If you take a look at the 3X Pitching Profiles, which are measurements of speeds and distances of some of the best pitcher’s mechanics in the game, you will discover that most of these pitchers have either above average 3X into hip to shoulder separation or below average hip to shoulder separation with above average 2X. To truly understand what is going on here and how this effects velocity, it is important we first understand the relationship of 3X to 2X and hip rotation.

3X to 2X and Hip Rotation

Triple extension (3X) – Is the extension of the drive leg knee, ankle and hip flexor and it will usually extended in that order. The 3X approach to pitching teaches us that achieving 3X before front foot strike will create hip rotation just at or just after front foot strike. It will also promote more explosive hip rotation which leads to optimal hip to shoulder separation. This hip rotation is occurring because when the drive leg achieves 3X, it pushes the hip flexor of the back hip forward before front foot strike. This will just open the hips a little, so when the front leg lands and stabilizes, the hips slam completely open towards the target. If the pitcher does not open the hips through 3X before front foot strike, hip rotation will happen late, reducing hip to shoulder separation.

Double Extension (2X) – This is the extension of the knee and ankle of the front leg at front foot strike into pitch release. The 3X approach to pitching also teaches us that achieving 2X before pitch release is critical to support hip to shoulder separation and it will transfer more energy or power into the ball increasing velocity. Taking 2X even farther into hyper-extension will force the hips to completely open towards the target. We know the more open the hips are towards the target at release, the more front leg extension will occur which will put more power and energy into the ball, increasing pitching velocity.

How 3X and 2X together Promote High Pitching Velocities

The best way to understand the relationship of 3X to 2X, is using the car crash analogy, which I have used a few times on this site. 3X would be the high performance car heading towards an immovable brick wall (2X). The passenger (test dummy) in the car is the ball. We do not know the effect of 3X to 2X until the car hits the wall. The farther the passenger flies out of the car, the more effective 3X to 2X worked together.

Just like when pitching, 3X is our acceleration system and 2X is our breaking system. If we increase 3X then 2X must support it to increase pitching velocity and vice versus. They work hand in hand. You can’t have one without the other.

On the elite level, when a pitcher is working to break 90mph, the relationship of 3X to 2X becomes even more important. In the case of Brandon Morrow (see 3X Pitching Profile) he has an above average 3X with a below average 2X and he is a 95+mph pitcher. In the case of Justin Verlander (see 3X Pitching Profile) he has a below average 3X with an above average 2X and he is a 95+mph pitcher. The diamond in the rough here is that both these pitchers have an above average relationship between 3X to 2X. This is why they throw in the upper 90′s.

Let’s look at these pitchers and their 3X to 2X relationship, so we can learn how to improve our relationship of 3X to 2X. Brandon Morrow has one of the best 3X moves in the game but he has a below average 2X move to support it. If you watch his front leg stabilization in slow motion you will see that it never flexes or moves after front foot strike, it is stabilizing and supporting his explosive 3X, like the immovable brick wall in the car crash analogy. This is allowing all that power from 3X to slam the hips open into his stabilized but not extended front leg, like in the car crash analogy. If he had a weaker 3X, with his below average 2X, he would lose velocity but if he had an explosive 2X like Justin Verlander, to go with his explosive 3X, then what would happen? This would change the car crash analogy. The brick wall would now be replaced with another car moving towards the original car at the same speed. Let’s replace these cars with bumper cars so the impact is greater. Now what would happen to the passenger in the original car? He would project himself even farther out of the car at impact. So you can see how powerful 3X and 2X can be if they work together. You can also see how if you increase one and decrease the other, at the same rate, then you haven’t effected velocity but if you increase one without decreasing the other then you increase velocity. 3X to 2X go hand in hand, so you must understand their relationship before you can effectively use them to increase velocity.

How to implement 2X before Pitch Release

The key to implementing 2X into your delivery is through both the motor coordination training of the component through drills and strength and conditioning. Let’s look at them separately.

