sci fi reality…conceptual environments 3

e n v i r o n m e n t s  3

bY HENRYK SZUBINSKI..

 

a basis of connection based on two functions

 

 

1)the basis to displace to point 1 =non return basis to function 1..by reference

 

 

2)function 1 is the reaction

 

of of the basis to continue basis 1.

3) THIS IS THE HALF WAY POINT .iT IS THERE ALWAYS …AND WILL ALWAYS BE THERE..

 

 

 

a artificial intelligence unit can tell you why; but it has been sworne to scilence..

sci fi reality …the functioning shadow

T H E  B O X  E X P E R I M E N T

By Henryk Szubinski

 a long box

 

 

 a fisheye lens

                                                                                                                                                         (function shown later)

 

 

 o.k the concept challange here is to use a box and to punch 6 holes in its surface to make a photon ray travelleing from one side, travell faster than the gravitational lensing that results in a complete unfloding of the box into a observable format and to do it befor the shadows hit the inner surface of the box..

you might need a fisheye lens (show above)

this is a problem concerning the variant rates of the data being responded toas the values of a system in usage with a point view perspective on high velocity processess that are used in value systems for the definitions of angles and their repeat responses based on the same sequence of events in 2 nd state and again repetaed in 3rd stage..

 

The only difference between this problem and the schrödingers cat experiment is that this one has certain data pertaining to the usage of a format for the envelopment of data on the perforations of objects by the displacement value of a positorn problem due to large scale structure inversions of volumes..

you might need a colour refractions index on a lens system ou in space infront of it ..and yopu have constructed a colour alteration detector for fisheye lens type dispersals detections of colour rays that cast no shadows when projected onto a screen that is similar to a black body..to observe the visible bending of certain spectrums of light and input it into a storage device in space orbit..

 

 

Data is here characteristic of a very large problem in how to make astronomical observations of cold matter

cold matter wherin the old usage of a box

 

to cover the lens and to again remoove it as the exposures are made..might be out there in the same format but as a astronomical reality…similar to a box that is faster that the closed or open states of excposure and has variant data concerning the object that covers a astronomical body similar to a box..Why the data on the parameters of such objects is unflding is basic  in relation to why there woudl be shadows cast from a object foreground that is visible only as the shaow casters structual expansion of a mini model..

everywhere similar in small scale linear prths of photons or galaxies

 

 As such the data on why a process like this has the basic conceptual ability of function to suggest a object is being viewed might be a generally human constructed model of a shadow reflector in the parameter observed..It might also be that the whole format is everywhere present in stages of surfaces in construction

that theese planar surfaces are used in large scale formats with holes punched through them and that the general problems are about the usage of shadows to generate increadible amounts of energy by a force that would be used to project a lrge surface shadow absorvbancy into space time..

 

 

A shadow is an area where direct light from a light source cannot reach due to obstruction by an object. It occupies all of the space behind an opaque object with light in front of it. The cross section of a shadow is a two-dimensional silhouette, or reverse projection of the object blocking the light.

An astronomical object casts human visible shadows when its apparent magnitude is equal or lower than -4^[1]. Currently the only astronomical objects able to produce visible shadows on Earth are the Sun, the Moon and, in the right conditions, the planet Venus.

 

[edit] Variation with time

Shadow lengths change dramatically throughout the day. The length of a shadow cast on the ground is proportional to the cotangent of the sun’s elevation angle – its angle θ relative to the horizon. Near sunrise and sunset, when θ=0° and cot(θ) is infinite, shadows can be extremely long. If the sun passes directly overhead, then θ = 90°, cot(θ)=0, and shadows disappear completely.

[edit] Non-point

Umbra, penumbra and antumbra

For a non-point source of light, the shadow is divided into the umbra and penumbra. The wider the light source, the more blurred the shadow.

If there are multiple light sources there are multiple shadows, with overlapping parts darker, or a combination of colors. For a person or object touching the surface, like a person standing on the ground, or a pole in the ground, these converge at the point of touch.

