Not in the transition. There is a point just before the forward move of the hand to the ball that the wrist goes to neutral. That is the case on the ATP forehand whether the wrist is extended in the unit turn or not. If the wrist stays extended during the entire motion, from the unit turn on, it is basically the WTA type forehand.

Wholeheartedly agree, Nadal and Fed the number 1 and 2 forehands ever to me. They are so similar, as BG pointed out years ago(before anyone else). Nadal just does everything Fed does to an extreme to produce the ball he did.

thank you guys. Sorry. My account would not allow posting until Jeff fixed it.

Here are a few thoughts:

In tennis, speed is power, and what matters most is racket head speed at the point of contact, not just raw mechanical force.

When a player like Roger Federer extends the arm, it doesn’t necessarily increase angular velocity. In fact, it can reduce it—because extending the arm increases the moment of inertia, or the resistance to rotation. However, it can increase total angular momentum, which is what ultimately matters when transferring energy through the kinetic chain.

This concept comes from the equation:

L = I x w

In this equation:
• L is angular momentum
• I is moment of inertia
• w (omega) is angular velocity, or the rate of rotation in radians per second

Even though omega may decrease due to the increased length of the lever, I (moment of inertia) increases substantially as mass is distributed farther from the axis of rotation (e.g., the shoulder). This can result in greater overall angular momentum, which helps generate high racket head speed when efficiently transferred through the kinetic chain.

Biomechanics researcher Dr. Brian Gordon has also hypothesized that the straight-arm forehand configuration—where the hitting arm is extended beyond 155 degrees—can contribute to producing a heavier ball. The reasoning is that this configuration allows for a greater contribution from internal shoulder rotation (ISR), which is the dominant source of racket head speed in the modern forehand. By maximizing ISR contribution, players may increase spin rate and momentum transfer to the ball, resulting in a shot that combines pace and heavy topspin.

This becomes especially effective when the full kinetic chain—starting from the ground and moving through the hips, torso, shoulder, arm, and wrist—is sequenced correctly. The result is a whip-like effect that generates maximum speed at the point of contact, even without an increase in torque at the shoulder.

Let’s continue the discussion—happy to explore the implications of ISR, angular momentum, and forehand configurations in more detail.

So my observation is that great players are extending their arm for the forehand to generate more angular momentum but also to generate higher spin rates.​

Yes!

Thanks. This is a great comment. Good discussion. I added these thoughts:

In tennis, speed is power, and what matters most is racket head speed at the point of contact, not just raw mechanical force.

When a player like Roger Federer extends the arm, it doesn’t necessarily increase angular velocity. In fact, it can reduce it—because extending the arm increases the moment of inertia, or the resistance to rotation. However, it can increase total angular momentum, which is what ultimately matters when transferring energy through the kinetic chain.

This concept comes from the equation:

L = I x w

In this equation:
• L is angular momentum
• I is moment of inertia
• w (omega) is angular velocity, or the rate of rotation in radians per second

Even though omega may decrease due to the increased length of the lever, I (moment of inertia) increases substantially as mass is distributed farther from the axis of rotation (e.g., the shoulder). This can result in greater overall angular momentum, which helps generate high racket head speed when efficiently transferred through the kinetic chain.

Biomechanics researcher Dr. Brian Gordon has also hypothesized that the straight-arm forehand configuration—where the hitting arm is extended beyond 155 degrees—can contribute to producing a heavier ball. The reasoning is that this configuration allows for a greater contribution from internal shoulder rotation (ISR), which is the dominant source of racket head speed in the modern forehand. By maximizing ISR contribution, players may increase spin rate and momentum transfer to the ball, resulting in a shot that combines pace and heavy topspin.

This becomes especially effective when the full kinetic chain—starting from the ground and moving through the hips, torso, shoulder, arm, and wrist—is sequenced correctly. The result is a whip-like effect that generates maximum speed at the point of contact, even without an increase in torque at the shoulder.

Let’s continue the discussion—happy to explore the implications of ISR, angular momentum, and forehand configurations in more detail.

So my observation is that great players are extending their arm for the forehand to generate more angular momentum but also to generate higher spin rates.​

Thoughtful comments. It all comes down to mathematics.

Here are a few thoughts:

In tennis, speed is power, and what matters most is racket head speed at the point of contact, not just raw mechanical force.

When a player like Roger Federer extends the arm, it doesn’t necessarily increase angular velocity. In fact, it can reduce it—because extending the arm increases the moment of inertia, or the resistance to rotation. However, it can increase total angular momentum, which is what ultimately matters when transferring energy through the kinetic chain.

