristics. We implement a dual-band response by integrating a matching network and harnessing the inherent parasitic inductance of SMT capacitors. This strategy generates transmission zeros (TZs) in the high-frequency band, significantly enhancing frequency selectivity. The performance of the filter was verified through odd-even mode analysis and validated through experimental measurement. The experiment measured that the low pass cut-off frequency of the filter is 360 MHz, and the second channel exhibits good band-pass characteristics at 800 MHz, with an insertion loss of -2.191 dB.

This study introduces and evaluates a smaller rectangular antenna featuring parasitic mushroom patches to achieve enhanced gain and wide impedance bandwidth (WIBW) for 5G millimeter-wave (mm-wave) applications (28 GHz/38 GHz). The antenna structure consists of a simple rectangular patch fed by an inset feed microstrip line operating at 50 Ω. To improve the antenna gain and impedance bandwidth, a parasitic mushroom structure is introduced around the edges of the main patch. Additionally, to further enhance operating bandwidth and matching, two rectangular Defected Ground Structures (DGSs) are incorporated in the bottom side. The antenna is fabricated on a low-cost substrate specifically FR4 (ε_r = 4.4 , tangδ = 0.02), with dimensions of (12 × 13 × 0.8) mm³. The results demonstrate a wide impedance bandwidth of 14.2 GHz (50.71% FBW) covering frequencies of 25.98 GHz to 40.18 GHz, and the antenna achieves a maximum gain of 7.20 dB at 28 GHz and maintains an efficiency more than 80% across the entire bandwidth. These outcomes make the antenna a good choice for 5G applications at 28 GHz and 38 GHz.

This paper presents a compact four-port ultra-wideband (UWB) multiple-input multiple-output (MIMO) antenna with exceptional isolation characteristics, specifically designed for high-frequency band communications. The antenna features a sunflower-shaped radiating patch and an irregularly stepped rectangular ground structure, which are optimized to achieve broadband impedance matching and low coupling. With dimensions of 1.26λ₀ × 1.26λ₀ × 0.025λ₀, the antenna operates across 5.4-20 GHz, covering C-band (4-8 GHz), X-band (8-12 GHz), and Ku-band (12-18 GHz), while supporting multi-band communication compatibility. Simulation and measurement results show a return loss (|S₁₁|) below -10 dB over the entire frequency range, with a fractional bandwidth of 109.5%. The inter-port isolation (S₁₂) exceeds -20 dB across the band and reaches -30 dB in the high-frequency range (10-20 GHz). The antenna exhibits a radiation efficiency exceeding 80%, a peak gain of 9.3 dBi, an envelope correlation coefficient (ECC) below 0.008, a total active reflection coefficient (TARC) below -30 dB, and a group delay less than 2.3 ns, thereby meeting the stringent requirements for MIMO systems. This design offers a high-performance solution for applications in 5G, satellite, and radar communications, which combines wide bandwidth, high isolation, and low coupling in a compact form factor. The 5.4-20 GHz antenna bandwidth supplements 5G/6G applications which caters to multi-scenarios of Wi-Fi and satellite communications and facilitates signal reception and preprocessing in LEO satellite systems.

A high-impedance ground plane has been proposed that enables the reflection of magnetic fields within a frequency range of interest. When being combined with loop coil antennas or H-field-oriented structures, it can boost transmission efficiency by up to 3 dB. Although several approaches, such as mushroom-shaped protuberant surfaces paired with capacitive loading, have been described to suppress surface waves at certain frequency ranges, the shift to a desired frequency range (e.g., from 5 GHz to 1 GHz) is marginal, and their form factors make these methods less ideal for applications in power and data communication. Here, we describe new strategies for a low-profile high-impedance ground plane. The insertion of a metal ground plane between the top and bottom mushroom-shaped surfaces reinforces capacitive couplings between adjacent unit cells. When coupled with extended spiral paths, this configuration leads to an apparent change in the resonant frequency of the structure. Fabrication of the proposed structure demonstrates that the sandwiched metal ground plane, paired with extended spiral paths, leads to a noticeable shift in the resonant frequency toward lower sub-GHz ranges at given dimensions. Measurements are in good agreement with the results from the analytical model.

In order to reduce the use of rare-earth materials and solve the problem of rising manufacturing costs of permanent magnet motors due to higher rare-earth prices, this paper proposes an asymmetric segmented less-rare-earth permanent magnet motor (ASLREPMM), which combines NdFeB permanent magnets with ferrite permanent magnets to form a common excitation source. In order to efficiently design the parameters of this motor, an optimization strategy of sensitivity stratification and multi-objective optimization is proposed, with output torque, torque pulsation, cogging torque and peak air-gap magnet density as the optimization objectives, and multi-objective optimization is carried out on the optimization variables with high sensitivity. Compared with the V-type permanent magnet motor (V-type PMM), the cogging torque of the optimized ASLREPMM is decreased by 49.67%, torque pulsation decreased by 10.77%, peak air-gap magnetic density increased by 0.051 T, and the total amount of NdFeB material decreased by 2184 mm³. The reasonableness of the structural design and the effectiveness of the optimization of the ASLREPMM are verified through experiments.

This paper addresses the challenge of inter-band interference suppression in Dual-Band Power Amplifier (DBPA) by proposing a high-isolation dual-band power amplifier design integrated with a Ring-Coupled Bandstop Filter (RCBSF). Through a ring-coupled structure of main transmission lines and coupled branches, combined with the collaborative tuning of λ/4 open stubs and coupling capacitor, the design achieves low-loss transmission in the dual-frequency passbands of 1.5 GHz and 2.1 GHz, forms a suppression band of ≥ 20 dB in the 1.6-2.0 GHz range, and realizes deep suppression of > 40 dB for second/third harmonics. The RCBSF is embedded into the output matching network of the power amplifier to form a dual-band power amplifier. Measured results show that the power-added efficiencies (PAEs) of the amplifier at 1.5 GHz and 2.1 GHz are 58% and 60%, respectively, with output powers of 38 dBm and 37 dBm, and gains of 15 dB and 14 dB, respectively. In non-target frequency bands, the PAE approaches 0%, and a suppression greater than 40 dB is achieved, verifying that the filter's high selectivity and compact layout enhance the performance of the dual-band power amplifier. This design achieves efficient power transmission and strong interference isolation, providing a cost-effective solution for multi-band communication systems.

This article addresses the challenges associated with poor tunability and the single absorption function in absorbers. To address these challenges, we designed a dual-band switchable tunable absorber utilizing graphene and vanadium dioxide.The proposed absorber exploits the phase transition characteristics of vanadium dioxide to achieve absorption in the low-frequency band when it is in the dielectric state and absorption switching in the high-frequency band after phase transition. Furthermore, the Fermi level is altered by applying a bias voltage to the graphene, resulting in reduced square resistance. This mechanism allows tuning of the absorption frequency when the vanadium dioxide is in the dielectric state and adjustment of the absorption bandwidth when it is in the metallic state. Simulation results reveal that when the vanadium dioxide is in the dielectric state, the absorption rate exceeds 90% within the 20.0-27.7 GHz range. At this time, increasing the Fermi level of the graphene alters the absorption frequencies to 11 GHz and 42 GHz, respectively. Conversely, when the vanadium dioxide is in the metallic state, the absorption rate exceeds 90% within the 31.1-48.7 GHz range. Thus, elevating the Fermi level of the graphene leads to absorption band tuning at higher frequencies. This absorber demonstrates strong tunability and multifunctional absorption capabilities, offering outstanding practical application value.