The projected shadow may appear to have moved faster than the speed of light, but there is no actual physical manifestation moving upon the surface. The misconception is that the edge of a shadow “moves” along a wall, when in actuality the increase of a shadow’s length is part of a new projection, which will propagate at the speed of light from the object of interference. Since there is no actual communication between points in a shadow (except for reflection or interference of light, at the speed of light), a shadow that projects over a surface of large distances (light years) cannot give information between those distances with the shadow’s edge

the punch throough might be like dark matter

sci fi reality…the type civilisations 1,2,3 are here..

RESPONSIVE DISPERSLAS 

By Henryk Szubinski

 

processess on inverse

 

volumetrics of a process to designate the three levels

 

of type

Density independent dispersal

Organisms have evolved adaptations for dispersal that take advantage of various forms of kinetic energy occurring naturally in the environment. This is referred to as density independent or passive dispersal and operates on many groups of organisms (some invertebrates, fish, insects and sessile organisms such as plants) that depend on animal vectors, wind, gravity or current for dispersal.^[4][5]

Density dependent dispersal

Density dependent or active dispersal for many animals largely depends on factors such as local population size, resource competition, habitat quality, and habitat size.^[6][7] Due to population density, dispersal may relieve pressure for resources in an ecosystem, and competition for these resources may be a selection factor for dispersal mechanisms.^[8]

Dispersal of organisms is a critical process for understanding both geographic isolation in evolution through gene flow and the broad patterns of current geographic distributions (biogeography).

At some time during its life, an animal moves, or is moved, so that it does not die exactly where it was born. Such movement is called dispersal

 

 

1 civilisation

type 2 civilisations

type 3 civilisations

by the processess of designated 3 levels of a non reversal and a non forwards process in the designative detections of a level 3 certainty is only designated as to what a

human would be doing in the processess of a 1 /3 =similations with the process user…

volumetrical formats of dispersals are = to formats of similarity to scatter effects..

on a general note ; the effects of what would be obviously durational in a cause to alternate everything by everything as previously defined on the basis of a value pertaining to the values of levels of similar functions in the universe.The obvious conclusion is that there must be

 

 

1) 1/3 x buffers everywhere

2) that the similarity of proximal effects to a buffer is similarity to a singular value

3) and that the process is used in half by a designated stemm cell reality of half the value process in exterior as =a singular value that when recombined is equal to law 2..

and that it contains a 1/3 value in each…

sci fi reality…flying cars..

^{C O P U T E R I S E D  A L T E R A N C E  O F  F L Y I N G  C A R  C L A S S}

^{by Henryk Szubinski..}

^{as concerns a displaceemnt- controll system that was designated to have a common basis of a}

^{30 x  similarity by a functional value in the large scale structures}

^{30 x =1/2(F+vel )[anti gravity] by the designated usage of the response rates of a full functional /responsive effect on the vechicle..in the response of a}

^{20 x similarity as the data on the process response of the subsequent data:}

^{the levels of a concerted interaction on the basis of distributions of the 30 x value as a whole number variance of the common integer in the value of a 6x as a sequence}

^{20x————————–>6x——————————->30x}

^{and the data on why the process has a variance basis designated to the structuality in the processings of the data of high controll as sensitivity..of the data being in the definitions range of a formational share value response based on the seperations of similar system responses on the levels of a full value effect of the response by similar responses on the basis of consequence of compensative reductions and increases as the data on the value system of the 6 x = to the designations to a location s function in the full spectrum of the volume of involvement as}

THE ONE POINT SYSTEM HAS A SIMNPLE RELATION TO THE 1 POINT GRAVITY WITH A EFFECT ON THE POINT SYSTEM IN DECIMAL VALUES OF

2  X RESULTANTS /3= G (20)

as concerns the uncertainty of a 2 system in usage with its resultant to connect a 1 point with a 1 point and to make the relation in compbinations as referencable to a gravity effect that has decimal sections that indicate it is divided by the processess of

