Split Thread The validity of classical physics (split from: DWFTTW)

[humber]

Wrong

"The compressibility of water is a function of pressure and temperature. At 0 °C in the limit of zero pressure the compressibility is 5.1×10-5 bar−1.[11] In the zero pressure limit the compressibility reaches a minimum of 4.4×10-5 bar−1 around 45 °C before increasing again with increasing temperature. As the pressure is increased the compressibility decreases, being 3.9×10-5 bar−1 at 0 °C and 1000 bar. The bulk modulus of water is 2.2×109 Pa.[12] The low compressibility of non-gases, and of water in particular, leads to them often being assumed as incompressible.

The low compressibility of water means that even in the deep oceans at 4000 m depth, where pressures are 4×107 Pa, there is only a 1.8% decrease in volume.[12]"

Yes, that is why even steel ships can still sink to the ocean depths.

from http://en.wikipedia.org/wiki/Water_(molecule)

Yes, this is nitpicking in a way but water is compressible but we can often assume it is non compressible.

Air is compressible but we can often assume (regarding the pressure changes due to low velocity motion) that it is incompressible.

It is less than nit-picking Fredriks. To make your point, you have to assume that incompressible means infinitely stiff, (and so acknowledge the practicality of faster than light transmission and motion) or be seen as trivial.

Even then, your wikkification is incomplete. Water expands when heated, and when frozen.

 

[fredriks]

Whatever you say humber. Do you get a lot of calls from Stockholm?

 

[mender]

If I have such a MEMS device with me, I can hardly be accelerated to free-fall without knowing it.

I apparently don't need the device because I came equipped with a pair of tri-axial accelerometers that tell me when I am in free-fall.

 

[humber]

Are you sitting comfortably?

I use cats as cushions.

A lack of humility, expressed as you demonstrated here in thinking yourself right irrespective of any response from others, means you have a tighly closed mind, resisting any view that isn't already yours.

A self-serving 'open-mind' cliche. Good start. It would seem that you are defining 'right', as having your concordance.

Feigned or over-exaggerated humility can be a conceit, I grant you. People can also genuinely believe themselves to be very humble,

Define a difference between "believing to be" and "thinking themselves to be" or "being".

...while that confidence in their "asset" is a self-conceit. But those are like double-negatives; disregarding humility is just conceit, vain pride, arrogance, too great a confidence in one's knowledge or abilities.

Tautological and circular.

'If you can meet with triumph and disaster
And treat those two imposters just the same;'
(Kipling)
That sort of "double negative", do you mean?

...as any extensive dictionary should tell you, humility and conceit are to be found as antonyms: once again you seem to have something in direct opposition to how almost everyone else agrees it is.

Faux and assumed authority regarding dictionaries and word usage.

You seem actually to be quite sophisticated and deep in some respects, but this sophistication seems to cause you to mistrust the "bleedin' obvious" over and over again, as if you made a decision at some point that reality is always the opposite of what it seems.

I will let you know how I assess you, should the time come...
Your remark is ironic though. The ground is "bleedin' obvious" and that the treadmill is a sham, is also the patently so. It takes something not of whole cloth, to mask that.

What is the point in discussion unless each side accepts that they may learn from the other, change their mind, and practice just a modicum of humility by that? Discussion with you, if you consider yourself always right, must be mere absorption of instruction from your great wisdom, and all dispute in vain.

An appeal to the "greater good". No thanks. Self-conscious humility, is often the desire to be the most outstanding member of a flock of sheep.

I really thought we might discuss, put our theories forward, and learn from other people who have posted information on the net, together, as a shared educational experience. After being wrong before, I was trying not to be arrogant, and just accept that we had different views and whatever the truth turned out to be, well, ok. But clearly you aren't interested either in what I think or what anyone else has thought, discovered, theorised or proved anywhere else!

There can be no dispute of that nature. Science works by proof.
"God does not play dice". (Einstein)
"Don't tell god what to do" (Bohr)
A put-down to Einstein, exposing his attachment to an ordered Universe.
Nobody is "context free", John.

 

[mender]

A vehicle propelled along a road by wheels, cannot be simulated by that same vehicle driven from the wheels by a belt.

Which is one of the few statements that humber has correct. Too bad he isn't talking about the cart that we are talking about, which is the one where the propeller is driven by the wheels.

To make it applicable to the topic:

A vehicle propelled by the wind along a road with a propeller driven by the wheels, cannot be simulated by that same vehicle driven from the wheels by a belt.

How's that one Dan?

