A ball struck by a cue in billiards with English goes straight at first....

[poolplayer]

Hi, let me ask probably dumb questions to physics experts... Why does the cue ball goes almost straight when its right (or left) side is struck by a cue (right English)? This is quite different from when a ball hits another ball, in which case the ball goes almost perpendicular from the contact surface. Here, I want to focus on the ball direction immediately after the impact and ignore the curve after the ball starts to roll.

I heard that it is because the ball and cue can be thought as unity so the force only propagates to the cue direction. But if so, would it be possible that the cue makes the ball spin? My guess is that the friction between the ball and cue tip makes the ball not only spin but also go to the right direction and counteracts the force perpendicular from the contact surface (left), resulting that the ball goes to the cue direction? I heard that the friction coefficient is pretty high ~0.6. Any comments will be appreciated!

 

[fresh_42]

The ball first slips over the cloth, with or without rotation and independent of where it was hit. Once it hits another ball friction takes over and the linear movement becomes a rotation, such that the ball rolls from there on. During the collision, the linear movement comes to a hold for a moment which forces the existing angular momentum into a rotation.

 

[poolplayer]

Thank you for the comment! I didn't know that a ball always slips after I hit the ball. Would it be also the case when I strike the ball right above the center very softly? And I still wonder why the ball doesn't go to the left when I strike its right side with a cue stick...

 

[poolplayer]

It surely goes to left a little bit, but it goes relatively straight (the direction of the cue stick).

 

[fresh_42]

And I still wonder why the ball doesn't go to the left when I strike its right side with a cue stick...

If you play the ball properly, it receives a single force in the direction of the cue. For a change in direction you would need another force, either from a different direction or in addition to the cue's force. It happens if your cue slips off or along the ball which usually is a foul.

 

[poolplayer]

But, if a cue ball collides with the right side of an object ball, the object ball goes to the left, right? What is the difference between the ball-ball collision and ball-cue collision? I am sorry, but I am really weak at physics... I guess this is a very basic question.

 

[poolplayer]

To make it clear, I posted a drawing. Why does a ball go to different direction between ball-ball and cue-ball collision?

 

[Cutter Ketch]

The answer is indeed friction. The acceleration is not parallel to the normal of the contact point, so there must be a tangential component to the force. That requires friction or adhesion. The cue tip is soft compared to the balls and the contact lasts much longer than a ball to ball collision. The cue tip deforms, effectively sticks to the ball, and forces it along in the same direction the cue tip is traveling. It is something like throwing the ball rather than a hard elastic collision. During the contact with the cue the cue ball does indeed slide across the felt. This is easy to see if you look for it.

The need for high friction, or even adhesion is the purpose of chalk. A miscue is the result of the cue slipping along the surface of the ball. This happens when the friction is low due to lack of chalk, the contact is poor due to a poorly shaped, worn, or hard tip, or the friction required exceeds the friction available because the ball was struck too far off center and the tangential component is too large. Even with sticking the ball will deflect some. I've seen claims that say the stickier the chalk the less the cue ball deflects off axis. However that doesn't make sense to me. Either the cue tip slips or it doesn't. Once you've avoided slipping more stickiness is not any better.

The critical difference with the collision of two balls is that they are very hard and elastic and the contact lasts a very short time. There is a little bit of friction and some nonneglible throw in ball to ball collisions. However they are much closer to an ideal elastic collision and the direction is usually very close to the normal. On the other hand, accounting for the throw particularly at thin angles is part of what separates a good player from the rest of us.

 

[fresh_42]

But, if a cue ball collides with the right side of an object ball, the object ball goes to the left, right? What is the difference between the ball-ball collision and ball-cue collision? I am sorry, but I am really weak at physics... I guess this is a very basic question.

On the right side the red line shows the part of the force that applies to the object ball. The rest of the momentum is carried away by the white ball whereas the cue doesn't take any momentum to a different direction.

