 Poster: A snowHead
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SimonN, David Goldsmith said that the carve will slow you if you continue on an uphill trajectory.... no skier in the world will disprove this without powered skis.... 
This topic has relevance beyond skiing. If we were talking about annoying and endangering others, there are other sports where we could apply this. My other sport is golf, I see plenty of people who dont know the rules, who dont appreciate others and who go around 'duffing' or firing the ball at right angles. In many respects, those doing that are more of a problem than a skier out of their depth....
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Obviously A snowHead isn't a real person
Obviously A snowHead isn't a real person
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| little tiger wrote: |
I don't see very many who can carve... let alone confidently on moderate slopes....
Carve = TWO CLEAN tracks not one sort of smeared thingy that may or not be vaguely arc like but is more likely a sort of straightish angled line...... |
That's quite funny, because I saw quite a few in Zermatt a couple of weeks ago, myself included. I choose not to do it on black runs, because if I do then as Simon N said I either have to keep on turning right back up the fall line and so spend most of my time skiing across the piste, or accelerate to ridiculous speeds in a short space of time.
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Well, the person's real but it's just a made up name, see?
Well, the person's real but it's just a made up name, see?
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| buns wrote: |
| SimonN, David Goldsmith said that the carve will slow you if you continue on an uphill trajectory... |
Sorry to be pedantic but no he didn't! He said
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| A carved turn pulls you out of the fall-line (where the acceleration is at maximum), like any turn. It simply decelerates you less quickly than a skidded turn (the most decelerating being the hockey stop). |
I disagree with that. I even disagree about the uphill tregectory! Of course, at some point you will slow down but if the forces are enough, you will continue accelerating, even uphill, until the amount of up hill counters the amount of acceleration. You can actually feel when the acceleration stops because the strain through the legs decreases. Its simple physics
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I have just read what David Goldsmith has said and I disagree even more. He states
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| the fall-line (where the acceleration is at maximum) |
Maximum acceleration is at the point where you have maximum g-force being exerted and that is after the fall line, when you have fully set your edge, loaded your ski and completed an appropriate weight shift from the tip to the middle of the ski.
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Anyway, snowHeads is much more fun if you do.
Anyway, snowHeads is much more fun if you do.
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Do you scare yourself on slopes you should have avoided?
Yes.
Do 'insurance scare articles' terrify you?
No.
Are you immune to danger and totally fearless?
No, but I will try most anything. Haven't yet had a true near-death experience while boarding.
Are you insured against your own stupidity?
No. I think this must be more common in the UK/Europe than in Canada?
Also:
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| you will continue accelerating, even uphill, until the amount of up hill counters the amount of acceleration. You can actually feel when the acceleration stops because the strain through the legs decreases. Its simple physics snowHead |
"Simple physics" states that you are wrong. If you hold a carve uphill, there is no way you will be accelerating during the uphill portion, unless you have a jet-pack on or something. Well, technically you are accelerating, in the physics sense of the word (in physics, acceleration is just a change in velocity, positive or negative), but you are accelerating in the opposite direction to your velocity, which most people refer to as deceleration or more simply "slowing down."
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SimonN, Hi Simon, now, forgive me, my physics degree is some time ago, but I don't see how you can continue accelerating once you are no longer moving downhill. The motive force in skiing is gravity - although I do dearly want to mount a pair of model turbojets on the back of my old DH boards - nothing else is going on.
Maximum acceleration is in the fall line. And, there's just no way you will continue accelerating uphill. All forces on you are downhill, therefore all acceleration is downhill.
Unless you have cracked Heim physics, in which case, why aren't you in hyperspace right now?
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Sorry, ponder, but that's not quite right but I do conceed that my claim of accelerating up hill might only be theoretically possible! I might have to get the text books out to get the formula but I will try to put it in the right terms.
Simply put, if you increase the force acting on the ski when carving, without the ski skidding, you accelerate. Now, if that acceleration is greater than the gravitational forces of going up hill slow you down, you will continue to accelerate. However, here lies the challenge. Can the carve be tight enough so that the centrefugal g-forces are still there when you begin to go up hill? I don't actually know but if you can carve a small enough curve, then, yes, you would accelerate up hill.