2 x 1 opoint systems of gravity

so any value (20 etc..) G =20 . 3 (resultants 60 x 2 ) =

120 g = 20 g

the point that would not alter in a singular relation must be the common denominator of a super surface gravity complication of 2 singular value ; it continues then=

60 g =g

60 = 1 (the remooval of a g value common deniominator must define the gravity problem as being the value 60 and that the value 60 is the gravity denominator of a common alterations value—————–>taken to result in a volume basis of

360 g squared = 60

1/6= g squared..as concerns the super surface the value of a

l.b=

Area g=1/6…….the surface area then is 6 x larger than the l.b process of its half

1/6 ( 1/2) =area g /  root 2

designations of every re effect in the responses of the diffuse mechanics of the responses on the diagrammatics of the whoel system as usability in variance of functions that are designated into the displacement of levels on 30 levels with their point interfaced activity by the reference to a sequence of events

 

data on how and why variance is = to the sporadic redistributions of the format recouplin into a stage variance level of disfferent suarface irrgularities and the real time designations of the capacity in alternace of high velocity effects in what can alter and what can cause the decisions processess of vechicle controll in flying cars..

 the usage in prediefined exactness of retraction of informations of the basic in process designations in a level of non interactive . A brave a.i unit can make the moove. it can designate the apparency of the risk and it can alter the damage scenario of the intermix process of the non leftovers in the quantal computation.

 

NEWTON ONLY KNEW HOW TO INVOLVE A ROOT 2 VALUE PROCESS OF A DIVISIVE QUENSTION INDICATING THE CONTINUED RATES OF A RELATION TO HOW LENGTH IS MEASURED TO WIDTH ON A BASIS OF 1/2 A VALUE THE CLOSEST RESULTANT IS TO DIVIDE BY ROOT 2

Newton’s third law is a result of applying symmetry to situations where forces can be attributed to the presence of different objects. For any two objects (call them 1 and 2), Newton’s third law states that any force that is applied to object 1 due to the action of object 2 is automatically accompanied by a force applied to object 2 due to the action of object 1^[16]

This law implies that forces always occur in action-and-reaction pairs.^[10] If object 1 and object 2 are considered to be in the same system, then the net force on the system due to the interactions between objects 1 and 2 is zero since

This means that in a closed system of particles, there are no internal forces that are unbalanced. That is, action-and-reaction pairs of forces shared between any two objects in a closed system will not cause the center of mass of the system to accelerate. The constituent objects only accelerate with respect to each other, the system itself remains unaccelerated. Alternatively, if an external force acts on the system, then the center of mass will experience an acceleration proportional to the magnitude of the external force divided by the mass of the system.^[3]

Combining Newton’s second and third laws, it is possible to show that the linear momentum of a system is conserved. Using

and integrating with respect to time, the equation:

is obtained. For a system which includes objects 1 and 2,

which is the conservation of linear momentum.^[17] Using the similar arguments, it is possible to generalizing this to a system of an arbitrary number of particles. This shows that exchanging momentum between constituent objects will not affect the net momentum of a system. In general, as long as all forces are due to the interaction of objects with mass, it is possible to define a system such that net momentum is never lost nor gained.^[3]

the vechicle format for a shared cognitive experience in the cognitive doubling of the the process resultant in the vechicle turning in its displacement ..

.resultant expansions of the process by synaptic alterations to the responsive of a vechicle overturn and the values of the system of response values baseed on spent sections of a increased value response to the resultant artificial gravity.. can be utilised on high velocity exchanges that are defined to be rapid reaquuirive

 of the designated reusage of a vechicle exchange system..chordis6…as the freedoom of knowledge basuis on the distributions of spread of the gvechicle loss opf controll has majestic level -x as its consequence and subsequent informations missuse..

THE SLOAN GREAT WALL OF GALAXIES..