 

[Cutter Ketch]

View attachment 110621

On the right side the red line shows the part of the force that applies to the object ball. The rest of the momentum is carried away by the white ball whereas the cue doesn't take any momentum to a different direction.

The cue has a constraint and experiences external forces. Momentum conservation is not relevant. If you took the cue ball in hand and rammed it straight ahead through the object ball without deflecting I believe you would find that the object ball still goes off at an angle. (Somebody with a pool table please try). I don't think this is why the cue is different.

 

[poolplayer]

Thank you for your answers! I am still trying to understand the insights into momentum conservation (if so, is cue ball direction different when hit by rolling ball and ball-in-hand?). But friction explanation makes a lot of sense to me.

You know cue makers sell "low-deflection" cues with low density (mass) at the cue tip. Striking with a low-deflection cue with right English, a cue ball goes even more straight with less deflection to left direction. Is this probably due to increase in contact time between the cue and ball (because the cue is softer) and more friction*time to the right direction (and maybe less coefficient of restitution reduces the cue ball deflection to left)?

My thought is that if it is friction that makes the cue ball go straight, it would be theoretically possible to make the cue ball to the same direction as English if friction force can be increased (one could strike the right side of a ball and the ball goes to the right).

 

[poolplayer]

If you took the cue ball in hand and rammed it straight ahead through the object ball without deflecting I believe you would find that the object ball still goes off at an angle.

I am pretty sure that the ball goes off though I haven't tried it.

 

[Cutter Ketch]

Thank you for your answers! I am still trying to understand the insights into momentum conservation (if so, is cue ball direction different when hit by rolling ball and ball-in-hand?). But friction explanation makes a lot of sense to me.

You know cue makers sell "low-deflection" cues with low density (mass) at the cue tip. Striking with a low-deflection cue with right English, a cue ball goes even more straight with less deflection to left direction. Is this probably due to increase in contact time between the cue and ball (because the cue is softer) and more friction*time to the right direction (and maybe less coefficient of restitution reduces the cue ball deflection to left)?

My thought is that if it is friction that makes the cue ball go straight, it would be theoretically possible to make the cue ball to the same direction as English if friction force can be increased (one could strike the right side of a ball and the ball goes to the right).

If the ball completely completely stuck to the cue (like fused with it or something) it would travel straight with the cue. I think straight with the cue is the limit. I don't think you can make the ball turn towards the English during the collision. Of course if you can get the ball spinning correctly you can make it curve that way after the collision.

 

[sophiecentaur]

On the right side the red line shows the part of the force that applies to the object ball. The rest of the momentum is carried away by the white ball whereas the cue doesn't take any momentum to a different direction.

That comment worries me. Momentum (linear and angular) still has to be conserved. The cue / arm / rest of the world have a momentum change due to the collision. The resulting velocity change of the cue is 'near' zero because the effective mass is so high.
This would happen for a collision in space, with no contact with the ground. Whatever happens, due to friction etc., is a separate issue - total Momentum will still be conserved during the spinning interaction. The initial motion (Impulse) will be to the left but any friction effect of the ball spinning will be in addition to this and happens after the contact with the cue.
PS What is "turning to the English"?

 

[poolplayer]

I think straight with the cue is the limit.

I think you are right... Is this because the friction force is product of friction coefficient (<1.0) and the force perpendicular to the impact surface?

I was wondering whether the softness of the cue tip could reduce the initial velocity of the ball to left by reducing restitution coefficient or spring constant so that the friction force dominates and ball goes to right... I also noted that the cue could be bent to right during the impact (right English). I am not sure whether this bend significantly affects the ball direction though (I guess the bend increases both friction force to right and bouncing force to left)

What is "turning to the English"?

It refers to what I said: when a ball was hit on the right side (right English), the ball goes to the right, which may be impossible.