Oh, I just realized that we have to state a few more conditions to make it clear that the cart is driven only by the speed difference between the air and the ground, and the relative velocities of those two must be maintained for the comparison to be valid. A lot of extra words, so humber's original statement will end up being very black and blue from the beating it would take.

 

[humber]

Yet you've said several times that wheel motion is very tricky. So again, this demonstrates your conceit. Wheels, like every other subject we touch on, is much more complicated and subtle than anyone else could possibly understand, but you don't need to check anything out with anyone else, do empirical testing, or think further on the subject. I guess you must have been born knowing everything.

Need I remind you, that I raised the subject, and now there are "experts" appearing from wormholes.

That is what I said, the frictional force from the road is from the rear. You are ambiguous there, however. There is the other force, that from the wheel, which is from the front. First year physics,...

Should you do first year. No matter, but what a bromide, John.

....I'm fairly confident, will explain this: a wheel drives by "pushing" backwards against the ground, basically, and the friction of the ground "pushes" back. Now, while "pushing" might give you confidence that the wheel's contact position must therefore be rearwards of the axle (from the principle that we can't push a rope), it is wise to be cautious about that. Friction, as we all know, has some kind of stickiness about it, and we know that we can pull things with an adhesive surface, no push required. We can sit on a wheeled trolley on a flat surface, put out our hands and pull ourselves forward with just the friction of our hands on the surface, well in front of our bulk and centrre of mass.

Double-think. If you want to push a car forwards, where do you stand?
Ahh.. no enough for the wily fox, so where are your feet? Correct.
The force is between the car and your feet, which are to the rear of the intended direction of travel. The force is between the contact patch and the axle. You can keep this up, John, or consult a physics or engineering book. The intertubes do not seem to cover this topic well.

Ok. Good. Something we agree on. I would say that a completely solid, non-deformable wheel is an ideal, a mathematical abstraction, but that there is a gradation from soft objects through to very hard ones.

Such a wheel would slip 100%. Slide, but not rotate.

We haven't considered the surface, except in your suggestion of soft sand, but I didn't understand what you were trying to say. The mathematical ideal is very informative, actually. If a wheel and the surface did not deform at all, the contact point would be one of those odd things in maths, a kind of zero that isn't zero, an infintessimally small location, a point (or line if we give it the sideways dimension). Whether such a wheel could be driven is almost into the realms of philosophy, depending on whether you arbitrarily decide that forces can be transmitted (particularly frictional forces, laterally!) via an "area with one dimension infintessimally small or zero", a "contact line with no width", or however we conceive it. What is clear is that as we approach the "ideal" (in the sense of "in the mind") the usefulness for locomotion becomes less than "ideal". As a rough rule of thumb, I'd say that being deformed at the contact surface is part of how wheels work; without being somewhat elastic they would just spin; with a point contact in the limit, no friction can exist.

Yes, deformation is necessary. "one bit must move faster than another bit" is the way I spoon-fed it it to Spork.
The deformation is simply the equivalent of a toothed gear, though some care is definitely needed with that analogy. Some continuous drive gear boxes use smooth transmission wheels in direct contact, but use a special oil to do much of the 'deformation'. Wheels cannot work without friction.

Perhaps? Is that your conceit talking?

I'll ask The Dalai Lama.

If there was a "driving plough", I'm not sure what it is. Let me assume it is a compressed area, since you say it is further back, and imply, I think, that its presence pushes the wheel forward. But you say that it is the bit of tyre stuck to the road further back.

No, the deformation is forward of the axle, a visible effect in soft tyres or ground. The friction is behind the axle. The wheel rotates the tyre, so it distorts against the friction. Like a pushed string. Part of the tyre must be in tension to maintain the load.

If we take friction literally as a stickiness, then the contact patch behind the wheel would slow it, as the rubber was peeled off the road. It takes a lot of energy to unstick sticky things.

A car may loose 60% of its energy by that means, though typically it is but perhaps 2%. It depends on the wight of the vehicle, speed, road conditions.
Tyres are useful, even if not the most efficient, because the can adapt to conditions, and cushion etc.

But more importantly, if there is a compression of material behind the wheel axle position, I don't see how it can be sustained: that part of the tyre is being pulled away from the road.

Yes, the tyre is continuously flexed. They get hot. At 60kph, the same part of the tyre meets the road at perhaps 16 times a second.

Well, that's all rather confusing. The "frictional force", if by that we mean what the road applies to the tyre, will be with the direction of motion, not against it. But we might (I would say should) consider two opposite forces when something acts in this way, as per Newton's 3rd: the tyre applies a frictional force to the ground against the direction of motion. The bottom of a wheel doesn't exactly go backwards (or may slighly perhaps), but it has to be pushing backwards for the wheel to move forwards, just as a fish must push water backwards to move forwards or your feet must push backwards on the ground when you walk forwards (the usual way). These two opposing forces cause relative motion between wheel and ground.

