Quote from: zellerium on 11/26/2016 07:28 pmQuote from: WarpTech on 11/26/2016 04:25 amMaybe something like this could be simulated? This would show thrust and conservation of momentum, per Gauss's Law. I hope I didn't make any typos.OK great, I think some of these are already standard outputs. But many aren't so hopefully we can find some work aroundsTo start, does a transient solution need to be computed for all of the time derivatives? Or can we convert that to a phase derivative and compute the change per cycle? That would save time and steady state operation is really what we're after right?How do Q (and dampening factor) vary with time if the drive is at steady state? Is the mass density referring the air inside the cavity? If this was vacuum would there be an undefined velocity vector potential? What does relative voltage potential mean, relative to what? Are we ultimately after momentum density?Good questions!"... can we convert that to a phase derivative and compute the change per cycle? That would save time and steady state operation is really what we're after right?"I would agree that the derivative per cycle, or half-cycle even would be preferable, but "steady state" would be a pulsed, repetitive input signal they way Shawyer does it."How do Q (and dampening factor) vary with time if the drive is at steady state?"Haha, they don't! It should only thrust when charging and discharging. The magnetic flux into and out of the system is the momentum per unit charge."Is the mass density referring the air inside the cavity?"No, it is referring to the EM mass density, but later I used Reactive Energy/c2, the (mass) energy stored and not dissipated."If this was vacuum would there be an undefined velocity vector potential?"Yes! This is the gravito-magnetic vector potential. It's not undefined because I am equating this with the magnetic vector potential, at high Q."What does relative voltage potential mean, relative to what?"It is relative to the status of the magnetic flux inside the circumference of the circle, the integral of the electric field around 2pi*r. If the magnetic flux is not increasing or decreasing, then the voltage potential around this loop is zero "0". If the flux is increasing or decreasing there is voltage, and if it that change is accelerating, there is divergence. "Are we ultimately after momentum density?"We are after the momentum density normal to the unit area, through the big end as one integral, and through the rest of the frustum as the other integral. Preferably expressed as a difference between the two, where the damping factor can be different in each integral.That would express the thrust forward or backward, as positive or negative numbers, or 0.The divergence of the force would be the time derivative.
Quote from: WarpTech on 11/26/2016 04:25 amMaybe something like this could be simulated? This would show thrust and conservation of momentum, per Gauss's Law. I hope I didn't make any typos.OK great, I think some of these are already standard outputs. But many aren't so hopefully we can find some work aroundsTo start, does a transient solution need to be computed for all of the time derivatives? Or can we convert that to a phase derivative and compute the change per cycle? That would save time and steady state operation is really what we're after right?How do Q (and dampening factor) vary with time if the drive is at steady state? Is the mass density referring the air inside the cavity? If this was vacuum would there be an undefined velocity vector potential? What does relative voltage potential mean, relative to what? Are we ultimately after momentum density?
Maybe something like this could be simulated? This would show thrust and conservation of momentum, per Gauss's Law. I hope I didn't make any typos.
Quote from: Bob012345 on 11/26/2016 02:36 pmThere is no written rule that experimental physicists only do thus and theoretical physicists do that.It's the definitions of the term "experimental" and "theoretical". They're widely used and understood terms.Quote from: Bob012345 on 11/26/2016 02:36 pmYou are describing an ideal that is not a formal requirement.I'm doing neither. I'm giving the definitions of some widely-used terms.Quote from: Bob012345 on 11/26/2016 02:36 pmBesides, you are limiting physics when you require experimental physics to be in service of theoretical physics.That makes no sense at all. Did you even read what I wrote? There's no way that I'm "limiting" experimental physics.Quote from: Bob012345 on 11/26/2016 02:36 pmThat is the main reason modern physicists often reject new ideas, such as EmDrive or the hydrino, which don't fit into their neat paradigms.It saddens me to see such slander of the thousands of smart, open-minded physicists doing good work around the world. Shame on you!Modern physics has no bias against new ideas. What it does have is a filter to figure out which new ideas are more likely to be fruitful to explore than which other new ideas. To not have such a filter would be folly -- effort would be wasted on the wrong things.Quote from: Bob012345 on 11/26/2016 02:36 pmThey often trust the theory to such a high extent that they reject good data in front of their eyes as artifact or mistakes if they cannot explain it within currently understood theory. That makes experiment a slave of theory when it should lead theory.Utter nonsense. You obviously have no idea how physicists really work.It's actually the opposite. If anything, physicists have a bias toward wanting to believe they've found something new. Every physicist dreams of that Nobel prize that comes from discovering some new phenomenon that contradicts known theory. It's why they do their experiments. They are looking for contradictions. They accept it when they don't find them, knowing that usually they will not, but they are always hoping to find data that contradicts known theory. It makes for much more exciting papers and much more accolades, career advancement, and every other kind of reward.
