We can look at Tesla's Wireless Power Transmission Proposal using the Coexistence Triad to evaluate the interplay between three factors in development of Tesla's system - Structural Analysis (A), Functional Analysis (B), and Potential Analysis (C). All three components must exist in equilibrium for the entire system to function.
A. Structural Analysis: The Stabilization Triad is present in the cyclical nature of generation (A1), transmission (B1), and reception of power (C1), while the Counterbalance Triad offers an understanding of how breakdowns or failure in any part of the system would affect the others. Should any stage be inefficient or disrupted, it affects the whole system due to their interconnectedness.
A1: Power Generation: The generation of power is achieved through the use of AC generators and the Tesla Turbine. The power generated at this stage is intended to be amplified and converted into high-frequency alternating current, which can then be transmitted wirelessly.
B1: Power Transmission: The wireless transmission of power makes effective use of the Earth and its atmosphere as a medium for the signal's dispersion. Tesla's Module (comprising Tesla Coil, the Magnifying Transmitter, and Grounding Electrodes) helps to boost and direct electrical energy into the Earth's crust or surrounding atmosphere.
C1: Power Reception: This final stage involves the reception and use of the transmitted power. Power receivers with resonant circuits, tuned to the frequency of the transmitter, will capture the transmitted energy, which can then be converted back into a functional form of power for use.
B. Functional Analysis: The Contingency Layer Triads reflect the causal effects within such a system. The Tesla Turbine (A2) is necessary for the Transimission Infrastructure (B2), which enables the Power Receivers (C2).
A2: Tesla Turbine: This is important in the generation of power for Tesla's system. Any disruption in the function of the turbine could significantly impact power generation and, consequently, power transmission and reception.
B2: Transmission Infrastructure: The transmission medium (Earth and its atmosphere) are critical for successful power transmission. Any changes in the characteristics of these mediums could substantially affect the ability to transmit or receive power.
C2: Power Receivers: The properties of power receivers (resonant frequency, design, location, etc.) are crucial for the effective reception and utilization of power. Any alterations in the receiver's properties could adversely impact the power supply to the end user.
C. Potential Analysis: The Nonlinear Triad presents an analysis of potential outcomes of this system, recognizing that while power generation (A3) leads to both power transmission (B3) and reception (C3), these steps are not linearly dependent on one another.
A3: Power Generation: The generation of power, while crucial, is only the first step in the process. It doesn’t guarantee the successful transmission or reception of power due to other variables (e.g., medium conductivity, receiver tuning) that could potentially disrupt these processes.
B3: Power Transmission: The transmission of power is a central stage in this process, but it's dependent on other phases (such as C. Potential Analysis: The Nonlinear Triad presents an analysis of potential outcomes of various variables in the system. The Wardenclyffe Tower (A3) is critical for both the Electrostatic Induction method (B3) and the Reception Technology (C3), but these steps are not linearly dependent on one another.
A3: Wardenclyffe Tower: While the tower is crucial for creating an Electrostatic Induction field, its mere presence doesn't guarantee successful energy transfer or reception due to potential changes in variables like atmospheric conditions and technological limitations.
B3: Electrostatic Induction Method: Although Tesla's Electrostatic Induction Method was meant to create an oscillating electric field for energy transmission and communication, it doesn’t strictly correlate to successful reception. Factors like interference, distance, and receiver tuning also come into play.
C3: Reception Technology: The design and distribution of receivers heavily influence the system's overall success. Even with power generation and an effective transmission field in place, the receivers need to be correctly configured and located to harness the available energy. Disruptions or inefficiencies in this stage could undermine the reception of power regardless of the functioning of the previous stages.