The Multiwave Oscillator (MWO) is an innovative product recognized worldwide for its ability to generate a broad frequency spectrum, ranging from 10 Hz to an impressive 30 GHz. These capabilities often raise questions: how can a product like the MWO produce such a vast frequency range? In this blog, we explain this process step by step, delving into the scientific principles behind resonance, electromagnetic waves, and the unique technology of the MWO.
The Foundation: Resonance, Wavelengths, and the Speed of Light
The Multiwave Oscillator is based on the groundbreaking work of Georges Lakhovsky, who discovered that specific electromagnetic frequencies could support biological processes. The product uses multiple concentric, open rings of varying diameters. These rings function as broadband resonators, each with a specific primary resonance frequency determined by its size.
The primary resonance frequency of a ring is calculated using the following formula:
frequency (fₑₛₛ) = speed of light (c) divided by 2 π times the radius of the ring (r).
In symbols, this is expressed as:
fₑₛₛ = c / (2 π r)
Where:
fₑₛₛ represents the resonance frequency in Hertz (Hz).
c is the speed of light, 300,000,000 meters per second (m/s).
r is the radius of the ring in meters (m).
For example, a ring with a radius of 0.1 meters has a primary resonance frequency of:
fₑₛₛ = 300,000,000 / (2 π × 0.1) ≈ 477,465 Hertz (or 477 MHz).
Smaller rings generate higher frequencies, while larger rings produce lower frequencies. The MWO contains rings with diameters ranging from 79 mm to 810 mm, resulting in primary frequencies between approximately 118 MHz and 1.2 GHz.
Additionally, the speed of light (c) determines the relationship between wavelength (λ) and frequency (f). This relationship is expressed as:
c = f × λ
Where:
c is the speed of light in m/s.
f is the frequency in Hz.
λ (lambda) is the wavelength in meters (m).
At resonance, the wavelength matches the circumference of the ring (λ = 2 π r). This makes it possible to calculate the specific resonance frequency for each ring.
Expanding to a Broader Spectrum
Although the primary resonances of the rings appear to offer a limited range, the MWO generates a much broader spectrum thanks to three key mechanisms:
1. Harmonics
Harmonics are multiples of the primary frequencies. When a ring resonates at, for example, 1 GHz, frequencies are also generated at 2 GHz, 3 GHz, and so on. This process can extend to the 30th harmonic, depending on the system's energy. This allows the MWO to generate frequencies in the GHz range.
2. Subharmonics
Subharmonics are fractions of the primary frequency. A ring resonating at 100 MHz can also produce 50 MHz, 25 MHz, and even lower frequencies. This mechanism explains how frequencies in the low Hz range are produced. Interactions between the rings amplify these subharmonics, contributing to the overall spectrum.
3. Interference and Coupling
The rings in the MWO are electromagnetically coupled. This means they influence each other and can generate new frequencies through interference. These interactions fill the gaps between harmonics, creating an almost continuous spectrum from 10 Hz to 30 GHz. This is similar to how musical instruments generate harmonic tones through interaction.
The Role of High Voltage
The Multiwave Oscillator operates at a voltage of up to 120,000 volts. This high voltage plays a crucial role in generating the broad frequency spectrum. The strong electromagnetic field:
Stimulates harmonic and subharmonic production
Creates electromagnetic pulses (EMPs), generating broadband frequencies
Causes ionization effects in the air around the rings, enabling additional emissions in the GHz range
During ionization, air molecules are ionized, producing short, broadband waves. This process adds extra high frequencies to the spectrum.
How the Frequency Range of 10 Hz to 30 GHz is Achieved
The broad frequency range of the MWO is achieved through:
Primary resonances: Each ring generates a specific base frequency depending on its size.
Harmonic and subharmonic frequencies: These extend the spectrum above and below the primary resonances.
Interference: Interactions between the rings create a continuous spectrum.
High voltages and ionization: These processes generate broadband electromagnetic waves.
By combining these mechanisms, the MWO covers a frequency spectrum from 10 Hz to 30 GHz, utilizing the entire range.
Applications of the Broadband Spectrum
The broad frequency spectrum of the Multiwave Oscillator offers unique advantages. The product can stimulate various biological systems, as every cell has specific frequencies at which they function optimally. We believe the broad spectrum of the MWO offers potential for cell harmonization.
Conclusion
The Multiwave Oscillator is a technological marvel capable of producing a frequency spectrum from 10 Hz to 30 GHz through a combination of resonance, harmonics, subharmonics, interference, and high voltage. At Meditech Europe, we are proud to offer this product and share its potential.
Do you have questions or want to learn more about the Multiwave Oscillator? Feel free to contact our team. Meditech Europe is ready to provide you with personalized advice and a warm, professional approach.