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Chua's circuit

Chua's circuit is a simple third-order autonomous that exhibits behavior, comprising two capacitors, one , one linear , and a single nonlinear featuring a three-segment piecewise-linear voltage-current characteristic, often called the Chua diode. Developed by in 1983 during a visit to in , the circuit was first experimentally demonstrated and analyzed by T. Matsumoto, revealing a double-scroll distinct from previously known systems like the Lorenz . Its minimal component count—only five basic elements—makes it the simplest known electronic realization of , governed by a set of three coupled nonlinear differential equations that model voltage across the capacitors and current through the . Since its introduction, Chua's circuit has served as a foundational paradigm in nonlinear dynamics research, enabling studies of period-doubling bifurcations, homoclinic orbits, phenomena, and the and of chaotic systems. Implementations have evolved from discrete components to monolithic integrated circuits, with applications extending to schemes leveraging , , and modeling of biological and physical systems.

History and Overview

Invention and Development

Chua's circuit was conceived by in late October 1983 during his tenure as a Japan Society for the Promotion of Science (JSPS) fellow at in , . The invention arose from Chua's ongoing research into nonlinear circuits and dynamical systems, specifically aimed at addressing two key challenges in at the time: constructing a simple, robust laboratory system to demonstrate as a verifiable physical phenomenon and providing a rigorous of chaotic behavior in such a system. This effort was spurred by the practical limitations encountered in earlier attempts to realize the Lorenz equations electronically, particularly the unreliability of analog multipliers for generating the necessary nonlinear terms. The circuit's design emphasized simplicity, utilizing just a few basic elements to produce chaotic oscillations in an autonomous third-order system, thereby serving as a for studying in . Shortly after its conception, T. Matsumoto, a collaborator at , conducted the first theoretical analysis through computer simulations, confirming the existence of a and coining the name "Chua's circuit" to distinguish it from prior implementations. This work culminated in the seminal publication "A from Chua's Circuit" in the IEEE Transactions on Circuits and Systems in December 1984, marking the first formal of the circuit to the . Experimental validation followed in 1985, when G.-Q. Zhong and F. Ayrom at the , constructed and tested the circuit, providing empirical confirmation of its chaotic behavior through observations and calculations. Their findings, detailed in "Experimental Confirmation of Chaos from Chua's Circuit" published in the International Journal of Circuit Theory and Applications, established the circuit's practicality and reproducibility, solidifying its role as a foundational tool in nonlinear dynamics research.

Role in Nonlinear Dynamics

Chua's circuit stands as the simplest electronic realization of , comprising just a few passive and active components yet capable of generating complex, deterministic chaotic behavior that serves as a foundational for studying nonlinear dynamics. This minimalistic design, featuring a single scalar nonlinearity in its dimensionless state equations, distinguishes it from more intricate models like the , which requires three nonlinear terms, enabling straightforward experimental verification and theoretical analysis of phenomena such as bifurcations and attractors. The circuit has profoundly influenced research in chaos and control, where identical or coupled systems are driven to exhibit identical trajectories despite initial differences, paving the way for applications in secure communications, , and engineering systems. Pioneering studies demonstrated in Chua's circuit through methods like Pecora-Carroll drive-response coupling, highlighting its utility in transmitting information via chaotic carriers while suppressing noise. Its adaptability has extended to control techniques, such as and switching methods, to stabilize chaotic orbits or steer them toward desired periodic behaviors, impacting fields from physics to . Chua's circuit is emblematic of Leon Chua's broader contributions to nonlinear circuit theory, including his 1971 postulation of the as the fourth fundamental passive element, which relates charge and and exhibits memory-dependent resistance. This work on universal circuit elements underpins explorations of memristive variants of Chua's circuit, where memristors replace traditional nonlinear resistors to realize "" dynamics—regions of parameter space yielding maximal complexity for and biological modeling. Such connections emphasize the circuit's role in unifying circuit theory with emergent phenomena in complex systems. A rigorous of chaos in Chua's circuit was established in 1997, confirming positive and the existence of nonperiodic orbits through interval analysis of Poincaré return maps, thereby providing mathematical validation beyond empirical observations. This proof solidified the circuit's status as a for chaotic systems, influencing subsequent theoretical advancements in .