 

[sophiecentaur]

It refers to what I said: when a ball was hit on the right side (right English), the ball goes to the right, which may be impossible

Right hand side then?
If it is struck on the right hand side then it (the centre of mass of the ball) cannot move to the right initially. It has to move towards the left. That is what momentum conservation tells us and there will be a force on the cue tip, to the right. The tip may bend or be rigid and the details of what happen to the ball will depend on the stiffness of the cue etc. and also the friction of the tip on the ball and the ball on the table. There is no simple answer but friction will make the ball rotate anticlockwise (looking down on it) and, depending on whether the contact is above or below the mid point, the ball will also have top spin or bottom spin. So the path of the ball can follow a right hand or left hand curve, depending.
The whole business of striking the ball with the cue will have many variables involved and what the player 'thinks' is happening may well not be what is actually happening. That doesn't matter to the player, who learns, from experience and from 'discussions' what to do. The Physics may be very loosely connected with the player's subjective feeling about what's gong on. This doesn't matter; a good player is a good player and doesn't have to be a good Physicist.

 

[Cutter Ketch]

I think you are right... Is this because the friction force is product of friction coefficient (<1.0) and the force perpendicular to the impact surface?

I was wondering whether the softness of the cue tip could reduce the initial velocity of the ball to left by reducing restitution coefficient or spring constant so that the friction force dominates and ball goes to right... I also noted that the cue could be bent to right during the impact (right English). I am not sure whether this bend significantly affects the ball direction though (I guess the bend increases both friction force to right and bouncing force to left)It refers to what I said: when a ball was hit on the right side (right English), the ball goes to the right, which may be impossible.

When I said the ball couldn't go the other way I hadn't thought about the idea that the cue may deflect. However, under the assumption the the player is trying to move the stick in a straight line and any deflection is a reaction to hitting the ball, I would think that would move the ball off more in the expected way by Newton's law of action and reaction.

Now if the player jerks the tip the outside direction during the collision that is a different story.

 

[sophiecentaur]

When I said the ball couldn't go the other way I hadn't thought about the idea that the cue may deflect. However, under the assumption the the player is trying to move the stick in a straight line and any deflection is a reaction to hitting the ball, I would think that would move the ball off more in the expected way by Newton's law of action and reaction.

Now if the player jerks the tip the outside direction during the collision that is a different story.

You are neglecting the question of top spin and bottom spin. All good players are well aware of the effects of these on the path of the ball.

 

[poolplayer]

under the assumption the the player is trying to move the stick in a straight line and any deflection is a reaction to hitting the ball, I would think that would move the ball off more in the expected way by Newton's law of action and reaction.

So, the bend would make the ball goes even more left (more cue ball deflection). I don't know its math, but I believe you. I will do a little research and find how I can calculate them. Thank you for your suggestions!

a good player is a good player and doesn't have to be a good Physicist.

Right, but I wanted to know basic Physics as well! So, do you think that the friction only affects the curve and does not affect initial direction? Curve is of course an important factor in the game. But I will think about curves in other time, and here I want to focus on the initial direction/velocity of the cue ball.

 

[poolplayer]

Now if the player jerks the tip the outside direction during the collision that is a different story.

This is a good point. Some people do this hoping to reduce cue ball deflection.

 

[Cutter Ketch]

You are neglecting the question of top spin and bottom spin. All good players are well aware of the effects of these on the path of the ball.

If you read the last sentence of post 13 you will see I am not neglecting spin. However I do believe spin acts to change the trajectory primarily after contact with the cue is ended.

 

[sophiecentaur]

If you read the last sentence of post 13 you will see I am not neglecting spin. However I do believe spin acts to change the trajectory primarily after contact with the cue is ended.