Motor Training 2X – When using drills like the Med Ball or Target throws in the 3X Pitching Velocity program you want to work to keep the front leg knee behind your heal when in these drills. This will allow you to more easily achieve 2X. Once the front leg knee pushes out over the front foot it becomes too difficult to achieve 2X. These drills will help you develop the motor coordination around 2X because when you are in these drills, you are positioned with your hips open to the target at start. 2X will not occur if your hips are closed towards the target. This is why it is difficult to practice 2X within your entire pitching delivery. If you are not opening your hips at front foot strike then it will be almost impossible to achieve 2X before pitch release. This is why I recommend using the drills in the 3X Pitching Velocity Program to train this 2X motor skill.

Strength and Conditioning 2X – This is important to support 2X because for a pitcher to achieve 2X before pitch release, he must have strong quads and flexible hamstrings to complete this movement. If a pitcher is able to get the hips open at front foot strike but does not have the strength to fire the quads against the force of the landing leg hitting the ground and his hamstrings are not strong and flexible enough to support this extension and forward trunk tilt movement then the pitcher will never achieve this velocity component. The 3X Pitching Velocity program uses heavy load training to develop the quad power along with lifts like the RDL’s to develop the hamstring flexibility.

The Science behind 2X to 3X

If you need more science to support this information in this article then please study more about the physics of impulse and momentum. You can actually put together the math that supports this 3X to 2X relationship.

Here are also the studies that support these pitching components.

NPA Velocity Study conducted 2005-2006

http://www.nationalpitching.ne…..UV_NPA.pdf

“The results from our study indicate that just about 80% of a pitcher’s real velocity comes from the torque of hip and shoulder
separation”

ASMI – Comparison of High Velocity and Low Velocity Pitch Deliveries

http://www.asmi.org/asmiweb/re…..itches.htm

“Compared to the low ball velocity group, the higher ball velocity pitchers demonstrated less lead knee flexion velocity after front foot contact and greater lead knee extension velocity at the time of ball release. Extending the lead knee in this manner may provide stabilization allowing better energy transfer from the trunk to the throwing arm, and could be a critical factor in pitch velocity.

More open pelvis angle at the time of ball release (REL) also correlated with increased pitch velocity increased.”

Velocity is a product of power and if you can understand how we generate power as athletes, you will then discover how you can personally increase and maintain velocity.

Power is both speed and strength. It isn’t enough to be an athlete who can only move a lot of weight or an athlete who can only move very quickly. You must be that athlete who can move a lot of weight, very quickly. This is called explosive power or explosive strength. This can all be measured in what I call the Pitcher Power Curve.

The Pitcher Power Curve

This diagram alone is the secret to velocity, if you have learned how to convert power to velocity. To learn how power is converted to velocity then watch the 3X Pitching 101 video. If you understand or have implemented the 3X Mechanics and you are dealing with a power issue then this diagram is what you need to discover where you must spend your time. The way this curve works is simple. Write down your percentages of your 1 Repitition Maximum or 1RM for these three lifts; the Back Squat, the Power Clean and the Bench Press. Also write down your vertical or broad jump distances with your sprint times in the 40 yard dash or the 60 yard dash. Here is how to decipher these numbers.

• Pure Strength can be measured in the Back Squat and Bench Press exercises.
• Pure Speed can be measured in the 40/60 Yard Dash. You can also record how many times you can jump rope in say a 1 minute time.

Now look at your measurements and determine, based on your age and size, where do you stand as compared to the average athlete at your age and size. You can determine this by measuring up your teammates and competition. Once you get a good understand of how you match up to them, within these lifts and exercises, then you can see where you fall on the Pitcher Power Curve.

