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The Vertical Jump Development Bible
I increased my vertical jump by 19 inches- I’m gonna show you how to increase yours too! By: Kelly Baggett Higher-Faster-Sports

Copyright 2005 by Higher-Faster-Sports.com - All rights reserved. No part of this work may be reproduced or transmitted in any form or by any means without express written permission of Higher-Faster-Sports.
Warning: There is always risk of injury when performing exercise with weight. Before beginning any exercise program, consult with your physician to ensure that you are in proper health. This program is not meant to provide medical advice; you should obtain medical advice from your private healthcare practitioner. No liability is assumed by Higher-Faster-Sports for any of the information contained herein.

If you want to fly, you’ve got 3 options: 1. Buy a plane ticket 2. Sprout feathers and wings 3. Improve your vertical jump

While flying in a plane is nice and all, it’s a bit expensive and way too temporary. Sprouting feathers and wings ain’t gonna happen! So, unless you’ve got money to burn or you really believe in evolution, you’re stuck with improving your vertical jump. A strong vertical jump is at the core of some of the most beautiful and graceful movements known to man – Kobe Bryant dunking on the fast break, Michelle Kwan hitting a triple axle, and Barishnikov seemingly floating in air during the ballet. But don’t get me wrong, the vertical jump is also a measure of pure raw power that is used widely throughout professional and college athletics as a performance test. An athlete’s vertical jump can effectively determine how explosive they are and how efficiently they utilize their strength in athletic movements. In fact, in the NFL, the single biggest predictor of success isn’t one’s size, speed, or strength, but rather their vertical jump!

Vertical Jump I Know – So Tell Me How I Can Improve It! Of course the reason you bought this manual was because just like everybody else you’re wondering, “What is the best routine to give me the hops?" People pursuing the answer to that question are responsible for millions of dollars of revenue per year for the athletic performance industry. Unfortunately, a lot of those dollars are wasted. If you’re like most athletes you’re probably confused as to what exactly you should do. What program works best? What’s the “magic bullet”? Should I be doing plyometrics, isometrics, jump rope, sprints, calf raises, 1 million jumps per day, wearing special shoes, weight training, weighted-vests, stretching, taking special pills, doing special exercises to increase my height, wearing ankle weights, or meditation? The list goes on and on and on. I’ve been part of the athletic performance industry for a very long time now and I’ve seen it all. With so many programs, products, modes, systems, gimmicks, and so much information (mostly mis-information) floating around out there its no wonder the average athlete is so confused. What’s even worse is every program promises the moon but usually does nothing more then empty your wallet. You may be one of these guys who has a long list of programs, gadgets, and systems that you either have tried or are going to try. You probably know plenty of people who’ve had success using one or more of the many programs out there. You may have had success at some of them yourself. Or maybe you haven’t? You may have tried other programs without getting anywhere or maybe you’ve just stalled out and want more. You may have asked the question, “well how come xxxx programs worked for him but not for me?” Why did xxxxx program put 10 inches on so and so’s vertical but made me lose 3? Why can so and so jump but I can’t? The truth is, I can’t tell you what the best program is out there because every program or gadget I’ve seen neglects solid training principles. You might wonder what motivated me to write this manual. Well, truthfully, I was originally motivated because I was angry. I get questions everyday from people who have been burned by fast-buck artists selling hype without results. I’ve seen a lot of

programs that seem to do no more then extract dollars from unknowing athletes. These programs are put together without much understanding of how the body works, the science or reasoning behind how the training methods work, and the reasons why a system brings gains if in fact it does. So, I decided to do something about this and help do what I can to spread the knowledge. Vertical Jump Secrets? So what exactly is the secret to a great vertical jump? The truth is, there are no secrets or magical systems. There are, however, solid principles that have been around for ages. The magic lies in the application of established principles. The information you’ll find here comes from a variety of resources compiled over the better part of the last century. The approach I talk about is the same approach used by the best athletes and the best leapers in the world. This includes track and field athletes, jumpers, throwers, olympic weightlifters, football players, volleyball players, as well as a few basketball players. You see, olympic or professional athletes achieve their spectacular leaping ability as a "side effect" of effective training principles and practices. Their approach is multifaceted and their vertical jump improves because of effective training designed to improve various other qualities like strength, speed, and overall explosivness. When these qualities improve the vertical jump just comes along for the ride. Rest assured you won'find any professional or olympic athletes out there searching for t the magic jumping cure because there is none. The vertical jump itself is a feat that coaches from government sponsored programs all over the world have spent over 50 years investigating. The number of readily accessible scientific studies on the VJ is astounding. In other words, if there was a magic bullet that was really going to put 20 inches on anyone’s vertical in 6 weeks then you can be sure that a sport scientist would’ve known about it long ago. Fortunately, these same scientists have produced principles that take the guesswork out of everything. What I’ve done is taken all the information, tested it, and compiled it into a format that “zeroes in” on the vertical jump. It’s taken me many years to compile, test, and implement all this information. The information was out there all along but sorting through it all it has been much like searching for needles in haystacks! This meant spending endless hours, days, and nights not only training athletes but also perusing through countless scientific studies and huge complicated texts in an effort to pull out miscellaneous tidbits of effective information. It also meant listening to feedback and advice from other coaches and observing thousands of athletes over the years. I have spent the better part of 10 years researching and practicing the methods outlined in this book. This has meant using myself, and others, as a virtual guinea pig for the last 10 years. I have to admit I’ve loved doing it all! Experimenting, observing, and putting it all into action is the fun part. My only hope is that this manual will make a substantial difference for you. When I write, it is in a no-nonsense, straightforward manner. I prefer to talk about “principles” rather then “secrets”. What I will do is explain the science involved in the

vertical jump and do so in a simplistic manner complete with real-life everyday examples. My goal is not only to tell you what to do but also to help you understand why you’re doing it. There’s a saying that goes, “Feed a man a fish, and feed him for a day.” “Teach him how to fish and feed him for a lifetime.” What I’d like to do is give you both. I promise when I’m done you’ll have a newfound understanding of this athletic display and how to improve it. I will explain the various training methods you might be familiar with and show you how you can easily determine which method of training or combination of training will work best for you or anyone else at any given time. Then I’ll give you several complete programs. Along the way, I’ll also answer practically every question you’ve ever heard on vertical jump development including gadgets, programs, and just about anything else you can think of. SHOW ME THE MONEY Years ago it was thought there wasn'a whole lot if anything we could do to improve t jumping ability because it relied solely on genetics. More and more we now know this is utter nonsense. The reason why athletes of years past didn'improve is because they: t 1. Didn'train at all t or 2.Didn'know how to train correctly. t Fortunately, those days are coming to a close. I will admit the large majority of athletes and even a lot of coaches still fit into group #2 - They don'know how to train correctly t and a lot of the training they do actually detracts from the qualities necessary to jump high. Yet, in the coming years this will completely change and you can count on it. Once a person understands what is needed for spectacular jumping ability as well as understands the correct training methods and their application - improvement is relatively easy. In fact, near never ending improvement is possible. Let me tell you right now, barring injury and old age, permanent plateaus should never occur providing you know how to correctly train. Regardless of how advanced a person is they can always improve. Now you' probably saying, "That all sounds well and good but how about specific re improvements - What exactly can you give me that I want and what makes you an authority?!" For one thing, since everybody is an individual and responds differently, I won’t promise specific results. I can, however, show you how to progress from wherever your starting point might be. I also don'necessarily believe that in order to be a great coach that you have to be a great t athlete. However, I recently heard a top strongman say “If you' gonna coach someone re to an 800 lb. squat than you gotta know what it feels like to bust your butt for years and work up to an 800 lb. squat yourself”- and I do believe in large part that is true. Science and theory is great but unless you have experience implementing that information there

remain many lessons to be learned. There are plenty of people who really seem to know their stuff yet have never practiced what they preach. However, there are also plenty of naturally gifted athletes who can “walk the walk” yet would have a difficult time coaching because they don'know what its like to be average and have to struggle for t everything. In between those 2 extremes there is an optimal balance between knowledge and personal experience. I don'want to toot my own horn but just so you realize you don'have to be t t born with spectacular ability I can tell you that for me personally, over several years and using a similar but less refined approach than what I' show you here, my vertical jump ll improved from 23 to 42 inches and my forty-yard dash times improved from 5.0 to 4.27 seconds. If you would like to read about my personal story you can read about it later on in the miscellaneous questions section. However, let me say that I don’t consider what “I” did all that important. What is important is how much of that experience and accumulated knowledge I can pass along to develop others like you. Performance coaches are usually limited in the time they have to work with a specific athlete because of all the obligations that athletes have to deal with. Therefore, it’s rare that a performance coach gets to work one on one with an athlete for an extended period of time without outside interference. Even then you can'control what someone does out t of the gym. Yet even with that I expect most people that I work with to surpass their previous 2 years performance improvements within 3 months - and that is usually not too difficult. If you’ve already decided that you’d like to skip the science and background portion and would rather get started right away then you can just skip ahead to the INDIVIDUAL TESTING section and you’re only 5 minutes away! With that said, let’s get to it! Welcome to Vertical Jump 101! Vertical Jump 101 To begin, understand that the vertical jump is basically just a measurement of power. WHAT IS POWER? Power is a side effect of explosive strength and is determined by a simple equation: Power = Force x Velocity To break it down just realize that power and explosive strength simply mean the ability to apply a lot of force in minimal time. The more force you can put out and the faster you can apply that force, the higher your power output will be. In order to understand how to improve power, it helps if we to know how to manipulate each component of the equation, force and velocity.

When we most often think of force, the word strength comes to mind. In mathematical terms Force = Mass x Acceleration. Simply put, if you move a larger or heavier mass or accelerate it more rapidly from point A to point B, you will increase force and subsequently, power output. For our purposes however, no need to get overly technical! It’s easier to think of the force part of the equation as your maximal level of strength. Velocity- is the speed of movement. Simply put, the greater the force or velocity, the higher the power output. It’s really not much more complicated then that. However, before we move on, I’d like to define some key terms that are all interconnected in the quest to improve power and jumping ability. You’ll see some of these terms periodically throughout this book. Limit Strength- is simply the maximum force you can voluntarily apply. Maximum force is typically measured in the weight room with powerlifting being a classic example of a sport that measures maximum force. Actually a better name for that sport would be force-lifting or strength lifting. Because of the slower velocities inherent when lifting a maximal load, powerlifters actually generate less power then athletes in many other sports. Other then arm wrestling and maybe tug of war, powerlifting is also about the only sport where maximum force is measured. Absolute strength- is the maximum force one is potentially capable of applying. As you will learn later it is rare to see our strength potentials fully realized. Relative strength- is the strength per pound of bodyweight Rate of force development- Is the speed at which you can develop force. Starting strength- influences rate of force development and is the ability to instantaneously turn on as many muscle fibers as possible when movement begins to take place. Reactive strength- is also known as elastic strength, reversal strength or plyometric strength. This is the ability to gather and utilize reflexive force during a movement when switching from an eccentric (negative) contraction to a concentric (positive) contraction. Now let’s use a real life example to see what the above complicated terms look like in real life.

WHAT STRENGTH AND SPEED REALLY LOOK LIKE

Athlete A Athlete B

Bodyweight Maximum force or strength without time constraint (squat) 175 lbs 400 lbs. 175 lbs 300 lbs.

Max force put out in the vertical jump (.2 seconds) 200 lbs. 225 lbs.

Look at the chart for a moment and try to decide which athlete would have an advantage in the vertical jump. Assuming both athlete A and B are the same size, you can see how they have very different strength patterns. Both of them weigh 175 lbs. Now look at the next row that says “maximum force or strength without time constraint”. In this example we’re using a maximum squat since it is a slow movement and during a squat we have ample time to apply max force. What we’re describing here is how much force these athletes can put out regardless of how long it takes them to apply that force. A squat is a good example of that. As stated, power-lifting, arm wrestling, and tug-of-war are some sports that measure this. In practically every other athletic event, there isn’t enough time to allow true maximum force to be developed. So in this case you see that athlete “A” reaches a higher peak force and he squats more weight, 400 lbs vs 300 lbs, yet if you look at the 3rd row, the amount of force he can put out in .2 seconds, which is the same amount of time it takes to complete a vertical jump, - Athlete A’s force output is lower then that of athlete B, so he develops force slower. Therefore, athlete A is going to be able to squat more than athlete B, but athlete B is going to smoke athlete A in a vertical jump test. Here’s why: In the maximum squat or maximum force test, the athlete has plenty of time to generate peak force. It takes roughly .4-.7 seconds to develop peak force. On the other hand, movements like the vertical jump inherently occur very quickly, around .2 seconds. So, how much force you can put out in a short period of time is going to determine performance. Don’t get too carried away with this just yet though. Although being able to apply force rapidly is a very useful characteristic, you still need to have enough potential force to tap into for anything to happen. The 6’3”, 200 lb guy with a max squat of 100 lbs is not going to be dunking any time soon, even if he can apply all that force very rapidly. Here is an example of what that athlete might look like on paper when we break his strength qualities down like we did above: Bodyweight Max force (strength) in the Squat 200 lbs 100 lbs Max force in vertical jump 95 lbs

Weak Athlete

You should be able to see that even though this athlete utilizes 95% of his potential force (95 lbs) within those .2 seconds, and has good rate of force development, he still doesn’t have enough potential force to tap into for that awesome rate of force development to do much good. He’s only capable of squatting 100 lbs and even though he’s able to use 95% of that in the vertical jump he’s still only putting out 95 lbs of force, which isn’t going to do a whole lot to get him off the ground! Now here is an example of what an ideal athlete’s maximal force and rate of force development profile might look like: Bodyweight Max force (strength) in the squat 175 lbs 400 lbs Max force in the vertical jump 325 lbs

Ideal Athlete

Even though this athlete is very strong he is also capable of utilizing a large % of that force in a very short time-span, which is ideal. His max squat is 400 lbs. and he’s able to utilize over 75% of his potential force, or 325 lbs., at toe off. 10 Key Performance Qualities With that out of the way let’s now quickly go over 10 key qualities that you’ll be using and focusing on in the programs. Keep in mind that none of these qualities or training methods exist completely in isolation yet they are all important.. 1. Control and stability- Obviously before you can develop maximum power, strength, speed, or anything else, - you need to be able to stabilize and control your own bodyweight and control minimal loads. Control and stability is related to coordination and learning. When it comes to learning a new skill or movement, this should be the initial focus. If you’ve never done a particular movement before it’s best to start off light and slow so that you can learn the correct performance. Once you’ve learned incorrect movement patterns those bad habits can be hard to break so it’s essential you learn how to do each movement correctly. After you have enough experience you can then move on. 2. General Strength- The goal here is to strengthen the muscles involved by adding additional loading. An emphasis should be placed on correct technique with less emphasis on the load. 3. Range of Motion- Range of motion is also known as flexibility. You need to have a certain degree of flexibility in order to prevent injury and optimally carry out the movements in your sport. In the vertical jump, if your ankles and calves are so tight that you can’t achieve the desired range of motion then you risk serious injury. On the other hand, it’s not necessary and could in fact be

detrimental to have the flexibility of a contortionist. It is essential that a minimal amount of flexibility be maintained yet flexibility training won’t do miracles. 4. Maximum Strength- Here the focus is on strengthening the musculature by lifting maximum loads. This greatly enhances a muscle’s maximum force output. If you were to attempt a maximum strength phase without first developing basic conditioning there would be a high risk of injury. To illustrate this, consider an exercise such as the squat. If you’ve never executed a squat before and you immediately go in the gym and try to establish a 1-rep maximum (max out), there’s a chance you’ll injure yourself. A better way is to learn the correct movement performance using low loads and more repetitions (general strength and stability). Pay attention to form and work the correct muscle groups. After you’ve done this, you can gradually begin to add additional loading and advance towards maximal strength training. 5. Maximum Power- Power (force x velocity) is a combination of strength and speed. Virtually any type of training can qualify as power training as long as there is some load that must be moved and you “focus” on moving fast. You can train for power using your bodyweight, your bodyweight with an additional load, lifting light loads, or attempting to move a heavy load quickly. Most of the training methods utilized in this manual will either directly or indirectly impact power. Maximum strength training, due to it’s inherent slower movement speeds, may not produce a lot of power during it’s execution, yet it will boost your strength levels and that will enable you to put out more force which translates into more power. 6. Starting Strength- Starting strength is the ability to instantly apply lots of force at the very beginning of a movement. Try this. Sit back in a chair in a “ready to jump” position. Make sure your butt is touching the chair. Now without rocking backward simply jump up from this dead stop position. This is an example of starting strength and also involves rate of force development. Just like any other strength quality, it can be trained and improved. Your muscles can be trained to fire quicker. 7. Force Absorption Training- This is the ability to absorb and stabilize high eccentric or negative forces and is the first step in developing great plyometric power. In the vertical jump, the eccentric forces are the forces that are created as you execute a quick countermovement or bend down before you jump. You can also see this when you run-up into a jump stop and have to stop or reverse direction in order to transform your horizontal mass into a vertical movement. These movements create a lot of force as the negative movement (or eccentric) causes your muscles and tendons to stretch, which creates a gathering of energy. The forces you gather are then stored in the tendons and muscles, causing your tendons to act like a stretched rubber band. In order to excel at this you first need good levels of basic strength along with muscular control. Being able to absorb energy is a pre-requisite to the next step, which is reactive training.

