Imaging technology offers realtime video of bodies electromagnetic structure

Therefore, behold, I will proceed to do a marvellous work among this people, even a marvellous work and a wonder: for the wisdom of their wise men shall perish, and the understanding of their prudent men shall be hid.

We 'wind' dual-loop transmitter/receiver combos and create 8, 16, 32, or more of them. We place the magnetic generators in an equidistant fashion around a scanning ring, the area we wish to study. Each transmitter must aim at the same point at the same time so we must synchronize every waveform. 

I used multiple computers running in parallel to output 'video' waveforms, driving all the transmitters concurrently. We create our waveforms from simple math which tells us the angle each transmitter must point to hit our moving spot.

The overall field strength of all transmitters combined remains equal, only the vectors change. As such, there is no frequency dependent depth of penetration restriction. The amplified waveform vectors, for each transmitter, pull the rod of balanced magnetic vectors, through space, in realtime. The amplitude of the output will be related to both the velocity of the magnetic rod, which remains constant, and the electromagnetic properties of the scanned point.

And in every place where the grounded staff shall pass, which the Lord shall lay upon him, it shall be with tabrets and harps: and in battles of shaking will he fight with it.

Returning to our magnetic loops from above - we already know we can direct a magnetic field with digital data. We turn digital 'wave tables' into real-time voltages, we amplify the signal and apply it to our loops of wire. With simple vector addition we can determine the angle we wish to point the 'loops' for any point within our scanning window. For each sample we ensure the vector sum, of each transmitter pair, is equal:

Much like a television we choose to scan in a raster fashion from left to right, going line by line. The actual scanning rate of this system was 320*320*30 frames per second = 3,072,000 points per second. We use a 'standard' computer which operates at video frequencies. We lock each computer to a single master clock which generates vertical and horizontal sync signals, in this case for Amiga computers.

If we think of the system in terms of a block diagram, we can greatly reduce the size and complexity of our system. For each 'transmitter block', 1 of 8, 16 or 32, can be thought of as dual video memory, a counter to cycle through the memory, and finally dual digital to analog convertors connected to amplifiers and the dual coil transmitters. Readily available video memory, d/a convertors, or modern ramdacs, and CRT high current amplifiers can be employed to engineer our scanner. Clock each 'board' from a single horizontal and vertical sync signal and we can output, concurrently, the massive amount of digital data required for above defined system.

I will show you the mystery of the woman, and of the beast that carries her, which has seven heads and ten horns.

And out of his mouth goeth a sharp sword, that with it he should smite the nations: and he shall rule them with a rod of iron: and he treadeth the winepress of the fierceness and wrath of Almighty God.