I
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SimonN, to be quite pedantic, if you're not skidding at all and you increase the turning force, yes, you will accelerate. You just won't go any faster. (Acceleration being a vector, change of direction means you're accelerating in that direction...)
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You'll get to see more forums and be part of the best ski club on the net.
You'll get to see more forums and be part of the best ski club on the net.
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SimonN, is correct, when an body is undergoing circular motion as in a ski turning, if you reduce the radius of the motion then the body will accelerate. To demonstrate this twirl a cotton reel on a thread, and then suddenly pull the thread to decrease the radius, the cotton reel will twirl faster.
It's to do with resolving the forces acting on the ski, when you turn tighter, the reaction of the snow against the ski increases, and so when resolved against the centripetal force causes an increase and change of direction of the acceleration vector.
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snowHeads are a friendly bunch.
snowHeads are a friendly bunch.
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SimonN, A man with a well defined and developed sense of humour clearly. Nice one!
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And love to help out and answer questions and of course, read each other's snow reports.
And love to help out and answer questions and of course, read each other's snow reports.
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SimonN, while I've been thinking about this DM's got there - the force you feel through your legs is there for changing your direction (i.e. the velocity of your centre-of-mass), but as it's essentially perpendicular to the skis it won't be changing their speed. The maximum acceleration in the direction of the ski will be when pointing down the fall line, but the maximum speed will be achieved when traversing directly across it (i.e. when gravity no longer has a component along the length of the ski)
Kramer, sorry but I disagree there. Yes, if you pull on the thread the bobbin seems to move faster, and it spins around at a higher angular frequency, but the bobbin speed stays unchanged. Think about conservation of angular momentum: mv = mwr (can't do omega, so omega=w). d/dr (mwr) = 0, so as r goes down w goes up, but the tangential speed of the bobbin v=wr is unchanged. If we're splitting hairs there will be a small increase in v while the radius of the curve is changing as there is a very small radial component proprtional to the rate of change of curvature.
[edited afterthought]
The one thing that could affect this all though (but not to the extent of appreciableacceleration uphill) is the fact that we are not (once we get beyond beginners' snowploughs, ideally anyway  ) rigid bodies, and can move ourselves with respect to the skis. So it's possible to build up a bit of stored potential energy by sinking into a turn, then explode upwards at the apex of the turn, pushing perpendicular to the skis at that time and gaining momentum across the slope, i.e. giving our bodies a bit of a slingshot, which translates to additional in-line speed only once the skis have followed around and completed the turn. At least I think this is the physics behind what a coach was trying (without much success) to get me to do when giving me some GS coaching back in October.
Last edited by And love to help out and answer questions and of course, read each other's snow reports. on Thu 26-01-06 22:06; edited 3 times in total
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[quote="David Goldsmith"]
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| A carved turn can decelerate you to a stop, if continued to an uphill trajectory. It just takes longer to slow you down than a skidded turn. |
Simon N: He did say this!
Of course any circular trajectory has acceleration (this is almost by definition). But you cant consider it in the same fashion as you compare speed to velocity. Acceleration is a vector and you cant liken it to scalar!
I think if you cared to do the sums based on a perfect carve (with your turn radius), the slope you are on (i.e. gravity) and the friction, I would bet my degree on it being impossible to continue to gain speed when you are skiing back up the hill.
When you are directly perpendicular to 'down hill' the centripetal force (i.e from going in a circle) is directly up hill. So for you to be accelerating DOWN the hill, gravity would have to be greater that v^2/r. When you would carve to pointing directly up the hill, the centipetal acceleration is now ACROSS the slope, there is ZERO down the slope component. This means that at this point, you have NO acceleration up the slope, you have friction slowing you and gravity is acting in direct opposition to your velocity. So with you going one direction and all forced acting against you, how do you propose that your speed increases?!
Perfect carves of course will increase speed (to a point) but I think this is almost entirely to do with frictional components.
Adam
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You know it makes sense.
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| buns wrote: |
SimonN, David Goldsmith said that the carve will slow you if you continue on an uphill trajectory.... no skier in the world will disprove this without powered skis....