Let’s say you rank very high in pure speed but you rank very low in pure strength. Your arrow swings all the way over to the right. Then you need to focus more on strength to develop more power. This doesn’t mean stop training for speed, but that you need to focus more on your strength training. Power is the goal here, so wherever you fall on the Power Curve, your goal is to get your ability more towards Pure Power.

The reason I told you to record your clean 1RM is because this is a Pure Power lift. It will tell you where you stand when it comes to Pure Power, which is the goal. The problem is the cleans do not tell you where are you lacking on the power curve. Is it pure strength or pure speed? The Power Curve will do this for you.

The Fusion System in the 3X Pitching Velocity Program includes a full spectrum of lifts and exercises that fall on the Pitcher Power Curve and if you would like to know the lifts and exercises that or more towards pure strength or pure speed, please contact me.

To understand how to implement this into your pitching delivery we must first define these terms.

Force Production

“Generally, nerves stimulate muscles causing the fibers to contract with tension placed on their adjoining connective tissues. Since muscle contractions create the forces necessary to overcome resistance, the nerves represent the control center, whereas the connective tissues transfer the forces to the skeletal system. Ultimately, it is the ability of the muscle to generate forces that determines whether it will perform a movement effectively.” www.nsca-lift.org

Triple Extension

The force production generated through the extension of the ankle, knee and hip flexor is the most effective and efficient way to move the body. The extension of these three joints is call triple extension.

What does it take to increase force production through triple extension?

First, you must train your muscles to generate more force. Even better is to train through triple extension. This would include heavy load training using Plyometrics and the Olympic lifts, like the cleans. The reason for the heavy load training is because this has been proven the most effective way to develop more explosive power from your muscles. Heavy load training forces the body to recruit more fast twitch muscle fibers and also will develop more motor units to fire those muscle fibers more frequently.

Second, you must make mechanical adjustments to take advantage of this increased force production. This is because there is two different ways to move through force production. One way is a vertical movement, like a jump and the other way is a linear movement, like in a stride or sprint. In pitching we move with a linear stride and that stride is also moving down hill.  Because we are moving in a linear movement, instead of a vertical movement, we must set what is called our force vector, with our center of gravity, before the launch. The 3X Pitching Velocity Program goes into this more but the basics of this mechanical adjustment is that you must line up your drive leg ankle and knee with your front hip, and these all should be pointing towards the target. Once this occurs, then the force production of triple extension will drive the body in a linear movement towards the target. If this does not all line up, then triple extension will not occur and force production is limited.

The 3X Pitching Velocity Program produces results because it trains you to generate more force production both physically and mechanically like describe in this article. You must have both to effectively increase velocity. The 3X Pitching Velocity Program goes into full detail on how to train 3X and force production and also has many drills teaching you how to do this.

The two greatest pitchers of our time is Nolan Ryan and Roger Clemens. Their success came from their genetic make up and also their work ethics. Both of these pitchers had intense training programs. Roger Clemens was even using illegal drugs to enhance his work ethic and increase his improvements. Both of these pitchers grew bigger, stronger, faster in their careers and they both threw harder the older they got. This is because their work ethics improved their overall strength, which helped keep their flawless mechanics consistent and efficient. If they had slacked on their off-season training programs then you would have noticed a decline in their careers. This wasn’t the case and it is known today that they both where extremely hard workers.

Nolan Ryan and Roger Clemens careers are proof that proper weight training and plyometric training will lead to a successful career. So why do coaches ignore this fact? Because they usually do not have first hand experience. If you want to be a high performance machine then you must train your body to become one.

Why should pitchers use a good strength and conditioning program?

1. To enhance pitching mechanical efficiency, which will lead to more consistency and increased longevity.
2. Help the body heal faster.
3. Develop fast twitch muscle fibers which have a higher capacity for explosive energy.

