For the Electrical Resonance analysis, we must consider the oscillating electrical system (A), the resonant frequency at which the system operates (B), and the subsequent boost in efficiency of power transmission/reception (C). The interaction and co-dependency of these elements determine the feasibility and optimization of Tesla's wireless power transmission concept.
A. Structural Analysis: The Coexistence Triad illustrates how the oscillating electrical system (A1), its resonant frequency (B1), and the amplification effect that subsequently boosts power efficiency (C1) are inherently interconnected in Tesla's design.
A1: Oscillating Electrical System: The concept of an oscillating electrical system with a distinct resonant frequency is fundamental to Tesla's proposal. The characteristics of the system, including its design and configuration, impact the resonant frequency and, subsequently, the efficiency of power transmission and reception.
B1: Resonant Frequency: The resonant frequency is the specific frequency at which an electrical system naturally oscillates. Tesla theorized that operating an electrical system at its resonant frequency could boost the efficiency of power transmission and reception. Changes in these frequencies could directly influence the functioning of Tesla's wireless energy transmission system.
C1: Amplification Effect: This phenomenon is central to Tesla's goal of transmitting vast amounts of energy wirelessly with minimal losses. By operating the system at its resonant frequency, there's an enhancement in oscillations, leading to the efficient transmission and reception of power. Variations in this amplification effect could drastically affect system efficiency.
B. Functional Analysis: The Stabilization Triad shows how the alternated electric currents (A2) induce an oscillating electric field (B2), which, when tuned to the resonant frequency, brings about an amplification in power efficiency (C2).
A2: Alternated Electric Currents: The generation of alternated electric currents is pivotal for Tesla's model. Any deviation or disruption in generating these currents could decrease the efficiency of power transmission and the subsequent reception of power.
B2: Oscillating Electric Field: This oscillating electric field is created when alternated electric currents pass through the oscillating electrical system. Depending on the system's properties, these alternating currents can exhibit a variety of resonant frequencies.
C2: Amplification in Power Efficiency: By deliberatively tuning the system to its resonant frequency, one can achieve maximum power efficiency through the amplification effect. Although crucial, this process remains susceptible to fluctuating variables such as changes in the properties of the electrical system, the Earth's conductive properties, or the receiver's design and location.
C. Potential Analysis: With the Nonlinear Triad, one observes that alterations in the properties of the oscillating electrical system (A3) or the input of alternating electric currents (B3) could potentially affect the amplification effect, leading to variations in power efficiency (C3).
A3: Oscillating Electrical System: Tesla's wireless power transmission model is contingent on properties of the oscillating electrical system. However, changes in these properties do not straightforwardly predict the system's performance. They may affect the amplification effect and power efficiency non-linearly, due to the complex interaction of various elements including alternating electric currents and the Earth's conductivity.
B3: Alternating Electric Currents: Similarly, variations in the frequency, amplitude, or phase of the alternating electric currents fed into the oscillating system could also bring about non-linear changes in the output and the subsequent reception of power.
C3: Power Efficiency: The ultimate objective—achieving high power efficiency through the amplification effect—relies on numerous factors. It is not a linear result of either the characteristics of the oscillating electrical system or the nature of the alternating electric currents. Influences such as power receiver properties and Earth's ionosphere conditions can alter the culmination of these processes.