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Are you seriously saying carving uphill won't slow you down? Or that you cannot carve uphill? or what?
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Otherwise you'll just go on seeing the one name:
Otherwise you'll just go on seeing the one name:
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My name is Kramer and I am a ski geek.
I've made the first move gents, I think that it's time that you followed. 
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Poster: A snowHead
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Kramer, but we are all just mere pale imitations languishing in the shadows of the great ski geek that is physicsman 
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Obviously A snowHead isn't a real person
Obviously A snowHead isn't a real person
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Well, the person's real but it's just a made up name, see?
Well, the person's real but it's just a made up name, see?
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| little tiger wrote: |
| buns wrote: |
SimonN, David Goldsmith said that the carve will slow you if you continue on an uphill trajectory.... no skier in the world will disprove this without powered skis....
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Are you seriously saying carving uphill won't slow you down? Or that you cannot carve uphill? or what? |
No, it is SimonN saying that you can carve uphill without losing speed. I strongly believe that going uphill will slow you irrelevant of how you do it, but you can carve uphill all the same.... even though you are losing speed all the time
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buns, agree
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Anyway, snowHeads is much more fun if you do.
Anyway, snowHeads is much more fun if you do.
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Just to add my penny worth
I find what I’m happy to ski on depends more on the light than if the run is blue red or black.
I’ve skied blacks which on the first attempt in good light were fine then returned to them latter with the light going flat and managed to scare myself silly. I’ve certainly found myself stretched when I can't see the bumps. Though I’ve always got down in almost one piece
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You'll need to Register first of course.
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| buns wrote: |
| little tiger wrote: |
| buns wrote: |
SimonN, David Goldsmith said that the carve will slow you if you continue on an uphill trajectory.... no skier in the world will disprove this without powered skis....
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Are you seriously saying carving uphill won't slow you down? Or that you cannot carve uphill? or what? |
No, it is SimonN saying that you can carve uphill without losing speed. I strongly believe that going uphill will slow you irrelevant of how you do it, but you can carve uphill all the same.... even though you are losing speed all the time |
OK - I'm with you!
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Wohoo!!
On the bus back and forth to Banff I've been thinking further.... ignoring friction, it is pretty much impossible to go faster than you can by travelling directly down the hill. If you do the integration, any additional acceleration down the slope a carve will bring, will be negated as you carve back the other way. To some respects it would be like integrating under a sine wave.
So considering the experiment of the 'hare' going straight down the slope and the carvers taking the same time - I believe this has nothing to do with the acceleration due to the carved turns. My suspicion is that it could be down to (as GrahamN suggestes) work done by the body but I reckon the biggest factor will be friction. While on your base, you have a large surface area in contact with (potentially) soft snow. On edge, you have much less ski area in contact with the ground. In addition, the large pressure exerted whilst on edge will compact the snow it is contacting, so it is likely that the carved edge contact surface is going to be alot firmer (icier maybe) and have less resistive effect.
Adam
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Here's an easy way to think about it:
Lets take an ideal situation, ignoring friction, which in fact would only slow you down more no matter what. You are at point A. If you are travelling uphill, you will be going to a point higher up from point A, which we will call point B. Since point B is higher up from point A, you will have more potential energy at point B. Since this is an ideal system, all of your energy is made up of kinetic and potential energy, and no energy is lost or gained (in a real system energy would be lost). So since you have more potential energy at point B, you must have less kinetic energy, and thus less velocity. Even without friction, this proves that it's impossible to gain speed while travelling uphill (without an outside source of energy, e.g. rocketpack, herring-boning uphill, etc.), and in a real system with friction it's even more impossible.
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You'll get to see more forums and be part of the best ski club on the net.
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Or even simpler yet.... if you could actually continue gaining speed as you carved uphill..... we wouldnt need lifts and we would occupy ourselves by skiing UP and not down the skihill
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Ok, I'm no physicist (sp?) and no great shakes on skis either , but I refer the 'speed' debate back to my waterskiing analogy. Imagine two powerboats moving due north at 30 knots, both pulling skiers. One skier simply holds a straight line the other cuts across the line of travel 'carving' big esses behind his boat. How fast are they travelling?