Circuit Design

Core Components

Chua's circuit features a simple composed of two , an , and two linear , forming the foundational linear that supports chaotic dynamics when coupled with a nonlinear . The core structure is a third-order autonomous , where the components are arranged in a configuration to enable energy storage and dissipation. Specifically, the circuit includes capacitor C_1 connected in series with the nonlinear resistor (known as Chua's , detailed separately), followed by R leading to a parallel combination of capacitor C_2 and the series connection of L and R_0, all referenced to ground. For a prototypical implementation, standard component values are C_1 = 10 nF, C_2 = 100 nF, L = 18 mH, R = 1.8 k\Omega, and R_0 = 1.8 k\Omega. These values ensure the circuit operates in a parameter regime conducive to observing chaotic behavior, with tolerances of approximately \pm 5\% for capacitors and \pm 10\% for the inductor to maintain robustness. Each linear component plays a distinct role in the circuit's dynamics. Capacitor C_1 primarily handles the input voltage across the nonlinear element, integrating current to produce voltage variations at the input node. Capacitor C_2 serves as the output capacitor, storing charge and facilitating oscillatory responses in conjunction with the inductor. The inductor L stores magnetic energy as current, contributing to the inertial aspect of the oscillations. Resistors R and R_0 provide scaling and feedback: R controls the current flow from C_1 to the output stage, damping the signal appropriately, while R_0, in series with L, adjusts the effective impedance and fine-tunes the resonance for stability in chaotic regimes. In schematic terms, the linear passive elements form a ladder-like : starting from the input side, C_1 bridges to the intermediate , R connects to the output where C_2 shunts to , and L in series with R_0 completes the back to from the output . This arrangement creates a effect combined with , essential for the circuit's nonlinear interactions.

Nonlinear Element: Chua's Diode

The nonlinear element in Chua's circuit, known as Chua's diode, functions as a voltage-controlled negative resistor that introduces the essential nonlinearity driving the system's chaotic behavior. It exhibits a piecewise-linear (PWL) voltage-current (V-I) characteristic, typically composed of five segments to ensure passivity at high voltages while allowing negative resistance locally. The V-I curve of Chua's diode is odd-symmetric and features outer segments with positive slopes denoted as m_0 > 0, providing stable high-voltage behavior, and an inner region spanning breakpoints at \pm E where the slope m_1 < 0 corresponds to negative differential resistance. This configuration, with the inner three segments exhibiting negative slopes, enables the diode to absorb power in the central region, contrasting with the power-supplying outer regions. The breakpoints \pm E mark transitions where equilibrium points can lie on the negative-slope segments, facilitating instability. Practical realizations of Chua's diode approximate this PWL characteristic using operational amplifiers (op-amps), resistors, and pn-junction diodes, leveraging the op-amps' high gain for precise negative impedance conversion. A robust design employs two op-amps in parallel negative resistance converters, each configured with three resistors to generate overlapping linear segments that combine into the desired five-segment profile, powered by dual supplies such as \pm 9 V batteries. Resistor values are selected to tune the slopes (e.g., inner slope m_1 \approx -0.756 mS) and breakpoints (e.g., \pm 1.08 V), ensuring experimental reproducibility without specialized components. The theoretical foundation of Chua's diode rests on Chua's local activity principle, which posits that negative differential resistance in a bounded voltage interval—achieved through the device's powered, locally active nature—is prerequisite for emergent complex dynamics in nonlinear circuits. This principle underscores how the diode's design breaks global passivity locally, injecting energy to sustain oscillations and chaos when integrated with linear elements.

Mathematical Formulation

Governing Equations

The governing equations of Chua's circuit are a set of three coupled nonlinear ordinary differential equations that describe the time evolution of the voltages across the two capacitors and the current through the inductor. These equations are derived by applying at the nodes and around the loops of the circuit topology, which consists of two capacitors C_1 and C_2, a linear resistor R, an inductor L, and a nonlinear resistor known as . Let v_1 denote the voltage across C_1, v_2 the voltage across C_2, and i_L the current through L. The system is then given by \begin{align} C_1 \frac{dv_1}{dt} &= \frac{v_2 - v_1}{R} - g(v_1), \\ C_2 \frac{dv_2}{dt} &= \frac{v_1 - v_2}{R} + i_L, \\ L \frac{di_L}{dt} &= -v_2, \end{align} where g(v_1) is the characteristic function of the nonlinear resistor. The function g(v_1) models the voltage-controlled current-source behavior of and is typically piecewise-linear with three segments, featuring an inner negative slope m_a < 0 (for |v_1| \leq E) and outer slopes m_b (for |v_1| > E), where E > 0 is a breakpoint voltage. An analytical expression for this odd-symmetric function is g(v_1) = m_b v_1 + \frac{1}{2} (m_a - m_b) \left( |v_1 + E| - |v_1 - E| \right). This form ensures the desired negative resistance in the inner region to enable chaotic dynamics while maintaining passivity in the outer regions.