PF General Physics forum has a regular stream of questions where a 'sporting' phenomenon is analysed (boxing, tennis, motor sport etc). It always gets out of hand very quickly because the processes don't ever seem to have enough measurement data available. The problem which always arises is to decide how 'ideal' a situation is to be analysed.
So a perfectly elastic frictionless ball on a frictionless table would not spin at all and the only force would be normal to the ball. The direction of motion would be along a line which is a radial to the ball from the contact point. That's the starting point and the simplest case. Now how far do you want to go in introducing practical factors? Which ones would you include and which would you ignore? You'd have to include a lot of those factors and then you could perhaps show that some of them are not significant.
Once the contact time is not assumed to be instantaneous, it gets harder. If the ball or cue tip deforms then the contact time would be finite and the amount of rotation would depend on the length of time of contact and the lateral force over that time (and the MI of the ball).

 

[Cutter Ketch]

You are neglecting the question of top spin and bottom spin. All good players are well aware of the effects of these on the path of the ball.

In quoting the above I remind you that you are the one who wanted to talk about spin.

 

[poolplayer]

The direction of motion would be along a line which is a radial to the ball from the contact point.

In case you doubt that the cue ball goes straight with right English (struck right hand side), I put a little movie (20-times slower than actual time). You can see the cue ball direction (yellow line) is far from normal to the contact surface (red line). So some significant force should be taken into account. I now think that it is friction, although I am not sure how strong it is with the relatively short contact time (a few milliseconds at most, typically 1 ms). There may be other significant components. You can see that the cue waggles a lot after impact, indicating significant cue deflection.


Billiards are probably the simplest sports in terms of physics and I don't see any obstacles to measure everything in Billiards.

 

[Cutter Ketch]

In case you doubt that the cue ball goes straight with right English (struck right hand side), I put a little movie (20-times slower than actual time). You can see the cue ball direction (yellow line) is far from normal to the contact surface (red line). So some significant force should be taken into account. I now think that it is friction, although I am not sure how strong it is with the relatively short contact time (a few milliseconds at most, typically 1 ms). There may be other significant components. You can see that the cue waggles a lot after impact, indicating significant cue deflection.


Billiards are probably the simplest sports in terms of physics and I don't see any obstacles to measure everything in Billiards.

Terrific stuff. Thanks for posting that. I wish my iPhone could scroll through frame by frame better. Well, tomorrow when I'm at the computer ...

 

[rcgldr]

My guess is that the friction between cue tip and ball is significant, and the cue tip may deform a bit to fit the surface of the ball to enhance the friction effect. The cue tip also "bounces" off to the side during impact. There is a Newton third law pair of forces, cue exerts force onto ball, ball exerts force onto cue, but the cue tip has more of a reaction to the sideways component of force than the cue ball, due to having less effective inertia perpendicular to the direction of the cue, than the billiard ball. This is different than a ball to ball collision, where both objects have the same inertia.

 

[poolplayer]

My guess is that the friction between cue tip and ball is significant, and the cue tip may deform a bit to fit the surface of the ball to enhance the friction effect.

I am now a bit more confident that it would be friction. Thanks!

 

[poolplayer]

the cue tip has more of a reaction to the sideways component of force than the cue ball, due to having less effective inertia perpendicular to the direction of the cue

Wait... does the less effective inertia of the cue perpendicular to its direction affect the direction of the ball? (or force normal to the contact point to the ball?)

 

[sophiecentaur]

Billiards are probably the simplest sports in terms of physics and I don't see any obstacles to measure everything in Billiards.

That's a good movie you made and it's true that, in it, the ball appears to head off in a direction parallel to the average line of the cue. This is not surprising if the shot was made by someone who is a good player. Whatever situation that one tries to analyse, it is not valid to look for solutions that contravene Newton's Laws and Vector calculations. If something appears to be happening that goes against Regular Physics, then there is some factor that hasn't been included in the first look at the problem.
It cannot be that the only force (Impulse) acting on the ball is along the radius (the simplest model) or it would move in that direction. Your evidence suggests that it doesnt. There must be another force (or set of forces) at work that the skilled player is introducing (perhaps sub-consciously). Your movie does not show the height at which the ball is struck and that, imo, is a vital factor. If it's hit at its equator, it will spin anticlockwise. The table surface is designed with friction in it. If the ball is struck above the mid line The ball will rotate away from the cue and contact with the table will produce an impulse to the right, cancelling the slight leftwards impulse from the cue. Good training can ensure that the ball will go just where the player wants it to go by balancing those two effects.
If you could re-run your experiment with, possibly, a mirror to give two simultaneous views, one from the top and one from the side. But that wouldn't be necessary with a consistent player. You could just take some shots from the side, interspersed with shots from above. My guess is that the side shots would show that the cue is hitting the ball slightly above mid height.
Something that you could help me with would be to explain when and why the "English" shot is choses, over a straight impact. Something to do with bending the path of the ball, I guess. Those professionals do some annoyingly clever stuff with how the ball behaves.

