The Comsphasec Solution

The Company introduces a superior resonant digital modulation scheme that can be applied to a diverse array of communication mediums. Resonant Vortational Division Multiplex (RVDM) offers a new paradigm in electro-mechanical modulation schemes that breaks free from the 2D flatland of digital and analogue thinking. RVDM modulation and V-Data unit formats and V-Data Word formats are not bound by the narrow mathematical parameters of ones and zeros and other limiting two-dimensional numeric expressions. This method will enable an immediate advance in terms of the technological improvement of existing digital systems. Unlike any of the legacy digital modulation methods, the inventions RVDM modulation method is not frequency dependent, yet in can work in any existing frequency domain. Any analogue carrier signal can be modulated with RVDM modulation protocols, processes, and procedures. RVDM modulation can be applied to metallic conductor mediums that transport 50 and 60Hz electrical power signaling and fiber optic networks wireless radio air-interface frequency assigned channels, which include all forms of mobile radio and satellite telecommunication networks.

The inventions novel Resonant Vortational Division Multiplex (RVDM) is based upon the application of resonant digital data vector (RDDV) encoding and decoding that are mathematically defined in terms of fractalized data unit vector symbolic structures (VSS). One phase fractal envelop equates to one V-Data Unit, one V-Data Unit equals one conventional data byte-data unit.

Holophasec Technology Groups (HTG) Resonant Vortational Division Multiplex (RVDM) modulation scheme offers substantial data throughput performance in legacy networks.

This improvement in data throughput is neither frequency-dependent nor bandwidth-dependent; in fact, the improvement is more dramatic when used as a means to exploit lower frequency, narrow-bandwidth commercial allocations where conventional assumptions do not consider substantial data throughput rates to be a possibility.  Many of these bands in the VHF and UHF frequency ranges have ‘disappeared off the ‘radar’ in commercial terms.  RVDM brings a sea change in this perception.

Different reference frequency ranges suggest different definitions for bit frame resolution-bit granularity.  The following examples show how approaches to bit frame definition will vary according to differing reference frequency rates that are used in the inventions target communication and power grid channels. Comparison is made, where relevant, between conventional practical data rates and what is possible using a Holophasec’s Resonant Vortational Division Multiplex (RVDM) modulation scheme virtually.

Electric Power Grid

For the 50Hz/60 Hz power grid application, there exists with present-day technology simply no basis for bit/byte rate comparisons, as conventional science has not yet come up with a way to propagate data over the Grid in any but local applications such broadband over power lines.  The reference waveform period for electrical power grid 50Hz systems is 20 milliseconds, for a 60 Hz system is 16.66 milliseconds.  This suggests dividing each cycle into an arbitrary number of bit frames, based on use of readily available processor speeds.  Using an easily generated 10 MHz bit frame rate, in the case of a 60Hz system 166,666 bit frames, or roughly 20 Kilobytes per second is readily achieved with the inventions Resonant Vortational Division Multiplex (RVDM) modulation scheme over electrical power lines, and this is a conservative estimate.

VHF-UHF Channel Solution

A typical channel bandwidth for a VHF radio channel in the 220 MHz band is typically used for AMTS (Automated Maritime Telecom Systems) and/or for analog voice channel applications such as tow truck or taxi management.  A data or voice channel in this band is typically allocated a bandwidth of 5 to 6 MHz.  For digital communications, this translates to a data rate of 5 to 16 Kb per second.

The inventions Resonant Vortational Division Multiplex (RVDM) modulation scheme can be used to encode/decode data within the same channel bandwidth allocation. “Bandwidth” in a conventional sense and in this case becomes an irrelevant reference point.  Data frame rate is based on sample granularity, not bandwidth.  Data bit framing would be to send one phase fractal envelope which equals one vortational data unit which equals one data byte per reference cycle.  Using a 220 MHz reference center frequency as an application example, a translation state-engine with internal lookup tables will easily handle decoding one bit frame every 4.5 nanoseconds.  This translates to 27 Megabytes per second.  It is useful to compare this data rate to the rate available using conventional approaches.  In the example cited above, the bit/byte multiplication ratio ranges from 1700:1 to 5500:1.  Higher ratios are anticipated under real-world conditions.

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