8. Reactive training- This is the result of being able to “release” lots of stored energy after you absorb it. Reactive training is also known as plyometric training, reversal strength, elastic strength, and static-spring proficiency. They all essentially mean the same thing. Reactive training can account for a significant part of performance in any athletic endeavor. In the earlier example when you sat down and paused on the chair before jumping, were you able to jump as high as you normally do? Probably not. That is because you would naturally reflexively execute a quick ¼ squat, or countermovement, just prior to your jump. The difference between your vertical jump with and without a countermovement is how much additional force you’re getting from reactive contributions. This strength quality is also highly trainable. Certain drills allow you to increase both energy absorption ability and reactive ability. Together they make up plyometric training. This topic will be explained in more detail later. 9. Short response reactive training- This type of training differs from regular reactive training in that the switch from “down” to “up” happens a lot quicker and is nearly completely reflexive with little voluntary input. For example, look at the difference in the time you spend changing direction from down to up in a vertical jump done with a running start vs the time your foot spends on the ground during a max speed sprint. Which one occurs quicker? The quicker the movement, the shorter the response time, and the greater the reflexive force contributions tend to be. Sprinting is the ultimate display of reactive or plyometric training. The movements occur too quick for much voluntary force output or “strain”. In much the same way, executing a uni-lateral one legged jump after a run-up also qualifies as a short response reactive activity because the movement occurs much faster then a regular vertical jump. Certain drills are better for this type of training. 10. Speed of movement/Quickness/Velocity- When you increase the force and power behind your movements and then increase the absolute speed at which you move, you get the best of both worlds. The qualities above will mainly increase the “horsepower” behind your movements. When you combine that with an increase in absolute speed your results will be far superior. How fast can you turn your system off and on? How fast can you move your limbs without regard to force? Can you catch flies with your bare hands? How many times can you tap your feet in place in 5 seconds? Fortunately, you really don’t have to be all that “fast” to improve your vertical jump or even your running speed. There is a blend of physical qualities needed for optimal performance and typically strength and power output per pound of bodyweight are more important then the ability to actually move your limbs fast. However, improving speed of movement never hurts. It can be done by lots of practice being fast and developing an optimal mind to muscle link, better learning to control your muscles.

Strength as the Backbone Let’s go back to the importance of power production and our power equation (Power = Force x Velocity) You should be able to see that you can increase power either through an increase in force or an increase in velocity. However, it is generally accepted that the maximum force you put out is going to be the main determining factor for an increase in power. This is due to many reasons, one being that maximum strength is the foundation for all the other strength qualities such as speed, power etc. Think of this. If you weigh 150 lbs and your goal is to move your bodyweight off the ground as fast and as far as you can - and you are only capable of putting out 200 lbs of force, what is going to happen? If you can only squat 200 lbs then trying to move your 150 lb. bodyweight requires a significant portion of your maximum strength. You’d have to use 75% of your maximum strength just to move your own body. In this situation you’re probably not going to be moving very fast or jumping very high! Another example that may hit home – A space shuttle with a 4 horsepower motor surely won’t make it out of the earth’s atmosphere in a hurry! Being strong just makes things easier. In the above example if you were able to put 350 lbs of force into the ground then moving your bodyweight (150 lbs) requires a lot less of your maximum strength so you have a larger strength reserve to work from. In this case you would only have to use 30% of your max strength to move your body and 30% of your maximum can be moved with greater speed and power then 75%. Make sense? Another major consideration is that it is easier to increase force then it is to increase velocity. That is, the ceiling on maximal force or strength improvement is much lower then the ceiling on pure levels of speed. Speed has much more genetic limitation than strength does. It’s not that pure velocity or speed of movement can’t be increased, but due to genetic factors, such as body structure, neural factors, or the number of fast twitch fibers one has, speed improvement is much more limited. To illustrate this, many people who lift weights over a period of several years can easily double their strength in exercises such as the bench press and squat and thus double their levels of force. Yet in tests of pure speed of movement, such as the ability to tap the feet in place as many times as possible in 5 seconds, or to tap your finger as quickly as possible, improvement is much more limited. The good thing is that in most athletic events, speed of movement does not exist in isolation, but rather is strongly related to force. Even in what would be considered a pure test of speed, the 100-meter dash, it might come as a surprise that elite level sprinters don’t move their limbs much if any faster then regular folks do! Anybody can get on their back and cycle their legs 5 times per second. Rather, it’s the amount of force a sprinter puts into the ground with each foot strike that propels them down the track at lightning speed. Each footstrike does occur quickly, yet the amount of force per footstrike is key.

When executing a vertical jump, people do change direction during their countermovements (transition from down to up) at different speeds, but in much the same way, everyone pretty much straightens their legs at the same rate of speed. The main determining outcome in the vertical jump isn’t how fast your legs move, it’s the amount of force relative to your bodyweight that you are able to put into the ground. With that said I can now give the basic vertical jump equation: Spectacular vertical jump = High levels of force + High speed of force application That is all there is to it! Any improvement in the vertical jump comes about through increasing one or both of those factors. The goal of this entire program is to increase your vertical jump by increasing both of those factors. If velocity and rate of force development stay constant, yet force levels, or strength levels, go up, you can also expect your power, and thus leaping ability, to improve as well. So how do you increase levels of force without negatively impacting the speed at which you apply that force?

Can weight training make you slow?
As mentioned before, the application of force in a movement like the vertical jump occurs very quickly, somewhere around 200 milliseconds (2 tenths of a seconds). It generally takes around 400-700 milliseconds (4 to7 tenths of a second) to apply max force. Therefore the body must not only be able to apply a lot of force, but also be able to apply it quickly. One problem with weight training is that bodybuilding programs have dominated the programs of athletes everywhere and many athletes are trying to make “athletic” gains by following weight-training methods designed for bodybuilders. Not that I have a single thing against bodybuilding but bodybuilders should train for bodybuilding and athletes should train for athletic performance. Training programs based upon bodybuilding methods often include a high number of repetitions performed to exhaustion with a focus on keeping the muscle under tension for prolonged periods of time. Such programs mainly develop muscle size rather than improved force or rate of force development. Over time such programs can indeed make you slower by negatively impacting your ability to apply force at high speeds. Our goal is to become stronger while directly increasing transferable strength into power and increasing the speed at which we utilize our strength. In fact, we actually want to become stronger and faster at the same time! To do this requires strength training designed for athletic performance. When you lift weights, you must use fairly heavy loads and apply force against the resistance quickly so that your body learns to generate maximum force quickly. This recruits more fast twitch muscle fibers and trains the nervous system to engage more

muscle fibers. This makes the strength derived from the program directly transferable to our goal, which is to get you up in the air! Do I have to strength train? For those of you out there who are not keen on lifting weights and wonder if you have to strength train to improve your vertical jump the answer is, “no of course not”. I’ve included several very effective jumping programs that can be performed without weights just for these people and I know these programs are very effective on their own. It' been said that the main reason many trainees avoid leg training is because it hurts too s much. Maybe they' right. After all, leg training in the gym with heavy iron can be re painful. I’m not going to try and sugar coat anything. But I’ll also tell you that most of you out there are not going to come close to reaching your potential unless you do some strength training somewhere along the way. Now, some of you, especially those who are naturally strong, will be able to gain a significant amount on your vertical jump without ever even lifting weights. Sometimes even a VERY significant amount. However, eventually there will come a time when your gains will stop and the only way to further your improvement will be to increase your base of strength. I want everyone to benefit here. If you have only a very limited amount of time and don’t have access to a weight room I’d encourage you to give it your all on one of the non-resistance training programs. For those of you who still want to strength train but don’t have access to a weight-room I’ve also included a routine that will increase your strength using a variety of unique bodyweight exercises which you’ll find challenging. For everyone else, virtually all you’ll need is a weight room with a squat rack and a barbell! Training Loads Before discussing the exercises I’d like to address the loads used for strength training exercises. Load can be defined as the % of your 1-repetition maximum that you use in a movement. So, if you’re training with a 50% load and your max 1 repetition squat is 200 lbs, you would be using 100 lbs (50% of 200=100). Many people are confused as to how heavy the load should be for optimal power development. Some people say, “Use light weights with more speed.” Others say “Train with heavy weights or go home.” Still others say, “Use Olympic lifts.” It can get very confusing with all the varying opinions out there. The truth is, there is a time and place for ALL types of loading. However, different loading percentages have varying effects on the body. Following is a list of the different training loads and what they’re best utilized for: Speed training (0-25% of maximum): Here speed is maximized while power output and force are low. This training zone can be used to train speed of movement and rate of force development but has little benefit for improving maximal force production. Training in this zone could be considered similar to the effects of performing plyometric type training. With resistance exercises this training is more effective when you can project

either the load or your body in the air. Exercises such as jump squats and medicine ball throws are best suited for this training load. Speed-strength (25-50% of maximum): Here you’ll find a compromise between speed and strength with speed and rate of force development being the dominant qualities affected. If you train in this zone you will get gains in force development and speed, however the gains in maximal force production will be marginal. Strength-speed (55-80% of maximum): Here you’ll find the best compromise between speed and strength with strength (maximal force) being the dominant quality affected. Training in this zone will give you gains in both rate of force development and strength with a marginal gain in speed. Maximum strength (80-100% of maximum): Here strength and force are maximized. Now, which loading zone should you spend most of your time in? The answer to this is fairly complicated. First, remember the power equation. If your goal is to improve the “Force” part of the equation as quickly as possible then there is no question about it, using a heavy load (80-100%) will strengthen your muscles much quicker and will allow you to get more out of the time that you spend training. The problem with this approach is that if you were to only lift heavy loads 100% of the time while doing no other types of training or sports specific activity, you obviously wouldn’t be doing a whole lot to improve rate of force development and speed. Thus, over time those qualities would suffer. You would undoubtedly become very strong, but you’d eventually sacrifice some speed as well. However, you also have to consider the training effect that comes from other activities that you do outside the weight-room. If you’re also playing a sport requiring speed (basketball), or doing any running or plyometric work, you’ll be getting plenty of stimulation in the speed aspects as well. This occurs just from participating in and practicing your sport. So, for the majority of people who engage in sports training as infrequently as 2 times per week, there isn’t a whole lot of need to try to duplicate this work (speed and rate of force development) in the weight room. We also have to ask ourselves if training for speed in the weight room is as effective as other methods of speed training such as sprinting, plyometrics, or even playing a sport. Consider the effects of performing a 60-meter sprint vs using light weight training for speed. The movement speeds of a sprint are far faster then anything that can occur in the weight room. Lifting weights should improve your ability to apply more force, which you can then take advantage of and use in the sprint, yet trying to duplicate the speed of the sprint with a weight room activity is impossible. Since you can develop the velocity and rate of force development components through jump training itself, your priority in the weight room should generally be to develop your strength qualities. This is best achieved through the use of ‘limit’ strength exercises such as squats. This is also the same reason most top sprinters, jumpers, and other track

athletes spend the majority of their weight room time training to improve maximal force production by lifting weights in the 80-100% bracket, with a smaller percentage of the total volume dedicated to performing exercises in the 55-80% bracket for power and rate of force development (force + speed together). Most of you should spend the majority of your weight room time training in these 2 zones as well. Doing so will lead to quicker increases in maximal force and strength, and better economize your training time. However, you will also see the programs I’ve designed are customized to the individual and sometimes do lend a portion of weight-room time using lighter loads with quicker speed of execution. Yet, for the most part, those qualities are addressed using other training methods such as plyometrics. Specific vs General Strength Now another question that is often asked is, “Do specific weighted activities in the weight room that mimic the sporting activity carry over into increased performance better then general strengthening movements?” In other words, if our goal is to run faster, would it be better to perform a sprint running with a heavy loaded sled rather then increase leg strength through squatting? Or, if our goal is to hit a baseball harder why not just train with very heavy bats all the time instead of increasing general upper body strength? Well the answer to this question is fairly complicated. There is a place for general loaded movements, such as weighted jump squats. However, one needs to be careful about trying to get too specific and use too much loading in technical movements because when we add additional loading to a sports movement we can negatively affect the movement pattern. Load a movement too close to a technique-crucial sports movement pattern and you risk changing the technique of the athlete. You do not want to do this, as usually the loaded technique is significantly different than that of the unloaded technique. For example, say you try to train for increased sprinting speed by running with a heavy weighted sled all the time. If the weight is too heavy it will cause negative changes in your sprinting technique. Not a good thing. Since you obviously don’t sprint in competition with a weight attached to your body then the technique required for doing so wouldn’t do you much good if you’re a sprinter! The same thing occurs when baseball players use high volumes of very heavy bats in their training. The technical differences can throw off technique once the player returns to a regular bat. When used short term the heavier bat can enhance batting proficiency by creating a contrast effect. Yet use it all the time and it will detract from technique. Not to mention, swinging a heavy bat, running with heavy weights, throwing a weighted punch, or other specific loaded activity won’t have near the effect of increasing the maximal strength of your muscles like basic barbell exercises will. The goal in general strengthening movements is to increase the strength of the muscles involved in the movement and their order of muscular recruitment, not necessarily

duplicate the exact task. In other words, when you squat to develop maximum strength there is no need to perform it in the exact same manner and stance that you perform a vertical jump. To increase general strength, basic movement patterns should be chosen that stimulate the same muscles as the desired sporting activity. These exercises do not have to mimic the movement. This ensures there is no risk of ruining technique through heavy loading, yet you still get the adaptive stress. The squat is a perfect example of this. An example of a good exercise that can be loaded is a jump squat. When performing general strengthening exercises such as the squat, the technique is not so much like the vertical jump that the body compromises technical abilities. However, these also need to be utilized along with un-weighted jumps, which you’ll definitely be doing plenty of. When looking at jump squats vs squats, if the athlete could improve faster by increasing his general muscular strength, there is no contest, - regular squats and other strength development methods will offer substantial advantages. If the athlete already has plenty of general muscular strength then jump squats would be useful, but they aren’t as effective as a complete program that addresses development through multiple angles. WHY THE NEED FOR FULL RANGE MOVEMENTS?? Along these same lines many people will ask, “Since during a vertical jump one only descends into a ¼ squat position, then why should they do loaded squats with a full range of motion going past parallel?” Again, realize the purpose of strength training is to improve the general strength of the muscles involved. The fact is that a full deep squat is better at strengthening all the muscles involved in the vertical jump, despite the fact that one is capable of using much more weight in a ¼ squat. A full squat fully activates the muscles of the quadriceps and also strongly engages the hamstrings, glutes, and even calves. Not only does this build strength, but it also keeps the lower body in developmental balance and helps prevent knee injuries and muscle strains. A ¼ squat doesn’t strengthen the muscles of the posterior chain nearly as well and also puts a lot of stress on the tendons of the knee. However, there is a time when the ¼ squat can be effective. That is after a base of strength has been developed. The ¼ squat can then be used for short periods for further enhance strength development. If I could throw out one piece of advice to every young athlete in the world it would be, “Do squats and do them full and deep!” IMPROVING FORCE AND INCREASING STRENGH – EXERCISES OF CHOICE For our purposes, the basic barbell squat, the “king of all exercises”, is the exercise of choice. The barbell squat trains nearly all the muscles involved in the vertical jump and strength derived from the squat translates very well into increasing the Force part of the power equation. In fact, some studies have demonstrated one’s relative strength in the squat, or strength per pound of bodyweight, is the single biggest determinant in the vertical jump! (Chu)

