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Title: Patent Granted for Hyper-Light-Speed Antenna
Posted on Saturday, February 01, 2003 @ 00:33:32 UTC by vlad
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matt writes: Inventor granted patent for a "hyper-light-speed" antenna which apparently proves the existence of a new dimension that can send signals--and, therefore, energy--faster than the speed of light.
The US Patent and Trademark Organization has approved a patent (6,025,810) for a device which claims to be able to transmit and receive electromagnetic waves at a speed faster than light.
According to the patent disclosure, the invention can transmit and receive energy over a greater distance and at greater speeds than conventional antennae. The invention claims to use a dimension beyond the time-space continuum to accomplish this.
From the patent disclosure:
"The present invention takes a transmission of energy, and instead of sending it through normal time and space, it pokes a small hole into another dimension, thus, sending the energy through a place which allows transmission of energy to exceed the speed of light."
To investigate more, you can access the patent at the USPTO’s home page at
http://www.uspto.gov/
(A search engine is available for the patent number.)
If this invention does turn out to be true, a revolution could occur in the television industry. Re-runs could actually arrive before the original broadcast. (Just a little Einsteinian humor there.)
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Re: Title: Patent Granted for Hyper-Light-Speed Antenna (Score: 0) by Anonymous on Sunday, February 02, 2003 @ 15:55:45 UTC | The patent office doesn't make searching very easy, couldn't find this...
But I wonder if its based on the TWIN PHOTON?
Does the Fogal Transistor depend on the "halo" around a wire? If so a wireless superluminal device would be better.
The implications of this are interesting, and I recall reading in the very fringe that a type of "hyperscope" had been developed which allowed one to view (like a remote viewer) any event in the past or future...
Could this be scaled up for teleportation of objects? After all matter is just information. |
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Re: Title: Patent Granted for Hyper-Light-Speed Antenna (Score: 1) by Runes on Friday, August 04, 2006 @ 18:07:02 UTC (User Info | Send a Message) | Being a cynic to those claims I did a search for the patent and I will post it here as well as the link.
http://patft.uspto.gov/netacgi/nph-Parser?Sect1=PTO2&Sect2=HITOFF&p=1&u=%2Fnetahtml%2FPTO%2Fsearch-bool.html&r=1&f=G&l=50&co1=AND&d=PTXT&s1=6,025,810&OS=6,025,810&RS=6,025,810
Now keep in mind that a patent is a concept written down but does not necessarily mean it works.
( 1 of 1 )
United States Patent
6,025,810
Strom
February 15, 2000
Hyper-light-speed antenna
Abstract
A method to transmit and receive electromagnetic waves which comprises
generating opposing magnetic fields having a plane of maximum force
running perpendicular to a longitudinal axis of the magnetic field;
generating a heat source along an axis parallel to the longitudinal axis
of the magnetic field; generating an accelerator parallel to and in close
proximity to the heat source, thereby creating an input and output port;
and generating a communications signal into the input and output port,
thereby sending the signal at a speed faster than light.
Inventors:
Strom; David L. (Aurora, CO) Appl. No.:
08/942,824
Filed:
October 2, 1997
Current U.S. Class:
343/787 ; 343/711; 343/721; 343/895
Current International Class:
H01Q 7/00 (20060101)
Field of Search:
343/711,713,721,725,787,788,895
References Cited [Referenced By]
U.S. Patent Documents
5714959
February 1998
Troy et al.
Primary Examiner: Wong; Don
Assistant Examiner: Clinger; James
Attorney, Agent or Firm: Martin; Rick
Parent Case Text
CROSS-REFERENCE TO RELATED APPLICATION
This application is a non-provisional application claiming the benefits of
provisional application No. 60/028,204 filed Oct. 2, 1996.