The usage of fysical levels of interactions based on the vechicle reusage are defined on the basis of ;

the data on how process es in effect by dissuse are referenced to their basic short displacement rates by lift in the very alterable specifics of the vechicle reusage of the force formats in the designated response reality of a drive to use a basic formative barrier in the high rate of alternance in curvature turning moments and the basis of a oversight format in the processings of any universal definition in obey format as the basic multi format angles of spherical alterant angles of k angles and their A alterant vectors..

 

sci fi reality…on the pipes

  T H E  W A T E R  L I F T I N G   C A R

By Henryk Szubinski

 

 a tubular structure illustration

the designated flow through it is blocked;

 

a mini computerised robot nano digger is inserted

 

 

it makes its way through the tube to the blockage.

 

it starts to dig,,from the sides

 

 

 because the nano sensor realises already that a direct insertion would make the blockage continue …it a.i has worked out why and a new approach has been planned..

 

 

 

it could not make the next fase of its operation a fail -function

 so it uses one that can be utilised in the flying of cars..the mass of the blockage  is measured and the exchange of its computer computations results in

blockage / 2 = vol (mass .)

 

 

 

it measures the mean value for the left side and the right side

 

m( left side + right side )  / 2= volume x

 

 

 

 the blockage…is then =…….the values are used on a mean plaform relation to its density..

mean value x = surface area.root  ( weight ) .

flow is then measured as a compatatble model for the following fase;

In physics, fluid dynamics is a sub-discipline of fluid mechanics that deals with fluid flow—the natural science of fluids (liquids and gases) in motion. It has several subdisciplines itself, including aerodynamics (the study of gases in motion) and hydrodynamics (the study of liquids in motion). Fluid dynamics has a wide range of applications, including calculating forces and moments on aircraft, determining the mass flow rate of petroleum through pipelines, predicting weather patterns, understanding nebulae in interstellar space and reportedly modeling fission weapon detonation. Some of its principles are even used in traffic engineering, where traffic is treated as a continuous fluid.

Fluid dynamics offers a systematic structure that underlies these practical disciplines, that embraces empirical and semi-empirical laws derived from flow measurement and used to solve practical problems. The solution to a fluid dynamics problem typically involves calculating various properties of the fluid, such as velocity, pressure, density, and temperature, as functions of space and time.

Historically, hydrodynamics meant something different than it does today. Before the twentieth century, hydrodynamics was synonymous with fluid dynamics. This is still reflected in names of some fluid dynamics topics, like magnetohydrodynamics and hydrodynamic stability—both also applicable in, as well as being applied to, gases.^[1]

 

 the surface area as a mean value

flow diagramms =s.A (1+x) /2

 

 

All fluids are compressible to some extent, that is changes in pressure or temperature will result in changes in density. However, in many situations the changes in pressure and temperature are sufficiently small that the changes in density are negligible. In this case the flow can be modeled as an incompressible flow. Otherwise the more general compressible flow equations must be used.

Mathematically, incompressibility is expressed by saying that the density ρ of a fluid parcel does not change as it moves in the flow field, i.e.,

where D / Dt is the substantial derivative, which is the sum of local and convective derivatives. This additional constraint simplifies the governing equations, especially in the case when the fluid has a uniform density.

For flow of gases, to determine whether to use compressible or incompressible fluid dynamics, the Mach number of the flow is to be evaluated. As a rough guide, compressible effects can be ignored at Mach numbers below approximately 0.3. For liquids, whether the incompressible assumption is valid depends on the fluid properties (specifically the critical pressure and temperature of the fluid) and the flow conditions (how close to the critical pressure the actual flow pressure becomes). Acoustic problems always require allowing compressibility, since sound waves are compression waves involving changes in pressure and density of the medium through which they propagate.

 

density of water flow in its fase 2 =high / low density = left /right sides…

 

 

the responsive water non penetrations value as comparative to the

density 1 + density 2 / 2 =flow ratio ( H2O +F)

 

 

ability of a surface to repell H2O is calculated bo be the same value relation of the pipe circumference————->to the point interaction of its volume…

 

 

because the calculations made designate the flow dynamics to a upsidedown state….the responses of effects of water ripples made by a larger surface cause in force the same value force effect of a ripple by a minial object can be made to function on the same basis of higher velocity responses but on the upside down format..

sci fi reality…impulsed to moove..