There is no written rule that experimental physicists only do thus and theoretical physicists do that.
You are describing an ideal that is not a formal requirement.
Besides, you are limiting physics when you require experimental physics to be in service of theoretical physics.
That is the main reason modern physicists often reject new ideas, such as EmDrive or the hydrino, which don't fit into their neat paradigms.
They often trust the theory to such a high extent that they reject good data in front of their eyes as artifact or mistakes if they cannot explain it within currently understood theory. That makes experiment a slave of theory when it should lead theory.
Quote from: deltaV on 11/26/2016 04:44 pmQuote from: Star One on 11/24/2016 07:57 pmList of unaddressed or missing issues from the recent EW paper via a poster on Reddit.https://drive.google.com/file/d/0B6juR48k_XoTREUxc1QycWxwZ2M/viewSee what you think?In Figure 7:When the calibration pulse is turned on there's an impulsive shift in the displacement that takes around 5 seconds. When the calibration pulse is turned off there's an impulsive shift in the displacement that takes about 10 seconds. When the RF is turned on there's an impulsive shift in the displacement that takes around 20 seconds. When the RF is turned off no impulsive shift is visible (or it takes minutes and is obscured by the thermal displacement). What happened to the RF-off impulsive shift?DeltaV:Question: "What happened to the RF-off impulsive shift?"Look at the attached slide-2 and try to understand what the superposition of an impulsive signal with a thermally induced torque pendulum (TP) center of gravity (cg) signal can look like when the thrust signal is about 1/3 of the magnitude of the value of the TP cg-shift signal at the time of RF turn-off. Of course the impulsive turn-off signal is swallowed or buried by the TP cg-shift signal as shown in the report's figure-5 and in the below repeat of same slide-2_Answer slide. It's just a graphic addition problem...Best, Paul M.Best,
Quote from: Star One on 11/24/2016 07:57 pmList of unaddressed or missing issues from the recent EW paper via a poster on Reddit.https://drive.google.com/file/d/0B6juR48k_XoTREUxc1QycWxwZ2M/viewSee what you think?In Figure 7:When the calibration pulse is turned on there's an impulsive shift in the displacement that takes around 5 seconds. When the calibration pulse is turned off there's an impulsive shift in the displacement that takes about 10 seconds. When the RF is turned on there's an impulsive shift in the displacement that takes around 20 seconds. When the RF is turned off no impulsive shift is visible (or it takes minutes and is obscured by the thermal displacement). What happened to the RF-off impulsive shift?
List of unaddressed or missing issues from the recent EW paper via a poster on Reddit.https://drive.google.com/file/d/0B6juR48k_XoTREUxc1QycWxwZ2M/viewSee what you think?