Claims
I claim:
1. A method to transmit and receive electromagnetic waves comprising:
generating opposing magnetic fields each having a plane of
maximum force running perpendicular to a longitudinal axis of the
respective magnetic field;
generating heat from a heat source along an axis parallel to the longitudinal axis of the magnetic field;
generating an accelerator parallel to and in close proximity to
the heat source, thereby creating an electromagnetic injection point;
and
generating a communication signal into the electromagnetic
injection point, thereby sending and receiving the communication signal
at a speed faster than a known speed of light.
2. The method of claim 1, wherein said magnetic fields are generated by electromagnets.
3. The method of claim 1, wherein said magnetic fields are generated by permanent magnets.
4. The method of claim 2, wherein said electromagnets are wound with 2500 turns of 22 AWG wire.
5. The method of claim 1, wherein the temperature of said heat source is at least 1000 degrees Fahrenheit.
6. The method of claim 1, wherein said heat source further comprises a 620-watt Halogen lamp.
7. The method of claim 1, wherein said accelerator is linear in polarization.
8. The method of claim 1, wherein said accelerator is circular in polarization.
9. The method of claim 1, wherein said communications signal is generated by a magnetic injection assembly and a BNC connector.
10. The method of claim 9, wherein said magnetic injection assembly further comprises a one-quarter wavelength coil antenna.
11. The method of claim 9, wherein said magnetic injection assembly further comprises a three-quarter wavelength coil antenna.
12. The method of claim 1, wherein said accelerator is wrapped around said heat source.
13. An improved antenna comprising:
a heat source;
at least one magnetic field source in close proximity with said heat source;
an electromagnetic injection point formed in close proximity to said magnetic field source;
at least one accelerator in close proximity with said heat source; and
an electromagnetic signal inserter placed at said
electromagnetic injection point whereby a communication signal may be
generated through said signal inserter, thereby sending the signal at a
speed faster than light.
14. The improved antenna of claim 13, wherein the temperature of said heat source is at least 1000 degrees Fahrenheit.
15. The improved antenna of claim 13, wherein said magnetic
field source further comprises an electromagnet or permanent magnet.
16. The improved antenna of claim 13, wherein said accelerator is linear or circular in polarization.
17. The improved antenna of claim 13, wherein said
electromagnetic signal inserter further comprises a magnetic injection
assembly and a BNC connector.
18. An improved antenna comprising:
a heat source;
first and second electromagnets in close proximity with said
heater, said first and second electromagnets each creating an opposing
magnetic field;
an electromagnetic injection point formed at the intersection of said opposing magnetic fields;
first and second accelerators in close proximity with said heat source; and
an electromagnetic signal inserter placed at said
electromagnetic injection point whereby a communication signal may be
generated through said signal inserter, thereby sending the signal at a
speed faster than light.
19. The improved antenna of claim 18, wherein said heater further comprises a 620-watt Halogen lamp.
20. The improved antenna of claim 18, wherein the temperature of said heat source is at least 1000 degrees Fahrenheit.
21. The improved antenna of claim 18, wherein said first
accelerator is biased at +2000 V DC and said second accelerator is
biased at -2000 V DC.
22. The improved antenna of claim 18, wherein said first and second accelerators are wrapped around said heat source.
23. The improved antenna of claim 18, wherein said
electromagnetic signal inserter further comprises a magnetic injection
assembly and a BNC connector.
24. The improved antenna of claim 23, wherein said magnetic
injection assembly further comprises a one-quarter or three-quarter
wavelength coil antenna.
25. An improved antenna comprising:
a 620 watt Halogen pencil lamp;
first and second thin wires attached to said lamp, said first
thin wire biased at +2000 V DC, said second thin wire biased at -2000 V
DC;
an inductor housing enveloping said lamp;
first and second electromagnets attached to said inductor
housing, said electromagnets oriented such that both magnetic norths
are disposed toward the center of said inductor housing;
a magnetic injection assembly disposed between said electromagnets; and
a BNC connector in serial connection with said magnetic injection assembly.