Friction is complex and dynamic. It is no "supplied by the road" but a reaction to the applied force. But, yes, like walking. What is confusing?

I think that's right, although you have of course reversed the condition from driven wheels to driven surface, and specified a cart on a belt, where I thought we were just discussing wheels, but no matter.

No that is the point. They are not "reversible". The implied symmetry of the treadmill is false. Spork just says the usual garbage in response. The treadmill is based upon ideas of equivalence, that may be or are true, but they are not applied in the treadmill. That is a design disaster. A dropped brick.

You're obsessed, man! First understand wheels, then get back to the cart on a treadmill.

I think you need to do yout home work, before that point.

I'm sorry to hear that.

That's perhaps why the ladies say, 'Yes, it was good, John'.

Well it does a very good impression of a wheel clawing its way up a curb.

And a rear wheel drive with it's front wheels at the curb? A caterpillar track?
George Jetson has a treadmill.

I don't understand any of that, but what wheel is circular?

It does not have to be. Check it out. However, if undistorted, the part of the wheel that could provide a leading and effective contact patch, would not first hit the ground until directly below the axle. Next stop is behind the axle.

Well it's time to get your rubber pencil eraser out again. Holding it tight in your hand will simulate a tyre on a wheel with the brakes on full. That would be unwise for a proper emergency stop, but it's the extreme case to start with. Rub it along your desk, and you'll find that its contact area is pulled to the rear of the motion. A wheel does the same thing and, with some rotation of the wheel instead of brakes locked, that force is still in the same direction, causes the same kind of distortion of the tyre, but reduces it. Even if we skid, the same is true.

Is the cart on the treadmill braking? If you can't make your case for drive, why should I even consider your case for braking? That is also a quite appalling analogy, and the equivalent of the "scrubbbing" I described, in anticipation of your likely response. Seems you missed the barn door.

Your vision is almost of a tyre that has to jump ahead of the wheel to provide a push force against the wheel...or you just realise that you have to say that, because we can reverse these motions and prove the first case wrong by it, which was why I asked the question, as you will already realise.

The car cannot get to where is is going, and pull itself from there. Caterpillar tracks are capable of this within the bounds of the track, but not ahead of it.

You would by changing frames of reference, of course, see that braking and accelerating are (almost?/absolutely?) identical-but-opposite conditions:

Braking is dissipative. So many mixed and wrong ideas in one sentence.
"Frames of..."

the momentum of a car requires that motion can't just disappear, ...

Wow. Not like the cart on the treadmill?

...the relative motion of ground and tyre can be thought of as the ground trying to apply a torque to the wheel, backwards at the bottom, but resisted by the wheel, hence the tyre will bunch up behind the axle position just as your eraser does on the desk. How could it jump - or the road suck it to a position - further forward of where the axle has got to?

The force is from the rear, becuase the wheel drives the car by thrust. The rest is flummery to avoid that fact, which is a simple and patently obvious mechanical denial of the treadmill. That is (perhaps) why 3bodyproblem remarks that "frames of reference" is a marketed idea.

 

[humber]

Which is one of the few statements that humber has correct. Too bad he isn't talking about the cart that we are talking about, which is the one where the propeller is driven by the wheels.

To make it applicable to the topic:

A vehicle propelled by the wind along a road with a propeller driven by the wheels, cannot be simulated by that same vehicle driven from the wheels by a belt.

How's that one Dan?

How about a vehicle that is driven by a propellor via its wheels is a powered vehicle?
Try that.


(1) You agree that only a powered vehicle can make progress up the belt.
(2) The cart is a powered vehicle, that moves by power to the wheels.
(3) It is not in principle possible for a belt to drive the wheels ( as in the unpowered car on the belt)
(4) The power for the cart comes from the belt
(5) Connect the dots to (3)
(6) The cart is spinning its propellor and wheels, but not moving.
(7) The spinning is due to the introduction of a third force (the air mass) that serves to keeps it in place, on what little energy it can get from the belt.

 

[mender]

How about a vehicle that is driven by a propellor via its wheels is a powered vehicle?
Try that.

Hey, another correct one by humber! Wow, you're on a roll!

See, you can make sense if you try!

 

[Dan O.]

If the sensor can detect motion from stationary within that field, to free-fall within that field, that is simply the same as detecting the acceleration.

