sci fi reality……vector replicators

 

the vector alternator

the problems of corrupt compressors

By Henryk Szubinski

CONSTRUCTING LORENTZ WIRES WITH A PRODUCTION LINE TYPE PROTRUSION AT SPECIFIC SECTIONS OF THE WIRE THAT ARE REPRESENTATIVE OF THE ZORENTZ PROTRUSION:

CONCEPT HERE IS TO DEVELOP WIRES THAT CAN BE USED AS THE VECTOR DIRECTIONS OF A MEMORY TYPE SPECIFICS OF WHAT A FLYING CAR CAN DO IN ITS TYPE MANOUVRES:

REPEATING LORENTZ ATTRACTORS IN A WAVEFORMAT STRING OF THEIR COMBINED CHAOS CONTINUIIMS:

as the x and y values in the string = sinusodial type references:

the problem of a connective z value as in complete projectional values:

The sine wave or sinusoid is a function that occurs often in mathematics, music, physics, signal processing, audition, electrical engineering, and many other fields. Its most basic form is:

which describes a wavelike function of time (t) with:

• peak deviation from center  = A (aka amplitude)
• angular frequency ω, (radians per second)
• phase = θ
  • When the phase is non-zero, the entire waveform appears to be shifted in time by the amount θ/ω seconds. A negative value represents a delay, and a positive value represents a “head-start”.

 

how to use a format tubule as the input for string data defined in its first format as a vector in which the connective vector process induces a type vector angle within the tubularity of a responsive wave format started where the protrusion from the external parameters is indicative of a proces that can generate multi protrusions in a waveformat..where each point in LINKING is =to attractor type data such as LORENTZ attractors..

The equations that govern the Lorenz oscillator are:

where σ is called the Prandtl number and ρ is called the Rayleigh number. All σ, ρ, β > 0, but usually σ = 10, β = 8/3 and ρ is varied. The system exhibits chaotic behavior for ρ = 28 but displays knotted periodic orbits for other values of ρ. For example, with ρ = 99.96 it becomes a T(3,2) torus knot.

a vector value in one specific orientation of its specific angle and value as going through the process of a LINK sequence of vector values in their values as being broken and then readapted to the process of their interactions to a resultant value vector that can be replicated to the same value of the first vector.

The Lorenz attractor, named for Edward N. Lorenz, is a fractal structure corresponding to the long-term behavior of the Lorenz oscillator. The Lorenz oscillator is a 3-dimensional dynamical system that exhibits chaotic flow, noted for its lemniscate shape. The map shows how the state of a dynamical system (the three variables of a three-dimensional system) evolves over time in a complex, non-repeating pattern

This means that the vector in a upside down value can nbe supported by another upside down vector value.

The multi possibilities of vectors as in the upp directions can also be supported by the force of their supportive values.

A vector alternation where a specific alteration of the angle or direction of a vector coupling can be made as the difference of

vector upp / vector 45 degrees in the upp =a angle of dipp

this type of argumentation of the mobility of vectors by the supportive argumentations of their comparative differences can be resultant in the difference without a third vector value.

This means that the velocity of a computation on 3 vector values can be constructed on the basis of the direction requirement of a vechicle motion vector in any specified angle force mass or direction and much more.

Data on how a compression of vector values can be made to simulate the cyclic process of the recombined single value of the first vector used in a vector process that uses the definition CYCLIC as the interactions of complete formats of replications as such the angles and their values of vectors can be stakked into COMPRESSOR type absorbtions of lift as SHOCK ABSORBTIONALITY in any direction as used inside the vechicle formats for the safe usage of high velocity vechicle constructs..

data and research courtesy of wikipedia

sci fi reality…dark matter problem a problem no more

problems of dark matter

By Henryk Szubinski 

using radio astronomy to locate real size discrepancies of astrophysical data without dark matter:

THE PROBLEMS OF PUSHING IN THE NON COMPUTATION OF STRINGS ON MICRO LEVELS GIVING A LERGER VIEW OF WHAT IS SMALLER

AND THE PROBLEMS OF PUSHING OUT THE UNIVERSAL COMPUTATIONS OF NON STRING COMPUTATIONS THAT ATTEMPT TO SHOW  HOW LARGE THE UNIVERSE IS FROM A DECREASED LEVEL OF THE POINT OF A LONELY VIEW IN THE REALITY OF ONLY A SENSE OF INCREASED DEPTH:

HAS SOME BASIC PROBLEMS OF THE STRING COMPOUNDING IN NON USAGE AS = DARK MATTER:

