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From: thejohnlreed on 21 Jul 2010 13:53 OK I can accept your word on the spring constant horizontal measure for mass. I have no quarrel with the fact that mass can be measured in a variety of ways. The ways to measure mass are as numerous as their are ways to measure resistance. Include a suitable conversion scheme for resistance and you have mass. Or even a suitable conversion scheme for any quantity the regularity of which can be paralleled to mass. I would guess that the mass spectrograph takes a given amount of mass, ignites it and measures the light spectra. But if I am incorrect there it has nothing to do with my primary focus. Its not the measure of mass in various ways that concerns me. It is the definition of mass that is most important especially because we require no greater accuracy in that definition than "amount of matter". The mathematical convenience of mass, its pragmatic mathematical and physical functionality, stops us from seeking any greater precision than "an amount of matter". The focus of physics then becomes the application of the working mathematics with respect to mass, and the development of physics is eventually left into the hands of the theoretical physicist mathematician, where mass is the primary initial physical tool, but the mathematics is an open ended field enabling any internally consistent fantasy. The scientist seeks physical truth. The mathematician seeks truth in numbers. This reflects our presumption that matter is fundamental and that we know what matter is. And mass even becomes synonymous with matter, which further supports our assumption that we know what matter is. Eventually the thinking process in physics becomes the exclusive domain of the mathematician many of whom perpetuate our ignorance and are pompous about it. Mass is consistent with the resistance we work against and it is convertible into a number of atoms for quantitative chemical reactions. And it is conserved in classical mechanics in general. These are crucial clues that can be easily missed simply because of our definition for mass. Mass is not an amount of matter. Mass is a resistance of matter that we can quantify and measure. What kind of matter? Stable and near stable atomic matter.
From: PD on 21 Jul 2010 14:32 On Jul 21, 12:53 pm, thejohnlreed <thejohnlr...(a)gmail.com> wrote: > OK I can accept your word on the spring constant horizontal measure > for mass. I have no quarrel with the fact that mass can be measured in > a variety of ways. The ways to measure mass are as numerous as their > are ways to measure resistance. Include a suitable conversion scheme > for resistance and you have mass. Or even a suitable conversion scheme > for any quantity the regularity of which can be paralleled to mass. I > would guess that the mass spectrograph takes a given amount of mass, > ignites it and measures the light spectra. No it does not. And why can you not take the trouble to Google "mass spectrometer" to find out what it is, rather than guess? > But if I am incorrect there > it has nothing to do with my primary focus. > > Its not the measure of mass in various ways that concerns me. It is > the definition of mass that is most important especially because we > require no greater accuracy in that definition than "amount of > matter". And that is wrong, as I've indicated. > The mathematical convenience of mass, its pragmatic > mathematical and physical functionality, stops us from seeking any > greater precision than "an amount of matter". The focus of physics > then becomes the application of the working mathematics with respect > to mass, and the development of physics is eventually left into the > hands of the theoretical physicist mathematician, where mass is the > primary initial physical tool, but the mathematics is an open ended > field enabling any internally consistent fantasy. The scientist seeks > physical truth. The mathematician seeks truth in numbers. > > This reflects our presumption that matter is fundamental and that we > know what matter is. And mass even becomes synonymous with matter, > which further supports our assumption that we know what matter is. > Eventually the thinking process in physics becomes the exclusive > domain of the mathematician many of whom perpetuate our ignorance and > are pompous about it. > > Mass is consistent with the resistance we work against and it is > convertible into a number of atoms for quantitative chemical > reactions. And it is conserved in classical mechanics in general. > These are crucial clues that can be easily missed simply because of > our definition for mass. Mass is not an amount of matter. Mass is a > resistance of matter that we can quantify and measure. What kind of > matter? Stable and near stable atomic matter.