Normalization and Analysis

To facilitate qualitative analysis and parameter tuning in the study of Chua's circuit, the governing differential equations are transformed into a dimensionless form by introducing scaled variables. The dimensionless state variables are defined as x = v_1 / E, y = v_2 / E, and z = i_L R / E, where v_1 and v_2 are the voltages across capacitors C_1 and C_2, i_L is the inductor current, E is a scaling voltage related to the breakpoints of the nonlinear element, and R is the linear resistor value. The time is also scaled as \tau = t / (R C_2), with dimensionless parameters \alpha = C_2 / C_1 and \beta = C_2 R^2 / L, where L is the inductance. The resulting normalized system of ordinary differential equations is: \begin{align} \frac{dx}{d\tau} &= \alpha \left( y - x - f(x) \right), \\ \frac{dy}{d\tau} &= x - y + z, \\ \frac{dz}{d\tau} &= -\beta y, \end{align} where the piecewise-linear nonlinearity f(x) models the characteristic of Chua's diode: f(x) = m_1 x + \frac{1}{2} (m_0 - m_1) \left( |x + 1| - |x - 1| \right). This form simplifies numerical simulations and theoretical investigations by eliminating physical units and highlighting the roles of the parameters \alpha, \beta, m_0, and m_1, which represent ratios of circuit components and slopes of the diode's voltage-current curve. Chaotic behavior in the normalized system emerges for specific parameter ranges, such as \alpha \approx 10, \beta \approx 14, m_0 \approx -0.8, and m_1 \approx -0.5, where the inner segment slope m_0 provides and the outer slope m_1 ensures bounded . These values correspond to regimes where the system transitions from periodic to aperiodic motion, as verified in early theoretical and experimental studies. The equilibrium points of the normalized system are found by setting the derivatives to zero, yielding three fixed points in the state space: the at (0, 0, 0) and two symmetric points at (\pm 1, \pm 1, 0). The is typically a , while the nonzero equilibria can exhibit unstable behavior conducive to chaotic trajectories under the aforementioned parameter conditions.

Chaotic Dynamics

Conditions for Chaos

Chua's theoretical framework for chaos in electronic circuits requires the presence of at least three elements—typically two capacitors and one —to achieve the minimum dimensionality for complex, non-periodic dynamics; at least one locally active , characterized by a negative incremental in a local voltage range that injects energy into the system; and a nonlinear to fold and stretch trajectories, enabling the formation of strange attractors. These criteria ensure the circuit can sustain sustained chaotic motion without external forcing, distinguishing it from periodic or quasi-periodic behaviors. Chua's circuit realizes these conditions in its minimal configuration, serving as the simplest autonomous electronic system capable of . The double-scroll serves as the signature indicator of in the circuit, manifesting as a symmetric pair of coexisting lobes in the projection of the voltage across the first (v_1) versus the (i_L). This structure arises when the nonlinear —Chua's —operates in a regime where its piecewise-linear characteristic drives trajectories to alternate between the lobes without settling into periodic orbits, filling the densely over time. The and duality of the scrolls highlight the circuit's robustness to parameter variations while maintaining chaotic properties. Confirmation of chaos is provided by the Lyapunov exponent spectrum, where the largest exponent is positive (approximately 0.07 under standard normalized parameters such as \alpha = 10 and \beta = 14), indicating exponential stretching of trajectories and the hallmark instability of chaotic systems. The full spectrum typically includes this positive value, a zero exponent reflecting the conservative flow along the trajectory, and a negative exponent ensuring volume contraction in the phase space, resulting in a fractal attractor dimension between 2 and 3. Complementing this, the circuit demonstrates extreme sensitivity to initial conditions, with infinitesimally close starting points leading to exponentially diverging trajectories after short times, underscoring the deterministic yet unpredictable nature of the dynamics. The normalized equations of the system, as derived in the mathematical formulation, underpin the parameter ranges where these chaotic indicators are observed.