EITHER YOU COMPUTE THE EXISTANCE OF A ACCOMANYING COMPUTATION ON EITHER END OF MACRO AND MICRO  AS STRING NECCESSARY OR THE DEFINITION OF DARK MATTER WILL EXIST AS A UNSLOVABLE PROBLEM:

problems of gravity squaring its value and the same implications of such gravity representing the wave form cause by a pulse to which the format is half the gravity value by a halved equalisation with the basics of vector processess that are exchanged and neutralised so that a general format for motion as a vector and the values of geingt in gravity are all =a angle with its lim x=a expansion of mini black holes

An optical image of the galaxy M87 (HST), a radio image of same galaxy using Interferometry (Very Large Array–VLA), and an image of the center section (VLBA) using a Very Long Baseline Array (Global VLBI) consisting of antennas in the US, Germany, Italy, Finland, Sweden and Spain. The jet of particles is suspected to be powered by a black hole in the center of the galaxy

in which the personal A.I section of data on personally minimal values that can be impersonally A.I  large as a universe have the same basic alterations of a responsive duplications of restoring a string by the break up of a vector height into 2 sections and the resultant string of the multiple value =x

of a very large number of repeat processess on the minimal format black hole = the universe  as the same personal A.I parameter of A.I

the process of a 3 value x comparative of the 3 Dimensional integrity of using large processess for small ones :

is the basics of the reconstructive difficulty of recombining a wave format into a broken gravity defined as a mini black hole . Even as such on a mini height , the data on reconstructing the data is thought of as observable on the microscopic parameter where the components would be recombined into the primary structure:

But the model increases with every process of non recombined growth as unobservable on the micro level so that to not permit the function to increase is the same as permitting the format to go unnoticed in its increase multiple: the resultant is observation of dark matter that is basically a format of non simultaneous couplings of restored size relation with the growth of the parameter to observe ; so that a microscopic perspective could be seen to increase the spacetime the longer one goes into the macroscopic focus on small details.

The basic reasoning follows that the telescopic would have a similar process where no combined growth vector calculations are occuring ,that the simulated growyth of parameters on the macro level of the universe = the process where the objective is not localised on the cause or the objective to be observed rather a fuzzy and unclear image and then the data id defined on basic terms as being a objective in motion from the real image which could have been computed and located as a real evelnt by the laws that follow:

2S shareing 2h of a S1 String in what appears to be a 1 gravity value = 2 x events:

in a compounding problem that can be reached by hyperspace giving a faster avoidance of dark matter as it is by a avoidance by assist formulation defined as the quantality of 3 x + 3x in either direction of macro /micro levels =

6x (macro / micro )

this hyeprspace is designed as usable by a A.I computer that can use the

2S 1 squ.2h .g=2x

so that the shared computation.6x and divided by 6y ( on either size scale)

2Ssqu(6x)2.h.g= 2y.2z

this then is the z value in shared computations of the universes real size in 10 Dimensions:

24( h.g.S.x) squ=4.y.z

THE COMPUTATION :

designing the new format for macro / micro simultaneity:in radio astronomy

Power dividers and directional couplers are passive devices used in the field of radio technology. They couple part of the transmission power in a transmission line by a known amount out through another port, often by using two transmission lines set close enough together such that energy passing through one is coupled to the other.

The coupling factor is defined as:

where P₁ is the input power at port 1 and P₃ is the output power from the coupled port (see Figure 1)

The coupling factor represents the primary property of a directional coupler. Coupling is not constant, but varies with frequency. While different designs may reduce the variance, a perfectly flat coupler theoretically cannot be built. Directional couplers are specified in terms of the coupling accuracy at the frequency band center. For example, a 10 dB coupling +/- 0.5 dB means that the directional coupler can have 9.5 dB to 10.5 dB coupling at the frequency band center. The accuracy is due to dimensional tolerances that can be held for the spacing of the two coupled lines. Another coupling specification is frequency sensitivity. A larger frequency sensitivity will allow a larger frequency band of operation. Multiple quarter-wavelength coupling sections are used to obtain wide frequency bandwidth directional couplers. Typically this type of directional coupler is designed to a frequency bandwidth ratio and a maximum coupling ripple within the frequency band. For example a typical 2:1 frequency bandwidth coupler design that produces a 10 dB coupling with a +/- 0.1 dB ripple would, using the previous accuracy specification, be said to have 9.6 +/- 0.1 dB to 10.4 +/- 0.1 dB of coupling across the frequency range

research and images courtesy of wikipedia