From: glird on 21 Jul 2010 15:35 On Jul 21, 1:53 pm, thejohnlreed <thejohnlr...(a)gmail.com> wrote: > > The ways to measure mass are as numerous as their > are ways to measure resistance. [snip] > Its not the measure of mass in various ways that concerns me. It is > the definition of mass that is most important especially because we > require no greater accuracy in that definition than "amount of > matter". The mathematical convenience of mass, its pragmatic > mathematical and physical functionality, stops us from seeking any > greater precision than "an amount of matter". The focus of physics > then becomes the application of the working mathematics with respect > to mass, and the development of physics is eventually left into the > hands of the theoretical physicist mathematician, where mass is the > primary initial physical tool, but the mathematics is an open ended > field enabling any internally consistent fantasy. The scientist seeks > physical truth. The mathematician seeks truth in numbers. The physicist seeks numerical quantities that can be summarized in equations, > > This reflects our presumption that matter is fundamental and that we > know what matter is. And mass even becomes synonymous with matter, > which further supports our assumption that we know what matter is. We DO know what matter is, in the only possible way: Via direct sense evidence. > Eventually the thinking process in physics becomes the exclusive > domain of the mathematician many of whom perpetuate our ignorance and > are pompous about it. Physicists abandoned the primary goal of physics, which was to help us understand physical reality, i.e the metaphysics. Having done that, they perpetuate their own ignorance, pompously claiming that metaphysics is beneath their dignity. > Mass is consistent with the resistance we work against and it is > convertible into a number of atoms for quantitative chemical > reactions. And it is conserved in classical mechanics in general. > These are crucial clues that can be easily missed simply because of > our definition for mass. Mass is not an amount of matter. Well said, but wrong. Mass IS a quantity of matter. It is generally measured by weighing a body. Unfortunately, that gives us its WEIGHT not its mass. But unstructured non-particulate matter has no weight; so weighing it is the wrong way to measure mass. > Mass is a resistance of matter that we can quantify and measure. What kind of > matter? Stable and near stable atomic matter. You are referring to F = ma, in which F is a force and m is measured in grams.A force is a quantity of net pressure, measured independently of the area of application; and m in grams is the weight of the given mass. What kind of matter has that weight? Atoms do, but the matter of which they are made does not! How can that be? Because a gravitational field is a density gradient in and of the material filling a local space. That gradient permeates and sums with the gradient of any embedded atom. Because an atom has a very dense layer of matter as part of its construction, any wave system circling within it will meet increasingly stronger resistance to its motion as it enters a denser region. It is THAT net pressure, a force, that is the weight per atom. In atomic reactions some of the matter is released from the reacting atoms, so the density of the nuclei will be less so the remaining weight will also be less. The material so released will have no weight. Thats why e = mc^2 works; not because a mass has converted into energy, but because some of its weight - which is a form of energy - has.. glird
From: thejohnlreed on 21 Jul 2010 22:27 On Jul 21, 11:32 am, PD <thedraperfam...(a)gmail.com> wrote: > On Jul 21, 12:53 pm, thejohnlreed <thejohnlr...(a)gmail.com> wrote: > > > OK I can accept your word on the spring constant horizontal measure > > for mass. I have no quarrel with the fact that mass can be measured in > > a variety of ways. The ways to measure mass are as numerous as their > > are ways to measure resistance. Include a suitable conversion scheme > > for resistance and you have mass. Or even a suitable conversion scheme > > for any quantity the regularity of which can be paralleled to mass. I > > would guess that the mass spectrograph takes a given amount of mass, > > ignites it and measures the light spectra. > > No it does not. And why can you not take the trouble to Google "mass > spectrometer" to find out what it is, rather than guess? > > > But if I am incorrect there > > it has nothing to do with my primary focus. > > > Its not the measure of mass in various ways that concerns me. It is > > the definition of mass that is most important especially because we > > require no greater accuracy in that definition than "amount of > > matter". > > And that is wrong, as I've indicated. > > > > > The mathematical convenience of mass, its pragmatic > > mathematical and physical functionality, stops us from seeking any > > greater precision than "an amount of matter". The focus of physics > > then becomes the application of the working mathematics with respect > > to mass, and the development of physics is eventually left into the > > hands of the theoretical physicist mathematician, where mass is the > > primary initial physical tool, but the mathematics is an open ended > > field enabling any internally consistent fantasy. The scientist seeks > > physical truth. The mathematician seeks truth in numbers. > > > This reflects our presumption that matter is fundamental and that we > > know what matter is. And mass even becomes synonymous with matter, > > which further supports our assumption that we know what matter is. > > Eventually the thinking process in physics becomes the exclusive > > domain of the mathematician many of whom perpetuate our ignorance and > > are pompous about it. > > > Mass is consistent with the resistance we work against and it is > > convertible into a number of atoms for quantitative chemical > > reactions. And it is conserved in classical mechanics in general. > > These are crucial clues that can be easily missed simply because of > > our definition for mass. Mass is not an amount of matter. Mass is a > > resistance of matter that we can quantify and measure. What kind of > > matter? Stable and near stable atomic matter. Hello PD> We go back a rather long way on these newsgroups. At every point along the way you have put forward points that I have considered and responded to. Most of your points have helped me to address areas that need clarifying one way or another. A mass spectrograph does not merit the time to spend on investigating it when it is mentioned to support a concept that has no bearing on the subject I post. However the fact that you put it forward as an alternative approach to the measure of mass does require that I point out that I agree there are many ways to measure mass. Some are direct and meaningful and some are indirect and meaningful and many are indirect, based on established erroneous theory, and therefore garbage. The concept of gravitational lensing and its associated assumptions being a case in point. However I will now investigate mass spectrometry just in case it holds a key that can be applied to either my error or my support. Thank you for that inclusion. Again I have no quarrel with the fact that we can calculate mass in a variety of ways and that the calculation can be direct with respect to resistance even with particles of matter. The problem comes into play when we try to treat mass resistance as a conserved quantity with respect to the particles. We must then utilize the least action properties of natural physical motion itself, where units of energy and momentum are defined consistent with that motion. Where experimental validity comes from the least action itself and where we interpret it in units of the quantities we use to define it.