Bifurcation and Stability

The route to chaos in Chua's circuit typically proceeds through a period-doubling triggered by variations in key parameters such as \alpha or \beta. As \alpha increases from values around 8 to beyond 9, the system transitions from stable fixed points to periodic orbits, followed by successive where the period doubles repeatedly (e.g., period-1 to period-2, then period-4, and so on), culminating in the emergence of a strange for \alpha \approx 10.814 and \beta \approx 14.286. This aligns with the Feigenbaum route observed in many nonlinear systems, where the ratios approach the universal \delta \approx 4.669. Similarly, increasing \beta from low values (e.g., around 13) initiates period-doubling from a born via , leading to chaotic dynamics through infinite doublings and the formation of a double-scroll . The stability of the circuit's equilibria is analyzed using the matrix of the governing equations, with eigenvalues determining local behavior. The system has three equilibria: the origin O(0,0,0) and symmetric outer points O_{\pm}(\pm \sqrt{1 - \frac{g}{\alpha}}, 0, \mp \sqrt{1 - \frac{g}{\alpha}}) for g < \alpha, where g relates to the nonlinear element's slope. At the origin, the Jacobian yields one positive real eigenvalue, rendering it unstable (saddle or saddle-focus) for typical chaotic parameters like \alpha > 9 and \beta > 14. The outer equilibria are stable for small \alpha (e.g., \alpha < 1) but lose via a supercritical as \alpha increases, where a pair of eigenvalues crosses the imaginary with zero real part (e.g., at \alpha \approx 8.4, \beta = 15), giving birth to a that later undergoes period-doubling. In smooth approximations of Chua's system, the Hopf occurs when the real part of the eigenvalues changes sign, confirmed by the first Lyapunov coefficient being negative for subcritical cases, ensuring a periodic orbit emerges. Multistability arises in parameter regions where multiple attractors coexist, including periodic limit cycles and chaotic orbits, depending on initial conditions. This phenomenon stems from the system's symmetry and multiple basins of attraction, allowing trajectories to settle into either ordered periodic or aperiodic chaotic states. To manage chaotic behavior, control techniques like the Ott-Grebogi-Yorke (OGY) method stabilize unstable periodic orbits embedded in the attractor through small, targeted perturbations of a parameter such as \beta. In applications to Chua's circuit, the method linearizes dynamics near the desired orbit using a Poincaré section, applying feedback (e.g., \delta \beta \approx K \delta \xi, where \delta \xi is deviation from the orbit) to shift the stable manifold, achieving stabilization of low-period orbits like period-1 with minimal intervention (perturbations <1% of nominal value). Variations, such as using Lorenz maps instead of Poincaré sections, enhance robustness in experimental implementations.

Attractor Types

Self-Excited Attractors

Self-excited in dynamical systems, including Chua's circuit, are defined as those whose basins of intersect with every open neighborhood of at least one unstable point, allowing them to be readily located through standard numerical simulations starting near such points. In Chua's circuit, these attractors are easily observable and form the basis of its chaotic behavior, contrasting with hidden attractors whose basins avoid neighborhoods of unstable equilibria. The prototypical self-excited attractor in Chua's circuit is the double-scroll , first observed in numerical simulations of the circuit's governing equations in 1984. This manifests as a symmetric, figure-eight-shaped structure in the projection onto the x-z plane, resembling two intertwined scrolls centered around the origin. Its chaotic nature was rigorously proven through analysis of return maps and , confirming the presence of a strange with positive . Key properties of the double-scroll attractor include a fractal structure with a Lyapunov dimension of approximately 2.1, indicating a between a surface and a volume, and confirmation of via Poincaré sections that reveal transverse intersections consistent with Smale horseshoes. These sections, obtained by intersecting the with a plane in state space, display dense, banded patterns underscoring the attractor's non-periodic, sensitive dependence on initial conditions. Robust self-excited , including the double-scroll , emerges in the normalized parameter regime with α ≈ 10 and β ≈ 14.28, where the circuit's three unstable fixed points lie within the of , facilitating predictable numerical detection and experimental realization.