Quote from: Star-Drive on 11/26/2016 06:00 pmQuote from: deltaV on 11/26/2016 04:44 pmQuote from: Star One on 11/24/2016 07:57 pmList of unaddressed or missing issues from the recent EW paper via a poster on Reddit.https://drive.google.com/file/d/0B6juR48k_XoTREUxc1QycWxwZ2M/viewSee what you think?In Figure 7:When the calibration pulse is turned on there's an impulsive shift in the displacement that takes around 5 seconds. When the calibration pulse is turned off there's an impulsive shift in the displacement that takes about 10 seconds. When the RF is turned on there's an impulsive shift in the displacement that takes around 20 seconds. When the RF is turned off no impulsive shift is visible (or it takes minutes and is obscured by the thermal displacement). What happened to the RF-off impulsive shift?DeltaV:Question: "What happened to the RF-off impulsive shift?"Look at the attached slide-2 and try to understand what the superposition of an impulsive signal with a thermally induced torque pendulum (TP) center of gravity (cg) signal can look like when the thrust signal is about 1/3 of the magnitude of the value of the TP cg-shift signal at the time of RF turn-off. Of course the impulsive turn-off signal is swallowed or buried by the TP cg-shift signal as shown in the report's figure-5 and in the below repeat of same slide-2_Answer slide. It's just a graphic addition problem...Best, Paul M.Best, I disagree with that conclusion. The superposition graph should show a change in slope where the RF is switched and when it is switched off. The "impulsive signal" is really the step response of the torque pendulum to a constant force. That signal, in the superposition graph, should have the same shape as the finned capacitor calibration force, except inverted. Any constant force acting on the torque pendulum will always produce a second order step response. I believe the correct way to analyze your data would be to do a curve fit to a first order step response. That is the dominant signal in the waveforms I have seen. After the first order step response signal is determined it can be subtracted from the waveform. The remainder, if it fits a second order step response, is the force.Since only one distance sensor was used, the displacement waveforms may have been the result of the apparatus tilting in one direction. If multiple distance sensor had been used and the measurements averaged, any error from the apparatus tilting would have been nulled out.
Quote from: ChrisWilson68 on 11/26/2016 09:44 pmQuote from: Bob012345 on 11/26/2016 02:36 pmThere is no written rule that experimental physicists only do thus and theoretical physicists do that.It's the definitions of the term "experimental" and "theoretical". They're widely used and understood terms.Quote from: Bob012345 on 11/26/2016 02:36 pmYou are describing an ideal that is not a formal requirement.I'm doing neither. I'm giving the definitions of some widely-used terms.Quote from: Bob012345 on 11/26/2016 02:36 pmBesides, you are limiting physics when you require experimental physics to be in service of theoretical physics.That makes no sense at all. Did you even read what I wrote? There's no way that I'm "limiting" experimental physics.Quote from: Bob012345 on 11/26/2016 02:36 pmThat is the main reason modern physicists often reject new ideas, such as EmDrive or the hydrino, which don't fit into their neat paradigms.It saddens me to see such slander of the thousands of smart, open-minded physicists doing good work around the world. Shame on you!Modern physics has no bias against new ideas. What it does have is a filter to figure out which new ideas are more likely to be fruitful to explore than which other new ideas. To not have such a filter would be folly -- effort would be wasted on the wrong things.Quote from: Bob012345 on 11/26/2016 02:36 pmThey often trust the theory to such a high extent that they reject good data in front of their eyes as artifact or mistakes if they cannot explain it within currently understood theory. That makes experiment a slave of theory when it should lead theory.Utter nonsense. You obviously have no idea how physicists really work.It's actually the opposite. If anything, physicists have a bias toward wanting to believe they've found something new. Every physicist dreams of that Nobel prize that comes from discovering some new phenomenon that contradicts known theory. It's why they do their experiments. They are looking for contradictions. They accept it when they don't find them, knowing that usually they will not, but they are always hoping to find data that contradicts known theory. It makes for much more exciting papers and much more accolades, career advancement, and every other kind of reward.Speaking on behalf of "every physicist" is no different than speaking on behalf of every taxpayer. I'd give the user a little bit more consideration and respect, especially considering the frequent point of authority arguments you've made on this page. There are widely held views across this country. Some might not be so obviously widespread as evidenced by the past election.
I do have a very good idea of how physics really works when you strip out the BS. I've seen first hand how new ideas can be denigrated and the scientists who publish them are reviled. I've seen it over and over. Often they are bound by paradigms they are not allowed to question. It's true.
