SCALAR ELECTROSTATIC GRADIOMETER

The Scalar Electrostatic Gradiometer is a device which measures the interaction of environmental electrostatic fields and gradients with an artificially generated electrostatic field. This interaction is displayed on an analog meter, along with a separate electromagnetic field strength meter, so that the user may compare the relative activity of electromagnetic and electrostatic phenomena.

The user may control the polarity and magnitude of the artificially generated electrostatic field, which is used to sense environmental fields and phenomena by direct electrostatic field to field interference. By noting the response to changes in this reference field, a great deal of information about the environmental fields may be deduced. Normal electromagnetic phenomena are indicated separately, to clarify the nature of the electrostatic effects.

By mapping non-linearities in the ambient environmental electrostatic fields, an area may be scanned for "congruences" of bioelectric and exotic fields, and anticipate probable sites for future activity as well as locations of present or past events.

This surprisingly simple device has proven to be highly sensitive and accurate. By noting environmental non-linearities in the electrostatic field interactions, a broad range of formerly subjective phenomena now becomes hard, cold, objective data. New patterns of interaction between environmental field sources can shed some light on the nature of these phenomena.

This device is suitable for the study of an enormous range of subjects, such as: investigations into Paranormal phenomena of all types, geomantic and divination studies, study of standing wave phenomena, both electromagnetic and scalar, and the detection and mapping of telluric currents.

In a short time, users with no technical understanding of the device are able to detect and collect useful data in practical studies.

Notes on Component Selection:

By convention the electromagnetic field strength meter is a standard meter movement, while the electrostatic meter uses a zero centered meter that deflects right for positive and left for negative currents. Full sized meters in the 0 to 5 milliamp (-2.5 to 0 to +2.5 ma. for the electrostatic meter) range are recommended. The meters selected should be rugged, and have easily readable faces and good mechanical damping. Use the highest quality meters available, as the nature of the meters' actions convey a great deal of information in most situations.

It is possible to use a normal meter movement for both sections without circuit modifications other than selecting the correct value for the series resistor. The value of the current limiting resistors in series with each meter must be selected so that full range deflection occurs one to two volts below the positive supply voltage.

If you prefer to use a LED or LCD bar graph type display, substantial circuit modifications will be needed to prevent false readings induced by power line frequencies. These have no effect on the mechanical meter movements in the circuit as presented. Several stages of active filtering may be needed.

Digital displays should not be used, as the trend of the meter reading is often important. This is an analog device in nature, and should remain so. If computerization is mandatory, a graphical display should be used.

Construction:

Assemble the circuit according the schematic diagram. Use proper component layout techniques to minimize stray capacitance. To minimize microphonics, use either "pad per hole" copper clad breadboard, or fabricate a printed circuit board. Pay close attention to grounding. As the circuit is quite simple, the board may be mounted directly to the connections on the rear of the meters, using the electrical connections as the mechanical mounting for the circuit board as well.

The Gradiometer MUST be built in a metal box to prevent the user's body capacitance from severely limiting the sensitivity and performance of the unit. All connections for the three sense antennae should use BNC or similar connectors.

By convention, the two meters are placed side by side, with the RF sniffer on the left, and the "Delta Es" or electrostatic meter on the right. The sensitivity control for the sniffer should be located on the left, under the meter or on the left hand side of the unit. The sensitivity and bias controls for the electrostatic meter circuit are placed under or beside the meter on the right hand side of the unit. The two electrostatic antennae connect on the top side of the enclosure.

The antennae themselves should be simple straight antennae. Telescoping sections may be used, so that the operator may control the field interaction area. The electrostatic antennae should be parallel, or slightly divergent. The RF sniffer antenna may take any reasonable form, but should not intrude between the electrostatic antennae.

To wind L1, select a small toroid core with high reactance at lower frequencies. Twist a foot or so of small diameter insulated wire, and then wind this twisted pair onto the core in the normal manner for a toroidal coil. Use two different colors of insulated wire, and make sure the correct connections and phasing are used.

If you cannot locate a 100 megohm resistor, use a small number of the largest value resistors available. This resistor provides a path to ground for excess charge deposited onto the collector antenna by electrostatic field interaction and greatly enhances the stability of the device. The exact value is not critical, but it should be as high as practical.

The "gimmick" is a short length of the same twisted pair as is used in L1. This forms a small value capacitor to stabilize the electrostatic meter amplifier. Start with five inches or so. This will be trimmed in the checkout and calibration section. Do not substitute a variable capacitor here, use the old fashioned "gimmick" from the old days of radio.

As always, verify that there are no wiring errors, check that all grounding points and connections are of good quality.

Checkout and Calibration:

With the unit fully assembled, and fresh batteries in place, verify by moving the bias control that the "Delta Es"`meter will move throughout its full range. If the meter will not deflect evenly in both directions, check that both batteries are in good condition and that the bias potentiometer is working correctly, and does not have any non-linearities or other problems.

Check that the sensitivity control also works well. If the electrostatic meter "pegs and sticks" easily, and cannot be brought back by changing the bias control alone, trim a few millimeters of the "gimmick" device, and repeat the testing. This must be dome by trial and error. Be comfortable with the operation of the device before each interaction of the trimming and testing process. If you have trimmed too far, tighten the twisted pair just a bit.