Velocity is Speed! By saying, “I want to increase my velocity” is no different than saying,” I want to increase my 60 yard dash time” or “I want to increase my vertical jump.” If you want to throw harder you need to learn to move faster. Every professional ball player I have played with or had the opportunity to watch had some hidden explosive power within them. Every young athlete that comes into my Baseball Academy who wants to increase velocity shows potential but does not have the awareness and understanding to accelerate their bodies to levels of a professional ball player. If you spoke with any Major League Umpire about the difference between the game in the high school levels to the major league levels the first thing out of their mouth would be the speed of the game. If speed is such a big factor in the advanced levels of the game then why do most baseball players train like golfers? Why do they look like cross country runners? To answer these questions we need to first ask one more. Why does Major League Baseball spend more time recruiting in Latin countries than American States?

The reason is laziness and conventional wisdom. Latin countries play the game as we do but when Americans dream of playing Major League Baseball it means having the opportunity to play on TV and look like a super star. Latin ball players see the dream of playing Major League Baseball as the opportunity to save their families from oppression and poverty. This is a bigger fear factor for them than us Americans. Just read about the story of Aroldis Chapman from Cuba who risked his life to play Major League Baseball and left his entire family behind, including his new born child. This fear factor forces them to do whatever it takes to perform at an optimal level. This optimal level in any sport is a measurement of speed. If you do not have fear or an obsessive drive pushing you to reach your optimal level then how will you ever increase pitching velocity. It sure doesn’t come from a quick mechanical fix or the latest supplement. It comes from a deep desire way down in your soul to be an extra ordinary individual. Not someone who is satisfied with just playing video games all day or satisfied with just making the varsity team. It comes from a soldier of the game who is determined to be the best no matter the circumstances.

If you really want to increase pitching velocity you must find that desire I speak of and use that drive to push your levels to speeds of a professional athlete. If you can not find this drive within you then your chances of actually increasing pitching velocity are limited. Once you have accomplished this then learning good pitching mechanics will help prevent injury and will assist velocity through efficiency.

When you are ready, I recommend you sign up for the FREE Velocity Starter Kit and read these articles:

10 Legitimate tips to Pitching Velocity

Triple Extension – 3X Pitching

The Phenomenon of Speed Mechanics!

The start of a 40 yard dash is first based on the athlete’s explosive power to help get them from a static position out into the drive phase of the sprint. Many coaches today have their athletes start in a 3 point stance athlete stands with front foot 2-6 inches from line depending on the athletes size and back foot 2-4 inches from front foot with toes facing forward. The athletes front knee should be bent nearly at 90 degrees and back leg around 120 degrees with hips slightly above knees, back flat and chin tucked. The left arm is bent at 90 degrees at the hip if the left leg is in front, and the right arm is on the line with thumb pointing towards your left foot and index finger point to the right. The athlete’s right shoulder is directly over the right hand with the athlete’s weight leaning forward.

Once the athlete has left the static position the athlete is now in the acceleration or drive phase. Michael Gough (2006), defines the acceleration phase from the initial movement of ground contact until the athlete reaches top end speed. A powerful triple extension of the hip, knee, and ankle joints is important for maximum power development off the start. Forward body lean is critical during the acceleration phase with the shoulders always over the hips. Most coaches want the athlete driving out in a 35 to 45 degree angle with elbows at 90 degrees and driving their heel over their knee with foot dorsiflexed and foot striking under hips. In fact, research by Weyand, Sternlight, Bellizzi and Wright (2000) indicated that the force applied at ground contact is the most important determinant of running speed. Ken Jakalski (2008) states in his article that the dorsiflexion of the ankle is the “magic bullet” of the sprint cycle. He explains this of the dorsiflexed ankle because it puts a stretch on the gastrocnemius, soleus and achilles complex which contributes to knee flexion and hip flexion. He goes on to explain that if the athletes does not dorsiflex the ankle, the gastrocnemius soleus and achilles complex cannot help out as a leg flexor. If the gastrocnemius cannot assist in this process, another muscle group will, which are the hamstrings. Hamstrings should not serve a primary role as knee flexors they are hip extenders, not knee flexors. If the hamstrings are called upon to assist in knee flexion, they will be less effective in carrying out their primary responsibility.