26. The improved antenna of claim 25, wherein said thin wires are wrapped around said lamp for circular polarization.
27. The improved antenna of claim 25, wherein said thin wires
are placed 180.degree. apart along said lamp for linear polarization.
28. The improved antenna of claim 25, wherein said inductor housing is thermally insulated.
29. The improved antenna of claim 25, wherein said electromagnets are wound with 2500 turns of 22 AWG wire.
30. A method to transmit and receive electromagnetic waves comprising:
generating opposing magnetic fields each having a plane of
maximum force running perpendicular to a longitudinal axis of the
respective magnetic field;
generating heat from a heat source along an axis parallel to the longitudinal axis of the magnetic field;
generating an accelerator parallel to and in close proximity to
the heat source, thereby creating an electromagnetic injection point;
generating a communication signal into the electromagnetic injection point; and
receiving said communication signal as transmitted from said electromagnetic injection point. Description
FIELD OF INVENTION
The present invention relates to a new type of antenna for
transmission and reception of RF signals. The present invention can be
used to replace conventional antennas. It is believed that this
invention can transmit energy at a faster speed
and over a greater distance than conventional antennas with the same
power.
BACKGROUND OF THE INVENTION
All known radio transmissions use known models of time and space dimensions for sending the RF signal.
The present invention has discovered the apparent existence of
a new dimension capable of acting as a medium for RE signals. Initial
benefits of penetrating this new dimension include sending RF signals
faster than the speed of light, extending
the effective distance of RF transmitters at the same power radiated,
penetrating known RF shielding devices, and accelerating plant growth
exposed to the by-product energy of the RF transmissions.
The following describes, in simple terms, what the present
invention actually does. The present invention takes a transmission of
energy, and instead of sending it through normal time and space, it
pokes a small hole into another dimension,
thus, sending the energy through a place which allows transmission of
energy to exceed the speed of light.
The following is a description of how the communications medium converter functions.
First, you need to create a hot surface that is more than 1000
degrees Fahrenheit. Next, it requires a strong magnetic field. Then,
you need an accelerator, followed by an electromagnetic injection
point. For communications or data
communication, you need 2 devices. Each device is connected to a
transmitter and receiver. This allows electromagnetic energy to enter a
dimension and to travel at speeds faster than the speed of light.
The magnetic fields are focused onto the heat generating
device. The electromagnetic injection point is the plane generated by
the two opposing magnetic fields.
It has been observed by the inventor and witnesses that accelerated plant growth can occur using the present invention.
For accelerated plant growth, first, you need to create a hot
surface that is more than 1000 degrees Fahrenheit. Next, you need a
strong magnetic field. Only one device is needed for this function.
This allows energy from another dimension to
influence plant growth.
SUMMARY OF THE INVENTION
The main aspect of the present invention is to send RF signals faster than the speed of light.
Other aspects of this invention will appear from the following
description and appended claims, reference being made to the
accompanying drawings forming a part of this specification wherein like
reference characters designate corresponding parts
in the several views.
The preferred embodiment is an additional piece of equipment
that connects to an existing communications device in place of its
original antenna. This device changes the medium of transmission and
reception of electromagnetic waves. This allows
the transmission and reception of electromagnetic radio signals to
exceed the speed of light.
The main purpose of this device is:
1. To allow signals to travel great distances at many times the speed of light.
2. To use considerably less power to travel the same distance, compared to transmitters not using this device.
A. There are several pieces that make it work.
B. The following four things (numbered 1)-4) below) must occur for this unit to function efficiently.
1) There must be a heat source that produces more than 1000 degrees Fahrenheit.
a) This heat source may or may not be in a sealed assembly.
2) There must be at least one magnetic field. This unit uses two opposing magnetic fields.
a) These fields may be produced by electromagnets or by
permanent magnets. This can be done with just one magnetic field, but
it would be harder to find the penetration point. Consequently, it is
harder to find where to inject the
electromagnetic radio signal. The strength of the magnetic field is
variable, the closer to the heat source, the lower the magnetism can
be.