Verify that the RF sniffer section and its sensitivity control also work correctly. Use a radio source such as a small wireless mike or garage door opener for testing. The RF sniffer should be able to detect low powered RF signal sources at a good range, and CB transmitters many tens of yards away. Background electromagnetic radiation levels should be easily visible at the highest sensitivity settings. This value should be noted first in each field survey or measurement.

Note the effect of RF transmissions on both meters. There should be only a small electrostatic effect unless standing waves are present.

If you travel with the device, it may be wise to make allowances to alter the gain of the sniffer amplifier stage itself. Ambient RF levels vary over a wide range; make sure that this background level may be measured in "quiet" areas. At full sensitivity, there should always be a reading on this meter.

Local effects which produce a lowering of this background level and anomalous electrostatic effects deserve special attention, as do higher than usual EM signal areas, with and without electrostatic anomalies.

The combination of such EM nulls with electrostatic-effect anomalies, along with localized endothermic effects (such as cold spots, or high heat loss zones) confirms "exotic" phenomena.

If the device is built in a humid environment, allow the unit to stabilize in an air conditioned area before calibration of the gimmick. Seal the unit well and include a small packet of dessicant inside the unit, secured so that it will not move about. New England winters are ideal times for gradiometer calibration.

Theory of Operation:

The electrostatic section consists of a differential electrometer and an associated electrostatic field source designed to have high rejection of RF and ambient electromagnetic signals. The high gain configuration limits the frequency response to a few Hertz only.

The bias control presents a DC voltage to C3, and the electrostatic leakage through this capacitor charges the emitter antenna until C3 has reached equalibrium. RFC1 prevents ambient RF from entering the power supply. The two capacitors shown on the bias potentiometer should be physically on the bias control itself to minimize lead length.

L1 and its associated capacitors form a pi network RF filter. The bifilar winding of L1 helps common mode RF signal rejection, and enhances the electrostatic field interaction.

IC-1 forms a differential electrometer, and produces an output in proportion to the electrostatic differential between the antennae. This first stage is kept stable by the electrostatic "gimmick". The second stage of IC-1 forms a simple meter driver and integrator.

The RF sniffer is conventional in its operation. A simple detector drives an amplifier stage. The 1 megohm resistor from output to inverting input may be changed to alter the gain. If the ambient RF levels in your area are low, you may wish to raise the value of this resistor to increase the maximum sensitivity of the RF sniffer section.

Operation and Use:

Once you have completed and calibrated your gradiometer, spend some time familiarizing yourself with its operation and behavior. In a dry environment try moving different types of plastics around the antenna area and note the reaction. Try this with differing amounts and polarities of charge on the emitter element by adjusting the bias control and watching the meter.

Watch how fast the electrostatic meter reacts to changes in the bias control, note any differance, or preferance to one polatiry or the other. Watch the reaction of the meters as you move along the electorstatic gradients. Be aware that large concentrations of ions will also be detected.

Try placing insulators with large free electrostatic fields some distance from the unit, and move the unit around the bit of plastic. Repeat this with a conducting electrostatic shield near the plastic object, and note how the electrostatic "shield" effects the readings.

Once familiar with your gradiometer, take it out for a walk. Note how objects effect the electrostatic field locally, and note any patterns of interaction. Pay attention to areas with higher than ambient RF fields, as there may be electromagnetic standing waves present with associated electrostatic fields.

If possible, take your new gradiometer to a site with known "exotic" phenomena activity. You will find that the gradiometer is quite sensitive to a wide range of effects. If at times the gradiometer appears to be suffering from some form of external interference, not electromagnetic in nature, shut the unit off for a few minutes. Shorting the electrostatic antenna briefly may also help. Wait a few calm minutes, and then resume your measurements. If this becomes common in a specific location, check for the presence of any ionizing radiations.

This gradiometer design has been used sucessfully in measurements of neolithic sites. It detected faulty reconstruction at the site, as well as standing stones not shown on maps of the site, and the original locations of stones which had moved due to frost-thaw cycles. Measurements of anomalous electrostatic fields associated with quartz crystals which had been "charged" by shamantic processes have been made. Areas reported to have experienced paranormal phenomena, also verified by "sensitives", have been independently found and measured by gradiometer survey.

In more than one case, hidden objects were found by use of a gradiometer. The person who owned and hid the objects was present during the test, and as the operator moved closer to the hidden objects, the owner of the objects would experience some anxiety. Electrostatic anomalies would then be manifest around the objects, givng away their position. There was no way for the owner of the hidden objects to cue the gradiometer operator.

If in doubt, try it yourself. Objective experience expands the mind.

Objects that had been "protected" from detection by alleged psychic means were also easily detectable without the hider being present. This should be tested with lost objects as well!

I hope this starts a few lines of inquiry into any of the many apparently different types of reported exotic phenomena. The general utility of this device might suggest that these apparently different phenomena may actually all be quite closely related. This simple device allows us to open the door to a much larger world.

I look forward to hearing of your adventures with this device. For years I've wanted to see what readngs might be collected from a "genuine" crop circle, as well as several other such subjects.