This concept comes from the equation:

L = I x w

In this equation:
• L is angular momentum
• I is moment of inertia
• w (omega) is angular velocity, or the rate of rotation in radians per second

Even though omega may decrease due to the increased length of the lever, I (moment of inertia) increases substantially as mass is distributed farther from the axis of rotation (e.g., the shoulder). This can result in greater overall angular momentum, which helps generate high racket head speed when efficiently transferred through the kinetic chain.

Biomechanics researcher Dr. Brian Gordon has also hypothesized that the straight-arm forehand configuration—where the hitting arm is extended beyond 155 degrees—can contribute to producing a heavier ball. The reasoning is that this configuration allows for a greater contribution from internal shoulder rotation (ISR), which is the dominant source of racket head speed in the modern forehand. By maximizing ISR contribution, players may increase spin rate and momentum transfer to the ball, resulting in a shot that combines pace and heavy topspin.

This becomes especially effective when the full kinetic chain—starting from the ground and moving through the hips, torso, shoulder, arm, and wrist—is sequenced correctly. The result is a whip-like effect that generates maximum speed at the point of contact, even without an increase in torque at the shoulder.

Let’s continue the discussion—happy to explore the implications of ISR, angular momentum, and forehand configurations in more detail.

So my observation is that great players are extending their arm for the forehand to generate more angular momentum but also to generate higher spin rates.​

thank you guys. Sorry. My account would not allow posting until Jeff fixed it.

Here are a few thoughts:

In tennis, speed is power, and what matters most is racket head speed at the point of contact, not just raw mechanical force.

When a player like Roger Federer extends the arm, it doesn’t necessarily increase angular velocity. In fact, it can reduce it—because extending the arm increases the moment of inertia, or the resistance to rotation. However, it can increase total angular momentum, which is what ultimately matters when transferring energy through the kinetic chain.

This concept comes from the equation:

L = I x w

In this equation:
• L is angular momentum
• I is moment of inertia
• w (omega) is angular velocity, or the rate of rotation in radians per second

Even though omega may decrease due to the increased length of the lever, I (moment of inertia) increases substantially as mass is distributed farther from the axis of rotation (e.g., the shoulder). This can result in greater overall angular momentum, which helps generate high racket head speed when efficiently transferred through the kinetic chain.

Biomechanics researcher Dr. Brian Gordon has also hypothesized that the straight-arm forehand configuration—where the hitting arm is extended beyond 155 degrees—can contribute to producing a heavier ball. The reasoning is that this configuration allows for a greater contribution from internal shoulder rotation (ISR), which is the dominant source of racket head speed in the modern forehand. By maximizing ISR contribution, players may increase spin rate and momentum transfer to the ball, resulting in a shot that combines pace and heavy topspin.

This becomes especially effective when the full kinetic chain—starting from the ground and moving through the hips, torso, shoulder, arm, and wrist—is sequenced correctly. The result is a whip-like effect that generates maximum speed at the point of contact, even without an increase in torque at the shoulder.

Let’s continue the discussion—happy to explore the implications of ISR, angular momentum, and forehand configurations in more detail.

So my observation is that great players are extending their arm for the forehand to generate more angular momentum but also to generate higher spin rates.​

Great comment.

But here’s the nuance: in tennis, speed is power, and what matters most is racket head speed at the point of contact, not just raw mechanical force.

When a player like Roger Federer extends the arm, it doesn’t necessarily increase angular velocity. In fact, it can reduce it—because extending the arm increases the moment of inertia, or the resistance to rotation. However, it can increase total angular momentum, which is what ultimately matters when transferring energy through the kinetic chain.




This concept comes from the equation:




L = I x w




In this equation:

• L is angular momentum
• I is moment of inertia
• w (omega) is angular velocity, or the rate of rotation in radians per second

Even though \omega may decrease due to the increased length of the lever, I (moment of inertia) increases substantially as mass is distributed farther from the axis of rotation (e.g., the shoulder). This can result in greater overall angular momentum, which helps generate high racket head speed when efficiently transferred through the kinetic chain.




Biomechanics researcher Dr. Brian Gordon has also hypothesized that the straight-arm forehand configuration—where the hitting arm is extended beyond 155 degrees—can contribute to producing a heavier ball. The reasoning is that this configuration allows for a greater contribution from internal shoulder rotation (ISR), which is the dominant source of racket head speed in the modern forehand. By maximizing ISR contribution, players may increase spin rate and momentum transfer to the ball, resulting in a shot that combines pace and heavy topspin.

This becomes especially effective when the full kinetic chain—starting from the ground and moving through the hips, torso, shoulder, arm, and wrist—is sequenced correctly. The result is a whip-like effect that generates maximum speed at the point of contact, even without an increase in torque at the shoulder.


Let’s continue the discussion—happy to explore the implications of ISR, angular momentum, and forehand configurations in more detail.
​

In tennis...speed is one element of control, which is power. The other two are spin and placement.