 T H E    R E Q U I R E M  E N T S    T O   FL Y    A    C A R

By Henryk Szubinski

a new genome for flying vechicles (but wheras the human genome was exterior the human vechicularity(SPACE TRAVEL,,,FLYING CARS..ETC..) is exterior.

 

 

a b number ( universe ) value response to impulse

 

 

where

I is impulse (frequently marked J),

F is the force, and

dt is an infinitesimal amount of time.

t₁ and t₂ denote a time interval

A simple derivation using Newton’s second law yields:

where

p is momentum

This is often called the impulse-momentum theorem.^[1]

As a result, an impulse may also be regarded as the change in momentum of an object to which a force is applied. The impulse may be expressed in a simpler form when both the force and the mass are constant:

where

F is the constant total net force applied,

Δt is the time interval over which the force is applied,

m is the constant mass of the object,

Δv is the change in velocity produced by the force in the considered time interval, and

mΔv = Δ(mv) is the change in linear momentum.

It is often the case that not just one but both of these two quantities vary.

In the technical sense, impulse is a physical quantity, not an event or force. The term “impulse” is also used to refer to a fast-acting force. This type of impulse is often idealized so that the change in momentum produced by the force happens with no change in time. This sort of change is a step change, and is not physically possible. This is a useful model for certain purposes, such as computing the effects of ideal collisions, especially in game physics engines.

Impulse has the same units and dimensions as momentum (kg m/s = N·s).

Impulse can be calculated using the equation:

can be calculated, if initial and final velocities are known,

where

F is the constant total net force applied,

t is the time interval over which the force is applied,

m is the constant mass of the object,

v₁ is the final velocity of the object at the end of the time interval, and

v₀ is the initial velocity of the object when the time interval begins.

 

 

 

T H E   V E C H I C L E  G E N O M E  I S  A S  F O L L O W S

1)which is represented by radius 1

2) the point here is that the velocity of light as a circuit construction

3) amid all the radiality as a  r 2

4) is basically a dimensional effect or result of using the the impulse in a multi

5)  impulse at the parameter where it occurs as a dimensional perspective on the 3D similarity

6) of its comparative to a displacement…

7) So by looking straight ahead on the parameter the result is a circuuit that can measure the depth of impulse complications by a charge of a volt for example..

CHORDIS 6 ;the resultant is a way in to the circumferencial divisions of the value by a comparative reference to 6 section as continually inputted and positionaly referenced by  subsequent usage of the position in a NO LET GO situation of balanced displacements as a general model of high velocity calculations on every value

9) calculation event by the collective delays to get through the wast off product of impulse motion and the apparent surface that results in CLEAN relations…which can

10) be used to the advantage as alterations of flying car gravity lift devices that function in this way..

 

 

The angular momentum of a system of particles is the sum of those of the particles within it.^[1]

In 2 dimensions the angular momentum of a particle of mass m with respect to a chosen origin is given by:^[2]

where m is the mass, v is the speed, r is the distance from the origin and θ is the angle between the velocity and the radius vector.

In 3 dimensions the angular momentum of a particle about an origin is a vector quantity related to rotation,^[3] equal to the mass of the particle multiplied by the cross product of the position vector of the particle with its velocity vector.^[4]

Angular momentum is important in physics because it is a conserved quantity: the angular momentum of an isolated system stays constant unless an external torque acts on it. Rotational symmetry of space is related to the conservation of angular momentum by Noether’s theorem. The conservation of angular momentum explains many phenomena found in nature and angular momentum has numerous applications in physics and engineering.

sci fi reality…processess of everywhere..