3) There must be at least one accelerator. This unit uses two accelerators.
a) These accelerators may be linear or circular in polarization.
b) These accelerators need to be close to the heat source and
near to the junction of the opposing magnetic fields and close to the
penetration point.
c) This unit can use one accelerator, but is more efficient with two.
4) There must be a way to insert the electromagnetic signal
which is the electromagnetic injection point. Digital data can also be
sent through this device.
a) The electromagnetic signal is inserted at the junction of
the two opposing magnetic fields or at the penetration point, if you
are using just one magnetic field.
The following is a description of how the preferred embodiment known as the Hyper-Light-Speed Antenna is constructed.
1. R5 is a 620-watt Halogen pencil lamp approximately 12 inches
long with a diameter of approximately 0.3 inches. Power to the lamp is
supplied at the ends of the lamp.
2. The accelerators are a thin piece of wire wrapped around
the glass lamp. (This is for circular polarization). For linear
polarization, two thin pieces of wire are attached to the lamp. One
wire runs down one side of the lamp, the other
wire runs down the other side of the lamp (180 degrees from each
other). The spacing is not critical but must have enough spacing to
prevent arcing between the accelerators. The accelerators operate at
+2000 V DC on one accelerator and -2000 V DC on
the other.
3. This assembly goes inside a tube approximately 10.3 inches
long.sub.-- this length is not critical. Diameter of the tube is
approximately 1.1 inches.
4. Heat insulating material is installed on the tube.
5. Coil forms are installed on the tube, the forms CF1 and CF3
are 4.3 inches long. These forms are then wound with 2500 turns of 22
AWG wire.
6. The coils are wired so both Magnetic Norths are toward the
center of the tube. (The unit can be set so both Magnetic Souths are
toward the center.)
7. In the middle of the tube there is 0.4 inches for the magnetic injection assembly L2.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic of the current invention.
FIG. 2 is a schematic of the power entry and rectifier circuitry.
FIG. 3 is a schematic of the 5 V DC and the .+-.2000 V DC power supply.
FIG. 4 is an assembly drawing of the inductor housing.
FIG. 5 is a schematic of the inductor housing.
FIG. 6 is a partial parts list for the current invention.
FIG. 7 is a schematic of the heater power supply for R5.
FIG. 8 is a schematic of the electromagnet power supply.
FIG. 9 is a side and end plane view of the electromagnet coil form.
FIG. 10 is a side and end plane view of the magnetic injection assembly coil form.
FIG. 11 is a side and end plane view of the inductor housing and heater.
FIG. 12 is a continuation of the parts list of FIG. 6.
FIG. 13 is a schematic view of the electromagnets and their generated magnetic fields.
Before
explaining the disclosed embodiment of the present invention in detail,
it is to be understood that the invention is not limited in its
application to the details of the particular arrangement shown, since
the invention is capable of other embodiments. Also, the terminology
used herein is for the purpose of description and not of limitation.
DESCRIPTION OF THE PREFERRED EMBODIMENT
The current invention functions like an antenna that can
replace an existing antenna on a transmitter or receiver. The current
invention changes the medium of transmission and reception of
electromagnetic waves such that information is
transmitted at greater than the speed of light.
FIG. 1 illustrates the general layout of the preferred
embodiment of the invention. The invention is an antenna that, it is
believed, can transmit or receive information at a speed greater than
the speed of light. L1 and L3 are electromagnets
which create two opposing magnetic fields. A heater R5 consisting of a
620-watt Halogen lamp is used to raise the temperature to 1000.degree.
F.
Two accelerators L4 and L5 are biased at .+-.2000 V DC. The accelerators are wires wrapped around the glass heater R5.
The intersection of the opposing magnetic fields created by electromagnets L1 and L3 form an electromagnetic injection point.