Another exercise we’ll use heavily in one form or another is the deadlift. The deadlift works the muscles of the posterior chain (hips, hamstrings, and lower back) like no other. These muscles are not only very important for power production but also tend to be the weak link in the chain for many athletes. You’ve probably heard that a chain is only as strong as it’s weakest link. The prime muscle contributors to the vertical jump are the quadriceps, glutes, hamstrings, calves, and lower back. Even if your quadriceps are very strong if your posterior chain, or to put it more eloquently, your backside, is weak; - your performance will be severely limited. By strengthening both the squat and the deadlift we can ensure that ALL the muscles involved in getting you off the ground are strengthened optimally. HOW TO TRAIN Your strength will improve as a result of creating high-tension levels in the muscle, which is directly related to the training method employed. Your ability to generate maximum strength depends on the size of the muscle involved, the capacity to recruit or use your fast twitch muscle fibers, and the ability to coordinate all of your muscles involved into action. The ability to recruit your fast twitch fibers depends on training content, in which heavy loads and explosive power training should dominate. Improving your muscle coordination and synchronization depends on learning, which means performing many reps of the same exercise. High-tension levels in the muscle are necessary to create increased levels of force and strength. So how does one go about creating a lot of tension in the muscles and thus improve force output? The answer is simple. Lift a moderately heavy to heavy load in good form with as much force as you can muster! When lifting a heavy load, even though you might be pushing as hard and as fast as you can, the weight probably won’t move all that fast. Each muscle cell has to contract forcefully for fairly long periods of time, therefore your muscle cells are subject to greater amounts of tension which is necessary to create strength. Lifting a lighter load with more speed doesn’t subject the muscle cells to the prolonged levels of high tension, so, although useful for increasing other aspects of performance like increased rate of force development, won’t have near the effect of heavy weights at creating maximum levels of useable strength and force. Won’t Getting Bigger Muscles Slow Me Down? If any of you out there are worried about becoming overly “muscular” or getting too big from weight training, first I might ask what are you worried about? Don’t you know the opposite sex loves hard bodies?! All kidding aside you definitely don’t have to develop huge bodies and large muscles to become significantly stronger. Research shows that strength training methods typically bring a 3:1 ratio of strength vs. muscle mass increase. This means if your body mass increases 10%, your strength should increase 30%, which makes your gains purely functional.

Say you weigh 150 lbs right now and can squat 200 lbs. Your bodyweight is 75% of your squat. Let’s say you gain 15 lbs of bodyweight bringing you to 165 lbs while at the same time your squat increases to 260 lbs. Now your bodyweight is only 63% of your squat! This means your relative strength, or strength per pound of bodyweight, has improved substantially and your performance will also improve dramatically. The take home point is to not be afraid of gaining muscular bodyweight. Can’t I get Too Strong? Remember that the vertical jump occurs in about .2 seconds and it takes at least .4 seconds to develop maximal force. Up to a certain point strength is beneficial for power development. However, if you were to do nothing but train for maximum strength for months or years on end there will come a time when your bodyweight and strength increases above and beyond the speed at which you can apply useable force. This is why it’s important to pay attention to your strength per pound of bodyweight or relative strength. So you may ask, “What is the point that additional strength per pound of bodyweight is of no use for vertical jump improvement?” This will vary from person to person and depends on many factors, the biggest probably being your plyometric capacity in comparison to your maximal strength. Fortunately, there are tests to determine this, which I’ll go into detail on later. One simple thing you can do is pay attention to how quickly you can move heavy loads. You want to be able to lift relatively fast and explosively with a relatively high % of your maximum strength. To give you an idea, Fred Hatfield set a world record squat of over 1000 lbs. What’s really amazing is his squat attempt took him less than 3 seconds to complete from start to finish. With that kind of explosiveness it’s no wonder he at one time had a vertical jump around 40 inches even without any specific training for it! You should be able to complete your maximum lifts in 4 seconds or less from start to finish. If it takes you longer then that any extra strength you gain won’t be very useful when performing a high-speed maneuver like a jump. To make it easier we can say that strength training can be detrimental to your performance when: 1. Increases in strength fail to yield improvements in leaping performance 2. When strength increases are only achieved through a large increase in body weight and hence do not increase the power to bodyweight ratio. 3. When the training frequency required for an increase in strength compromises the time needed for sport specific activity. 4. When extra strength can only be gained by increasing the duration of a max lift above ~4 seconds. We can also do a strength analysis of some of the most powerful and explosive athletes around, sprinters. Upper level sprinters are universally very strong for their bodyweight. In fact, at bodyweights anywhere from 160 to 200 lbs they will routinely squat a

minimum of 400 lbs on up to 600 lbs! With this knowledge it’s probably safe to say that unless you’re squatting 2.5 to 3 times or more your bodyweight you could still benefit from increased strength! THE CNS – YOUR MUSCULAR COMPUTER The next step towards maximum strength and force involves manipulating the central nervous system (CNS). You might know that the central nervous system basically connects your brain through a neurological network to all of your muscles. Your central nervous system is like the computer that controls all of your muscles. Your mind is like a central computer and your CNS carries out what you tell it to do. When you decide to move in any fashion your brain sends a message telling your muscles to contract. The more efficient your CNS operates, the more muscle cells you can use, the better you can control your muscles, and the greater your potential levels of strength and force development. Imagine if you could supercharge your CNS so that the signals you send your muscles are sent faster and with more precision? Fortunately you can impact this through correct training. Step one is optimizing the mind/muscle connection and learning how to activate a large number of fast twitch muscle fibers. Through correct training methods - using the correct loads, speed of force application, and rest intervals between sets; you will be able to supercharge your central nervous system and be able to call upon and use muscles you’ve never used before. You’ll also increase your muscular control and coordination and move not only in a powerful manner but also an effortless manner. Before talking about what to do to improve this aspect of your performance let’s talk about what not to do! A Word On Fatigue This training program does not call for repetitions of weight training, drills, or plyometrics to be performed under conditions of muscular exhaustion or extreme fatigue as in bodybuilding or endurance training. Doing so would inhibit the central nervous system and dampen FT fiber recruitment and basically amount to a waste your time. Imagine trying to run as fast as you can for 30 seconds and then having to perform a maximal vertical jump. Try it sometime if you haven’t! You’ll probably find you don’t get very high. The reason for this is that optimal speed and power can only be maintained for about 6 seconds. After this, lactic acid begins to accumulate in the muscles and this is what gives the “burn” feeling after a long set. This lactic acid interferes with the contraction of the fast twitch muscle fibers. If you train with elevated lactate frequently enough you will interfere with power production as your muscles adapt to endurance. If you’re training with higher repetitions and getting a humongous “burn” from your training, then you’re probably not able to use enough weight or put enough intensity into the exercises you’re doing to create the adaptations or affect the muscle fibers that you want. Likewise, when performing plyometric drills, some of the goals are to increase the efficiency of the nervous system, improve rate of force development, and increase

muscular recruitment. To accomplish this, the rep range needs to be fairly low so that each repetition can be performed with nearly 100% intensity and power. Some programs out there use repetitions of 100-500 per exercise! This is training muscular endurance, not muscular strength or power! Any gains made on these programs are made in novice athletes mainly because technical abilities were lacking. If you think training for endurance is all well and dandy realize the average marathon runner has a vertical leap of about 12 inches!! Any high volume endurance training you do will tend to interfere with power development. The body can be trained to be fast, quick, strong, and powerful at the same time, or it can also be trained to have a lot of endurance. It does not do both (gain power and endurance) at the same time very effectively. I realize that athletes do need to maintain a level of conditioning but it needs to be the right kind of conditioning that develops the endurance specific to the sport. There definitely is a time and place for the right type of conditioning and endurance training but unless you’re very out of shape ideally you should not try to train for vertical jump improvements along with endurance at the same time. If you want to train for strength and power in a workout then focus on that. If you want to train for conditioning and endurance don’t try to do it with your strength and power program by doing high reps of exercises designed to increase your power. Ideally you should focus on boosting your power and jumping capacities while maintaining general fitness. Once you have your power capacity in place you can then focus more on endurance and conditioning. More On Specific Endurance Another reason you don’t want to train for endurance in power related events until you first have developed the power you want is because training endurance won’t transfer into increased maximal performance, it will only increase the length of time you can maintain a sub-maximal effort. One of the best ways to improve your power endurance is to simply increase your maximum because when your maximum goes up any given percentage of that maximum becomes easier as well. I know that was a mouthful but let me give you an example. If you have a 30-inch vertical jump and you increase that to 40 inches, you will then be able to perform more consecutive jumps at 24 inches then you could before because 24 inches goes from being 80% of your max to 60% of your max. A 60% effort can be maintained with less effort than an 80% effort. However, performing 100 consecutive 24-inch vertical jumps won’t take your vertical jump from 30 inches up to 40 inches, it will only improve the number of lower intensity jumps you can do before fatigue. Would you rather be able to vertical jump 24 inches 100 times in a row or would you rather be able to vertical jump 40 inches one time? I would assume you want the latter so I suggest you train for that while maintaining a minimal level of conditioning. In much the same way, performing a drill of jumping as high as you can in place 50 times might improve your jumping endurance, but unless you’re de-conditioned it won’t do much to improve the height you can jump one time. Elite level 100-meter sprinters don’t

actually develop their speed training over 100 meters. They develop speed training at 10, 30, and 60 meters. After they have built up the necessary speed in these shorter distances they then train to extend that speed out to 100 meters. The point to take home is that you should develop your vertical jump to the max and pay some attention to conditioning but don’t do a high volume of endurance training until your power is where you want it to be or until you must prepare yourself for your sporting season. Now back to how this relates to the topic at hand, the central nervous system. You can get maximum activation of your central nervous system through factors such as concentration, motivation, taking enough rest between sets, and training in the correct repetition and loading bracket without creating the wrong kind of muscular fatigue. With each and every repetition you will also improve muscle coordination and synchronization. This translates into an overall more efficient movement. Jumping With a Weighted Sled The next step to manipulating the CNS (central nervous system) is to prevent it from antagonistic muscle contraction and muscle recruitment inhibition. I know that probably sounds complicated but it’s really easy to comprehend. An antagonistic muscle is the muscle opposite the one contracting. For example, if you’re doing a pulling movement the antagonistic muscles would be the pushing muscles on the opposite side and vice versa. If you were doing a bicep curl, the antagonistic muscle would be the triceps, which is the muscle on the back of your arm. Normally, when contracting a muscle, some tension is maintained in the antagonist muscle and this decreases the force application of the working muscle. Try this out for yourself. Try to do an arm curl while also contracting your tricep muscle as hard as you can. When you perform a high-speed movement with a lot of force and power your body will exactly that to a certain extent. What happens in this situation is your master controller (CNS) tries to work against you by “pushing” while you “pull”. It’s largely a protective mechanism to prevent you from injuring yourself and also occurs because you haven’t trained your CNS to relax completely when moving at high speeds. This is like running with a weighted sled attached to you. Any weight you can remove from that sled will instantly make it easier to go the same speed or in the case of the vertical jump, make it easier to go higher. For another simple example of this, tap your hand on a desk as fast as you can for 10 seconds straight. Did you find it difficult to avoid tensing up? If so, that’s because you were unable to completely relax in between taps. Being able to put out a lot of force is very useful but being able to relax completely is just as important for any high- speed movement and the vertical jump certainly qualifies here. In fact, the key characteristic of world-class sprinters is their ability to completely relax between strides. Lower class sprinters will maintain lots of tension in the antagonists yet top sprinters relax completely which enables them to go faster. Training methods such as energy absorption training and reactive methods done at high speed with an emphasis on relaxation can teach your system to eliminate antagonist contraction.