 

[Cutter Ketch]

Wait... does the less effective inertia of the cue perpendicular to its direction affect the direction of the ball? (or force normal to the contact point to the ball?)

To some degree the inertia of the cue matters, but don't forget you are holding the cue. It is constrained by the force of your hands. If the cue was sliding through a fixed bearing instead of your bridge hand so that it really couldn't move, then the contribution of the inertia of the cue to the left/right deflection would become almost completely unimportant and the elastic bending of the cue would be the dominant contribution to the deflection of the cue at the contact point. I suspect a good bridge hand is closer to this highly constrained case than the free body case that makes the inertia of the cue important.

 

[sophiecentaur]

Absolutely, CK. The issue is more that there seems to be no deviation, rather than the actual amount. Pairs of contacting balls seem to behave pretty much textbook, exchanging Momentum when they're the same masses. Their surfaces do not seem to transfer rotation in the short time of contact, normally. The cue is much more complex, with a soft tip, an almost 'infinite mass' acting along its line (incompressible and bolted to the pushing arm and Earth) but a high amount of flexibility, as the movie shows, and not a lot of mass at the tip region. I have been looking at skill, rather than simple Physics for the best explanation. That sort of attitude tends not to satisfy the non-Physicist but it's the way Physicists tend to operate.

 

[Cutter Ketch]

There must be another force (or set of forces) at work that the skilled player is introducing (perhaps sub-consciously).

It is just friction. It is not in the subconscious of the skilled player. It is in the softness of the cue tip and the coating of chalk. Note that the contact between the cue and the ball persists for a significant distance. The ball did not bounce off the cue in an elastic collision.

English can be applied at various locations but this is the result you get even when it is directly right of center on the equator. I'm sure that is what poolplayer will tell you he did as that is what he was trying to demonstrate. Practically everyone who plays pool with any regularity does this all the time and we know that the cue pretty much goes straight regardless of where around the center we strike the ball unless we miscue. (We exceed the limit of static friction and the cue slides)

 

[sophiecentaur]

It is just friction.

But the friction force between tip and ball isn't acting to the right hand. At best, it is acting in the cue direction. Won't that plus the normal contact force still produce a leftwards resultant? I still feel that there needs to be a relevant force from the table surface. The problem is that doing a good, appropriate diagram is proving difficult!
Edit: PS, we had a similar kind of discussion about how an arrow appears to sneak round the front of the bow and end up heading in the right direction. It's a similar example of Man and Machine where you can't easily measure what the Man is putting in.

 

[sophiecentaur]

Practically everyone who plays pool with any regularity does this all the time

Which part of the tip makes contact with the ball and is the cue actually horizontal? I don't think it can be. Now, there's another thing!

 

[rcgldr]

Wait... does the less effective inertia of the cue perpendicular to its direction affect the direction of the ball? (or force normal to the contact point to the ball?)

To some degree the inertia of the cue matters, but don't forget you are holding the cue. It is constrained by the force of your hands. If the cue was sliding through a fixed bearing instead of your bridge hand so that it really couldn't move, then the contribution of the inertia of the cue to the left/right deflection would become almost completely unimportant and the elastic bending of the cue would be the dominant contribution to the deflection of the cue at the contact point. I suspect a good bridge hand is closer to this highly constrained case than the free body case that makes the inertia of the cue important.