The next phase of the forty yard dash is maximal velocity. This takes place for the last 12.66 yards. Michael Young (2007) of the USA Military Academy and Human Performace Consulting explains there are three primary goals of maximal velocity sprinting: preservation of stability, minimizing braking forces and maximization of vertical propulsive forces. Preservation of stability is the body’s ability to stay in perfect posture for the sprint because when stability is disrupted the loss of elasticity occurs. This stability relates to the athletes core for the most part, think of a squat an athlete holds their breath on the way down to support their back and keep their spine protected. The next goal is to minimize braking forcing which is any force that act in the opposite direction of the desired movement. The primary cause of excessive braking forces is making ground contact too far out in front of the athlete’s center of mass. This can go back to the stability goal because if an athlete has good stability the athlete is less likely to lean back or stand strait up which tends to disrupt the foot strike under the hips. The last goal is maximization of vertical propulsive forces which is the distance traveled in the air before ground contact. Vertical propulsive forces help the athlete with a more effective ground contact position and an increase in negative foot speed which when the foot is moving backwards at ground contact with respect with body moving forward; which, in turn helps the athlete accelerate through the line. Another benefit to the maximization of vertical propulsive is an increase in leg stiffness which is the ability of the legs to act like a spring during contact. Actually, Bret, Dufour, Messonnier and Lacour did study on leg strength and stiffness as ability factors in 100 meter sprints and found that leg stiffness is critically important to maximal velocity sprinting and the maintenance of momentum developed during the acceleration period of a sprint.

Throughout this paper one can see that there are many detailed mechanics through a 40 yard sprint. In a recap we know how to start, we know during the drive phase the athletes elbows are firing past the hips to the shoulders at 90 degrees, the heels are driving up over the knee, the shoulders are in advance of the hips and the athlete is making ground contact beneath the athletes hips which helps drive the athlete forward. During max velocity phase the athlete is doing everything that is in the drive phase except now we are trying to aim for more of a vertical propulsive movement. There is many other factors that go into sprinting for instance breathing, power and strength but for the purpose of this paper I am just explaining the mechanics of a sprint.

Now, that sprint mechanics are understood, what are some improper mechanics that athletes usually do and how can they be fixed. For starters many young athletes have problems with mechanics and it starts with their posture. Most young athletes have tight hips, glutes, hamstrings and gastrocnemius, soleus and achilles complex, internally rotated shoulders and an everted foot due to sitting in class all day. Think about if these kids are in flexion all day and that is what their body knows. So, how can these athletes improve their posture and the answer is through corrective exercises. Pete Egoscue suggests in his book Pain Free to do arm circles for internally rotated shoulders, and many other great corrective exercises for the hips, glutes, hamstrings and gastrocnemius, soleus and achilles complex. But, the most important corrective exercise when it comes to sprinting is foot circles. If an athlete has a foot that is everting and supinating the athlete may lose up to 2/3 or more of surface area and all important assistance of the knee and hip and their associated musculature (48). Once foot circle are performed the athlete feels an increase on surface area as well as more strength because of the assistance of the knee and hip so, if an athlete increases surface area, the athlete then increases force and if the athlete increase force the athlete in turn increase speed with proper sprint mechanics. The next error most athletes are with their elbows many athletes kick their arm back to 180 degrees past their hip which turns their arm into a long slow pendulum. Some athletes cross their bodies with their arms and many do not lock their wrist out which can inhibit the stretch reflex mechanism in the athletes shoulder if the hand supinates past the hip. These improper elbow mechanics can be improved by seated arm swings drills and arm circles. Brown and Ferrigno (2005) explain seated arm drills Starting Position: Seated on the floor with the legs straight out in front of you. Swing arms in a sprinting motion. Elbows should be kept at 90 degrees and keep hands relaxed. Your hands should come up to about shoulder height and should go past your hips in the back. Be careful to not bounce off of the floor as you swing your arms faster. Other problems athletes have is driving heel over knee, driving off of their power pads, heel contacting ground and shoulders not over hips. To help improve these faults there are the Mach Drills invented by Gerard Mach. A cornerstone of his system was the A B & C drill series. Mach (1977) broke the stride into its components parts, knee lift, foreleg action and the push off through the drills. The A Drills were designed to work the knee lift component. The B Drills were designed to work on foreleg reach or pawing action. According to Mach All exercises with leg extension and active down are special exercises to strengthen the hamstrings (6). Mach (1977) also explained The marching and skipping exercises were designed to develop the technique required for body lean, arm action, high knee lift, leg extension, and keeping the center of gravity high, but did not emphasize the strong driving forward or push forward action and the C Drills were designed to work on push off and extension (6). Brent McFarlane uses similar drill for improving speed and technique as does Tom Shaw. Other ways to enhance performance is by doing explosive Olympic lifting and plyometrics. In fact, Eduardo S¡ez, Gonz¡lez-Badillo, Juan Jose, Izquierdo did a study on Low and Moderate Plyometric Training and found that the lower training frequency produced a greater jumping and sprinting gain compared to high frequency. Therefore, sometimes as a coach remember less is more.