The end result after implementation of these training methods is a very smooth and powerful contraction of the muscles involved and a relaxed flow to the movement. Eventually, when you apply maximum force at high speed the antagonist muscles are coordinated in such a way that they don’t contract to oppose the movement, which automatically means increased performance. Have you ever noticed how most of the best jumpers, or athletes in any field, appear to be so relaxed and perform with such ease and grace that they make what they’re doing look easy? They leave the ground smooth and relaxed without any unnecessary muscle involvement. This is just one of the effects of an efficient nervous system. Contrast this to the guy with a 15-inch vertical jump who looks like he’s about to have a conniption when he jumps!. Programming Your Master Computer Now the most important part of CNS manipulation. The nervous system normally prevents you from fully activating all of your muscle motor units in a particular task. Yep, not only can it make things difficult when you want to move effortlessly, it also prevents you from exerting all of your potential force in a given movement! If you were to take a muscle and hook it up in the laboratory to a special measuring device you can accurately determine how much force that muscle is potentially capable of exerting. This figure is the definition of absolute strength and is the maximum amount of force you could apply if you were able to voluntarily contract all motor units in a t muscle. Potential is big here because it turns out most folks aren'able to use anywhere near the potential force their muscles are capable of exerting. In fact, untrained folks might only be able to voluntarily put out around 50% of their potential absolute force in a given task. Trained athletes with years of experience can approach 85-90%. The nervous system inhibits you from using all your potential strength in 2 ways. First, exerting all your voluntary force and getting all your muscle motor units turned on requires strong and efficient neural (electrical) signals emanating from the brain and spinal cord. These signal your muscles to turn on and exert force. The more efficiently this process works the more muscle fibers you can fire and the quicker you can turn your muscles off and on. However, the reason your body makes this difficult is because if you were able to voluntarily turn on all your muscle motor units you' stand a good chance of d ripping your muscles right off the tendon! Therefore, the body naturally “protects” or inhibits you from doing this. However, it is possible to condition your body to push this natural inhibition back with proper training and this is why trained athletes are able to use more of their potential ability than sedentary folks. This also partly explains why some small guys are exceptionally strong and powerful, while some large guys are weak. Second, and this example will be more specific to jumping, eccentric stretching brought on by plyometric activity (which leaping inherently relies on) causes the muscles and tendons throughout your lower body to stretch and quickly store energy in the tendons like a spring. When this energy is released it causes a reflexive, or involuntary contraction that can increase force output more than double what you’d get through voluntary force output. The faster the speed and more forceful the stretch in

reactive/plyometric activity the greater the level of force in the subsequent contraction which is why we instinctively use plyometric contractions in just about everything we do (rearing the arm back to throw, dipping down prior to a jump etc). However, most are not able to fully take advantage of this because the muscle/tendon complex has proprioceptors. The job of a proprioceptor is to monitor the degree of the eccentric stretch and prevent overstretching and injury by basically shutting the muscle down when the stress or stretch is too great. The problem is, sometimes these proprioceptors kick in sooner than you would like and they inhibit you from taking full advantage of your reactive, or plyometric capacity. So, they prevent you from injuring yourself but also prevent you from fully utilizing all of your potential power output. To illustrate this for yourself perform a simple vertical jump from the floor (down and up) and measure the height you jump. Next, find some aerobics step boxes about 6-8 inches high and stand on one, step off, and as soon as you hit the ground immediately jump as high as you can and again measure the height you jump. The large majority of you will notice you can jump higher when stepping off the box then you can from the floor. This is because when you step off the box you increase the rate and the force of the eccentric stretch in your lower body muscles and tendons at ground contact - so your muscles responded with a stronger reflexive/reactive contraction, which caused you to jump higher. Notice you didn'have to really try any harder, the added force just kind of t came reflexively, which is what plyometric strength is all about. Next, keep increasing the height of the boxes until you find the point where your jump after ground contact begins to decline. For some this might be 8 inches, for others 15, for others 25 inches or more. Wherever that point may be it signifies the point where the force of the eccentric stretch begins to cause your proprioceptors to kick in and cause muscular inhibition. Fortunately, this can be trained and improved - an increase will translate into increased jumping prowess. Examples of Superhuman abilities Under extreme circumstances, such as life and death situations, adrenaline causes the nervous system to send stronger then normal electrical signals to the muscles and proprioceptor inhibition is largely removed. This allows nearly all the muscle motor units to turn on and nearly 100% of one' strength and force potential can be utilized. Have you s ever heard stories of 110 lb women lifting cars off of children? Have you ever been chased by the cops, an attack dog, or anything else that scared the living daylights out of you and noticed how much faster you ran!? Have you heard stories of people on PCP or other drugs being able to bust out of straight jackets and handcuffs? These are all good examples of manipulation of the nervous system. Because of the apparent life or death situation, inhibition is removed and all the muscle fibers are able to fire with the outcome being apparent superhuman strength, force, and power. Unfortunately, the people who accomplish these tasks often end up hurting themselves because of what I described above. The muscles are potentially strong enough to rip the tendons right off the bone!

Here' another less dramatic example of this. Have you ever noticed how you can jump s quite a bit higher and run faster whenever you' feeling really energetic, fired up, or re maybe even anxious? Most players notice they can "get up" better or move faster in a game or even prior to a game when their adrenaline is pumping. This is because the increased adrenaline allows you to fire more muscle then normal and thus produce more force and power. One of the main objectives of this program is to learn to eliminate CNS inhibition without needing an adrenaline surge or life or death situation to do it! Imagine what would happen if you went from using 50% of your force capacity and you suddenly increased that to 100%? The results would be very, very impressive to say the least! Improving Strength – What will that give you? The raw force and strength gains you make through a solid strength program can greatly enhance power development alone. Remember again Power=Force x Velocity. After an effective phase of properly designed strength training, even in the absence of additional sports specific activities, your Force part of the equation should go up substantially, and your Velocity should stay the same or possibly even increase. However, your power will increase substantially more if you also focus on methods designed to increase the rate of force development and reactive strength, which allow you to apply your force in a shorter time span and also increase the velocity side of the power equation.

IMPROVING RATE OF FORCE DEVELOPMENT AND VELOCITY
Before I get into describing specific means of improving the rate of force development I’d like to mention again that even when you perform strength training with heavy loads you can also significantly impact your rate of force development as well. A high speed of contraction against a heavy load will not only help accomplish all the processes regarding the nervous system I described above but it will also train your CNS to quickly recruit FT fibers resulting in the best of both worlds - more force and improved rate of force development. Can I really get both stronger and faster in the weight room? Again, because of the stereotype that weight training builds muscle bound athletes who can’t move, and perhaps because many athletes are still under the influence of old-time coaches who think weight training automatically makes people slow; many people are under the misguided assumption that one can’t become both stronger and faster at the same time through weight training. The fact is there are correct and incorrect methods of training. Bodybuilding won’t do much for your speed and power but plenty of athletes have been using weights to not only get extremely large and strong but extremely quick and powerful as well. Consider Olympic lifters. Chances are you probably don’t know a whole lot about Olympic lifting other then what you see during the Olympic games on television, and even then the networks typically only show the heavier weight classes.

Olympic Lifters and Explosiveness The Olympic lifts consist of the clean + jerk, and the snatch. In the clean and jerk, the weight is lifted from the ground, to the shoulders (called a clean), and then overhead (the jerk). In the snatch the weight is lifted from the ground all the way overhead in one motion. The Olympic lifts inherently have to be executed quickly and require a good blend of force, speed, and thus power in order to be performed correctly. Because of this, performance in the Olympic lifts correlates quite strongly with other tests of power. In fact, due to the nature of their training, Olympic lifters are some of the most powerful athletes in the world! In a test conducted at the 1968 olympic games the lifters were actually faster then sprinters in a 25 meter dash! Well how about their vertical jumps you might ask? It is well known in the strength and conditioning community that Olympic lifters consistently have very high vertical jumps relative to their size. It' not uncommon s to see lifters weighing nearly 300 lbs. with verticals of 35 +! The same thing can be said for high level shot-putters and throwers. In fact, if you take a true vertical jump from a standstill without any run-up, these folks tend to vertical jump as well or better then any group of athletes. The world record standing broad jump is actually held by a thrower weighing close to 300 lbs! Unfortunately, basketball players aren'anywhere close to this t level of explosiveness. The average NBA 1st round draft pick has a standing vertical of something like 28 inches Now I’m not going to try and turn anyone into an Olympic lifter and I’m not saying their training is perfect for what you want, but this is just an example to illustrate a point! The point is that if you train properly in the weight room with a program designed to increase your power production you definitely can become both very strong and very explosive at the same time, even without much jump training. When jump training is added to a properly designed resistance program the results are magnified even more. When you’re lifting weights, all you have to do is pay attention to how fast you attempt to lift the weight. There are some movements that can be dangerous if you try to do this, but whenever possible try to control the load during the negative portion and execute the positive portion with as much speed as possible. Doing so will allow your muscular system to adapt to quickly recruiting the fast twitch muscle fibers. If you’re lifting a heavy enough load the weight probably won’t actually move all that fast but your force application against the resistance should still be as quick as possible. One thing you can do to help achieve this explosive attitude is to maximize your concentration and motivation prior to each set. You don’t have to go into a manic rage in the gym or anything but try to get focused up prior to each set of every exercise you do!

Rate of Force Development
So how does rate of force development fit into the picture and why is it so important? You’ve probably seen the following scenario many times. There are some athletes who are very strong under the iron, with a very large muscle mass, yet be unable to effectively display their “potential” power due to an inability to contract their strong muscles in a very short time. The typical muscle bound athlete comes to mind. Usually when you see

someone like this they train for maximal size or maximal strength like a bodybuilder or powerlifter, rather then maximal power like a thrower, Olympic lifter, or jumper. How Do We Increase Rate of Force Development? The methods used to increase the rate of force development are numerous. In the weight room there exists a wide variety of lifts designed for this task. Exercises such as weighted jump squats and other explosive lifts that are done with an emphasis on speed really hone in on the “force development” aspect. As mentioned above, many exercises done in the weight room can increase both maximum levels of strength and rate of force development at the same time, as long as you emphasize speed of contraction. Outside the weight room certain plyometric type drills and other bodyweight exercises are inherently good at improving your rate of force development. All of these methods have a few things in common. They are inherently explosive and performed with high velocity or speed. The advantage of explosive, high velocity power training is that it trains your nervous system to fire quicker by shortening the time it takes your muscles to contract, especially the fast twitch muscle fibers. Training in this fashion also improves your mind to muscle link giving you better muscular recruitment ability. Strength training by itself stimulates a high recruitment of fast twitch muscle fibers leading to increased levels of force. Explosive and high velocity movements increase the speed at which your muscle fibers can contract. Combine them together in some fashion and you get power improvements across the board.

Plyometrics No discussion on vertical jump training would be complete without a section on plyometrics. Before we get into discussing various plyometric drills and how they work I’d like to first address their history. Plyometrics is the term now applied to exercises that have their roots in Soviet training methods. This method was originally known as “shock” training and was invented by Yuri Verkhoshansky in the Soviet Union. Interest in this jump training increased during the early 1970s as East European athletes emerged as powers on the world sport scene. As the Eastern bloc countries began to produce superior athletes in such sports as track and field, gymnastics, and weight lifting, the mystique of their success began to center on their training methods, which consisted of plyometric training. The actual term “Plyometrics” was first coined in 1975 by Fred Wilt, an American track and field coach. Based on Latin origins, plyo + metrics are interpreted to mean “measurable increases”. These seemingly exotic exercises were thought to be responsible for the rapid competitiveness and growing superiority of Eastern Europeans in track and field events. Although thought to be secretive and exotic, originally plyometrics consisted of only 2 rather simple exercises, - “depth” jumps and “shock” jumps. A depth jump entails jumping or stepping off of a bench or object and immediately jumping up as high

as possible at ground contact. A shock jump is pure energy absorption training and consists of jumping off of a very high object and simply landing and absorbing the impact. After plyometrics were given their now common name, coaches began to lump all types of hopping, jumping, skipping, and bounding drills in with the original plyometrics. Plyometrics rapidly became known to coaches and athletes as exercises or drills aimed at linking strength with speed of movement to produce power. They became essential to athletes who jumped, lifted, or threw. During the late 1970s and into the ' those in 80s, other sports also began to see the applicability of these concepts to their own movement activities. Throughout the 1980s, coaches in sports such as volleyball, football, and weight lifting began to use plyometric exercises and drills to enhance their training programs. So How Do They Work? Plyometric drills are utilized to bridge the gap between force and explosive power and increase reactive strength. Reactive strength fits in nicely with power development. It is also known as plyometric strength, reversal strength, and elastic strength. You can think of a reactive movement as a “spring-like” movementt. The drills are performed to develop force by a quick loaded eccentric, or negative contraction. This contraction causes a stretching of the tendons and also increases muscle recruitment. Basically the muscle cells lock up as the tendons stretch. The body stabilizes this negative force, stores this force, and then “releases” this force. The reflex action brought on by the quick stretch allows you to put out a stronger than normal muscular contraction in the opposing direction. Pick up a ball, any ball, and throw it. Now pay attention to what you naturally did without thinking about it. Did you bring your arm back behind your head and pause and then throw it? I would hope not! Chances are you quickly drew your arm back and let it fly. That is a plyometric movement! The quick rearing back of your arm quickly stretched the tendons in your shoulders and built up energy, which allowed you throw harder. Would you have thrown as hard if you brought your arm all the way back, paused for 3-seconds and then released the ball? Definitely Not! By definition, almost all activities (and certainly all sports) rely to some degree or another on this stretch-shortening cycle, plyometric strength, elastic strength, reactive strength, or reversal strength. Don’t let the terminology confuse you, they all mean the same thing! Examples of plyometric activities are walking, running, rope skipping, jumping, and just about any dynamic activity that you can think of (i.e. all of them). However, I want to differentiate between a plyometric activity (such as walking) and plyometric training. Generally speaking, true plyometric training is very high intensity work like depth jumps (stepping from a box, hitting the ground and exploding) and bounding type exercises that require a strong loading and stretching of the muscle/tendon complex. Even many of the introductory plyometric exercises are not technically

plyometric training. They are intended to condition the body for the more intense work to come. True plyometric training involves high intensity activity. Plyometric action is much like a rubber band in that, if you stretch a rubber band quickly, it will spring back faster due to storing potential energy. Stretching the elastic muscle and tendon components produces elastic potential energy similar to that of a loaded spring. When the muscle is stretched rapidly the muscle-tendon complex stores a portion of the load force in the form of potential energy. The recovery of that stored energy occurs during the concentric or upward phase. To take advantage of the SSC reflex, the concentric (positive) muscle action must immediately follow the stretching. When you jump, a great amount of force is gathered as you absorb the negative (downward) forces and gather this energy to propel your body upward. The body must be able to quickly stabilize and store the negative (downward) forces and then flex and extend to leave the ground. A muscle that is rapidly stretched before a contraction will also contract faster and more forcefully. This is why the best leapers tend to move “down” into their countermovement the fastest and poor leapers move down slower. AMORTIZATION PHASE Plyometric training also works by decreasing your ground contact times when you run or jump. The ground contact time is also known as the amortization phase. The amortization phase refers to the time between your foot contacting the ground and being able to leave again (i.e. the time in between the muscle stretching and being able to contract again). The amortization phase is in essence the time spent paying off the time spent on the ground. Analysis of great jumpers and sprinters shows that they spend very little time on the ground during their activities. Thus, by decreasing this time by specific training you should be able to improve jumping and sprinting skills. Plyometrics can be broken down into several categories. All the various categories are important and have their place in a program. These categories include: 1. Light reactive exercises- such as jump rope, toe and ankle bounces, side- to-side line jumps, and low stair jumps. These exercises are characterized by relaxation and lack of “strain”.

2. Moderate standing “power” or “up” variety exercises- these exercises are characterized by less reactivity or stretch and rather a focus on applying max force from more of a standstill either vertically or horizontally. These, along with lighter load/high speed weight training are great for improving the rate of force development. They include for example: on-box jumps (jumping on a box from the ground), standing broad jumps, 1-leg step-up jumps and un-weighted squat

jumps. They develop the ability to apply max force instantaneously without a large involvement of the reflexive stretch shortening cycle.

3. Moderate reactive exercises- these are true plyometric exercises, but of the less intense variety. They include low-box depth jumps (jumping off a box impacting the ground, absorbing the energy, and immediately transferring that energy into an explosive jump, lateral cone jumps, jumps over hurdles and a variety of other exercises.

4. High intensity reactive exercises- generally these are the original plyometric exercises depth jumps and drop jumps. They can also include other intense methods such as high barrier jumps and other various hybrids.

