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Introduction: Time Travel
These are the
points you should keep in mind while studying this technology:
* Time exists in
a wave-like structure. I do not yet completely know if the
"vibration" changes, or if it is even a
standing wave. Also, each point in space and time is designated by
a series of complex waves. A true
time machine is able to act similar to a radio and lock into these
frequencies.
* The energy of
Planck's constant and E=MC2 are equal and is the theoretical 100%
efficiency of sending
particles through time.
* This
technology has a naturally occurring safety feature to so far
prevent time paradoxes.
Faraday's theory
of electromagnetism predicts that a wave transmitted will travel
away from the source at the
speed of light. But the negative solution also predicts that a
wave can be produced that will go at
the speed of light back in time.
Distance is
always positive, but time is the same whether you use t or -t in
the equation (I know there are exceptions to
this principle, like the decay of a K meson, but the difference is only a few parts per million). Like any other
electromagnetic wave, it is self-sustained by its oscillations. A
changing electric field gives rise to a
changing magnetic field which recreates by magnetic induction the
original electric field. So the wave can have no
limit on how much it can oscillate through space. But like any EM
wave, when you double the distance
from the transmitter, the total power decrease by one-four
(inverse-square law). There are no
paradoxes
At the moment of
creation, everything was present in some form of energy. So even
by going backward or forward in time,
energy and mass are always conserved. In order to move a particle
back and forth in time requires the
expenditure of energy equivalent to a particle's mass. Because of the
basic Bilfilar windings doubling-back on itself, there is a Phase
Conjugate spherical wave pair consisting of 2
waves, one going forward in time and one going backward in time,
so that they are time-wise out of phase,
yet they are spatially phased at all times. One wave is outgoing
from a point and the other is incoming. They
move in the fabric of space at the speed of light. Together they
display properties such as charge and mass,
just like particles. Also, both particles are aware of each other
as dictated by ERP theorem. Einstein's
equivalency of mass and energy is E=MC^2, and Planck stated that
E=hF. The frequency of a photon which
transfers energy between two charges is proportional to the actual
energy. Mass, energy or
frequency is
equivalent depending on if the multiplier constant c^2 or h is
used as the unit. Using frequency as the energy
unit is the best way to describe an energy exchange at the speed
of light. So E=MC^2=hF. If the frequency is
negative temporally to an observer with the speed of light
positive, the oscillator should be producing
negative energy. I have no way at present to verify this.
{Freqgen.gif}
{interferometer.jpg}
Now for the
interferometer.
As you can see,
the transmitter is set up so the RF is made into a beam by
parallel mirrors and is reflected off of two
reflectors. For example, since a wave going at the speed of light
travels a little under a foot a nanosecond, if
the first reflector is one foot away from the transmitter, the
second reflector is half a foot away from the first
reflector. The focal point is half a foot from the transmitter. As the wave from
the transmitter travels backward in time one nanosecond, it hits
the first reflector and continues
traveling half a nanosecond backward in time to be reflected off
of the second reflector.
After this
interferometer setup has been on for two and a half nanoseconds,
the beam bouncing off of the second reflector
will come into the path of a similar wave from the future wave
also traveling toward the past at the focal
point. By modulating the phase of the wave at a future point, I
can cause constructive and destructive
interferance at the focal point in the past.
{Loopmap.gif}
By sending a
carrier wave to two receivers, one built to receive a negative
frequency and the other built to receive a
positive frequency. The positive frequency receiver doesn't
receive the negative frequency because the capacitor
acts as a filter. The negative frequency receiver should pick up
the signal and display it on channel two of
the oscilloscope. One important
fact is the Heisenberg Uncertainty principle, which states that
you can never know both a particle's
velocity and position. If I measure a particle's velocity, and
then I went back in time and measure the position,
the velocity isn't the same. This is because going back in time
requires a shift of energy, which changes the
quantum state of the particle. What happens if
I build a small transmitter capable of bouncing a signal off an
object one light minute away, therefore
sending a reverse temporal radio signal returning two minutes
before I sent it? At 11:55:00 p.m., I set the timer of
the transmitter to broadcast the signal at 12:01:00 a.m.. I then
sit back eating pizza while
watching the
oscilloscope waiting to see the signal. At 11:59:00 p.m., I see
the as yet unsent signal pattern on the
oscilloscope. Wanting to finish my pizza, I eat for the next two
minutes. At 12:01:00, the timer operates the
transmitter, and the signal races backward in time.
No paradox
occured.
{time.gif}
Now let's say I
included a receiver linked to the timer. If the receiver receives
the backward signal, it will stop the timer.
At 11:59:00, the receiver detects the signal and disables the
timer. Now the transmitter won't send the signal
at 12:01:00 a.m. Then what did the receiver receive? A paradox?