Quote from: zen-in on 11/26/2016 09:58 pmQuote from: Star-Drive on 11/26/2016 06:00 pmQuote from: deltaV on 11/26/2016 04:44 pmQuote from: Star One on 11/24/2016 07:57 pmList of unaddressed or missing issues from the recent EW paper via a poster on Reddit.https://drive.google.com/file/d/0B6juR48k_XoTREUxc1QycWxwZ2M/viewSee what you think?In Figure 7:When the calibration pulse is turned on there's an impulsive shift in the displacement that takes around 5 seconds. When the calibration pulse is turned off there's an impulsive shift in the displacement that takes about 10 seconds. When the RF is turned on there's an impulsive shift in the displacement that takes around 20 seconds. When the RF is turned off no impulsive shift is visible (or it takes minutes and is obscured by the thermal displacement). What happened to the RF-off impulsive shift?DeltaV:Question: "What happened to the RF-off impulsive shift?"Look at the attached slide-2 and try to understand what the superposition of an impulsive signal with a thermally induced torque pendulum (TP) center of gravity (cg) signal can look like when the thrust signal is about 1/3 of the magnitude of the value of the TP cg-shift signal at the time of RF turn-off. Of course the impulsive turn-off signal is swallowed or buried by the TP cg-shift signal as shown in the report's figure-5 and in the below repeat of same slide-2_Answer slide. It's just a graphic addition problem...Best, Paul M.Best, I disagree with that conclusion. The superposition graph should show a change in slope where the RF is switched and when it is switched off. The "impulsive signal" is really the step response of the torque pendulum to a constant force. That signal, in the superposition graph, should have the same shape as the finned capacitor calibration force, except inverted. Any constant force acting on the torque pendulum will always produce a second order step response. I believe the correct way to analyze your data would be to do a curve fit to a first order step response. That is the dominant signal in the waveforms I have seen. After the first order step response signal is determined it can be subtracted from the waveform. The remainder, if it fits a second order step response, is the force.Since only one distance sensor was used, the displacement waveforms may have been the result of the apparatus tilting in one direction. If multiple distance sensor had been used and the measurements averaged, any error from the apparatus tilting would have been nulled out.Zen, let me show you what a null, thermal displacement looks like on a torsion beam. Note the difference between my trace and ew's. On mine, I was experimenting with PCM and this kept the mag frequency too high. It never slid down to resonance @ 2441 MHz where I measured 18.4 mN displacement. In effect this is a reference test for an out of resonance signal supplied to the frustum.
Quote from: rfmwguy on 11/26/2016 09:57 pmQuote from: ChrisWilson68 on 11/26/2016 09:44 pmQuote from: Bob012345 on 11/26/2016 02:36 pmThere is no written rule that experimental physicists only do thus and theoretical physicists do that.It's the definitions of the term "experimental" and "theoretical". They're widely used and understood terms.Quote from: Bob012345 on 11/26/2016 02:36 pmYou are describing an ideal that is not a formal requirement.I'm doing neither. I'm giving the definitions of some widely-used terms.Quote from: Bob012345 on 11/26/2016 02:36 pmBesides, you are limiting physics when you require experimental physics to be in service of theoretical physics.That makes no sense at all. Did you even read what I wrote? There's no way that I'm "limiting" experimental physics.Quote from: Bob012345 on 11/26/2016 02:36 pmThat is the main reason modern physicists often reject new ideas, such as EmDrive or the hydrino, which don't fit into their neat paradigms.It saddens me to see such slander of the thousands of smart, open-minded physicists doing good work around the world. Shame on you!Modern physics has no bias against new ideas. What it does have is a filter to figure out which new ideas are more likely to be fruitful to explore than which other new ideas. To not have such a filter would be folly -- effort would be wasted on the wrong things.Quote from: Bob012345 on 11/26/2016 02:36 pmThey often trust the theory to such a high extent that they reject good data in front of their eyes as artifact or mistakes if they cannot explain it within currently understood theory. That makes experiment a slave of theory when it should lead theory.Utter nonsense. You obviously have no idea how physicists really work.It's actually the opposite. If anything, physicists have a bias toward wanting to believe they've found something new. Every physicist dreams of that Nobel prize that comes from discovering some new phenomenon that contradicts known theory. It's why they do their experiments. They are looking for contradictions. They accept it when they don't find them, knowing that usually they will not, but they are always hoping to find data that contradicts known theory. It makes for much more exciting papers and much more accolades, career advancement, and every other kind of reward.Speaking on behalf of "every physicist" is no different than speaking on behalf of every taxpayer. I'd give the user a little bit more consideration and respect, especially considering the frequent point of authority arguments you've made on this page. There are widely held views across this country. Some might not be so obviously widespread as evidenced by the past election.Are you claiming that providing widely accepted definitions is a point of authority argument?The only place he speaks on behalf of every physicist is "Every physicist dreams of that Nobel prize that comes from discovering some new phenomenon that contradicts known theory." Obviously people all have different motivations, but this checking on this statement would be like asking lottery players "would you like to win the lottery?" Even the ones who understand that they do not have a real chance of winning would say yes.