5. Short response reactive exercises- these exercises are characterized by a very short amortization (ground contact) phase. Most of them tend to be 1-legged variety jumps. Examples include: power skipping, one-leg bounding, single leg speed hops, 1-legged speed box jump, and 1-legged jumps for height or distance.

Furthermore, plyometric exercises can be broken down into 3 simple methods of performance. These include: 1. Jumps- land with both feet 2. Hops- done with single leg 3. Bounds- take off on one foot land on the other

The good thing about plyometric training is that all the individual components of the reactive stretch-shortening cycle are trainable and respond to training. Over time, plyometric training results in the following:

1. Recruitment of most motor units and their corresponding muscle fibers. 2. Development of explosive power. 3. Development of the nervous system so it will react with maximum speed to the stretching of the muscle developing the ability to contract rapidly with maximum force, thus leading to better plyometric strength. 4. An increase in rate of force development 5. A shift in muscular fiber type from type I (slow contracting), into type IIA (fast contracting), and type IIA into type IIB (fastest contracting).(Paddon-Jones 2001) 6. Increase in plyometric or reactive strength. 7. An increase in the proficiency of the central nervous system (CNS) 8. An increase in the ability to transform eccentric force absorption into concentric force output. It is important to note that plyometrics, especially more intense methods such as depth jumps and shock jumps, can fatigue the nervous system to a large degree and are best used within an intelligent plan. The nervous system actually takes about 5 times longer to recover then the muscular system. Plyometrics increase muscle recruitment but the nervous system still has to fire to recruit those muscles and it is like a battery that needs recharging. The fatigue of the nervous system can be illustrated like this. Imagine going for 3 whole days without any sleep. Even if you were completely inactive during those 3 days and hadn’t used your muscles at all, you’d still likely be very weak and tired. Remember that your CNS is like your computer or central controller and needs recharging once it’s worn down. Plyometrics may not create much muscle burn or soreness, but because of the way they involve the nervous system, intense plyometric drills can actually take as long or longer to recover from then any other training method. The problem with many athletes and coaches is that they don’t feel that intense plyometric drills are all that difficult. After all, getting up on a box and jumping down 20 times may not be considered as difficult to some people as going out and running a mile! Because of this, many people prescribe and/or do way too much volume in depth and/or shock jumps and young athletes without much of a training base to begin with do way too much volume of them and wonder why they don’t see much improvement. So make sure you pay attention to the total amount of intense plyometric training you do. The programs are designed to give you enough plyometric volume without leading to overtraining, but if in doubt do less plyometric training and never more. Next, let’s take a look at the guidelines for the prescription of high intensity plyometric drills. Guidelines when performing depth jumps: 1.The ground contact (amortization) phase should be short enough to avoid losing the elastic energy produced but long enough to allow for the shock stretching to occur. To

maximize the training effect, you should not spend more than .5 seconds on the floor and less than .2 seconds is much better. It’s best when doing plyometrics to think of the ground as a hot skillet. If you stay down too long your feet will get burned. Plyometrics are very effective, but when increasing maximum power is your goal, they should be done with concentration and intensity on every repetition and not in a fatigued state or in a high volume per set fashion. When performance begins to decrease during a set it is time to stop. Much like strength training involving higher repetition sets, doing depth jumps in a high volume fashion dampens recruitment of the FT fibers which is essentially just wasted time unless you are training for endurance. 2. The height of the drop should be regulated so that the heels don’t touch the ground during the landing phase. If they do the height of the drop is too high. A height varying between 18-28 inches appears to be ideal for most strength and power athletes with up to 45-50 inches for advanced athletes. The distance that you jump away from the box should be approximately the same distance as the height of the box. So if you’re jumping off a 36-inch box you should land approximately 36 inches out. (Zatsiorsky) 3. Depth jumps have a very powerful training effect so the volume of work should be low: no more than 4 sets of 10 repetitions (or 40 total jumps spread over more sets), 2-3 times per week for advanced athletes and 3 sets of 5-8 repetitions (or 15-24 total jumps spread over more sets), 1-2 times per week for lower classes of athletes 4. Because of the very powerful training effect of depth jumping, it is best to avoid performing this type of training constantly throughout the year. For consistent gains these blocks should only be used when a rapid rise in power and reactive strength is needed. Every training method, regardless of how effective it is, will lose its effectiveness over time. Plyometric training is no different. If you use it year-round there comes a point where you will get no added benefits from it. However by using shorter blocks of training of no more then a few weeks, you can give a quick boost to your performance and everytime that you use them you will get a substantial boost. Guidelines for “shock” or depth drops or jumps: Remember a shock jump is also called a depth drop and is done when you step off a box and just try to “stick” the landing without jumping back up. The landing portion of a depth jump has a very high training effect when it comes to improving explosive force output and even strength. During the landing portion the stress is at its highest as all the energy accumulated during the fall is transformed into muscle loading (energy absorption training). With each foot contact in a sprint the legs have to absorb forces equivalent to around 5-6 times bodyweight. With a shock jump the force upon impact can exceed 10 times bodyweight. Specific training in this fashion can greatly increase your capacity to absorb energy. If you are weak in the eccentric (landing) portion of the depth jump what will happen? The amortization phase or coupling time (time it takes you to switch from landing to jumping) will be very long and the resulting jumping capacity will be low.

Before you can put force out in a plyometric movement you have to be able to take force in and gather it. The more force you’re able to efficiently take in and store, the shorter your amortization phase will tend to be and the more force you’ll put out, thus the higher your subsequent jump. Depth jumps do increase absorption strength but shock drops really allow you to zero in on this portion of a plyometric movement. So, when utilizing shock jumps you will just execute the “landing” portion of a depth jump and practice sticking the landing without allowing your heels to hit the ground. You can vary the position as well to zero in on different muscle groups. Sometimes you may land with straight legs, sometimes you will land in a squat, and sometimes you will land in a lunge. Regardless of the performance, you will immediately break the downward movement as soon as you hit the ground. You can also use higher drop heights (up to 30-50 inches). Just make sure you always pay attention to the point at which force created starts to overcome force absorbed. When you land with a loud “thud”, you’re no longer absorbing the energy efficiently. Like depth jumps, when executing a drop jump you should land “away” from the box about the same distance as the height of the box. Guidelines for “other” plyometric drills: Other plyometric drills include various hops, bounds, and jumps that don’t have the same extreme landing forces of depth jumps or shock jumps. Athletes of all ages and classifications can do some form of these drills and they are very effective to use to build an athlete up to being able to tolerate a cycle of more advanced plyometric depth jump or shock jump training. The intensity and volume can be gradually built up, but just like the more intense versions of plyometrics, one must pay attention to recovery and volume. I like to do a higher volume of these drills in between cycles of more intense depth jumps and plyometrics and a lower volume during the cycles of depth jumps and shock jumps. A sample 12-week cycle might look something like this: Week 1-3: Higher volume lower and moderate intensity jump training (i.e. single and double leg jumps, hops, skips – depth jumps up to 18 inches) Week 4-6: High volume weights + low volume low intensity jump training Week 7-9: Moderate volume accelerated weight training (jump squats, speed pulls) + low volume shock jumps (depth drops) Week 10-12: Low volume general weights + high volume depth jumps In this way one can progress consistently and get the most from their training without burning out on any particular training method. The workouts I’ve designed provide plenty of variety so that people never have to worry about performing the same exercise over and over again! Is a certain level of strength necessary before engaging in plyometrics?

A certain level of strength is necessary for optimal performance in plyometric movements and added strength can also bring enhanced reactive strength. To explain this, let’s use the example of performing a depth jump. During a depth jump you stand on a box or bench, drop off, and at ground contact you absorb the impact, your muscle lock up, your tendons stretch and gather energy, then you reverse direction and jump up. Now, whenever you step off the box gravity is quickly bringing you down to the ground. Upon immediate impact your muscles are trying to lock up and stabilize. At that point they are subjected to tension and forces up to 9 times or more your bodyweight. If you do not have enough strength to absorb these forces your body will do one of 2 things: 1. It will shut down the stretch reflex to avoid injury 2. You will take too long absorbing the forces to utilize the stretch shortening response. The greater your strength the more force you’ll be able to gather and put out and the quicker you’ll be able to do it. A minimal level of muscular strength is necessary to absorb the high forces. So what is the minimal amount of strength I need? Many people ask this question and the entire topic has really created a lot of confusion in strength and conditioning community. Many coaches say that athletes should be able to squat at least 1.5 times their bodyweight before performing any plyometric training. This is both true and false. Remember that from their eastern roots originally plyometrics consisted of only 2 exercises, depth jumps and “shock” jumps. Remember that a depth jump consists of stepping off of a bench or object and upon hitting the ground immediately jumping back up. A shock jump consists of stepping off of a very high object and simply landing and absorbing the impact. Both of these exercises were also used for heights of around 3 feet or more. It is true that for intense exercises like these an athlete needs to have strength levels sufficient to absorb the high forces without injury. Squatting 1.5 bodyweight would be a minimal number for these types of high intensity exercises. The problem is, after plyometrics were brought to the USA and given their now common name, coaches began to lump all types of hopping, jumping, skipping, and bounding drills in with them. In the process, many of the general strength recommendations such as being able to squat 1.5 x bodyweight given for "real" plyometrics ie.- depth jumps and shock drops, were also carried over to include all plyometric drills. Although having good strength levels is definitely a positive thing it is not necessary to squat 1.5 x your bodyweight to partake in light to moderate plyometric drills. These include just about all kinds of jumps, hops and bounds. In fact, pretty much everything except for high depth jumps and shock jumps. If you think about it, life and play are plyometric activities! Next time you go by a playground have a look at the kids jumping around off and on playground equipment and such. They are putting a lot of stress on their bodies and

surely not able to squat 1.5 x bodyweight yet how often do they get injured? Not very often! The bottom line is that improving your strength will allow you to get more out of the plyometric activities that you do and will also allow you to do more intense variations of them. So, when it comes to plyometric activity, strength is definitely necessary and gives you an advantage. Now you probably know more than 99% of all people when it comes to the science of the vertical jump. Comprehending power, force, and velocity is quite simple but let’s do a quick review! The vertical jump is a measure of power. Power= Force x Velocity Force- is increased by high-tension movements such as moderately heavy and heavy weight training Velocity- is increased by lighter and faster weight training movements to improve the rate of force development, and by plyometric type movements to improve both rate of force development, and reactive strength. To keep it simple all you need to know for a spectacular vertical jump is that you need: 1. Force or Strength 2. Rate of Force Development 3. Plyometric or Reactive Strength High Tension vs High speed movements To better understand the reasoning for the various training methods and their focus think of it this way. Methods that improve maximal force tend to be high tension/long duration movements. That is, the weights are generally heavy, our force output is high and the muscle fibers are subjected to a fairly long duration of tension due to the load. When you execute a maximal squat it is impossible to move the weight at a lightning rate of speed no matter how hard and how fast you push. The muscle cells are under tension for a longer period of time, which improves their maximal force capacities. In contrast, an exercise such as a jump squat is a high tension/low duration movement. The force output is high, but because of the reduced loading and the speed at which the exercise occurs, the duration of this tension is much shorter. This doesn’t do a whole lot to improve maximal force output yet it does do a great job at improving maximal rate of force development or the speed at which you can build up to maximum force!

Now consider a depth jump. When stepping off a high box and impacting the ground at the moment of impact the force output is very, very high. In fact, the amount of force is up to 9 times your bodyweight or more! At first glance you might think this may be good for increasing maximal force production and it does provide value in this regard, yet the duration is also very, very short. The depth jump, due to the quick stretching of the muscles and tendons and subsequent powerful contraction, trains the stretch-shortening cycle. This is something that heavy load weight training and even lighter load/high speed power training do not do quite as well. Likewise, the depth-jump, although great for training the stretch shortening cycle and reactive strength, is not as good as weight training at boosting maximal force capacity. Also, due to its reliance on the quick stretch-shortening cycle, which is largely an involuntary reaction, this training method is not as good as some others at improving the rate of force development. Pure rate of force development training is purely voluntary and “cheating” bouncing or trying to get a reflexive reaction actually takes away from its training effect. Now, to see how these training methods all fit together if you were to take out a sheet of paper and to the far left hand side write “Squat”, and to the far right hand side write “Depth-Jump”, those exercises are at the 2 extremes for power training. The squat for pure voluntary force and the depth jump for involuntary force. They are both necessary but do not train the same qualities. One is high tension/long duration and one is high tension/short duration. One is dependent on muscular strength and one is more dependent on tendon strength. Next, if we were to progress from left to right from high tension/long duration to high tension/short duration there are a lot of middle ground training techniques to fill in the big gap between squats and depth jumps. These would include for example: squats progressing to lighter weight explosive squats, weighted jump squats, 1 and 2-legged skips, hops, and jumps, jumping on or over objects, bounding activities, and finally, drop jumps and depth jumps. The following table categorizes the different training methods as either targeting maximum force, rate of force development, or stretch-shortening cycle/reactive strength. Maximum Force and Strength (high tension-long duration) Any strength training movement using 75% or more max weight in that particular movement Squats Deadlifts Rate of Force Development (high tension-short duration) Any strength training movement using less than 60% maximum weight done with maximum speed and force along with little if any prior countermovement. Weighted jump Squats and speed Squats – especially those done with a pause before the contraction Stationary “up” and “out” variety Reactive Strength (very high tensionvery short duration) Any rhythmic exercise heavily involving the stretch-shortening cycle Jumps back and forth over obstacle Hurdle jumps

Lunges Romanian Deadlifts Glute-Ham raise Leg-curl Calf raise

plyometrics On-box jumps Standing broad jumps 1-leg step up jumps Un-weighted jump squats Vertical jump from dead stop crouched position

Depth jumps Shock jumps (depth drops) One leg speed hops Jumping off of 1 leg for height Rhythmic rim jumps

Of course, no single exercise is usually going to be purely a maximum strength, rate of force development, or reactive strength exercise. With most exercise variations there is generally going to be some overlap between the different qualities. However, I wanted to make the point that certain exercises do a better job at targeting different qualities. The following table summarizes the effects different types of training have on different strength qualities. Strength Quality Heavy Weight Training Excellent Good Poor Poor Lighter load explosive weight training (jump squats) and other explosive bodyweight exercises Fair Excellent Good Good Plyometric drills like shock jumps and depth jumps Fair to Good Fair Excellent Excellent

Maximum Strength Maximum Rate of Force Development Stretch- shortening cycle/Reactive strength Jumping skill and muscle coordination

You know you need optimal levels of all the 3 qualities (maximum strength, rate of force development, and plyometric strength) to really improve your vertical. This is also verified by scientific studies that show a combination of the above training methods to provide much better results then either method alone. Check out the results from a 6week study: Effect of Squats and Plyometrics on Vertical Jump EXERCISE TYPE Squats Plyometrics Squats + Plyometrics VERTICAL JUMP INCREASE 3.30 cm 3.81 cm 10.67 cm

Those results show those who performed both strength training (squats) and reactive training (plyometrics) gained more then 3 times the amount on their vertical jump training then either method alone! Simple enough! Identifying Individual Strengths and Weaknesses Obviously, the most effective type of training for a given athlete may depend on which component of strength is most deficient for that person. One might be deficient in strength yet have very well developed rate of force development. Another might be deficient in reactive ability yet have very well developed strength. Testing of these components can help define individual needs. Targeting your weakness will produce the greatest overall gains. One question you might be asking by now, especially if you’re quite intelligent and dedicated as many readers who purchase this program tend to be, (Hey dummies don’t normally invest in improving themselves!) is, “well how do I know if I should train more for increasing my max strength or for increasing my rate of force development and reactive strength? Do I need to lift weights for more force? Do plyometrics? Improve rate of force development? Never Fear!! By the time we’re done you will know exactly what type of training will be most effective for you so all the guesswork will be eliminated. If you’re one of those guys who’s always dreamed of flying above the rim throwing down on Shaquille O’Neal, or even just getting above the rim for the first time, you probably can’t wait to see the training prescription just for you. But before we get you hopping off boxes, throwing a ton of iron around, and bounding across the gym, there are just a few more considerations that need to be addressed. 1. Body composition – You probably already know this, but if you want to fly, you need to keep your body-fat levels in check. Excess body-fat is going to do nothing but glue you to the ground. Don’t try to get too lean, as doing so will probably leave you too weak to perform optimally, but do pay attention to your body composition. If you’re above 10% body-fat you’re going to also need to pay attention to diet and possibly do some general fitness work as well throughout the program. Here’s a way to determine your body-fat percentage. A. First determine your waist measurement. The best time to do this is first thing in the morning. Get a cloth measuring tape and measure your waist just around your bellybutton. Don’t suck in or push your stomach out, just relax it. B. Find your height in the left-hand column of the table below and find your weight at the top of the chart. C. Locate where your height and weight measures intersect. This location on the table indicates the average waist measurement of someone who is 10 percent body-fat.