Well of course in a northerly direction the are both doing an AVERAGE of 30 knots, but the one who is carving across is accelerating as he begins each turn, going well over 30 as he crosses the wake, and slowing almost to a stop as he finishes each turn (Has anyone ever done this? you know that it's true). In fact if you carve out hard enough, and you are good enough you can actually get enough 'slingshot' acceleration to pull alongside and (briefly) overtake the boat. Clearly the carving skier covers a lot more distance in the same time (measured by his trail in the water, not by the trail of the boat) and so MUST be doing a higher average speed.
Now substitute snow skiers, and gravity, on a perfectly smooth piste, assume perfect carved turns and the model holds true. One last point, Isn't it true (I'm sure this has been said with regard to downhill racers many times) that they lose speed when they lose contact with the piste? Isn't this because they lose the force of the carve resisting the turning force? (bearing in mind that downhill courses are not in a straight line). I think SimonN and Kramer are right in what they are saying. 
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snowHeads are a friendly bunch.
snowHeads are a friendly bunch.
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| Kramer wrote: |
| although in some cases, having successfully negotiated a black can provide a confidence boost that makes blues or reds seem far less steep and intimidating. It does seem to be a case of kill or cure. |
This is how it works for me, I can trick my head into self-belief like this. So how the hell do I do this for blacks? I'm technically perfectly capable, but the head says "don't go there"
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And love to help out and answer questions and of course, read each other's snow reports.
And love to help out and answer questions and of course, read each other's snow reports.
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eng_ch, if any of my friends are a bit wobbly on blacks then I just get them to follow my (aggressive) line. It stops them thinking about anything else, and also gives them the confidence that if you ski aggressively it makes most marked pistes a lot easier.
IMO loads of people get in trouble on steeper pistes because they spend far too much time going back and forth across the fall line, whilst getting more and more frightened looking down the piste.
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You know it makes sense.
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AxsMan, I have spent whole lessons almost exclusively on blacks without turning a hair because I trust the instructor not to take me anywhere I can't do. If we're on our own, I don't trust my or our judgement. Especially unknown ones - I won't do them. The problem with blacks is they can cover anything from a steepish red gradient to a vertical wall and I seem to be petrified of encountering a sheet ice vertical wall or couloir, unable to either get down it or go back. Someone on Epic the other week had a technique I want to try out, though - "don't look down the damn hill!". As Kramer said, psychologically I know I'm not going to encounter anything I can't do on a red (like is a different matter) because I can "do" blacks. But there isn't anything worse than a black to have the same mental effect. Or is there?
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Otherwise you'll just go on seeing the one name:
Otherwise you'll just go on seeing the one name:
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AxsMan, the leading you onto the wrong colour is how my mate got me onto a black run at my first day at verbier at new year.
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Poster: A snowHead
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AxsMan, the problem with your waterskiing analogy is that the accelerating force (the skiboat) is not a constant: as the skier tracks to the side there is a higher force in the tow rope which would tend to slow the boat down, so the boat has to up the gas to keep at a constant speed, so it's doing more work. Gravity cannot do that - you only get the same downhill force whichever direction you are skiing, gravity does the same amount of work on you for the same vertical drop, so the same amount of kinetic energy.
Now to thinking about SimonN's demonstration of a carver getting down the hill at the same rate as the straight-liner. This would indicate that the carver does have more kinetic energy than the straight-liner. I personally doubt that this is possible without a significant amount of work from the carving skier, but I can see how this may just about be achievable with the sort of compression/extension work I described above.
But this would say that the carver should be able to get down the hill faster than the straightliner if they stopped carving at the apex of one curve and straightlined it from there. So why don't we see downhill racers weaving their way down the first part of straight sections of the course and then gliding out the bottom part of that section? And finally is not the loss of speed when the skier is in a jump loss of a ground effect, and so increas of wind resistance, rather than loss of "carving force".
Energy-based arguments are a bit difficult to make watertight though, particularly when the skier is moving at speed, as there is a significant energy loss to due wind resistance (just stand upright and stick your arms out and see how quickly you slow down).