In closing, one can see how complex and how much detail goes into sprint work. Again, there is much more that goes into sprinting besides mechanics for instance strength, muscle fibers, breathing and etc. Finally, remember that the start and the finish of a sprint are equally important and if you want to run a good 40 yard dash there is much more than just genetics that come into play. In the words Vern Gambetta used in his article about speed drills there are many roads to Rome and another famous idiom there are many ways to skin a cat. What this mean is coach the drills and training that work for your athletes.

References

1. Bret, C., Rahmani, A., Dufour, A.B., Messonnier, L., and Lacour, J.R. (2002). Leg strength and stiffness as ability factors in 100m sprint running. Journal of Sports Medicine and Physical Fitness. 42(3): 274:281.
2. Brown, Lee and Ferrigno, V. (2005). Training for Speed agility and Quickness: Champaign, IL: Human Kinetics.
3. Eduardo S¡ez, Gonz¡lez-Badillo, Juan Jose, Izquierdo, Mike .Low and Moderate Plyometric Training Frequency Produces Greater Jumping and Sprinting Gains Compared with High Frequency. Journal of Strength and Conditioning Research. 22(3): 715-725. 2008.
4. Gough, Michael. The Forty-Yard Dash for the High School Athlete. National Strength and Conditioning Association Journal. 28( 2): 24-25. 2006.
5. Jakalski, Ken. Sprint Technique and Speed Training. 2008. Enhanced Fitness and Performance.http://www.enhancedfp.com/sport-specific/track-and-field/400-meter-training-ken-jakalski
6. Mach, Gerard. Sprinting & Hurdling School. CTFA 1977: Page 6
7. McFarlane, Brent. A Basic and Advanced Technical Model for Speed. National Strength and Conditioning Association Journal. 15(5): 57- 61. 1993.
8. McFarlane, Brent. A Look Inside the Biomechanics and Dynamics of Speed. National Strength and Conditioning Association Journal. 9(5): 35-41. 1987.
9. Pete Egoscue (Author), Roger Gittines (Contributor) (1998). Pain Free: A Revolutionary Method for Stopping Chronic Pain: New York: Bantom.
10. Weyand, P., Sternlight, D., Bellizzi, M. and Wright, S. (2000). Faster top running speeds are achieved with greater ground forces not more rapid leg movements. Journal of Applied Physiology, 89, 1991-2000.
11. Young, Michael. Maximal Velocity Sprint Mechanics. Track Coach. No. 179. Spring 2007.