Specifically, the sensor detects the force exerted on a small mass. The force exerted on that mass in a 1g gravitational field is exactly the same as the force exerted by accellerating the device at 9.8ms^-2. In free-fall, the force due to acceleration exactly cancels the force due to the gravitational field.

When in free fall, moving the device in opposition to free-fall for example, will provide acceleration that is either in the direction of free fall or not.
Rotating the sensor, is all that is required to do that.

The accelerometer sees only the sum of the forces involved. The rotation may add an additional force in the same direction as the force due to gravitational field but the force due to the acceleration is still present so the sum of the forces when F_a=F_g is F = F_g+F_a+F_r = F_r and therefore tells you nothing about the direction of F_g or F_a.

If I have such a MEMS device with me, I can hardly be accelerated to free-fall without knowing it.

That is true. But you could still be taken on a 1g spiral trajectory starting from a position at rest with respect to the ground to a catastrophic impact with the ground without a peep from your accelerometer.

Think of yourself sitting in a chair in the middle of a closed room. The whole room could be rotated horizontally slowly enough that you would not perceive the rotation. In the same way, the room could be rotated vertically slowly enough that the rotation would not be perceived. But eventually you would notice that the room was tilted because the force of gravity is no longer perpendicular to the floor. We can compensate for that perceived tilt by accelerating the room so that the resultant sum of gravity plus our acceleration is 1g perpendicular to the floor. If the rotation is carried far enough, you can end up upside down being accelerated at 2g towards the ground but your seat is still comfortably sitting in the chair and your laptops hard drive still thinks that it's at rest in a 1g field.

If the logic and control behind the sensors of that simple application can detect the laptop is falling and so react to it and to anticipate, that is knowing, in any meaningful sense of the word.

There is no question that free-fall and not falling in a 1g gravitational field can be detected. What we are saying is that the gravitational field is indistinguishable from an applied acceleration. Your laptop would be just as happy sitting on a bench in a rocket ship being accelerated through space at 9.8ms^-2. And if it were to fall off a support in that rocket so that it was no longer being accelerated with the rest of the ship it would react the same as if it fell off a table on earth.

When in free-fall, a body is not in zero-g in the sense that there is no significant gravitational force. The Earth is causal to the acceleration in the case of free-fall, isolated environment or not. It is 'there', and cannot be shut out. It is 'invisible' in that is undetectable unless opposed, at which point it visibly asserts itself.
Of course, true zero-g is not a reality, but is commonly used to describe conditions of "weightlessness" such as on the 'vomit comet'. That condition is always detectable.

You are still confusing "zero-g" with zero gravity. Look it up.

 

[Michael C]

How about a vehicle that is driven by a propellor via its wheels is a powered vehicle?
Try that.

That's fine. Now I'll add something:

A vehicle that is driven by a propellor via its wheels is a powered vehicle. The power can come from the relative movement of the air and the surface on which the vehicle runs. It doesn't make any difference if it is the air that is moving across a surface, or a surface that is moving underneath the air: in both situations power is delivered to the vehicle in exactly the same way.

 

[Belz...]

Anubis flying a kite on a treadmill (the belt of which has harmonics akin to chewing gum on the road) in an elevator, in absence of gravity, accelerating at much less than the speed of light, the speed of light being refered to as stiff.

Pick yur poison.

Aw... come on. You know how much I love throwing vitriol on an open fire. I just need to know what I'm supposed to be abrasive about, before I get started...

 

[Belz...]

Are you sitting comfortably?

I use cats as cushions.

Best. Post. Ever.

 

[Michael C]

duplicate post

 

[humber]

Specifically, the sensor detects the force exerted on a small mass. The force exerted on that mass in a 1g gravitational field is exactly the same as the force exerted by accellerating the device at 9.8ms^-2. In free-fall, the force due to acceleration exactly cancels the force due to the gravitational field.

No, the result is due to differential displacement of the masses. For the beam and mass approach to work, gravity is necessary to its operation.
If the mass were "freely suspended", then the device would not work in that manner. The force-balance device, uses a magnetic field to approximate that latter condition.

The accelerometer sees only the sum of the forces involved. The rotation may add an additional force in the same direction as the force due to gravitational field but the force due to the acceleration is still present so the sum of the forces when F_a=F_g is F = F_g+F_a+F_r = F_r and therefore tells you nothing about the direction of F_g or F_a.

Yes, but they are on opposite ends of a rod. One is opposing gravity, the other with it. The direction of rotation will tell me which way is 'up'.

That is true. But you could still be taken on a 1g spiral trajectory starting from a position at rest with respect to the ground to a catastrophic impact with the ground without a peep from your accelerometer.