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Obviously A snowHead isn't a real person
Obviously A snowHead isn't a real person
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The reason that a skier in the air is slower than one on the snow is to do with resolving the forces acting on them.
For the skier in the air, the only force (apart from wind resistance) acting on him is gravity, which is accelerating him straight down, with no forward component.
For the skier on the snow, gravity is acting on him straight down, but you also have the reaction of the hill to his weight, which is perpindicular to the gradient (as well as wind resistance). When you resolve the vectors of these two forces you end up with a proportional forward accelerative vector which is what makes him gain speed down the hill.
eng_ch, there are always itinerary runs, which most resorts have now made their worst blacks into.
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Well, the person's real but it's just a made up name, see?
Well, the person's real but it's just a made up name, see?
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You need to Login to know who's really who.
You need to Login to know who's really who.
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Firstly, everybody is getting a little worked up and confused. I have never said you will continue to accelerate by turning up hill. What I have stated is that, if due to a force acting through the skis you are accelerating, there is a period of time when the graviational forces of going up hill are not great enough to counteract that acceleration and therefore for a period, however, brief, you will accelerate up hill.
The waterskiing analogy is, IMO, correct. The speed of the speedboat is constant to within .5 mph. It needs to be for competitive reasons. The boat goes down middle of the course at a set speed or in snow ski terms the fall line and the set speed = gravity. By setting the ski across the course of the boat, you accelerate and has been pointed out, you can get to the point where you catch the boat and the line goes slack. You are definately going significantly faster than the boat.
As for what you feel through when turning, it is the result of a g-force which you are resisting and this is what leads to increased speed.
Now, if you guys how say that you only decelerate once you leave the fall line, explain those who ride pipe. Why do they go from side to side to pick up speed? It is because they set an edge and use the effects of increased g-forces to build speed.
Lets try to take another look at this. Assume at all times you are carving WITHOUT sideslip.OK, you are going down the fall line at max warp! Now, if you turn there are a series of forces that come into play. There is a decellerating force due to the change of slope angle and if you do it very gently, this will slow you. However, when going at max in the fall line, your body was ony applying its own weight in a downward direction and you aren't accelerating any more. As soon as you set your edge across the direction of graviational pull, your body gets subjected to an increased force, which we know as g-force. This has the effect of increasing the weight that goes through the ski. As you are carving and not sliding, this force has to go somewhere and it gets translated into forward motion.
Now, the acceleration due to the increased load can be less than the deceleration due to turning into a less steep trejectory and you slow, but it is also possible to have the acceleration greater than the deceleration and therefore the turn makes you accelerate.
It is no different from the forces that mean that "skating" accelerates you. One is powered by human mussle, the otherby gravity.
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Anyway, snowHeads is much more fun if you do.
Anyway, snowHeads is much more fun if you do.
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| Kramer wrote: |
| eng_ch, there are always itinerary runs, which most resorts have now made their worst blacks into. |
Meaning? Bear of little brain today - off at crack of dawn tomorrow and desperately trying to get everything done
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| SimonN wrote: |
| The waterskiing analogy is, IMO, correct. The speed of the speedboat is constant to within .5 mph. It needs to be for competitive reasons. The boat goes down middle of the course at a set speed or in snow ski terms the fall line and the set speed = gravity. |
Incorrect: the speed of the boat does not relate to gravity, the power of the boat does. And when you are cutting the boat has to increase its power output to maintain the same speed (which is why skiboats have automatic speed control regulators). For another analogy, in electrical terms we would be talking about a constant current supply - its voltage has to go up to maintain a constant current (speed) as the resistance (cutting skier) goes up. Gravity would be a constant voltage supply - where the current (=speed) would drop as the load resistance goes up.
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Now, if you guys how say that you only decelerate once you leave the fall line |
No-one said that; rather than the acceleration reduces as you come out of the fall-line - you could still be accelerating until you are pointing horizontally across the hill, and only decelerate (if we ignore drag/friction for the moment) when you start going up the hill.
