Things pyrazo related...
- From: David Bright Morning <froggisarmi@xxxxxxxxx>
- Date: Wed, 22 Jul 2009 15:12:38 -0700 (PDT)
Introducing the Pyrazo (signal absorption induction) circuit.
This circuit induces a oscillation from a oscillation source to be
drawn into said circuit. It works using the following principle: the
first pi/2 radians of the oscillation are used to power up a primary
of a pulse transformer, at which point the current through that
primary is interrupted and the voltage spike in the secondary that
results from that interruption is shunted back to the antenna, which
pulls the oscillation into the device for the second pi/2 radians of
the oscillation. In the full duplex version of the device (pictured
above), this process is repeated in the other direction in the same
manner for the third and fourth pi/2 radians respectively.
Components of the Device
The device is composed primarily of a timing circuit, pulse
transformer, interrupt switch, shunt switch, and a power harness
switch. There are other components which are optionally included to
improve the operation of the device. The switches used in the device
may be transistors, triodes, tetrodes, pentodes, krytrons, relays, or
any means of regulating current from the electric signals generated by
the timing circuit.
Antenna System
The optional antenna system connects the device with the oscillation
source. It may be a radio antenna, a speaker, an electromagnetic
mechanical oscillation receiver/generator, or any device capable of
both receiving and transmitting oscillations from and to the
oscillation source and converting the oscillations to and from an
electromagnetic signal.
Tuning Circuit
The optional tuning circuit filters out unwanted frequencies. In the
device pictured above a simple tank circuit is used.
Timing Circuit
The timing circuit generates phase shifted output which is used to
power the interrupt and shunt switches. It must be isolated from the
effect of the pulse transformers voltage spike. You can use any
circuit that will create output shifted by pi/4 radians to drive the
interrupt, shunt, and harness switches. One may even use a
microcontroller that does DSP for this portion.
Choke
The optional choke is used to quickly overcome the initial condition
of the device by allowing current to flow through the timing circuit,
and then gradually through the switches and transformer.
Interrupt Switch(es)
The interrupt switches are used to interrupt the flow of the signal
through the primary of the pulse transformer. In the device pictured
above the flow is blocked in one direction only.
Shunt Switch(es)
The shunt switches shunt the pulse, generated in the secondary of the
pulse transformer when its primary is interrupted, back to the
antenna.
Pulse Transformer
The pulse transformer has its primary charged by one portion of the
signal, then that signal is abruptly interrupted near its peak to
generate a pulse in its secondary, which is used to induce said
signal.
Power Harness Switch(es)
The power harness switch(es) are used to isolate the signal output of
the device from the pulses generated in the secondary of the pulse
transformer, and to ensure that those pulses are properly routed back
to the antenna.
Step Down Transformer
High voltages may be generated by the device and the optional step
down transformer helps to reduce that voltage and to generate more
current.
Rectification Circuit
The optional rectification circuit is used to convert the AC to DC if
one wishes it to charge a battery, or store it by some other means.
Tube Heater Power Circuit
Not all frequencies and voltages will work in a cold-cathode tube
version of the device. You may want to optionally provide current for
tube heaters if tubes are used.
Half-Duplex Version of Device
The half-duplex version of the device is similar, although its design
has been simplified by using only half the signal and shorting out the
rest of the signal by means of a specially constructed diode circuit
named the "Valve Circuit". This specially constructed diode circuit
allows through the lower voltages of the input signal in one direction
while blocking the higher voltages of the shunted voltage spikes in
the same direction so that they may be routed back to the antenna. In
the example pictured above, a tube is used in combination with a
reverse-biased zener diode that breaks down and allows negative
current to the grid when the voltage is above a certain value. Also
note that when only dealing with half the cycle, a diode suffices for
the power harness switch. Another variation of the half-duplex
version has a two-directional interrupt switch. This allows for a
positive feedback loop of the generated spike back through the primary
again.
Operation of the Device
Note that during the operation of this device that a positive feedback
loop forms, limited by the impedance of the primary, when the spike is
routed through the primary.
Operation of the Half-Duplex Version
Applications of the Device
The device may be used to absorb or amplify signals from any signal
source. Specifically, it may be used for: converting ionosphere
vibrations to usable energy, converting radio signals generated by
pulsars, quasars and black holes to usable energy, converting noise
pollution to energy, amplifying radio signals, amplifying sounds,
absorbing the energy produced by earthquakes, absorbing the vibrations
in bridges and large buildings, and much more.
Principles of the Device
Canceling Wave
The spike that is generated is equivalent to generating a canceling
wave. As we know, energy is not created or destroyed by this
cancellation, but merely transferred.
Attraction of Photons
When this device is used on radio signals, the voltage spike that
occurs happens when the nearby photons are at their most polarized,
and the spike is oriented such that it might attract these photons.
Inductive Coupling
When used on radio signals, the receiving antenna starts generating a
canceling wave that matches the broadcasting antenna. This draws in
more signal to the receiving antenna than would otherwise intersect
the receiving antenna naturally. Eventually the signal follows paths
that resemble magnetic lines of force.
Stay Tuned!
Further developments in this technology will be posted here. Happy
Tinkering
(C) Copyright 2009 David Robert Morgan
.
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