By "effective inertia", I meant how easy it is for the cue to flex a bit and allow the cue tip to move sideways by a small amount. However the cue stick is virtually incompressible, so the forward "effective inertia" is much greater. So during the time of the collision, the cue tip moves forwards and sideways, effectively making an angled collision with the ball, with enough friction to induce a spin on the ball.

 

[sophiecentaur]

I meant how easy it is for the cue to flex a bit and allow the cue tip to move sideways by a small amount.

The movie implies that the lateral movement is around the thickness of the cue tip. It shows that that contact time is fairly lengthy. Shame that a frame with actual contact seems to be missing. It would be necessary to for several takes or 10X the frame rate in order to see that. The movement of the tip will be well damped, I guess as the later frames show no movement.
This is more and more interesting.

 

[rcgldr]

The movie implies that the lateral movement is around the thickness of the cue tip.

I think that's the key aspect of this; the cue tip moves at an angle to the side (and not just straight forward) during the collision.

 

[poolplayer]

friction force between tip and ball isn't acting to the right hand. At best, it is acting in the cue direction. Won't that plus the normal contact force still produce a leftwards resultant?

I thought that the friction force between the cue and ball if any is the right hand, parallel to the contact surface. When you say the cue direction, is it the initial cue direction before the contact or actual cue direction during the contact?

Your movie does not show the height at which the ball is struck and that, imo, is a vital factor. If it's hit at its equator, it will spin anticlockwise. The table surface is designed with friction in it. If the ball is struck above the mid line The ball will rotate away from the cue and contact with the table will produce an impulse to the right, cancelling the slight leftwards impulse from the cue. ... My guess is that the side shots would show that the cue is hitting the ball slightly above mid height.

I tried to strike the ball right of center on the equator, although it is possible that I accidentally hit slightly above mid height. As Cutter Ketch knows, even if the ball is hit below the mid height, it goes almost straight as when it is hit above the mid height. I didn't think that the contact between the table and ball is relevant to the ball direction, but could you explain a bit more how the impulse to the right is generated when the ball is struck above the mid line?

Which part of the tip makes contact with the ball and is the cue actually horizontal? I don't think it can be.

It should be the left hand side of the cue tip that makes contact with the ball. But, it could be a little above the mid height of the cue tip because the cue is often pointing slightly downward although we always try to make it horizontal as much as possible.

 

[poolplayer]

The movie implies that the lateral movement is around the thickness of the cue tip. It shows that that contact time is fairly lengthy. Shame that a frame with actual contact seems to be missing. It would be necessary to for several takes or 10X the frame rate in order to see that. The movement of the tip will be well damped, I guess as the later frames show no movement.
This is more and more interesting.

I think the contact time is a few milliseconds at most. I only have GoPro and its maximum is 240fps. I could increase lighting to get clearer videos, but 240fps is not good to capture the details of the cue during contact... Dr. Dave has some videos taken with high-speed camera if you want to see the cue movement during the contact (this is a draw shot though... the ball was hit below the center). Frame rate seems 2000 fps and it looks that the contact persists 4 frames, so contact time would be ~2 ms.

 

[sophiecentaur]

Full marks for the evidence gathering. That's the advantage of a near-perfect system.
I still have a problem in explaining all of what happens in terms of just cue-ball interaction. All forces on the ball from the cue are in the leftwards direction and that can't account for lack of leftwards motion. Is that argument OK with you?
The table must also be contributing a significant force to account for what happens. The rotation of the ball will be due to two couples - one from the cue impact and reaction force of the CM of the ball (would happen in free space) and another from cue impact and reaction due to friction with the table. Imo, the latter must produce an effect of steering to the right. As skilled players, you guys seem to be finding it hard to accept that the player is actually making a contribution to getting the effect just right. As an unskilled player (A level Physics is the limit to my certainties about the situation), I can tell you that what happens to the ball is usually a bit of surprise to me when I strike it. I have not acquired the subconscious control that good players have. I would guarantee that, in a movie of what would happen if I did the experiment, the ball could go every which way in different shots.
A suitable diagram of the situation (3D) would, I am sure, resolve my problem.