Zen-In:OK lets look at similar to Dave's on- and off-resonance traces from the EW ICFTA tests I performed in-air due to the thermal limitations of the RF amplifier. What do you consider first and second order effects in the two below slides that used the same ICFTA test setup on the EW TP with the only difference being the first one is being excited at the TM212 resonant frequency and the second example being driven at an off-resonance frequency. Best, Paul M.
...Quote from: Star-Drive on 11/26/2016 10:37 pmZen-In:OK lets look at similar to Dave's on- and off-resonance traces from the EW ICFTA tests I performed in-air due to the thermal limitations of the RF amplifier. What do you consider first and second order effects in the two below slides that used the same ICFTA test setup on the EW TP with the only difference being the first one is being excited at the TM212 resonant frequency and the second example being driven at an off-resonance frequency. Best, Paul M.I don't know what is going on with that data. My earlier post related to a method you used to extract a force from the waveforms that appear to be entirely thermal in nature. Do you agree that a force applied to the torque pendulum will always produce the same response, regardless of how the force is generated?
................M.LeBel,I hope I'm playing in the right field, working very hard to get at least somewhere. As far as what you have seen in things zipping around the night sky with your Smith & Wesson Star Tron night scope, could be their funding is better than mine, or they have bigger brains. Best,Shell
Quote from: rfmwguy on 11/26/2016 10:17 pmQuote from: zen-in on 11/26/2016 09:58 pmQuote from: Star-Drive on 11/26/2016 06:00 pmQuote from: deltaV on 11/26/2016 04:44 pmQuote from: Star One on 11/24/2016 07:57 pmList of unaddressed or missing issues from the recent EW paper via a poster on Reddit.https://drive.google.com/file/d/0B6juR48k_XoTREUxc1QycWxwZ2M/viewSee what you think?In Figure 7:When the calibration pulse is turned on there's an impulsive shift in the displacement that takes around 5 seconds. When the calibration pulse is turned off there's an impulsive shift in the displacement that takes about 10 seconds. When the RF is turned on there's an impulsive shift in the displacement that takes around 20 seconds. When the RF is turned off no impulsive shift is visible (or it takes minutes and is obscured by the thermal displacement). What happened to the RF-off impulsive shift?DeltaV:Question: "What happened to the RF-off impulsive shift?"Look at the attached slide-2 and try to understand what the superposition of an impulsive signal with a thermally induced torque pendulum (TP) center of gravity (cg) signal can look like when the thrust signal is about 1/3 of the magnitude of the value of the TP cg-shift signal at the time of RF turn-off. Of course the impulsive turn-off signal is swallowed or buried by the TP cg-shift signal as shown in the report's figure-5 and in the below repeat of same slide-2_Answer slide. It's just a graphic addition problem...Best, Paul M.Best, I disagree with that conclusion. The superposition graph should show a change in slope where the RF is switched and when it is switched off. The "impulsive signal" is really the step response of the torque pendulum to a constant force. That signal, in the superposition graph, should have the same shape as the finned capacitor calibration force, except inverted. Any constant force acting on the torque pendulum will always produce a second order step response. I believe the correct way to analyze your data would be to do a curve fit to a first order step response. That is the dominant signal in the waveforms I have seen. After the first order step response signal is determined it can be subtracted from the waveform. The remainder, if it fits a second order step response, is the force.Since only one distance sensor was used, the displacement waveforms may have been the result of the apparatus tilting in one direction. If multiple distance sensor had been used and the measurements averaged, any error from the apparatus tilting would have been nulled out.Zen, let me show you what a null, thermal displacement looks like on a torsion beam. Note the difference between my trace and