From: thejohnlreed on 3 Aug 2010 11:46
On Jul 21, 12:35 pm, glird <gl...(a)aol.com> wrote: > On Jul 21, 1:53 pm, thejohnlreed <thejohnlr...(a)gmail.com> wrote: > > > The physicist seeks numerical quantities that can be summarized in equations, jr writes> No problem with that. Quantification. I want to know what we are quantifying as well. > This reflects our presumption that matter is fundamental and that we > know what matter is. And mass even becomes synonymous with matter, > which further supports our assumption that we know what matter is. We DO know what matter is, in the only possible way: Via direct sense evidence. jr writes> Recognizing substance will not tell us what type of substance or what it is composed of. Assuming that substance is made of substance when all indications are that atoms are near stable or stable compacted electro-magnetic fields just has us building atoms out of the packets of energy released or emitted by the atom and the shards of rubble we acquire with our colliders. > Eventually the thinking process in physics becomes the exclusive > domain of the mathematician many of whom perpetuate our ignorance and > are pompous about it. Physicists abandoned the primary goal of physics, which was to help us understand physical reality, i.e the metaphysics. Having done that, they perpetuate their own ignorance, pompously claiming that metaphysics is beneath their dignity. jr writes> Its not that dignity is an issue but that the integrity of science requires that we quantify, verify, comprehend and predict logical consequences from the data we gather. You can't prove that fairies exist. You can't show that God exists. > Mass is consistent with the resistance we work against and it is > convertible into a number of atoms for quantitative chemical > reactions. And it is conserved in classical mechanics in general. > These are crucial clues that can be easily missed simply because of > our definition for mass. Mass is not an amount of matter. Well said, but wrong. Mass IS a quantity of matter. It is generally measured by weighing a body. Unfortunately, that gives us its WEIGHT not its mass. jr writes> Weight is a quantity that we feel. Like force. We lift an object and we feel resistance to the force we apply. We say we feel its weight. OK cool. In order to determine the magnitude of what we feel we have to compare that object to another standardized object of such and such a resistance. We use a measuring device the simplest of which is a two pan balance scale. We place the object in one pan and we blance both pans where the items we use to balance the object we lifted have graduated magnitude based on some consistent standard. Balancing the object we lift against a standard object we lift gives us a number we can call the weight of an object which we feel. What the balance scale is doing is comparing masses. Each pan has [g] acting on it to start. As we increase the magnitude in one pan and then another and so on until a balance is obtained [g] has not been a part of the action except in terms of what we feel. The magnitude of [g] has not changed beyond the miniscule change during the up and down action of the scale while it is being balanced. The end result on balance is not a comparison of [mg]. [g] is not being balanced. The scale is stationary at one location where [g] acts on each pan equally. [g] is a constant at that location. Each mass is being balanced. We balance the mass and we feel the weight. Weight is subjective but the mass is being compared. Consider a pure element. Imagine that we can place one atom at a time in a pan. We have a standard mass in the other pan. We can place one atom at a time in the pan until it is balanced against the mass in the other pan. When you lift either the pan with atoms or the pan with the standard mass you feel weight. You feel the combination [mg]. The balance compares the mass and you feel the weight. The balance scale feels nothing. All it can do iscompare the mass. But unstructured non-particulate matter has no weight; so weighing it is the wrong way to measure mass. jr writes> What!!!! You are talking about unstructured non- particulate matter with no weight and conclude that using a balance scale is the wrong way tomeasure mass? Christ this does not look good. > Mass is a resistance of matter that we can quantify and measure. What kind of > matter? Stable and near stable atomic matter. You are referring to F = ma, in which F is a force and m is measured in grams.A force is a quantity of net pressure, measured independently of the area of application; jr writes> You are defining the universe in terms of what you feel. What you feel is not fundamental. Mass can be measured in any unit. Where you lift mass determines the magnitude of [g]. So it is not independent of the area of application. and m in grams is the weight of the given mass. jr writes> Mass stays the same under transport. Weight varies. What kind of matter has that weight? Atoms do, but the matter of which they are made does not! jr writes> It appears that a fundamental part of an atom is a proton. Where a proton remains after the atom gives up an electron. The mass of a proton is by far the lions share of matter. The proton is stable. What is true for an atom is also true for a proton. An object floating in space has no weight. It only has mass. You reference weight and that is subjective. Have a good time. jr |