Didn't I just violate casuality (cause always preceded effect). Maybe the word
"exist" needs a Clinton redefinition to where something can both
exist and not exist. In H.G. Wells book, The
Time Machine, the protagonist asked whether a cube can exist in
space, but not in time. Let's keep the
English language intact and look for alternatives. If we think
about time loop paradoxes as if it were a computer data flow
chart, time would keep looping until a solution
occurs. There is no such thing as a true computer infinite loop,
because the loop numbers are limited by the physical
size of computer's memory. The same thing
is true with a paradox in time. A time loop is an example of
information, and information always degrades
because of entropy. If you don't believe this fact, print this
paper and photocopy it. Take that photocopy,
and photocopy it again. Do this a few hundred times. The small
errors start to add up
exponentially.
If you take two
uncharged parallel plates and hold them close enough together, you
can measure an attraction. This is
impossible under classical mechanics since they are uncharged. But
because these plates are close enough so the
plates lie under the average wavelength of radiation, particles
that normally pop in and out of the vacuum
become physical. Since Pauli's exclusion principle staes that two
particles in any system can't occupy the same
quantum state at the same time, each time time loops, the amount
of particle mass/energy that pops out of the
quantum vacuum will never be the same. So in quantum
mechanics, at least, there is no such thing as a time paradox.
How it works:
First it is
based on the Bajak capacitor:
The Bajak Flux
Capacitor is similar to an electroshock machine, except for the
addition of R2, S2 and the piezoelectric transducer. Even so, be
careful about touching across the capacitor. It can take as little
as 50 milliamps to stop a human heart.
B1 3 9V
source
C1 1 1200
uF 35V electrolytic
PS 1
piezoelectric transducer (any value)
S1 1 SPST
switch for charging circuit.
R1 1 25-ohm
rheostat to contol forward time.
R2,S2 SPST
switch and 1M-ohm potentiometer for backward time.
{Bajak.gif}
It is critical
that the total capacitance is as close to 1215.9 microfarads as
possible. Variable capacitors may be helpful. Note that the
voltage in the battery will decrease with time, changing frequency
values. A stable power supply should be used for precise
measurements.
After installing
the batteries, depress S1 for 2 to 3 seconds and then release it
for 3 to 4 seconds; Repeat as necessary. By closing S2, the
circuit controls forward time. By opening S2, the circuit controls
backward time. R1 controls the resistance for backward time
control. The more resistance the faster the circuit moves to the
past. R2 controls the resistance for forward time control. The
less resistance the faster the circuit moves to the future. It may
seem paradoxical that you have to hold down the past control THEN
press the future control to travel forwards in time, but it does
work.
One warning for
builders is that if you are sensitive to high frequencies, you
need to use a driver circuit for the piezo transducer or else
you'll have headaches.
In the Bajak
circuit, the rheostat controls inductance. The potentiometer
controls voltage frequency. This, and the capacitors create an LC
resonant circuit. The rheostat and potentiometer controls the
frequency, and once the correct one is hit, the time distortion
resonates out the piezo-transducer to a short distance depending
on the amplitude and voltage of the square wave.
Let's explore
this resonance a little more:
An LC circuit is
a frequency selector, and is used on all circuits dealing with
dynamic frequencies. The rheostat has a variable inductance, where
the current lags the voltage. The capacitors have capacitance
(voltage lags current). The two combined create an LC circuit.
Theoretically, the power is fed to the LC circuit. Think of the
Bajak capacitor as a radio (which it really is when fully
evolved). The piezo is the antenna which sends the energy out of
the circuit to effect time. The varied inductance resonates
through the piezo At the right "frequency", the piezo will
release the "time distortion wave". The charging pattern partially
alters how fast time is accelerated or decelerated, similar to
modulating information on a carrier wave.
It is my belief
that there are frequencies at every point in the universe, which
means this moment is a point in the
universe, and if those points are like individual carrier waves
then that would tend to suggest that space and time are all
information carried by those frequencies as interference.
I have replaced
in my early experiments S1 for a 555 timer in astable mode, but
any oscillator that would trigger the pulses at a variable
frequency would work. Then I added solid state memory so it could
automatically reset back to its initial settings. Then, based on
the information in the book Harmonic 695 By Capt. Bruce Cathie I
reset it's resonance to match the square frequency of light with
the translation oscillator I invented. (144000
squared=20,736,000,000Hz, resonance resistive load found using 1/2
pi of frequency multiplied by capacitance). Someday I hope to
boost this to Plank's frequency.
{circuitreson.gif}
Now by adding a
bifilar coil with negative induction, we can get an interesting
circuit response:
Let's use an inductor and capacitor in parallel for example. To
calculate the resonance, I would use
resonance=1/2(pi)(squreroot of c*l).
For example, if the capacitor is 1 farad and the inductor is one
Henry (to make the math easy), the circuit would be resonant at
159.2 Hz.
Now, there are
certain things that have negative inductance like bifilliar coils.
If we leave the capacitor
positive, but
put negative inductance as l in the equation, the circuit is
resonant at -159.2 KHz.
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3rd
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