The magnetic injection assembly L2 is a one-quarter or
three-quarter wavelength coil antenna placed at the electromagnetic
injection point. J1 is a BNC connector for the insertion of the RF
signal if the device is a transmitter or for the
extraction if the RF signal of the device is a receiver.
The power supply PS1 supplies the +30 V DC to +140 V DC to
supply the electromagnets L1 and L3 and the heater R5. The power supply
also supplies the +2000 V DC and -2000 V DC bias voltages for
accelerators L4 and L5.
FIG. 2 is the input filter and regulator circuitry for the
power supply PS1. FL1 is a power entry module which uses a common
PC-style power cord. FL1 has an EM1 filter built into it.
SW1 is a double pole single throw switch which turns power to
the device on and off. Circuit breaker CB1 and CB2 are installed for
protection in the event of a circuit failure. Rectifier BR1 and
capacitor C3 generate an unregulated DC voltage
for use in the circuitry on FIG. 7 and 8. The AC voltage from SW1 is
used on the circuitry of FIG. 3.
FIG. 3 is the power supply PS1. The signals TS1-2 and TS1-3
from FIG. 2 go to terminal strip TSI and supply transformer T2. Diode
D5 rectifies the output of transformer T2 and generates an unregulated
+34 V DC. Capacitor C5 is used to filter
some of the ripple from the +34 V DC. The fixed frequency pulse width
modulated control circuit U1 is used to control the switching regulator
power supply PSI. Power supply PS1 produces +5 V DC VCC, +2000 V DC,
and -2000 V DC.
T1 is a split core, open frame flyback transformer. The
Primary is hand wound on the side of the flyback that has no existing
windings. The primary is 20 turns center tapped using 22 AWG magnet
wire. The +5 volt secondary is wound on the same
side the primary is wound. This winding is 18 turns center tapped using
22 AWG magnet wire. (T1 can be almost any open frame split core flyback
transformer, which was designed for about 10,000 volts with an external
high-voltage diode).
C11 and R13 provides a soft start to the power supply PS1. R19
and C12 sets the oscillator frequency at approximately 80 KHz. R14,
R15, C9, and C10 provide feedback to pin 3 of U1. R10, R16, and R21
provides current limit for the +5 V DC
output.
Q8 and Q9 drive the primary winding of transformer T1 to
produce the output voltages, R11 provides bias to keep Q8 turned off,
and R12 provides bias to keep Q9 turned off until U1 sends a varying
pulse width to drive Q8 and Q9. Pin 4 of U1
provides a +5-volt reference voltage, R9 and R20 is a voltage divider
that provides a 2.5-volt reference to pin 2 of U1. When the voltage is
lower than 2.5 volts on pin 1 of U1 the pulse width is increased at U1
pin 8 and U1 pin 11, when the voltage is
higher than 2.5 volts on pin 1 of U1, then the pulse width is decreased
at U1 pin 8 and U1 pin 11. R22 and R23 is a voltage divider which
divides the +5 volts to approximately 2.5 volts. R22 sets the upper
limit of the +5 volts. The potentiometer R23
adjusts the +5 volts. The voltage at the wiper of R23 is compared to
pin 2 of U1. D1 and D2 full wave rectifies the +5 volts, C8 and C13
filters the +5 volts. The +5 volts drives D11 which is a light-emitting
diode, R6 limits the current through D11. D11 lights when high voltage
is being produced.
D3 and D4 connect to the high-voltage winding of T1, D3
rectifies and produces the +2000 volts DC, C1 filters the +2000 volts,
and C2 filters the -2000 V DC. R24 is selected to adjust the plus and
minus 2000 volts.
