Chapter 16
The De Witte Effect
"If
we ignore the facts contained in one part of the world, surely we are
hampering
scientific advance."
Sir
Douglas Mawson (1882-1958)
Introduction
As has
been stated many times in this text, our solar system, and thus our earth,
is
moving at about 370 kilometers per second (kps), relative to cosmic
microwave
background radiation (i.e. CMBR).
One of
the main purposes of the SR is to dispense with the concept of a URF
and to
replace it with the concept of a RRF. In other words, according to
Einstein,
the motion of our earth in space has no affect on anything that happens
on
earth, because the Universe itself is not a reference frame. This theory has
already
been disproven with the discovery of the CMBR. However, there is
another
experiment that more directly detects this URF - the Roland De Witte
experiment
of 1991.
During
a 178-day experiment in Belgium in 1991, Roland De Witte detected a
phase
shift in the frequency of a 5 Mz signal sent 1.5 kilometers on a copper
coaxial
cable. But what was of profound significance about the observed shifts is
that
the phase shifts changed constantly and formed a sinusoidal curve with a
nearly
perfect "sidereal day" period for the entire 178-day
duration of the
experiment![19]
A
"sidereal day" period can only be attributed to the motion of the
earth relative to
the
Universe. In other words, De Witte detected a URF; something that Einstein
said
did not exist! Neither Einstein's SR, nor his GR, would ever predict an
experiment
with a sidereal day period.
As to
why De Witte detected this sinusoidal period may be up for discussion, but
the
mere fact he detected such a period is indisputable proof that there is a URF.
His
data (ignoring his theories) is sufficient to prove that!
This
chapter is designed to help people understand the De Witte experiment.
The
most common explanations I hear for why he got uniform phase shift
patterns
involve: ground temperature, the magnetic field of the earth, or other
solar
activity related items. Such explanations reflect a total misunderstanding
140
as to
what a "sidereal day" is. Anything related directly or indirectly to
the orbit of
our
earth around the sun will generate data that synchronizes with a "calendar
day,"
not a "sidereal day." A sidereal day is an entirely
different phenomenon
than a
calendar day (i.e. solar day), as I will explain below.
The
end result is that the De Witte experiment is one of the great experiments of
the
twentieth century and deserves to be replicated and understood by everyone.
Overview of the De Witte Experiment
During
1991, while at the Belgium Telephone Company (now Belgacom), Roland
De
Witte set up an experiment using 1.5-kilometer copper wires, six cesium
atomic
clocks and six phase comparators. A phase comparator gives a DC
signal
proportional to the phase difference variation between two signals. This
DC
signal was recorded 24 hours a day, during the 178-day experiment.
Three
atomic clocks were set up at point A and three at point B, where A and B
were
both in Brussels. Point A and point B were 1.5-km apart (Note: generally
the
cable was north/south, but it was not straight). Two key signals traveled over
separate
underground coaxial cables. The signals from A1 towards B1 and from
B1
towards A1 demonstrated a clear sinusoidal waveform (per the phase
comparators)
with a consistent sidereal day period for the entire experiment. The
other
clocks were used to establish a baseline.
The Definition of a Sidereal Day
A
"sidereal day" is 23 hours and 56 minutes (and 4.09 seconds), as
opposed to a
"calendar
day," which is exactly 24 hours. Our clocks are defined and
calibrated
to
specifically measure one revolution of the earth relative to the location of
our
sun.
That is the calendar day. In other words, as the earth orbits the sun, a
calendar
day is the rotation of the earth defined such that in 24 hours the same
spot
on the earth is again directly under the sun.
But a
"sidereal day" is an entirely different matter. A sidereal day
measures one
revolution
of the earth relative to some distant object, such as a distant star. A
sidereal
day has absolutely nothing to do with the rotation of the earth relative to
our
sun, but is based on the rotation of the earth relative to a very distant point
in
outer
space, the further the better.
(Note:
As usual, my discussions on astronomy are simplified so the reader can
focus
on the important concepts and not get distracted with issues not directly
significant
to the discussion. A "sidereal day" is technically defined as:
"the
length
of time for the vernal equinox to return to your celestial meridian."
See:
http://csep10.phys.utk.edu/astr161/lect/time/timekeeping.html
141
However,
such a definition is neither intuitive nor instructive, nor is it any more
accurate
than my definition.)