D. If the waist measurement of where your height and weight intersect equals the same that is seen on the table you are approximately 10 percent bodyfat. Therefore, a player who is six feet tall and weight 190 pounds with a 34-inch waist is approximately 10 percent body-fat (19 pounds of fat and 171 pounds of lean muscle mass). If your waist measurement is lower, then you are below 10 percent body-fat. A higher waist measurement means you are above 10 percent body-fat. If you are above 10 percent follow sound nutritional practices until you get down to 10-percent or less. WEIGHT Height 110 120 130
5’2-5’4 5’5-5’7 5’8-5’9 5’10-5’11 6’0-6’1 6’2-6’3 6’4-6’6 6’7-6’9

140

150 32 32 32 31.5 31.5

160 32.5 32.5 32.5 32 32 32

170 33.5 33 33 33 32.5

180 34 34 34 33.5 33

190 34.5 34.5 34.5 34 34

200 35 35 35 34.5 34.5

210 36 36 35.5 35.5 35

220 36.5 36.5 36 36 36

230 37 37 37 36.5 36.5

240 37.5 37.5 37.5 37.5 37 37 36.5 36.5

29.5 30 30

30.5 31 30.5 31.5 30.5 31 31

32.5 33 32.5 33 33

33.5 34.5 35 35.5 36 33.5 34 34.5 35.5 36 33.5 34 34.5 35.5 36

2. Training experience – The less advanced you are the more basic your program should be. Don’t make the mistake of starting out with an advanced program if you haven’t built your training foundation. Doing so will likely cause you to overtrain and leave you weaker and less explosive. If you are relatively new to strength training or plyometrics, you’ll want to first complete the more basic programs, regardless of your current level of explosiveness. You’ll make superior progress on the basic programs and, by developing your foundation you’ll be able to get more out of the advanced programs when you finally do use them. 3. Initial strength levels – Regardless of what some of the following tests may indicate, if you haven’t built up a necessary strength base then it will be pointless to dive into intermediate and advanced plyometric drills. For this reason, one of the basic programs provides an initial phase with the focus on general strength and muscular development. One of the ultimate goals is to get your back squat and deadlift up to 1.5-2 times your body weight. If you don’t like or want to lift weights or don’t have access to weights I’ve also included a program using bodyweight exercises that will also allow you to boost your strength. If you’ve read this far and are STILL not convinced of the value of strength training I’ve also included programs utilizing only plyometric and other bodyweight drills. Now you COULD go ahead and jump in and do a more advanced plyometrics program, but you probably won’t get the full benefit or could possibly injure yourself. If you choose to do so anyway I’ll go ahead and admit that you’ll probably get superior results anyway, but you have been warned in advance!!

If you dedicate yourself to the program and follow all the tips that I offer by the end of this program, you will be stronger, bigger, faster and throwing down over Shaquille O’Neal. Ok, not the Shaq part, but maybe Shawn Bradley! Before you can throw down a dunk, you need to understand how to Jump! Ok, that was a joke! Everyone knows how to jump right? Of course they do, but have you ever wondered why people not only have different heights of their jump but also different styles of jumping? I’ve always found the topic of individual response and variety to training a very fascinating topic and this is what I’ve found. Individual Differences If there' one thing I learned over the years working with many individuals in athletic s programs and observing thousands more it’s that people have individual differences that determine what type of training routine will work best for them. These differences range from size, strength, body structure, limb lengths, fast twitch fiber ratio, mind to muscle connections, and variable performance in tasks like lifting vs jumping. Factors such as these will predictably determine what type of program an individual does or doesn'respond to. t All these individual differences go into consideration when determining what type of methods are going to work best for you. Unfortunately, not all athletes will respond alike to a particular training routine. A specific exercise or type of exercise that may produce superior results for one individual may only produce marginal results or inferior results for another individual. One example is an athlete with insufficient strength might experience great results from high-tension/high load exercises like the squat, while another athlete who already has sufficient strength but lacks rate of force development and reactive strength will likely find plyometrics and loaded acceleration methods work better for him. So there' really s no magic bullet for everyone and anyone. Furthermore, an athlete may find that a training method that doesn’t produce good results initially may produce excellent results at a future time as he gains strength, skill, coordination, or speed. Some training methods are good for a quick burst of improvement but over-relying on them will actually cause regression. Some exercises will plateau in their effectiveness very quickly while others should be consistent staples in the training of anyone desiring consistent progress - Other popular training methods or gimmicks should be chunked out the window. Taking a Look At The 2 Different Types of Leapers There are 2 dominant types of leapers with most people possessing a tendency towards ll one or the other. The first type I' cover is the strength jumper The strength jumper tends to rely more pure strength and explosive ability to get up in the

air. He tends to look a little less "springy" and a lot more “powerful” when he jumps. He may even appear and sound like he’s tearing holes through the floor when he takes off! When choosing his jumping style, he' definitely tend to do best jumping off 2 feet and ll likely feel quite horrid jumping off of 1. He' also tend to use a deeper knee bend and ll may also have physical characteristics like thicker muscles and joints. He will tend to have natural levels of "strength" that are greater then his natural levels of "bounce", or reactive ability. At the extreme end of this group are athletes like olympic lifters and throwers. Many of these guys have spectacular vertical jumps along with spectacular rate of force development. They can exhibit their impressive power from a virtual standstill, but you won'see them dunking from the free throw line or winning any high jump medals. t Now realize that not all strength jumpers are strong or can jump, it' just that their body s structure, muscle-tendon lengths etc. will naturally tend to make this their dominant style when they do begin working specifically for vertical jump improvement. Some people are "strength" jumpers but don'know it yet because they may not yet have any strength. t Having said that, as long as this style of jumper has his strength levels up to par, he' ll make further gains using plyometric and accelerative methods which, when coupled with his strength, will make him even more explosive and smoothen out his rough style. At the upper levels of sports, natural "strength" jumpers also learn to become smooth and graceful as well. Think for a minute about some of your favorite dunkers and I' sure m you can identify a few that fall into this group. The 2nd type of leaper is the elastic jumper. The elastic jumper, also known as the reactive, elastic, or plyometric jumper, tends to naturally be more fluid and often appears to take off effortlessly into the air when he jumps. He just looks bouncy. Most of the time, he will be gifted in the structural department with long legs, long achilles tendons, and small joints. He also tends to naturally be able to get up higher jumping off of one leg with a running start then he will be with a short 2-legged take-off or from a standstill. His levels of strength may often seem inconsistent with his performance and he probably won'be turning many heads in t the weight room. The elite level high-jumper or long jumper are both excellent illustrations of extreme elastic jumpers. The reasons the elastic jumpers tend to excel at this style of jump are due mainly to structure (length of the bones, muscles, tendons etc.), but also muscle fiber considerations. They naturally tend to rely more on the action of the stretch-reflex and involuntary plyometric ability. In contrast to the strength jumpers, over time at the upper levels, elastic jumpers learn and train to become more like strength jumpers. They do this by increasing their pure strength and voluntary rate of force development. Since the elastic jumper is naturally bouncy and gifted in the plyometric department, it usually doesn'require as much focus in his training. Michael Jordan is a good example of an t athlete who was naturally an elastic jumper but who also learned to become an excellent "strength" jumper.

In addition, most will favor a bilateral 2-legged takeoff if they rely more on their strength because one can obviously apply more muscular force with 2 legs than with one. Those who favor a 1-legged take-off do so either because their natural structure and build favors the quick reflexive rubber band type action in the tendons rather then pure voluntary explosive strength,- or because they don'have enough strength or aren'yet t t able to apply their strength quickly enough (rate of force development) to execute a powerful 2-legged take-off. This is why some people with sub-par jumping ability will gravitate towards this style. Different Means - Same Result To explore this a little deeper, jumping is inherently plyometric and regardless of your style of jump (1-leg or 2), there is still a process of stretching, stabilization, and reaction in the tendons and musculature of the lower body as you plant to take off. No matter what your dominant qualities are, you can both improve and learn to use your plyometric ability optimally, but there are differences in how you might go about doing it and the qualities required. The plyometric/reflexive/reactive/ or elastic contribution to jumping can be divided into two categories, long and short response reactivity. Recall from the plyometrics chapter, as you plant to jump, the brief time you spend changing direction as you' on the ground re just before the take-off is called the amortization phase. When executing a jump with a 2-legged takeoff the amortization phase is around .250 seconds or greater which, when it comes to plyometrics, can be considered long. We can call this longer response reactive ability because the ground contact times are fairly long. When leaping off of one foot the amortization phase is shorter than .250 seconds and generally closer to .100 seconds. We can call this short response reactive ability because the ground contact times are shorter. Some people, especially strength jumpers, tend to excel more at the 1st, longer ground contact type of jump; whereas elastic jumpers tend to naturally excel at the 2nd type. This is due to the fact that the longer the ground contact times are, the more voluntary strength tends to be involved - A jump off of 2 feet with a longer amortization phase allows one more time to voluntarily apply force. The shorter the amortization phase and ground contact times are, the more that natural structure, muscle tendon lengths, and speed are going to be dominant. These rely more on involuntary rubber band like action rather than strength. An example of a plyometric exercise that would improve longer response plyometric ability is a simple depth jump. An example of a plyometric exercise that would improve short response plyometric

ability is a running high jump or full speed sprint. Both long and short response reactive ability rely on a base of strength in order to add stability, absorb the eccentric forces created when planting, and give an athlete a bigger base of potential force ability to take advantage of. Muscular Contributions To Each Style It’s also worth mentioning that the muscular contributions to a uni-lateral (single leg) takeoff vs a bi-lateral (2 legged) take off are different. Both of them rely on the muscles of the glutes, hamstrings, quadriceps, and calves, yet the contribution that each muscle group provides changes depending on the style of jump. The unilateral jump relies much more on the glutes, hamstrings, and calves with the quadriceps providing a lesser role. The bilateral jump relies on the quadriceps musculature for up to 50% or more of the power output. The glutes and hamstrings are inherently fast twitch muscles and tend to be more efficient then the quadriceps when contracting at very high speeds such as those that occur in a unilateral take off. The quadriceps tend to be more efficient when contracting a little slower. To illustrate how 2 people can accomplish the same task via different strength qualities an athlete who is at an elite level utilizing the short amortization phase stretch shortening cycle (1-foot jump) like a higher jumper, long jumper or someone like Brent Barry, will not necessarily be proficient in performance of the other type of jump (2-foot jump) and vice-versa. It used to be in the NBA most all of the good dunkers were unilateral 1-foot dominant jumpers. If you ever check out some of the older NBA slam-dunk contests that run at 3:00 a.m. on ESPN classic you' see this! Back then, because of the lack of effective ll training, the thought was that there wasn'much you could do about increasing the t vertical jump and the guys who were good at it were naturally good at it. Nowadays, however, take a look at the best dunkers and you' notice the 2-foot jumpers dominate. ll This is in large part directly due to the influence of strength training, which really has a large impact on the 2-foot jump and allows one to take advantage of their voluntary explosive strength, which is much easier developed and under less genetic influence than speed and short response reactive ability (amortization phase of around ~.100 seconds) So just because you may naturally be slow, weak, and not blessed with a great jumping structure doesn'mean you have to stay ground bound because the sky is the limit! t Although raw speed of muscular contraction and short response reactive ability is under quite a bit of genetic control and in large part determines performance in movements like the high jump and long jump; Anyone and everyone can dramatically improve their explosive strength and longer response reactive ability, which can dramatically impact the vertical jump. Can You Switch Styles?