The voltage from rectifier BR1 FIG. 2 is used in FIG. 7 to
generate the voltage to drive R5 in FIG. 1. Resistors R27, R28, R29,
R30, R2, R1 and potentiometer R26 provide a voltage divider to
ultimately set the voltage on heater R5. Capacitor C4
provides additional filtering to the voltage on heater R5. The divider
output voltage on the anode of diode D6 is stepped down by the diode
drops of diodes D6 and D7 and emitter followers Q16 and Q15 to drive
the five parallel emitter followers Q10,
Q11, Q12, Q13, Q14. The emitter follower Q10-Q14 output currents are
balanced by resistors R7, R8, R17, R18, R25 and drive the heater R5.
The voltage from rectifier BR1 FIG. 2 is used in FIG. 8 to
generate the voltage to drive the electromagnets L1 and L3 FIG. 1.
Resistors R42, R43, R44, R45, R33, R31 and potentiometer R32 provide a
voltage divider to ultimately set the voltage on
electromagnets L1 and L3. Capacitor C7 and C14 provides additional
filtering to the voltage on electromagnets L11, L3. The divider output
voltage on the anode of diode D8 is stepped down by the diode drops of
diodes D8 and D9 and emitter followers Q7
and Q6 to drive the five parallel emitter followers Q1, Q2, Q3, Q4, Q5.
The emitter follower Q1-Q5 output currents are balanced by resistors
R37, R38, R39, R40, R41 and drive the electromagnets L1 and L3.
The diode D10 is used to suppress the inductive kick from electromagnets L1 and L3 when the device is shut down.
FIG. 4 is a more detailed mechanical depiction of the present
invention. Heater R5 is a 620 watt Halogen pencil lamp approximately 12
inches long with a diameter of approximately 0.3 inches. Power is
supplied at the ends of the lamp A, B.
Accelerators L4, L5 are thin wires wrapped around the heater
R5 for circular polarization. For linear polarization, accelerators L4
and L5 are placed along the lamp 180.degree. apart. The spacing between
accelerators L4 and L5 are not critical
but must be enough space to prevent arcing between the accelerators L4,
L5. The accelerators L4, L5 operate at +2000 V DC on L5 and -2000 V DC
on L4.
The heater R5 is placed inside of inductor housing 10
approximately 10.3 inches long and 1.1 inches in diameter. Heat
insulating material HI is installed on the inductor housing 10.
Coils are wound on forms to form electromagnets L1, L3. The
electromagnets L1, L3 are wound with 2500 turns of 22 AWG wire. The
electromagnets L1, L3 are placed on the inductor housing 10 so that
both magnetic norths are toward the center of
the inductor housing 10. The electromagnets L1, L3 are separated by 0.4
inches for the magnetic injection assembly L2. Connector J1 provides an
electrical connection to the magnetic injection assembly L2.
FIG. 5 further illustrates the electrical relationship between
the heater R5, the accelerators L4 and L5, and the electromagnets L1,
L3.
FIG. 11 shows the mechanical dimensions of the inductor housing 10 and the heater R5.
FIG. 9 is the mechanical dimensions of the coil form CF1 and
CF3 for the electromagnets L1, L3. The coil forms CF1 and CF3 are wound
with 2500 turns of 22 AWG wire to from electromagnets L1, L3.
FIG. 10 is the mechanical dimensions of the coil from CF2 for the magnetic injection assembly L2.
FIGS. 6 and 12 are a parts list for the current invention. The
invention has been built as a prototype and testing is in progress.
FIG. 13 shows electromagnet L1 which generates a first
magnetic field 101. Electromagnet L3 generates a second magnetic field
102. The intersection of first magnetic field 101 and second magnetic
field 102 forms electromagnetic injection point
100.
Although the present invention has been described with
reference to preferred embodiments, numerous modifications and
variations can be made and still the result will come within the scope
of the invention. No limitation with respect to the
specific embodiments disclosed herein is intended or should be
inferred.
______________________________________ GLOSSARY
______________________________________ L1. Electromagnet L2.
Electromagnetic injection assembly L3. Electromagnet L4. Accelerator
L5. Accelerator R5. Heater J1. BNC connector PS1. Power
supply ______________________________________
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