To
understand the difference between a sidereal day and a calendar or solar
day,
do this exercise. Pick a spot on your desk or table. Practice moving a pen
or
pencil in a large circle around the spot on your desk or table. The pen
represents
the earth. The spot on your desk represents the sun. The pen
circling
around the spot represents the orbit of the earth around the sun. Each
circle
represents one calendar year.
Actually
the pen represents a line drawn through the center of the earth, from
equator
to equator. The point of the pen always represents the same point on
the
earth, which is on the equator.
Now
orient the pen in two different ways. First, as you move the pen around the
spot,
make sure that the point of the pen always points to the spot. As the earth
orbits
the sun, after each 24-hour period the same spot on the earth (i.e. the
point
of the pen), points to the sun (i.e. the spot on the desk). If you were to
twirl
the
pen around its center about 365 times as the pen makes one circle around
the
spot, you would have 365 calendar days. Each time the point of the
rotating
pen points to the spot on the desk is another calendar day.
Now
let's do this a second way. This time pick a corner of a window pane, or the
corner
of something else, in your room, as far away as possible from your desk.
Now as
you circle the pen around the spot, make sure that the point of the pen
always
points to the corner of the window. Without twirling the pen, note that the
point
of the pen only points to the spot on the desk one time as it circles the spot.
If you
were to twirl the pen around its center about 365 times as the pen makes
one
circle around the spot, you would have 365 sidereal days. But in this case
the
beginning of the sidereal day is when the point of the pen is aimed at
the
corner of the window.
Thus,
as you quickly twirl the pen around as it slowly circles the spot, whenever it
points
to the spot on the desk is the beginning of a new calendar day, but
whenever
it points to the corner of the window is the beginning of a new sidereal
day.
Study this for an entire circle of the sun and note how the calendar day and
the
sidereal day become totally unsynchronized with each other as you circle the
spot.
Finally,
do one last key demonstration. Position the pen and start the experiment
so
that a line drawn through the long axis of the pen points to both the
spot on
the
desk and the corner of the window. Now, without twirling the pen,
keep the
pen
pointed towards the windowpane and move the pen in a half-circle until it is
on the
exact opposite side of the where you started. With the pen pointed
towards
the corner of the window, slowly spin the pen until it points to the spot on
the
desk. Estimate how many calendar day "hours" (360 degrees equals 24
142
hours)
it will take for the point of the pen to rotate until it points to the spot on
the
desk.
The
correct answer is 12 hours. Over a period of half a year, a sidereal day and
a
calendar day drift about 12 hours apart! Over a period of 178 days, the
length
of the
De Witte experiment, it is quite easy to determine whether the sinusoidal
period
of his data had a calendar day period or a sidereal day period.
So why
is there a difference? From an astronomy perspective, there is no need
to
have a calendar day, it makes no sense. But people who go to work at 8:00
AM
every morning, want to go to work in the morning all year long. They don't
want
to go to work at 8:00 AM in the middle of the night, as would happen
sometimes
if we used a sidereal day for our clocks.
Since
the earth orbits the sun, it is convenient for people to measure time relative
to the
sun. The sundial was obviously oriented towards a calendar day. Thus
the
calendar day was adopted over the more correct sidereal day. Thus, on
average,
the sun will reach its pinnacle at about noon (per our clocks) on every
day
(as I said this is a simplification), anywhere in the world and on any day.
Theoretical and Actual Data
Let's
look at a table showing how these two concepts become unsynchronized
using
theoretical data.
Column
1: The day number of the experiment, using standard calendar days.
Note
that on the chart 9 days are skipped between each row to better show the
difference
between a calendar day and a sidereal day.
Column
2: The calendar time, noon in this example, for the days shown. This is
what
our watch would read as each new calendar day begins (at noon in this
case).
Column
3: The calendar clock reading when the sidereal day starts. In other
words,
if we look at our standard calendar watch continuously, this is the
approximate
time that the referenced sidereal day begins.
143
(1)
(2) (3)
1
12:00 12:00
11
12:00 11:20
21
12:00 10:40
31
12:00 10:00
41
12:00 9:20
51
12:00 8:40
61
12:00 8:00
71
12:00 7:20
81
12:00 6:40
...
As can
be seen, in less than three months the sidereal day begins more than 5
hours
before the calendar day! By the end of a 178-day experiment the sidereal
day
and calendar day are about 12 hours off. In the actual experiment, a
regression
line drawn through the actual data was consistently very close to the
theoretical
sidereal day.
This
is why temperature, solar activity, humidity, etc. cannot cause a sidereal day
period.