 

[AstroChris]

So I happen to be a pro/am pool player myself and know a bit about physics. One thing that I didn't see mentioned and forgive me if it was but the reason that the ball will go almost straight but not quite straight is due to the shaft deflection. Because the shaft also deflects and recoils from the initial impact of the cue, it does slide a bit.

Someone said that the cue ball will always slide when you hit, that is also false. It will depend on many different things as to whether or not the cue ball will slide but most times it won't.

Oh and lastly, to demonstrate what I'm talking about poolplayer, go to your pool room and ask to use anyone's OB shaft or Predator shaft. Those are no to low deflection shafts and you can use extreme English and watch the ball travel in a direct line to where you hit it. Undoubtedly someone at your pool room has one of those too lol.

 

[poolplayer]

All forces on the ball from the cue are in the leftwards direction and that can't account for lack of leftwards motion. Is that argument OK with you?

Again, how about friction between the cue and ball? Why can you be so sure that the friction is not the key factor? I am still not convinced by your suggestion that the direction of friction force is leftward or straight at most (during right English). I feel it is rightward because the cue is moving rightward during the contact. It could be even deemed as clockwise rotation of the cue tip.

I am not sure that the rotation/spin of the ball is relevant to the initial direction of the ball after contact... It definitely affects the cue ball path, but I think that the ball usually slides on the table especially when the cue speed is fast (in my video the cue speed is ~2-3 m/s, which I believe is sufficient to induce slip of the ball on the table).

I have not acquired the subconscious control that good players have

It may require some skill to push the cue straight, but it is not so difficult if you apply chalk to the tip and strike it slowly. As Cutter Ketch said, this phenomenon is very robust and reproducible by anyone. Any unskilled player can just go to a pool bar, grab any cue, apply chalk to its tip, strike the right hand side (above/mid/below the equator), and he/she will see the ball goes pretty much straight. No professional tricks there.

explain when and why the "English" shot is choses, over a straight impact. Something to do with bending the path of the ball, I guess. Those professionals do some annoyingly clever stuff with how the ball behaves.

We use English to spin the ball. It is sometimes chosen to make the cue ball curve, but in most cases it is for positioning the cue ball where we want in order to pocket balls in a row. It is sometimes used to deflect the object ball direction hit by a cue ball. I think this is due to small friction between balls. Clockwise spin of a cue ball makes the object ball go rightward from the expected direction.

 

[poolplayer]

Someone said that the cue ball will always slide when you hit, that is also false. It will depend on many different things as to whether or not the cue ball will slide but most times it won't.

Right, that was what I thought! But, probably you would agree that a ball usually slides when it is hit hard, right?

use anyone's OB shaft or Predator shaft. Those are no to low deflection shafts and you can use extreme English and watch the ball travel in a direct line to where you hit it.

I actually have a Predator Z2 shaft and Meucci Ultimate Weapon shaft! So, do you have any ideas about how the cue shaft deflection makes the cue ball go straight rather than normal to the contact surface?

 

[sophiecentaur]

Again, how about friction between the cue and ball? Why can you be so sure that the friction is not the key factor?

You have to be right that friction is necessary for this to happen. A non friction contact with cue and ball and ball and table cannot cause any rotation and the ball would have to move to the left. But in what direction can this friction force act? Any force that rotates a ball isolated in space can't affect the direction it heads off in. That direction of the linear momentum change can only be radial from the contact point. The impact is prolonged, due to flexing of the cue and slippage so the contact point changes a bit and you have to consider the integral over the contact time but it's always to the left. Prove it for yourself with a force diagram and draw a circle and a contact point. You cannot obtain a rightwards resultant force, even allowing for the cue displacement. It's only when the ball has a contact point with the table that friction can have any effect on the final velocity of the cm of the ball. Once you allow the ball to rotate about a non vertical axis, it can 'walk' either way, depending on the angle of that axis. Being pushed forward will naturally tilt the rotation axis forward, which will cause a rightwards walk.