I would first have to get there, and before hand and explicitly determine my trajectory to avoid the output of a 3-axis accelerometer. That requires prescience. A matter of knowledge.

Think of yourself sitting in a chair in the middle of a closed room. The whole room could be rotated horizontally slowly enough that you would not perceive the rotation.

Or fast enough that I could.

In the same way, the room could be rotated vertically slowly enough that the rotation would not be perceived. But eventually you would notice that the room was tilted because the force of gravity is no longer perpendicular to the floor. We can compensate for that perceived tilt by accelerating the room so that the resultant sum of gravity plus our acceleration is 1g perpendicular to the floor. If the rotation is carried far enough, you can end up upside down being accelerated at 2g towards the ground but your seat is still comfortably sitting in the chair and your laptops hard drive still thinks that it's at rest in a 1g field.

Or simply tell me I can't do it, on the basis that you have already determined the outcome. Hallucinogens may also work.

There is no question that free-fall and not falling in a 1g gravitational field can be detected.

A change of tune, perhaps. RossFW, (and others) claimed that falling in gravity was the "same as zero-g" He's a Captain; they know how to crash planes. Who am I to believe?

What we are saying is that the gravitational field is indistinguishable from an applied acceleration. Your laptop would be just as happy sitting on a bench in a rocket ship being accelerated through space at 9.8ms^-2. And if it were to fall off a support in that rocket so that it was no longer being accelerated with the rest of the ship it would react the same as if it fell off a table on earth.

Yes, I cleared that up, several times. A point sourcein a uniform gravitational field is indistinguishable from acceleration.

"That is like saying unattributed acceleration, is indistinguishable from unattributed acceleration".

That is not quite so in practice. To be accelerated in your rocket, you would feel that. Constant acceleration, would push you back in your seat.
The vague difference is that gravity pulls on the entire body, so you don't "feel" it. However, oppose it and you do.

You are still confusing "zero-g" with zero gravity. Look it up.

In that context, I can find many interpretations, because the "zero-g" is notional ! You experience "weightlessness" in the vomit comet, not the absence of gravitational force suggested by that former notion.

 

[humber]

Whatever you say humber. Do you get a lot of calls from Stockholm?

Usually from Inga and Ulrika.

 

[humber]

That's fine. Now I'll add something:
A vehicle that is driven by a propellor via its wheels is a powered vehicle.

Yes.

The power can come from the relative movement of the air and the surface on which the vehicle runs.

It does, and it comes from the propeller to the wheels.
Referring to the motor car, its power comes from an engine, but the belt cannot turn its wheels, even in neutral gear. This means that were it to have a propeller, the wind generated by its motion in the direction of the belt, could not drive the wheels beyond that token stationary position.
Relative velocities, do not allow other uncontrolled changes, like where the power comes from. To do that, is an egregious error.

It doesn't make any difference if it is the air that is moving across a surface, or a surface that is moving underneath the air: in both situations power is delivered to the vehicle in exactly the same way.

The power of the wind is not limited by the drive to the ground. It is an independent causal force. The causal force on the treadmill is the belt, and it cannot drive the cart by more than friction due to gravity will allow, while the force from the propeller (should there be any) cannot exceed that force.
If the propeller were driving the wheels like the powered car, it must make progress relative to the belt. That is does not, but that the wheels simply spin synchronously with the belt, is evidence that there is no propeller drive.

 

[humber]

I apparently don't need the device because I came equipped with a pair of tri-axial accelerometers that tell me when I am in free-fall.

That joke already done. Stop.

Or when it's spring. Stop

That can be a problem with making generalizations. Stop.

ETA:

Hey, another correct one by humber! Wow, you're on a roll!

No that's honour roll, not "on a" roll

See, you can make sense if you try!

Your turn

 

[fredriks]

Usually from Inga and Ulrika.

So no calls from the Nobel prize committee? Strange.

 

[humber]

So no calls from the Nobel prize committee? Strange.

They are committed to a noble cause, if you know what I mean.

 

[jjcote]

OK, think about this, humber:

I have a little car. It has elliptical wheels. It's sitting on the floor, at its lowest possible position (the contact point with the floor is at the end of the minor axis of each ellipse). I have a little motor connected to the axle, that will turn the axle. As it does so, and the wheels begin to rotate, the contact point of each wheel will move in front of its axle, due to the geometry of an ellipse.

I'm interested only in moving as far as a quarter-turn of the axle will take me. During that time, the contact patch of every wheel will be ahead of the axle. Can this car move?