Temperature changes are synchronized with the calendar day (because
the
sun affects temperature). But the De Witte experiment was synchronized
with
the sidereal day!
From
the standpoint of the De Witte experiment, the fact that his data had a
sidereal
day period is of profound significance, because it means his data
is
related
to the universe, rather than to the sun!
Here
is actual data from the De Witte experiment.
The
first zero crossing time (i.e. the time where there was no phase shift)
occurred
on 3 June 1991 at 7h19 GMT or 22h20 Greenwich Sidereal Time. The
measurements
below represent zero crossing times compared to a sidereal day
period;
beginning with the first zero crossing time.
4
june 1991 +15m
11
june +20m
18
june +35m
25
june +15m
2
july 1991 -5m
9
july -10m
16
july -15m
23
july -5m
30
july +15m
6
august 1991 +15m
13
august +20m
144
20
august +10
27
august +25m
3
september 1991 +20m
10
september +25m
17
september +15m
24
september 0m
1
october 1991 -10m
8
october -5m
15
october +10m
22
october +25m
29
october +15m
5
november 1991 +20m
12
november +30m
19
november +10m
26
november +18m
By
studying the regression line for this data (see his web site), the obvious
answer
is that his data represents a perfect sidereal day period, but there is
minor
noise.
Considering
the number of variables during the experiment related to calendar
days
(e.g. temperature), some noise is to be expected, but the core of the data
(i.e.
the regression line) is clearly sidereal in nature!
It is
currently not know why the De Witte Effect exists. I will discuss several
possibilities
for why his data resulted.
Doppler Effect
Let us
consider a train that is headed down a perfectly straight train track at 150
kph.
The train headed down the train tracks represents the earth's net motion in
space.
On the
front engine of the train, suppose there is a very loud horn pointed
straight
ahead, as they always do. The horn represents the 5 Mz signal sent
down
the copper wire. The sound waves will clearly be compressed to those
people
in front of the train.
Now
let us rotate the horn as the train travels, and measure the sound wave
compression,
or expansion, from a point 100 feet directly in front of the direction
the
horn is pointed. For example, we could rotate the horn 15 degrees to the left
of the
tracks and measure the sound waves (frequency) 100 feet from the horn,
in the
exact direction the horn is pointed (i.e. not in the direction
the train is
headed).
145
Now
suppose we measure the frequency of the signal every 15 degrees until the
horn
has made a complete rotation (that is 24 measurements in total).
If we
plotted these 24 measurements on a graph, and then plotted a 25th
measurement
when the horn is again pointed straight ahead, we would notice a
somewhat
sinusoidal plot.
So
what is it that represents the rotation of the horn? It is the rotation of the
earth.
Just
like a train headed down straight tracks, the earth is moving in a straight
line
in the
direction of the constellation Leo. The rotation of the earth is equivalent to
rotating
the horn of a train, though things are a lot more complicated with the
earth.
Now
let us suppose that the train tracks were straight for many thousands of
miles,
and suppose we rotated the horn of the train continuously and smoothly so
that
it made one exact rotation once every sidereal day. If we plotted
the
frequency
of the horn signal, we would see a sinusoidal wave (under perfect
conditions)
with a period of exactly one sidereal day.
If someone
else came along, and didn't know anything about the speed with
which
the horn was rotating, he or she could look at the graph and conclude that
the
horn rotated once every sidereal day. The person could also determine the
speed
of the train by looking at the graph.
Likewise,
we can look at the De Witte data, and conclude that the earth is
rotating
once every sidereal day. Even though we already knew this, it is
earthshaking
news that electrical signals are affected by something that is related
to our
motion towards Leo!
So
where and why could the Doppler Effect happen? It must happen as the
electrical
signal is originally created. Because of ether drag, even though ether is
needed
for the electrical signal, the ether itself cannot have caused the Doppler
Effect.
If the Doppler Effect is the correct explanation, there must be something
related
to the universe (it cannot be our solar system or else he would have got a
calendar
day period) that ether drag does not filter out. What that might be I do
not know.
The Moving Target Laws
Understanding
this explanation requires a strong understanding of the Moving
Target
Laws (MTLs), which have been discussed in detail in an earlier chapter.
146
Suppose
there is a train traveling at 100 miles per hour forever on a train track
that
loops the earth at the equator, meaning the train is traveling in a permanent
loop
around the equator of the earth. Suppose that on this train there are three
flatbed
cars. In the middle of the middle flatbed car there is an archer. On the
car
just in front of the archer's car there is a target 100 feet from the archer.