Attractors

attractors in Chua's circuit are or periodic attractors whose of do not contain neighborhoods of unstable points, distinguishing them from self-excited attractors that are more readily observable near such points. This separation enables multistability, where multiple attractors—including stable —coexist, complicating the system's global dynamics. The theoretical prediction of hidden attractors in Chua's circuit emerged from analytical-numerical methods developed by G. A. Leonov and around 2009–2011, using harmonic linearization and describing function approaches to localize basins disconnected from equilibria. Experimental confirmation occurred in through a radiophysical setup with precisely controlled initial conditions, visualizing the attractors via projections that revealed chaotic trajectories inaccessible via standard perturbations. Further experimental observations were reported in 2023. These attractors often manifest as smaller double-scroll structures or asymmetric forms, with narrow embedded in vast safe regions surrounding equilibria, making them elusive in typical explorations. Their detection demands specialized global analysis techniques, as conventional numerical simulations starting near equilibria invariably converge to trivial attractors, potentially overlooking chaotic behavior. This has profound implications for understanding multistability in nonlinear circuits, emphasizing the need for rigorous basin estimation to reveal all possible dynamics.

Experimental Validation

Initial Demonstrations

The first experimental confirmation of chaotic behavior in Chua's circuit was achieved in 1985 by researchers G.-Q. Zhong and F. Ayrom at the of the . Their setup utilized an analog implementation closely matching the theoretical model, featuring two capacitors (C1 and C2), a linear (L), a (R), and a nonlinear known as the Chua's diode to provide the essential piecewise-linear voltage-current characteristic with a region. The Chua's diode was realized using operational amplifiers and to emulate the required N-shaped nonlinearity, with component values selected to align with the dimensionless parameters α ≈ 10 and β ≈ 15 from numerical simulations, ensuring the circuit operated in the chaotic regime. Oscilloscope measurements captured time series of the capacitor voltage v2(t) across C2, revealing aperiodic oscillations characteristic of , while phase portraits in the v1-v2 and v2-iL planes displayed the iconic double-scroll , confirming the nonperiodic and bounded trajectories predicted mathematically. These visualizations, obtained via Lissajous figures on dual-trace , demonstrated the attractor's symmetrical scrolls and sensitivity to initial conditions, validating the presence of strange attractors without periodic limit cycles. A key challenge in the experiment was precisely tuning the slope in the Chua's diode to maintain the locally necessary for , as deviations often led to unwanted periodic oscillations or stable equilibria that disrupted the double-scroll formation. By iteratively adjusting values in the op-amp and monitoring for in the , the researchers overcame these issues, achieving stable chaotic operation that corroborated the theoretical predictions of routes to .

Contemporary Implementations

Contemporary implementations of Chua's circuit have leveraged digital hardware for efficient and chaos generation, particularly for exploring hidden attractors. Field-programmable gate arrays (FPGAs) provide precise control over initial conditions, enabling the localization and visualization of coexisting hidden attractors in modified Chua's systems with absolute nonlinearity. For instance, a 2021 FPGA implementation using the DE2-115 board and fourth-order Runge-Kutta integration demonstrated periodic hidden attractors alongside self-excited chaotic ones, utilizing only 4% of logic elements for high-fidelity digital replication. This approach facilitates observation on oscilloscopes via digital-to-analog conversion, surpassing limitations of analog setups in parameter tuning. Memristor-based realizations, originating from the 2009 active-component emulation in Chua's circuit, have advanced to nanoscale integrations in recent years. A 2025 fully integrated design fabricated in a 180 nm process replaces traditional elements with a memristor emulator and , achieving operational frequencies up to 286 MHz and power consumption of 3.555 mW while confirming chaos through positive Lyapunov exponents (0.2572–0.4341). This miniaturization, occupying just 0.0072 mm², extends the 2009 framework to practical nanoscale applications with enhanced tunability. Efforts to reduce physical size have included active inductor replacements, eliminating bulky passive components. In a 2024 op-amp-based design employing Riordan gyrators, active inductors achieved circuit miniaturization while expanding the adjustable parameter range by up to 195.83% for single-vortex attractors and improving error tolerance to 12.61% for double-vortex modes. This configuration, integrated with non-autonomous elements, enhances accuracy and scalability without inductors. A 2024 experimental validation confirmed advanced dynamics, including vibrational in analog setups of the Chua's circuit with cubic nonlinearity. Driven by biharmonic signals (low-frequency 50 Hz at 0.7 V, high-frequency up to 3325 Hz), the circuit exhibited resonance peaks at critical amplitudes of 3.375 V, enabling transitions between single- and double-scroll attractors for . In addition, a 2025 analytical study using piecewise-linear nonlinearities generated even- and odd-numbered multi-scroll attractors by solving state equations across PWL regions, providing the first explicit solutions for higher-dimensional variants. These hardware implementations and analytical advances underscore the circuit's adaptability to modern technologies and nonlinear modifications as of 2025.