 

[sophiecentaur]

So, do you have any ideas about how the cue shaft deflection makes the cue ball go straight rather than normal to the contact surface?

Unless you give deliberate back spin, the ball will always have a roll-forward component as it will not slip on the table. That forward roll and the rotation about a near vertical axis will cause the sideways movement component.
Again, I have to insist that there are many additional variables involved here - even down to the nature of the cloth surface. One of the qualities for a 'good' cloth will probably involve a 'good feel' and you haven't quantified what is meant by that. Too slippy would not be acceptable, would it?

 

[AstroChris]

I actually have a Predator Z2 shaft and Meucci Ultimate Weapon shaft! So, do you have any ideas about how the cue shaft deflection makes the cue ball go straight rather than normal to the contact surface?

I don't really understand your question due to the wording but I'll run through it once more, no worries. The low or no deflection shafts combat the side way "skid" that you will see from using English. Even in cases of extreme English the cue ball will go straight vs "pushing" to the side a bit first as a regular shaft would do, much like your Muecci. Muecci by the way is one of the "livest" shafts out there, by that I mean it has tons of deflection and with that you can add large amounts of English on the cue ball without moving to the either side as much.

Too slippy would not be acceptable, would it?

Too slippy is what happens when a table gets recovered in new cloth. Because the cloth is stretched out so after it plays for a while it loosens a bit correctly, the grain is almost pulled out of it so to say and it causes a bunch of sliding when using English and just hitting at faster speeds.

 

[poolplayer]

Any force that rotates a ball isolated in space can't affect the direction it heads off in.

But, if you think something like a treadmill moving rightward, and push this treadmill against a ball, isn't the ball receive rightward force through friction? I don't think that curve induced by rotation/spin of the ball significantly affects the initial direction. If the rotation/spin is that strong, we see that the ball greatly curves rightward and crosses the straight line in its later path, which is not the case.

I have to insist that there are many additional variables involved here ... Too slippy would not be acceptable, would it?

I stroke a ball on a smooth table and it was indeed almost the same as usual table with cloth. So, I think that the friction between the table and ball is not significant. The table was quite smooth as it was really hard to set the ball (this indicates that the table was not completely horizontal, but I don't think it matters).

 

[poolplayer]

Muecci by the way is one of the "livest" shafts out there, by that I mean it has tons of deflection and with that you can add large amounts of English on the cue ball without moving to the either side as much.

I agree. I once tried to abandon Meucci because of their poor reputation, but it seems that I was so used to Meucci cues and could not accommodate myself to other cues.

My question was why the ball goes relatively straight even when we use a usual cue shaft. You know that a ball goes to the left during ball-to-ball collision when the aim is thin. But a ball goes almost straight even if it is extreme right English. I have never wondered this thing as most people, but I noticed that I don't know its physics.

 

[AstroChris]

Ok, so over emphasize the experiment and you'll understand what I am saying. At a very low stroke speed, line up at extreme right hand English and almost "push" through it and it will definitely move to the left, line up dead middle and it will go dead straight. If you are using a regular cue, it will most certainly move slightly to the opposite direction of the English you're using.

 

[poolplayer]

Ok, so over emphasize the experiment and you'll understand what I am saying. At a very low stroke speed, line up at extreme right hand English and almost "push" through it and it will definitely move to the left, line up dead middle and it will go dead straight. If you are using a regular cue, it will most certainly move slightly to the opposite direction of the English you're using.

Of course I know that cue ball deflection. What I am saying is that the cue ball direction is not perpendicular from the contact point between the cue tip and the ball... You see that the cue ball does not go on the red line in the movie above.