Likewise,
on the car just behind the archer's car there is a target 100 feet away.
Now
let us suppose that the archer shoots his arrow at such a speed that in the
time
it takes the arrow to travel 100 feet the train moves 50 feet (obviously wind,
momentum
and a lot of other things are ignored to make this example simple).
Relative
to the train, if the archer shoots an arrow at the forward car, the
arrow
will
travel 100 feet. But relative to the train tracks (meaning the air space
or the
ground),
the arrow will travel about 150 feet (simplified).
In
other words, if we marked a spot on the tracks below the archer at the
exact
moment
the arrow was released; and then if we marked a spot on the tracks
below
the target at the exact moment the arrow hits the target, these
two marks
on the
tracks would be about 150 feet apart. I call this the "virtual
distance" the
arrow
travels.
Relative
to the train, if the archer shoots an arrow at the car behind the archer,
the
arrow will travel 100 feet. But relative to the train tracks, the arrow shot to
the
rear
car only travels about 50 feet (ditto yielding marks about 50 feet apart on the
tracks).
Now a
simple question: is the "time" it takes the arrow to travel to each
target a
function
of the distance traveled by the arrow relative to the "train" or
relative to
the
"train tracks?" Obviously, relative to the train tracks! Ponder
that very
carefully
- "time" is measured relative to the ground, meaning the
"virtual
distance"!
Now
suppose the archer is born on the train in a large covered boxcar and knows
nothing
about the train tracks or the ground, meaning he only knows about the
box
car he lives in. In other words, the boxcar is as big as the three flatbed cars
in the
prior example. Note that the traveler cannot see the ground near the train,
nor
can he see the sky. To a person born on the train, who can only see the box
car,
the box car is not moving because everything on the train has the same
momentum.
Thus the archer would grow up thinking that the box car is
stationary
and the box car is the only reference frame.
Now
suppose the archer measures the time that it takes the arrow to
travel to the
forward
car and suppose he measures the time that it takes the arrow to
travel to
the
car behind the archer. He notes that both arrows have traveled 100 feet
relative
to the train, but he also notes that it took a different amount of time for
each
arrow to travel to their respective target. This would certainly puzzle the
archer
if he knew nothing about the train tracks.
147
However,
eventually he would conclude that the train he lives on is not the only
reference
frame and that there must be a "second" reference frame
other than
the
train!
Now
suppose the entire boxcar frame slowly rotates completely during each
sidereal
day. In this case, the time he measures, if he shot the arrow every few
minutes,
would form a sinusoidal pattern with a sidereal day period.
That
is basically what De Witte has done, he had detected a "second"
reference
frame
that the earth is subject to (other than the earth itself). When the
"velocity"
of the
earth has an affect on phase shifts in copper wires, there is clearly
something
significant going on. When the phase shift pattern follows a sidereal
day
period for 178 straight days, whatever is going on is related to the motion of
the
earth in open space.
Let us
assume that the cable was pointed directly in the direction the earth is
moving
towards Leo. In the time that it takes the electrical signal to travel 1,500
meters,
the earth moves about 1.5 meters (Note: the earth moves at slightly
above
1/1,000th the speed of light). This means that the signal actually has to
travel
1,501.5 meters to arrive at point B. This the "virtual distance,"
relative to
CMBR,
the signal has to travel.
Why
could this affect the frequency of the signal? In essence, the signal is
"stretched"
out because of the Moving Target Laws at the atomic level. In other
words,
if a signal leaves point A, and by the time the signal gets to point B, point
B is
1,501.5 meters away, the signal has to travel 1,501.5 meters to get to point
B.
The
point is that this "stretching" out (or "shrinking" 12
hours later) of the signal,
at the
atomic level, could very easily change the frequency of the signal. It fact it
must change
the frequency of the signal. What is not known, however, is how
much
the MTLs contribute to the overall sinusoidal wave.
Another
possibility is that it is the constant change in the distance
(between two
consecutive
measurements) the signal has to travel that causes the frequency
change.
In
fact, it is illogical to think that either the Doppler Effect or the MTLs could
affect
the
frequency of electrical signals. But something causes the frequency of the
signal
to change! Data is data, even if it can't be explained.
148
The Cavity of the Copper Cable
Another
possibility that is directly related to the MTLs is that the change in
frequency
is related to the copper wire itself. An electrical signal "bounces"
around
inside of a copper wire. This means that the outside surface of the
copper
wire essentially forms a "cavity," much like the cavity in the
Blackbody
Radiation
experiment or the cavity inside of a fiber cable.
