Back to Basics

[dankie]

That will be after and IF I fail with this Stephen Meyers replication of the hydroxyl refill , I am waiting on a casing for my cell that a friend of mine is making . Expect me to take 1 year or two on fine tuning that thing .

However , I have a wonderful phase delay driver I made for the Boyce toroid .But I am not sure if three frequencies of exactly f, f/2 anf f/4 @ exactly 50% duty cycle will even work anyways , maybe SM can answer that ? Phase is entirely adujstable tho .

Yay or nay ?

It will be pretty improbable to "find resonance" for three random frequencies of random duty cycle . AND  random phase delay.

Totally impossible to do with 3 seperate 555's , VERY advanced electronics will need to be designed for the single purpose of pulsing it .

[Grumpy]

That will be after and IF I fail with this Stephen Meyers replication of the hydroxyl refill , I am waiting on a casing for my cell that a friend of mine is making . Expect me to take 1 year or two on fine tuning that thing .

That may be too late.

A time-varying magnetic field external to the Earth induces electric currents in the conducting ground. These currents create a secondary (internal) magnetic field. As a consequence of Faraday's law of induction, an electric field at the surface of the Earth is induced associated with time variations of the magnetic field. The surface electric field causes electrical currents, known as geomagnetically induced currents (GIC), to flow in any conducting structure, for example, a power or pipeline grid grounded in the Earth. This electric field, measured in V/km, acts as a voltage source across networks.

Examples of conducting networks are electrical power transmission grids, oil and gas pipelines, undersea communication cables, telephone and telegraph networks and railways. GIC are often described as being quasi direct current (DC), although the variation frequency of GIC is governed by the time variation of the electric field. For GIC to be a hazard to technology, the current has to be of a magnitude and occurrence frequency that makes the equipment susceptible to either immediate or cumulative damage. The size of the GIC in any network is governed by the electrical properties and the topology of the network. The largest magnetospheric-ionospheric current variations, resulting in the largest external magnetic field variations, occur during geomagnetic storms and it is then that the largest GIC occur. Significant variation periods are typically from seconds to about an hour, so the induction process involves the upper mantle and lithosphere. Since the largest magnetic field variations are observed at higher magnetic latitudes, GIC have been regularly measured in Canadian, Finnish and Scandinavian power grids and pipelines since the 1970s. GIC of tens to hundreds of Amperes have been recorded. GIC have also been recorded at mid-latitudes during major storms. There may even be a risk to low latitude areas, especially during a storm commencing suddenly because of the high, short-period rate of change of the field that occurs on the dayside of the Earth.

GIC have been known since the mid-1800s when it was noted that electrical telegraph systems could sometimes run without power during geomagnetic storms, described at the time as operating on the “celestial battery”, while at other times they were completely inoperative [2].

[giantkiller]

Post some links to save time. Share the research not the headache...

Grumpy, That statement about space density is more profound than most will realize.  I'm surprised no-one called you out on it....

I agree, and feel that is how MANY common devices operate, including semiconductors.  I only wish I could properly put the concept into words that all would truly understand.   Oh Well.

Dankie, I'll watch for your TPU, this should be good.....   By the way, a phase controlled OSC (3) is NOT complex, unless you want it analog.  Such a circuit, in TTL, or Fast CMOS, takes about 1 hour to breadboard, and can be accurate to less than 1 nS.   Ttry looking up the old "boolean Algebra" texts and you will see demo circuits already laid out for certain communications.

[Grumpy]

Grumpy, That statement about space density is more profound than most will realize.  I'm surprised no-one called you out on it....

I agree, and feel that is how MANY common devices operate, including semiconductors.  I only wish I could properly put the concept into words that all would truly understand.   Oh Well.

Loner, apparently you are the only one that noticed that statement.

If you created a region of rarefracted space and moved it along a conductor, you will induce a travelling wave in the conductor moving at the same velocity as the rarefracted region.  There is no opposing travelling wave like in normal transmission lines when struck or induced by lightning where the inducing force is not moving along the line.  Make a sequential pattern of these "regions" moving along a conductor and you induce "DC with hash".

So, if you can induce a travelling wave into a conductor with a device that is not inductively coupled to the conductor, then you got the start of something, or not.

(By the way, the 5khz hash is probably somehow related to the repetition rate.)

Also, there are two effects occuring depending on paramaters, one is the typical induction by slow excitation such as when you draw arcs off stuff in the vacinity of the inductive field, the second is the charging effect that you get when the excitation is a shockwave and this is what you want.

[dankie]

Grumpy, That statement about space density is more profound than most will realize.  I'm surprised no-one called you out on it....

I agree, and feel that is how MANY common devices operate, including semiconductors.  I only wish I could properly put the concept into words that all would truly understand.   Oh Well.

Dankie, I'll watch for your TPU, this should be good.....   By the way, a phase controlled OSC (3) is NOT complex, unless you want it analog.  Such a circuit, in TTL, or Fast CMOS, takes about 1 hour to breadboard, and can be accurate to less than 1 nS.   Ttry looking up the old "boolean Algebra" texts and you will see demo circuits already laid out for certain communications.