ew's. On mine, I was experimenting with PCM and this kept the mag frequency too high. It never slid down to resonance @ 2441 MHz where I measured 18.4 mN displacement. In effect this is a reference test for an out of resonance signal supplied to the frustum.Zen-In:OK lets look at similar to Dave's on- and off-resonance traces from the EW ICFTA tests I performed in-air due to the thermal limitations of the RF amplifier. What do you consider first and second order effects in the two below slides that used the same ICFTA test setup on the EW TP with the only difference being the first one is being excited at the TM212 resonant frequency and the second example being driven at an off-resonance frequency. Best, Paul M.
I suggest you get beyond Wikipedia for your science and think for you yourself.
Quote from: Bob012345 on 11/27/2016 12:41 amI suggest you get beyond Wikipedia for your science and think for you yourself.This is very easily an unproductive line of thought. Where humans succumb to emotion and politics, fall back on the scientific method. If you can't prove it, you can't say for sure if it's true - and if you can't prove it false, you're not making any progress in either direction. If it's outside of your means to prove or disprove something, it's probably wise to consider whether or not you're making good use of your time by endorsing it.
Well, how else would Mill describe his work if he leads the field as the first hydrino scientist since he discovered the concept?
QuoteWell, how else would Mill describe his work if he leads the field as the first hydrino scientist since he discovered the concept?Since it was discovered, if it is real serious stuff i'd imagine that more people would join the research as it promise so much technological advances. When you're the only one to research something for decades, is very probable that this something doesn't have so much evidence.
Quote from: zen-in on 11/26/2016 11:12 pm...Quote from: Star-Drive on 11/26/2016 10:37 pmZen-In:OK lets look at similar to Dave's on- and off-resonance traces from the EW ICFTA tests I performed in-air due to the thermal limitations of the RF amplifier. What do you consider first and second order effects in the two below slides that used the same ICFTA test setup on the EW TP with the only difference being the first one is being excited at the TM212 resonant frequency and the second example being driven at an off-resonance frequency. Best, Paul M.I don't know what is going on with that data. My earlier post related to a method you used to extract a force from the waveforms that appear to be entirely thermal in nature. Do you agree that a force applied to the torque pendulum will always produce the same response, regardless of how the force is generated?Hi there. I was following this thread carefully, but lost the track here. Why would you expect the same response when the issue at stake is temperature here? From what I see, you have one test off-resonance and another in resonance, both same power and temperature to use a baseline. Then you have another 3rds test in vacuum in resonance with "emdrive thrust" superposed with the thermal response, BUT you also have a calibration impulse with no thermal response because the calibration thrust was generated in a "thermally-neutral way" (not with high powered EM like the emdrive to heat stuff up).I guess you could argue that the on and off resonance test was performed in-air and it is not certain it translates to vacuum, but that's a low-priority concern overall.
Quote from: Klebiano on 11/27/2016 01:26 amQuoteWell, how else would Mill describe his work if he leads the field as the first hydrino scientist since he discovered the concept?Since it was discovered, if it is real serious stuff i'd imagine that more people would join the research as it promise so much technological advances. When you're the only one to research something for decades, is very probable that this something doesn't have so much evidence.This is a good thought that I have applied it to both shawyers and Woodward's efforts. Shawyers recently has been picked up by others, Woodward's I am not so sure. Regardless, shawyers emdrive appears to be yielding more replication efforts at much higher force levels...mN compared to microN.