So what if you’re a 2-legged jumper or a 1-legged jumper and decide you want to switch styles, is this possible? Yeah, sure you can switch from being a 1-foot jumper to being a 2-legged jumper but it may take a lot of practice at the particular style you’re less gifted in. The 2 types don’t always share a direct correlation. That is, you could for example really increase your overall 2 legged jumping abilities while at the same time not see your 1-legged jump increase much and vice versa. This is in large part due to the muscular considerations I mentioned above. To switch from being a good 1-legged jumper to 2 legged jumper you' have to work on ll strength and explosiveness, particularly in squatting type movements, along with lots of practice with the 2-legged jump. To switch from being a good 2-legged jumper to a 1-legged jumper you will really have to bring up the ability of your glutes, hamstrings, and calves to absorb and put out energy at high speeds. One-legged jumpers who are really good at it (high jumpers, long jumpers and some ball players) probably do have a genetic advantage in body structure and speed of contraction in the tendons, connective tissue of the lower body that allows them to be good at it naturally. A few are good at both. Obviously, all leaping action is a combination of both general strength which is enhanced by movements like the squat, and reactive strength which is enhanced by various plyometric type exercises. The best leapers tend to have both but to varying degrees. Most of the time, regardless of structure or dominant jumping style, an individual will be more gifted towards one side or the other; ie either strength or reactivity, so his optimal training program should have him focusing on his weak points while maintaining his strengths. Barring injury, with this approach it' about impossible for improvement to s ever plateau. MORE INDIVIDUALITY Now imagine if we were to take someone who is naturally as strong as an ox and an excellent strength jumper and we put him on a program consisting of mainly weightroom work with little plyometric training. Chances are, his plyometric ability is his limiting factor in furthering his leaping ability. Because he already has well-developed strength, explosive, strength and rate of force development, a training program focused on those methods probably isn’t going to bring about much improvement for him. Now, say on the other hand, we have someone with good natural reactive ability and poor strength levels and we put him on a high volume of plyometrics with little strength and weight-room work. Chances are he won’t improve much either due to the fact that his progress is being limited by his strength How Body Structure Influences Expression of Strength

Your performance in the vertical jump and the type of training you respond to will also be influenced quite significantly by the way you are built. We can classify people as either long limbed, termed brachiomorphs, or short limbed, termed dolicomorphs. In weight-lifting, long-limbed individuals are prone to thinking that they’re genetically disadvantaged. But are they really? Depends on the sport or movement. Long-levered athletes can express their strength much more successfully on the playing field than in the weight room. For example, Michael Jordan at one time had a startling vertical jump and was very strong, yet when compared to a person his same weight and a foot shorter he has a large disadvantage in a parallel squat and I doubt if you would ever see him setting any lifting records. When you' 6' bending the legs to parallel is a long way down! re 6", At the same time, those in sport often say that those with short limbs are cursed on the field and, while their long limbed counterparts would appear to have an advantage, the short limbs curse is definitely not a rule. If anything, those with short limbs tend have an advantage during the beginning phase of a movement. Nobody ever accused former world record sprinters Maurice Greene or Kelli White of being long limbed, yet it didn’t seem to hold them back any. It also didn’t hold back guys like Dante Hall, Barry Sanders, Mugsy Bogues, Spud Webb, as well as any and every Olympic gymnast. In some sports, such as weightlifting, athletes with short limbs will have an advantage over those who possess long limbs, because the weight is moved through a shorter distance. On the other hand, if an athlete requires a long powerful stroke, such as in swimming, canoeing, sprinting, jumping, or rowing, - then a longer lever, provided it is accompanied by the muscular power to propel it, has an advantage in these types of sports because of the speed those longer limbs can generate at the end of their range of motion. The same point can be made in other sports where hitting or throwing are important. For example, speed in a tennis serve, volleyball spike, or a baseball pitch will all be higher for long-levered athletes as long as they have enough muscle power to rotate the longer limbs TENDONS LIKE A KANGAROO By the same token, many athletes who can jump high and/or run fast have physical characteristics such as long lower legs, high calves and long Achilles tendons. The length of the achilles tendon gives them a leverage advantage and enhances plyometric ability because it acts like a long rubber band. If you take 2 rubber bands of equal strength the longer one will fly further. Recall that in a plyometric movement the muscles and tendons are stretched and energy is stored and released in greater quantities. Having long tendons in the lower leg can enhance this entire process. The achilles tendon is amazing at storing elastic energy and giving it back to you; it' an adaptation to s make activities like walking and running more efficient. In the animal kingdom kangaroos have the longest achilles tendons and are also the best leapers. They can literally bounce around all day over 10 foot fences with hardly any effort. This doesn’t at all mean that if you don’t have long legs and tendons that you won’t be able to jump. It just means that your leaping ability will likely be naturally more dependent on pure strength and your reactive strength will come less easy. You’ll probably be excellent at demonstrating your explosive power from a virtual standstill as well. Likewise, if you

have long legs and tendons, - strength and the ability to demonstrate that strength in the weight room or jump from a pure standstill probably won’t come as easy for you, yet being able to bounce around like a kangaroo, running at top speed, high jumping, long jumping and overall just demonstrating good reactive ability will. Since there is obviously nothing you can do to change your body structure once you’re done growing besides adding muscle (despite what some people may want to sell you), the only thing you can do is work with what you have and train to maximize your natural attributes so that you can perform to the best of YOUR ability! Testing and Program Design Obviously you now know the importance of having good levels of strength, rate of force development, and well-developed reactive ability. If we separate the 3 strength categories and look at them independently most everyone will have one category that needs a bit more work then the other. For the tough guy who is already squatting 3 times his bodyweight it' obvious he' already strong enough, so he will immediately move to a s s program focused more on rate of force development and reactive strength training. For the rail thin guy that crumbles when he looks at ½ his body weight on the squat rack, it’s definitely time for strength training 101 with limited plyometric training. But for the rest of us that are somewhere in the middle, the answer may not be so clear. Finding Your Ideal Training Focus Is there anything we can do to determine this for you? Well, good thing for you there is but first you’re going to have to do a little test! An old mechanic once told me that vehicles will talk to you and tell you what’s wrong with them but the key is to know how to listen to them. I believe our bodies are much the same way. If we know how to read into them and listen to them, they’ll tell us how to train them for optimal results. Figuring all this out can take years however! Luckily for you, when determining where to focus your training and how to structure it, a highly effective diagnostic method has been around for ages Voluntary explosive strength and plyometric strength are independent components of motor function. That is, you can be really good at one and not the other but both are trainable. When analyzing the vertical jump, have you ever noticed how regardless of their style of jump, some guys can jump nearly as high from a standstill as they can with a long run-up, - while some guys can fly through the air with a long run-up but can’t get a foot off the ground when jumping from a standstill? In a sprint, some guys can accelerate to their top speed very quickly while others take forever to reach top speed but once they get there they' very fast. re As noted above, the ability to jump from a standstill position or start and accelerate in a sprint is more dependent on pure voluntary explosive strength and rate of force development while jumping after a run-up or sprinting at top speed are both more

dependent on involuntary plyometric efficiency. The greater speeds of movement both allow and rely more on reactive ability. Yet another example of this would be to compare the standing broad jump to a high jump, long jump, and sprinting at top speed. Even though one can initiate a bit of a bounce when performing the broad jump, it is still mostly dependent on pure strength and rate of force development. The long jump, high jump, and full speed sprint are much more plyometric in nature. Athletes who are really good at broad jumping are usually extremely strong (throwers and Olympic lifters) and tend not to be the best at high jumping or long jumping and vice versa. When your reactive ability is good the amount of energy that you put out in a movement will be directly proportional to the energy you take in. So if you absorb more force you develop more force. There is a test that will measure the amount of force you can take in and put out. It will show you the difference between your plyometric strength and your explosive strength. The test is called the Reactive Resources jump test. With the results of this test we can determine where to focus your efforts for quick improvement. SO HOW DO I TEST MYSELF? Simply follow these steps!! 1. Test your vertical jump using a regular "down and up" vertical jump descending down with your feet flat on the floor. Jump how you normally would. Descend naturally into a ¼ squat position and jump as high as possible and make a mark against a wall or use a piece of tape so you can measure your jump. This jump is heavily dependent on pure explosive strength without much of a plyometric response in the contributing musculature. 2. Next, find some benches or boxes that you can increase in 6-inch increments. Start off with a low 12 inch box and, standing on it next to a wall, step off with both feet, hit the ground, and immediately execute a depth jump and try to jump as high as high as possible and again measure the height you jump by making a mark on a wall. We will call this your reactive jump. Wait for the reflexive gathering of force that occurs at ground contact and explode out of it as high as possible. Don’t try to come off the ground too fast but don’t wait too long either. If you have to reset and gather yourself you’ve wasted too much time. Next, note the difference between the height of your down and up vertical jump and your reactive jump. If your reactive jump is less than your vertical jump than you can stop now, but if not continue on to step # 3. 3. Repeat the process but increase the height of the box in 6-inch progressions until you find the point where your reactive jump is less than your vertical jump. The depth jumps (reactive jumps) done off boxes heavily involve plyometric action and the plyometric contribution will increase the higher the box is raised. The greater the height

of the box the more force you' taking in at impact and as long as your reactive jumps re increase the greater the force you' putting out and thus the better your reactive ability. re By comparing your performance in the jumps you can determine where you are weak, or where to direct your efforts for further improvement. Some athletes best drop jump score off the lowest box may be below their normal squat jump, indicating large untapped reactive resources. This indicates a deficit in reactive strength with a need to emphasize reactive or plyometric training. If your vertical jump is about the same or less than your reactive jump your ability to absorb negative force and transfer it into positive energy is lacking. You’ll want to start using explosive and reactive training immediately along with depth drop landings to train your system to better absorb force. Once you become proficient at absorbing force you can then use regular depth jumps. For others there will be a gradual increase in jumping height with each increase in box height. They may find their best jump comes off a 30-inch box or better. The higher your reactive jumps are from increased box heights in comparison to your squat jump, the better your reactive ability is and the more you' benefit from increased muscle size and ll strength. If you fit into this group you are very plyometrically efficient so you' want to ll emphasize muscular strength and even hypertrophy so that you can create more basic resources you can utilize in plyometric movements. Here are a few examples of what different people might experience with this test: Athlete A: Vertical Jump: 24 inches Reactive Jump from 12-inch box: 22 inches Needs: Reactive strength and speed work Athlete B: Vertical Jump: 32 inches Reactive Jump from 12-inch box: 33 inches Reactive Jump for 18-inch box: 35 inches Reactive Jump from 24-inch box: 36 inches Reactive Jump from 30-inch box: 38 inches Reactive Jump from 36-inch box: 34 inches

Needs: Strength Athlete C: Vertical Jump: 28 inches Reactive Jump from 12-inch box: 29 inches Reactive Jump from 18-inch box: 30 inches Reactive Jump from 24-inch box: 27 inches Needs: An overall mix of Reactive strength, explosive strength, and Limit Strength work With the above tests we’re able to accurately determine where to best direct your efforts for further improvement. Performance in a movement involving lots of reactive (involuntary) strength always has much more potential then pure voluntary activities due to the additional reflexive force that occurs with the quick stretching, gathering, and releasing of energy through the tendons. When this action is eliminated, the result is determined by voluntary force. Quite often, however, we need to “tap into” this potential (plyometric) strength and teach our bodies how to utilize it. If someone has a regular “down and up” standstill jump that is better then their jump when using the boxes, this can be interpreted as a lack of development in the stretch-shortening cycle/plyometric abilities, with the subsequent need to emphasize reactive movements such as plyometrics in training. In contrast, another athlete’s best drop jump off the boxes may be 20-25% greater than his/her squat jump and their best jump will tend to be off a higher box. This indicates well-developed reactive (plyometric/reactive) strength. In this case, one should emphasize basic strength and muscle growth followed by methods designed to improve the rate of force development. This will create new potential, or raw muscle and strength, from which to draw from. To quickly recap, if your vertical jump off the boxes is 20% or more greater than the squat jump, you are very efficient plyometrically and will probably make further improvements by focusing on building up your strength through heavy weight training. If your regular down and up jump is fairly even with your drop jumps, your reactive strength is lacking so you should focus on plyometrics in training. Those who have very well developed reactive ability will find their best jump is off a higher box (>18 inches), and they are probably fairly strong as well as plyometrically efficient. Making It Easy! If that’s too confusing for you here’s another way to look at it. If you’re one of these guys who can really get up but you need to take a running start of 20 feet in order to do

so, then you likely need to work more on your strength. However, if you’re the guy who can stand flatfooted and jump nearly as high as you can with a long run-up then you will definitely see the best results using plyometrics and other dynamic methods. If you’re somewhere in the middle with no clear-cut weakness then you’ll do well on a well rounded overall program consisting of both strength training and plyometric drills. While we’re on the subject of testing for the vertical jump, make sure you don’t cheat during your test. There are several ways of cheating to make your vertical appear higher then it actually is. The easiest way is to simply not reach all the way up whenever you determine your reach. The 2nd way is to pinch your shoulder blades together when you reach up. If you pinch your shoulder blades together you won’t be able to reach as high even if your arms are fully extended. This will make your reach lower and thus make your vertical appear higher then it really is. Save these tricky little maneuvers until you want to impress someone besides yourself! Testing Part II – Testing General Leg Strength The next thing we need to do is determine your general leg strength. The best way to do this is to test your maximum squat in the gym. If you know how to squat, then get in the gym, perform a good warm-up, and build up to your 1 repetition maximum. If you already know what your 1-rep max is or can get an accurate estimate, all you need to know is how heavy it is in relationship to your bodyweight. Let me go ahead and mention that the results of this test over-ride the results of the first test. In other words, no matter what the reactive jump test tells you, - if your squat is less than 1.5 times your bodyweight you will need to work on building your basic strength! If your maximal squat is 1.5 x your bodyweight or more, your options become larger. So, for example, if you weigh 140 lbs. you will need to be able to squat 210 lbs with good form (140 x 1.5) before you start getting more specific analyzing other things. If you’ve never done a squat before then just assume it’s less than 1.5 x your bodyweight and start off doing one of the general strength programs using either bodyweight exercises or weights. If you currently train with weights it shouldn’t be too hard to test your squat. So what parameters do I use to test my squat? Most squats I’ve seen in the gym wouldn’t pass for what I consider a legitimate squat. To be considered legitimate, as you reach the bottom of the squat your hip joint should break parallel. To illustrate, put one hand on your knee and the other hand on the area where the upper thigh ties into the hip (the hip joint). When you descend into your squat, have someone monitor your form and pay attention to both the hip joint and the knee joint. In order to be considered a good squat your hip joint must temporarily go below the knee joint. This occurs roughly when the middle part of the thigh is parallel or a little beyond parallel. If you’re not used to squatting like this then don’t be averse to start off light until you get the feel of the movement. It can also help if you put a box behind you that you can use as a gauge to determine depth.

Are full squats dangerous? Many people ask if it is dangerous to squat full and deep like this and the answer is a resounding NO! There is actually more stress on the knee joint during a ¼ or ½ squat! When you squat deeper, the hip joint absorbs the majority of the load and takes stress off the knee. In contrast, when you squat above parallel the knees tend to absorb more of the force. Also, when you squat correctly the muscles of the vastus medialis, glutes, and the hamstrings are involved to a much greater extent. These muscles tend to be weak and underdeveloped in the majority of athletes. The vastus medialis (VMO) muscle of the quadriceps, also known as the “teardrop” muscle, is responsible for giving the knee stability. Full squats can effectively strengthen the VMO, which actually makes it a good exercise for knee stability. I don’t know how to squat, can I do leg presses instead of squats? First, I suggest you either get someone to show you how to squat or teach yourself. Squatting is a natural movement and is rather easy to learn. Simply start off with your bodyweight and squat down on a box to get the feel of it. Practically any good trainer, coach, or even experienced lifters, should be able to teach you how to do a squat within 10 minutes. Now to answer the question, yes, for the purposes of this test, if you don’t know how to squat, the leg press can be used as a substitute but you will need to do a leg press with 3 times your bodyweight to be considered equivalent to a squat done with 1.5 times your bodyweight. If you choose to do this, I still encourage you to learn to squat and drop the leg press in favor of the squat because the leg press really doesn’t have any carryover to athletic activities. PROGRAM COMPONENTS Now, lets quickly go over the intricacies of the program(s) structure so that you fully understand how the programs are structured to get you flying. 1. General Strength training – Remembering that P=FV, the goal here is to improve force and thus power. We will consider your limit strength equivalent to the maximal amount of weight you can lift for one repetition. For our purposes, the lift to focus in on will be the medium stance back squat. Unless otherwise noted, you should terminate each

set as soon as form begins to breakdown, which will generally be a couple of reps shy of failure. For almost all but the heavy-duty lifting crowd, general limit strength is an area that will likely need some improvement. It also is an area that can be improved quite quickly as the legs contain our largest muscle groups and respond very quickly to strength training. 2. Rate of Force Development training – While there are certain types of lifts that focus on acceleration, such as lighter load movements performed with great speed and acceleration, any lift or exercise can bring about improvements in rate of force development. The key to bringing about this improvement is to lift the load as fast as possible no matter how fast the load is actually moving. Whether the load is moving fast or slow does is really inconsequential. The act of trying to accelerate the load as fast as possible will lead towards the proper adaptations in the nervous and muscular system responsible for increased rate of force development. When you improve the ability to turn on as many muscle motor units as possible instantaneously you increase starting strength, which will enable you to begin a movement with greater proficiency. Certain types of lifts and bodyweight exercises that emphasize a start from a near dead stop are great for this. Starting strength is the ability to instantly develop force whereas rate of force development is the ability to build up to maximal force in the shortest time possible. A good example of a strength training movement that is good at developing both is a jump squat performed with a pause at the bottom. We will also use plyometric type drills of the “power” or “up” variety such as one-legged (uni-lateral) step up jumps. Because rate of force development is so important to increasing the vertical jump, it will be included throughout all programs and phases. 3. Reactive Strength Training – Again to confuse you, known as plyometric strength, reversal strength, or elastic strength! Being able to shift a load (especially your own bodyweight) quickly from the eccentric (down) phase to the concentric (up) phase is one of the key components of developing explosive power and jumping through the roof. Exercises include various jumping, hopping and skipping exercises along with the “bigdaddy” original plyometric movements depth jumps and drop (shock) jumps. Plyometrics maximize the stretch reflex, improve muscle recruitment and override CNS inhibition. Loaded full range jump squats are another exercise that will be used to developing a quick eccentric to concentric contraction, as are any other lifts and exercises that use a quick drop and explosion. This component of training will also be included in all programs, but to varying degrees, depending on your strengths and weaknesses. PROGRAM FLOW

