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Some preliminary tests don't cost you anything.
If you could listen very well to the input to your brain from handling objects in the proximity of the device, describe best you can in which way gravity or inertia seem affected, and if you descibe the size and location of the effect, a simple no-cost test can surely be devised to fit it.
Your ingenuity and curiosy got you this far, now you're being challenged to go beyond your nature peak talents, and take it further. this forum can help.
For instance, I'd be very curious to know whether for any area near the device, G (gravity's constant) is affected. This should be fairly easy to (priliminary, not scientifically) tested.
I propose a simple ball bearing dropping device, which produces the same type of drop each and every time. A simple camera on a tripod can make nice recording. Add clear release and land sounds, and the audio track can get very precise confirmation of drop times.
Should the effect somehow only exhibit itself laterally, one way would be to launch a ball bearing horizontally over the device (from east, west, south, north), device locked and open. Just record how far the bearing flies till it lands. All you need is a wooden or steel ramp to roll the bearing off, a free level floor, and some sand. The launching pad would rotate, and mounted to it a means to draw the distance rings for visual confirmation.
Should the effect not exhibit itself in the /sē dimension, a device can be thought up to get the ball to describe a very specific acceleration and/or radial acceleration pattern. A bit of lego and scrap metal should do the trick.
These almost primary school experiments should help you and the university to come up with more tailored tests, to descibed any anomaly most definately possible, at any budget.
I urge you to not wait for a testing setup to be presented to you only for the device to be placed on. A rudimentary G measurement within the affected area you observe, should be fairly basic to set up and carry out. If you get any signifacant difference in drop speeds or flight reach between the locked device and open device, that's huge.
I just realize that, magnetism being in some form available in the locked device, and compact non-metalic ball or weight would be welcome to be incorperated in any tests. Any material you've been able to get anomalous results from, is suspect for above proposed tests. On a small scale and low velocity though, even a tennis ball could prove sufficient for measurements.
If only metalic objects should give unexpected results, then at least we are to learn something about the otherwise seemingly hidden magnetic properties, even if they should turn out to not be gravity-related.
Please take an end of wood, mark it well for height. Say, a 2 meters long 2x4. A non-manual launch pad on top, which makes sound. Rolling the ball off in a controlled manner, narrow parabola, would do the trick. The camera can measure the drop time. Let's take it from there.
But again, your observations should poin to the first and best way to get objective measurements of any anomaly present.
Please try to put in words, specifically in which way you and others notice anything?
With your iniatial gravity wave claim though, it's not strange to request a simple drop test I think. My claim is you can do at free of any cost.
heck, use an existing cubboard to nudge a ball bearing off. You could make it land through the device itself if you consider that appropriate.
Another thing I'd love to see measured, is the amount of kinetic energy accumulated, by direction the ball to level and then vertical up outside of reach, see if it reaches higher or lower, (un)locked.
I could go on an on, but hope to inspire you to make simple measurement, until an objective anomaly is found.
Good luck,
J
If you could listen very well to the input to your brain from handling objects in the proximity of the device, describe best you can in which way gravity or inertia seem affected, and if you descibe the size and location of the effect, a simple no-cost test can surely be devised to fit it.
Your ingenuity and curiosy got you this far, now you're being challenged to go beyond your nature peak talents, and take it further. this forum can help.
For instance, I'd be very curious to know whether for any area near the device, G (gravity's constant) is affected. This should be fairly easy to (priliminary, not scientifically) tested.
I propose a simple ball bearing dropping device, which produces the same type of drop each and every time. A simple camera on a tripod can make nice recording. Add clear release and land sounds, and the audio track can get very precise confirmation of drop times.
Should the effect somehow only exhibit itself laterally, one way would be to launch a ball bearing horizontally over the device (from east, west, south, north), device locked and open. Just record how far the bearing flies till it lands. All you need is a wooden or steel ramp to roll the bearing off, a free level floor, and some sand. The launching pad would rotate, and mounted to it a means to draw the distance rings for visual confirmation.
Should the effect not exhibit itself in the /sē dimension, a device can be thought up to get the ball to describe a very specific acceleration and/or radial acceleration pattern. A bit of lego and scrap metal should do the trick.
These almost primary school experiments should help you and the university to come up with more tailored tests, to descibed any anomaly most definately possible, at any budget.
I urge you to not wait for a testing setup to be presented to you only for the device to be placed on. A rudimentary G measurement within the affected area you observe, should be fairly basic to set up and carry out. If you get any signifacant difference in drop speeds or flight reach between the locked device and open device, that's huge.
I just realize that, magnetism being in some form available in the locked device, and compact non-metalic ball or weight would be welcome to be incorperated in any tests. Any material you've been able to get anomalous results from, is suspect for above proposed tests. On a small scale and low velocity though, even a tennis ball could prove sufficient for measurements.
If only metalic objects should give unexpected results, then at least we are to learn something about the otherwise seemingly hidden magnetic properties, even if they should turn out to not be gravity-related.
Please take an end of wood, mark it well for height. Say, a 2 meters long 2x4. A non-manual launch pad on top, which makes sound. Rolling the ball off in a controlled manner, narrow parabola, would do the trick. The camera can measure the drop time. Let's take it from there.
But again, your observations should poin to the first and best way to get objective measurements of any anomaly present.
Please try to put in words, specifically in which way you and others notice anything?
With your iniatial gravity wave claim though, it's not strange to request a simple drop test I think. My claim is you can do at free of any cost.
heck, use an existing cubboard to nudge a ball bearing off. You could make it land through the device itself if you consider that appropriate.
Another thing I'd love to see measured, is the amount of kinetic energy accumulated, by direction the ball to level and then vertical up outside of reach, see if it reaches higher or lower, (un)locked.
I could go on an on, but hope to inspire you to make simple measurement, until an objective anomaly is found.
Good luck,
J
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