As the
earth rotates, because of the MTLs and the motion of the earth towards
Leo,
the "pattern" of bouncing around constantly changes. For example, if
the
wire
happened to be straight (which is wasn't), and the wire happened to be
pointed
directly at Leo, the center of the signal would barely "bounce" off
of the
sides.
On the other hand, if the wire happened to be straight, which is wasn't,
and
was pointed perpendicular to our path towards Leo, the center of the signal
would
have been bouncing around quite a bit. This extra bouncing could very
easily
have changed the frequency of the signal.
A
couple of subtle comments De Witte makes on his web lead me to favor this
theory.
A Second Kind of Ether
De
Witte, himself, believed he detected the ether. While it is true that without
ether
there would be no electricity, his opinion is in direct contradiction with my
experiments,
which have detected ether drag. Because the ether drag affects
the
surface of the earth, the only difference in the speed or frequency of light or
electricity
inside of the ether drag would have been related to the rotation velocity
of the
earth in Belgium (not the motion of the earth towards Leo). This is clearly
not
what De Witte detected. In fact, because his copper wire was buried in the
ground,
he would not have detected any type of change in the velocity of the
electricity,
due to the rotation of the earth, because the rotation speed of the
earth
would be constant (between the two endpoints of the cable).
Personally,
I feel it is possible that there is a second type of ether, but I highly
doubt
that De Witte detected this type of ether, if it exists. The normal ether that
this
book has talked about transmits an electromagnetic signal. The De Witte
Effect
only deals with an electrical signal in a copper wire. It is doubtful that an
electrical
signal would be affected by a second kind of ether in an entirely
different
way than the magnetic portion of the signal would be affected by the
main
type of ether. This would mean that the electrical and magnetic portions of
electromagnetic
signals would always be out of phase with each other. This is
not
likely and has not been observed to my knowledge. In fact, Telsa claimed
that
electrical signals, by themselves, could be transmitted through the ether this
book
talks about.
149
In any
case, because his electrical signal was passing through a copper wire, not
the
air, it is possible that the electrical signal could have been bound to the
copper
atoms and the issue of electromagnetic signals would be moot.
Nevertheless,
it is highly unlikely that a second kind of ether would deal with
electricity
in copper wires and the first kind of ether would deal with electrical
signals
in the air.
However,
there is a slim possibility that there is a second kind of ether that is not
subject
to ether drag. This kind of ether would have to be unrelated to light or
other
electromagnetic signals or electrical signals. Nevertheless, it could have
an
effect on the physical equipment that generated the signal (see the Doppler
Effect
discussion). But even this is unlikely because if the second type of ether
could
effect the De Witte experiment, it probably would have affected the H-K
atomic
clocks.
The De Witte Experiment Needs to be Replicated and Improved
The
reader might remember my lecture on keeping theories and data separate.
The
data of the De Witte experiment cannot be challenged in terms of it having a
sidereal
day period. Someone may disagree with my analysis and Roland's
analysis,
but the data cannot be disagreed with.
The De
Witte experiment is one of the great experiments of the twentieth century.
He
deserves credit for his experiment. But perhaps just as importantly, his
experiment
needs to be redone, with several changes.
First,
the copper wires should only be about 300 feet long (I don't know if there
were
any repeaters along his wire) and each should be "as straight as an
arrow."
It is
very disconcerting to me that the wire he used was not straight.
Second,
a fiber optic cable should be placed next to the copper wire, obviously
parallel
to the copper cable. This would allow a comparison of an electrical
signal
and an electromagnetic optical signal side-by-side. I have often said that I
thought
that "wander and jitter" in fiber optic signals was caused by our
earth's
motion
in space. I came to this conclusion before I learned about the existence
of
ether drag or De Witte's experiment. But even with ether drag the De Witte
experiment
leads me to believe the De Witte Effect also has an affect on fiber
optic
signals, particularly if the MTLs are involved.
Third,
very accurate celestial mechanics formulas need to be derived and
synchronized
with the exact direction the copper and fiber optic wires are
pointed.
In fact, this experiment should be done several times, with the wires
and
fiber pointed in different directions each time.
150
The
end result is that we can determine the real value of the De Witte
experiment,
and probably the real cause. Personally, I believe the De Witte
Effect
can lead to some major discoveries in physics!
151