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| It is no different from the forces that mean that "skating" accelerates you. One is powered by human mussle, the otherby gravity. |
I think it is very different. In a skate you are pushing your body away from the ski giving it momentum which you then use to accelerate the ski to catch up behind you - the same 'slingshot' mechanism I described above - and is dependent on your motion relative to the ski, not the ski relative to the hill/gravity. I don't know anything about snowboarding, but I would guess this is basically the same mechanism used for your halfpipe example.
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eng_ch, itinerary runs are the runs that aren't pisted or patrolled, but that are avalanche cleared. They tend to be the really steep narrow runs in a resort.
Far more scary than a black run!
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| Kramer wrote: |
eng_ch, itinerary runs are the runs that aren't pisted or patrolled, but that are avalanche cleared. They tend to be the really steep narrow runs in a resort.
Far more scary than a black run! |
OK, with you now! Not normally that slow
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You'll get to see more forums and be part of the best ski club on the net.
You'll get to see more forums and be part of the best ski club on the net.
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| GrahamN wrote: |
| SimonN wrote: |
| The waterskiing analogy is, IMO, correct. The speed of the speedboat is constant to within .5 mph. It needs to be for competitive reasons. The boat goes down middle of the course at a set speed or in snow ski terms the fall line and the set speed = gravity. |
Incorrect: the speed of the boat does not relate to gravity, the power of the boat does. And when you are cutting the boat has to increase its power output to maintain the same speed (which is why skiboats have automatic speed control regulators). For another analogy, in electrical terms we would be talking about a constant current supply - its voltage has to go up to maintain a constant current (speed) as the resistance (cutting skier) goes up. Gravity would be a constant voltage supply - where the current (=speed) would drop as the load resistance goes up. |
I don't think that power = gravity! When you cut, there is a need for a slight acceleration to maintain the chosen speed BUT, if you don't have that increase in power, the skier will still accelerate to a speed faster than the speedboat was going. In addition, the shape and weight of the boat will effect how much power is needed to mainatin the speedNow, in snow sking you don't have that drag factor on the boat "gravity" so you should accelerate faster than a waterskier!
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No-one said that; rather than the acceleration reduces as you come out of the fall-line - you could still be accelerating until you are pointing horizontally across the hill, and only decelerate (if we ignore drag/friction for the moment) when you start going up the hill. |
I think we are talking cross purposes. If you are going max down the fall line, you are not accelerating so how, when you start the carve, can acceleration reduce  My hypothisis states that once you are at max speed in the fall line and are no longer accelerating, a correctly carved turn increases your speed. On commencement of the turn I would expect a small deceleration before the forces overcome the change in angle, followed by and increasing acceleration to the point of maximum acceleration, followed by a period of reduced acceleration until that acceleration stops and gets replaced by deceleration!!!! 
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| It is no different from the forces that mean that "skating" accelerates you. One is powered by human mussle, the otherby gravity. |
I think it is very different. In a skate you are pushing your body away from the ski giving it momentum which you then use to accelerate the ski to catch up behind you - the same 'slingshot' mechanism I described above - and is dependent on your motion relative to the ski, not the ski relative to the hill/gravity. I don't know anything about snowboarding, but I would guess this is basically the same mechanism used for your halfpipe example.[/quote]It is that pushing that causes acceleration in the turn I am describing. In both cases, what is happening is that you are getting an extra force through the ski which translates itself in momentum in the direction of travel. In one case it is coming from your mussles, in the other it is the gravity increasing the g-force of your body. However, the ski doesn't know which so it only experiences that extra force and that force has to go somewhere.
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SimonN, gravity is a constant. It can't increase the g-force anywhere (gravitational waves notwithstanding).
"once you are at max speed in the fall line and are no longer accelerating, a correctly carved turn increases your speed".
I am afraid, no, not if what you mean is you can go faster.
If you are at max speed in the fall line and can't change your wax mid schuss, flatten your skis, attach a rocket pack, that is as fast as you are going to go. You will be at "terminal velocity". Turning can ONLY slow you down, although you might find that you accelerate in a sideways direction...
I am afraid those are just the sad realities of Newtonian physics.
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FAQ
! On that same argument though, if the jump results in a landing uphill from the takeoff point 