Applications and Advances

Traditional Uses

Chua's circuit, known for its ability to generate chaotic signals, found early applications in chaos techniques during the 1990s. The Pecora-Carroll method, introduced in 1990, enabled synchronization between a master and slave circuit by driving one subsystem with signals from the other, demonstrating robust coupling even with parameter mismatches. This approach was experimentally validated using Chua's circuit, where identical circuits synchronized their chaotic attractors, paving the way for systems that masked information within chaotic carriers to enhance privacy. By the mid-1990s, such master-slave configurations in Chua's circuit were employed to transmit digital signals securely, with the chaotic noise providing resistance to through desynchronization attempts. The circuit's unpredictable yet deterministic outputs also supported random number generation for cryptographic purposes in the 1990s and 2000s. Chaotic signals from Chua's double-scroll were sampled and quantized to produce bit streams passing standard tests, offering a hardware-efficient alternative to traditional pseudorandom generators. These true generators, implemented via simple analog components, were integrated into schemes, leveraging the circuit's sensitivity to initial conditions for high-entropy outputs suitable for . In parallel, Chua incorporated the circuit's nonlinear dynamics into cellular neural networks (CNNs) in 1988, creating a framework for parallel image processing. CNNs based on Chua's circuit elements performed tasks like and through local interconnections that mimicked chaotic evolution, enabling real-time operations on visual data with minimal computational overhead. This integration highlighted the circuit's utility in analog computing paradigms, where arrays of Chua-like cells processed inputs via and terms. Beyond research, Chua's circuit emerged as a staple educational in laboratories from the onward, allowing students to observe and transitions hands-on. By varying values, learners could plot diagrams showing the shift from periodic to aperiodic behavior, reinforcing concepts in nonlinear without complex simulations. These demonstrations, often using implementations, provided tangible insights into , making abstract phenomena accessible in undergraduate courses on circuits and systems.

Recent Innovations

In 2025, researchers developed analytical solutions for the state equations of a third-order Chua's circuit using piecewise-linear (PWL) functions to generate multiscroll chaotic attractors. By analyzing fixed points and stability across PWL regions, the approach enables the creation of even- and odd-numbered multiscroll attractors, visualized through portraits and that produce complex dynamical signals suitable for applications in communication systems, such as image encryption. That same year, studies on jump in driven variants of Chua's circuit demonstrated its utility in designing frequency selective devices, including real-time frequency demodulators by sensing signal drift. Using the Lur'e representation and describing function method, the work characterized width (Δω) and central (ω_c), with experimental validation on a state-controlled (SC-CNN) achieving at approximately 6,800 Hz for high selectivity. A deep learning-based parameter tuning further optimized for targeted frequency responses. Advancements in introduced a CCTA-based realization of Chua's circuit as a fast chaotic oscillator, operating at 37.5 MHz as confirmed by FFT analysis in PSPICE simulations with 180 nm technology. The design employs one CCTA block, two grounded capacitors, two fixed resistors, , and a , implementing the Chua's diode via dual negative resistances for efficient chaotic signal generation in high-speed scenarios like secure communications. Also in 2024, experimental investigations into vibrational (VR) in the canonical Chua's circuit with a smooth cubic nonlinear revealed effective suppression techniques for applications. By applying a biharmonic signal (low-frequency at 50 Hz and high-frequency at 2,000 Hz) to alter the effective , VR amplifies weak signals and transitions the system from double-scroll attractors to single-scroll or periodic states, with a critical high-frequency of 3.375 enabling control over a wide range. Analog circuit experiments using standard components (e.g., C1 = 10 nF, C2 = 100 nF, L = 15 mH) validated these findings, highlighting VR's role in mitigating unwanted behavior.

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