U N I V E R S E    S T A B I L I S A T I O N S

By Henryk Szubinski

 

 

the triangles do not represent a direction vector format to the left ..they are simply the expansion and the usage of a forwards collective mass effect by the increase of stability…though the wave front that is dragged by both of them the resultant is perplexing but there has to be a general comparative model in which the wave front would have similar expansional references ..

 

a general descriptive of a wave front;

if  the wave front was reversed by displaceing back in time it would look like this..look closely ..the two triangles are right there as the vergance to the point at its end..(on the bottom section ) ..on one point however ..this can be visualised by the rewind buttons mooving through the general field of the universe ..but not causing a wave rifft but instead a wave that is similar to both= the wave front that maintains its curvature as a shock wave as the wave that is continually mooving against the flow of time reversal..

 

You will notice that the common point is there……it is also the surface on which a wave mooves..turn this image any way and you will notice a general comparative to the lens as being the universe in general a basic comparative but where is the polar point..its on the top side..basic..

 

Optical systems can be described with Maxwell’s equations, and linear propagating waves such as sound or electron beams have similar wave equations. However, given the above simplifications, Huygens’ principle provides a quick method to predict the propagation of a wavefront through, for example, free space. The construction is as follows: Let every point on the wavefront be considered a new point source. By calculating the total effect from every point source, the resulting field at new points can be computed. Computational algorithms are often based on this approach. Specific cases for simple wavefronts can be computed directly. For example, a spherical wavefront will remain spherical as the energy of the wave is carried away equally in all directions. Such directions of energy flow, which are always perpendicular to the wavefront, are called rays.

The simplest form of a wavefront is the plane wave, where the rays are parallel to one-another. The light from this type of wave is referred to as collimated light. The plane wavefront is a good model for a surface-section of a very large spherical wavefront; for instance, sunlight strikes the earth with a spherical wavefront that has a radius of about 93 million miles (1 AU). For many purposes, such a wavefront can be considered planar.

draw a general x axis line through the whole syste, and the definition

of the universes functions become quite easy to grasp..lets use general theories and take a ride through the universes large scale structures;;designated as theory sections   1 to 10..

 

_——————————————————————————————————

 1) stability – Velocity (B) =————–>

2)m = t ? ………well for one 90 degrees = t

-x ( t .now ) = 1/4 – (vel – Big bang )- Volume..

3)F ( angle x . root S)

4) – x ( -y , x ) = root t

5) quantals

r.p.m Root Volume – S = lim x .c. Velocity ( – S .c cubed)

6) space time ? well ; g . (A. anti gravity )

7) g ? (space time .angle x . 2)

t [ 2 nd quadrant . 2 /2]

9) restrictive history = A.I

10 ) uncertainty space time ; t – (volume)

 

———————————————————————————————————

 

as basic as all this may seem by any value,,lets pick out the higgs boson ; the top dimensionality of curvature; ” multi universes grow while seeing ahead slows down the theories inbetween as take- along…

 

in a universe with only one point to be made..the gravity would be singular..i mean, the rotational cause would be singular ,this means that it causes the one point rotation…o.k there must be a dissbalance of a dissonance..the whole system would wobble…perhaps it does this and the effects are visible by the large scale structures……………….but being inside the universe it feels like a smooth ride..why

.well for one the balance of the point would have to be one polar..that point is designated as the north pole..there are no more poles…as a example..if the world was everything..the way to discover it was as such would imply a end to such illusion by the reference of a way out at the north pole..the universe is like this but it has no illusion and it is as yet not a way out..the rest of the action reactions would collect on the great wall that displaces through the universe..

In physical cosmology, the large-scale structure of the universe refers to the characterization of observable distributions of matter and light on the largest scales (typically on the order of billions of light-years). Sky surveys and mappings of the various wavelength bands of electromagnetic radiation (in particular 21-cm emission) have yielded much information on the content and character of the universe’s structure. The organization of structure appears to follow as a hierarchical model with organization up to the scale of superclusters and filaments. Larger than this, there seems to be no continued structure, a phenomenon which has been referred to as the “End of Greatness”.