Ok, now you’ve measured your vertical jump, your explosive to reactive jump deficit, you’ve tested your general leg strength, now it’s about time to get in the gym. So lets figure out how to decide what program you need. Raw Beginner1. Jumping efficiency and muscle coordination 2. General strength 3. Rate of force development 4. Reactive strength Novice1. General strength 2. Rate of force development 3. Reactive strength 4. Muscle growth Intermediate–: 1. Rate of Force Development 2. Reactive strength 3. General strength or 1. General Strength 2. Rate of force development 3. Reactive strength. Advanced – Everything Lets take a look at the various profiles you may fall under so you will know where to start Beginner Profile: 1. You’ve spent little time in the past lifting weights, doing plyometric drills, or any other jump programs. 2. Your strength and reactivity are both undeveloped. 3. Your vertical jump is poor to average (24 inches or less) 4. Your vertical jump from the ground is better or approximately equal to those done off boxes. Recommendations: If you’re a beginner you’ll need to develop a base of strength and begin conditioning your body by utilizing basic jump training. You should follow the raw beginner jump/plyometric routine and either the beginner weights or bodyweight strength training routine. This is the one situation where doing a fairly high volume of low intensity jump training can work fairly well for. The jump training increases general physical preparation and teaches the body how to work and move economically. After about 6 weeks of this type of training, you can then move on into another program that

incorporates more advanced strength training and more intense plyometric training. See the beginner strength programs. Novice Profile 1. You’ve spent little or no time lifting weights and thus squat less then 1.5 x bodyweight or leg press < 3x bodyweight 2. Your reactivity is naturally better developed. Your reactive jump off the boxes or with a running start will be somewhere around 20% or greater then from the stationary jump on the ground. 3. Your vertical jump is fair to good (up to 28 inches) 4. Lots of strength needed! Recommendations: If you’re this type of novice you have naturally better reactive strength. Whether this comes from structure, training, or practice, your strength needs to catch up to your reactivity. This means you need to focus on strength training. The beginners strength- training program is tailor made for you. When you have built up your strength strength, you can then move on to the intermediate programs and mix both plyometrics and strength training. See Novice Strength Training program Intermediate I profile 1. You’ve either lifted weights in the past or you’re naturally strong. You squat 1.5 x bodyweight or more or leg press 3x bodyweight or more. 2. Your reactive strength is under-developed. When doing the reactive jump test your jump off the ground will tend to be fairly even with your best box jump. Your jump with a 3-step run-up will be less than 20% better then your jump from a stand-still. 3. Your vertical jump is typically poor to good (< 28 inches) Recommendations: If you’re this type of athlete you need to emphasize plyometric and rate of force development training to better utilize your natural strength. If you’re this guy, a program consisting of Intermediate plyometrics with once per week strength maintenance will work extremely well. See “plyometric focused intermediate” routine. Intermediate II profile 1. You squat 1.5 x bodyweight or leg presses 3x bodyweight or more. 2. Your reactive strength is well-developed. Your best jump off the box or with a run-up will be somewhere around 20% or more better then your squat jump. 3. Your vertical jump could be good to very good (24-32 inches). Recommendations: If you’re this guy you have decent levels of strength along with excellent reactive strength. You’ll make your best gains with a program heavily focused on strength to balance out your well-developed reactive strength. A program focusing on strength with a moderate volume of plyometrics will be just the ticket. See “strength focused intermediate” routine.

Regular Intermediate Profile 1. You squat 1.5 x bodyweight or leg presses 3x bodyweight or more. 2. Your general strength and reactive strength are both good but neither one outweighs the other. Your best box jump will be somewhere between 5-20% greater than your ground jump but not more. 3. Your vertical jump could be anywhere from average to very good (20-32 inches). Recommendations: If you’re this guy you probably have a difficult time figuring out whether you need more general strength or more reactive strength. You really have no clear-cut strengths or weaknesses. You’ll benefit from a well-rounded combination program incorporating good amounts of both. See “general intermediate” routine. Advanced Profile 1. 2. 3. 4. You squat 1.5 x bodyweight or leg presses 3x bodyweight or more. You have experience both lifting weights and doing plyometric programs. You have an excellent vertical jump (32 inches or more) You generally, but not always, have excellent reactive strength with best box jump being 20% or more greater then his ground jump.

Recommendations: If you’re this guy you have an excellent vertical jump and have experience with all facets of training. If you do match the profile of the advanced athlete, yet don’t have the training experience, you should go back and do the intermediate programs first before doing the advanced program, regardless if you have a high vertical jump already. The advanced program utilizes very intensive weight training and plyometric drills. The one pre-requisite to the advanced program is you must have a high enough work capacity to recover from the high volume of lifting and jump training. If not then you probably won’t get much out of this program. See “advanced” program. What if I’m still not sure which profile I fit under? If you’re still not sure which profile best describes you I suggest you either consider yourself a novice and do the novice workouts or do the general intermediate workout. These workouts provide a nice blend of strength and plyometric work and will provide you a good balance. If you know that your strength or leaping ability is not yet up to the “Intermediate” level, these series of workouts will work like a charm for you. In fact, the novice workouts will work for just about anyone, regardless of whether they’re novice, intermediate, or advanced. The purpose of the more advanced programs is to provide a bit more specialization, focus, and variety for those who have a strong base of previous training experience.

EXERCISE DESCRIPTIONS

Low Intensity Plyometric Exercises exercises Ankle bounces- also referred to in some other programs as “thrusters”. To perform these you just jump as high as you can while using the force of your ankles and calves and without much knee bend. Perform the movement rhythmically without any pause between repetitions. Can be done using 2 or 1 legs. Jump rope- self-explanatory. If you don’t have a jump rope you can mimick the motion by pretending to be jumping rope but this is not as effective.

4-star drill- imagine 4 numbers or stars about 18-24 inches apart. It may look something like this: 1 2 4 3

Start off at 1, jump to 2 then to 3 then to 4 then to 1 then back to 4 to 3 to 2 to 1. Hop all the way around and back. That equals 1 repetition. Can be done with 2 legs or 1 leg. Slalom jumps- also called line jumps or slalom jumps. Simply imagine a line or low object directly on the ground under you and hop lightly back and forth across the line. Can be done with either both or 1 leg. Each ground contact equals 1 repetition. Pace will be about the same as you would use if you were jumping rope. Ricochet jumps- also known as low stair jumps. Find a low object, box, or stairs about 6-12 inches high and using the strength of your calves only simply jump up and down in quick fashion. Rhythmic jump squat- This exercise is known as “leap-ups” in some other programs. In a rhythmic fashion squat down and jump back up as high as possible. Can be done using either a ¼ squat motion or a deeper squat. Can be done with the hands either behind the head or with the hands reaching up with each jump.

Low squat ankle jump- Get in a low squat position while you rise up on your toes. From this position you should bounce up and down forcefully on the balls of your feet while you stay down in a squat position. Try to use the power of your hips and calves but without straightening your legs – With each mini-jump attempt to bring your feet up towards your chest

Bent over donkey ankle bounces- Find an object about waist high you can lean against for support. To perform the movement you bend over until your upper body is parallel to the ground and resting the majority of your upper body weight on the object. Your legs will be back behind you and straight. The exercise gets its name from an old bodybuilding calf exercise called Donkey Calf raises. The idea was to have someone sit on your back as you perform straight legged calf raises. You will be doing the same thing, only you won’t have anyone sitting on your back and you will be leaping up using the power of your calves and ankle extensors. Can be done with 1 or 2 legs and also jumping with 2 and landing on 1.

Moderate plyometric exercises (up variety) The following exercises place an emphasis on starting and explosive strength without such an emphasis on reactive strength. Most of these exercises have you starting off from the ground and jumping on, over, or above something without a chance to get much bounce into the action.

On-box jump- From the ground simply jump onto a box or bench and then step-off - Can also be done unilaterally.

Standing broad jump- Stand in a stationary position and jump up and forward as far as you can. Pause and re-set yourself and perform the required number of repetitions.

Double leg bounding- also known as leapfrogs – This exercise is performed much like a standing broad jump but is more rhythmic in nature and the squatting phase is not as deep. Jump up and out as far as you can and immediately execute another jump at ground contact.

Hurdle barrier jump- Set up objects in front of you that are approximately as high as your best vertical jump. Now simply jump over them one at a time. Try to perform the entire set smooth and with little effort. This exercise can be done unilaterally as well. If you don’t have objects or hurdles you can also use imaginary objects.

Knees to chest tuck jump- From a stationary position jump as high as possible while bringing your knees up into your chest. At ground contact immediately straighten your legs and execute another jump.

Star Jump- Bend down and grab your ankles and then jump up while you spread your arms and your legs so that you look sort’ve like a star. Hit the ground, reset for a second and repeat for the desired # or repetitions. Burpee- Also known as a “squat-thrust”- Start with your feet shoulder width apart and standing erect. Squat all the way down until your hands touch the ground on either side of your legs. From this position kick your legs all the way back so that you’re now at the start of the push-up position. From this position bring your legs back even with your hands so that you’re now in sort’ve a deep squat position. From here jump up as high as possible. At ground contact repeat the entire series.

One-legged step up jump- Also known as 1-legged bench jumps or split squat jumps – Find a bench about 18-24 inches high and place one leg on the bench with one leg on the ground. Now, from a dead stop and without bending down at all, jump as high as possible and land in the exact same position with the same leg on the bench and the same leg on the ground. Pause for a second and repeat. Perform all the reps for one leg before moving on to the other leg.

Box squat jumps- also known as sit jumps- Sit back on boxes or a chair in a ¼ or 1/2 squat position. From this position jump up as high as possible or out as far as possible. You can also have another box you can attempt to jump on or over. By varying the height of the box you’re sitting down on you can vary the intensity of the exercise. Paused Squat Jump- Done like a rhythmic squat jump only this time you pause for 3 seconds at the bottom of each repetition. Leap Frog Jump- Squat down with your hands on the ground. Next, jump up and out as far as possible, land, squat down once again, touch the ground and repeat. Moderate Reactive Exercises These include all types of commonly known medium intensity reactive plyometric movements. Rim jumps- Using a basketball goal or other high object as a target jump up and down without any pause between repetitions attempting to touch the object.

3 steps + jump for height (double legged variety)- Take 3 steps and using a quick jump stop jump for maximal height.

Lateral cone or obstacle jumps- Using cones or low obstacles (12-18 inches) jump back and forth over the object. Performed just like line/slalom jumps except you should be using an actual object to jump over and the jumps will be higher and more intense. Each ground contact equals one repetition.

---------Low box depth jumps- Using a low box (18 inches) but up to over 36 inches, stand on the box and step off, upon hitting the ground either immediately jump up as high as possible or jump up onto another box if you have one available. The distance that you jump away from the box should be approximately the same distance as the height of the box. So if you’re jumping off a 36-inch box you should jump approximately 36 inches out. If you don’t have another box turn around and step back up on the box and repeat. If you are using 2 boxes simply turn around on that box and repeat. Each ground contact equals one repetition.

Drop Jumps- Also known as “shock” and “altitude” depth drops. Using a high box (>24 inches) stand on the box, step off, and bending the knees as little as possible and staying on your toes simply attempt to absorb the impact. Hold the landing for a few seconds and get up on the box and repeat for the desired # or repetitions per set. Like depth jumps, the distance that you jump away from the box should be approximately the same distance as the height of the box.

Short response plyometric exercises and unilateral varieties Most of these exercises are executed unilaterally (single leg) and generally require a shorter ground contact time. For this reason they tend to be more effective at increasing 1-leg jumping performance. 3-step + jump for height- Take 3 steps and jump as high as you can. In between repetitions walk back to your starting point and repeat. You can either repeat all the repetitions for 1 leg before moving onto the other or alternate jumps with each rep, one rep take off of the left leg, the next rep take off with the right leg and go back and forth. 1-2-3 Jump- This is a drill that is performed in rhythmic alternating fashion. Take 2 short steps and jump as high as possible. As soon as you hit the ground take 2 more steps and jump with the opposite leg this time. Continue to do that alternating push off legs back and forth without stopping until the desired # of repetitions are complete. Power Skipping- Using an exaggerated powerful skipping motion attempt to jump as high and far as possible with each skip alternating legs with each skip - Usually done for a pre-determined distance such as 25 yards or 40 yards.

Standing triple jump- Standing in the erect position with feet shoulder width apart squat down and jump up of both legs as far and high as possible. Land on either the left or right leg and immediately upon landing again jump up as high and far as possible this time pushing off with the same leg you landed with. Land with the other leg and once more push off with that leg and jump as far as possible. It’s basically a 2-legged jump, immediately followed by a 1-legged jump, immediately followed by another 1-legged jump off the other leg. Walk back to the start and repeat for the desired # of repetitions. 1-leg speed hop- also known as 1-legged bounding - Usually done for a pre-determined distance such as 10 yards or 20 yards. Simply hop on one leg as fast as you can for the desired distance trying to maintain a straight plant leg. This exercise can also be done with a sprint into a 1-leg speed hop. In this version you start off with a moderate sprint and without slowing down begin bounding forward on one leg. Sprinting- The act of sprinting is self-explanatory but what many do not realize is that sprinting is very effective at training short response reactivity. In the programs sprints are done from a standstill and also done with a version called acceleration sprints. In this version you start off striding forward for 10-20 yards at a slower pace and then suddenly accelerate for the required distance.

1-leg box jump- This is an on/off box jump done with one leg. Set a box in front of you at a level somewhere between your ankles and your knees. You will stand on the ground on one leg. Next, hop up and tap the box with the same leg you jumped with and then quickly come back down, touch the ground and instantaneously spring back up on the box. The important thing to focus on is full extension of your leg at ground contact so that you recruit the glutes and hamstrings. If you do it correctly there should be little voluntary effort instead you should reflexively bounce on and off the box.

STRENGTH TRAINING EXERCISES USING WEIGHTSBarbell Back Squat- Position the bar on the squat racks at a height of approximately 3 to 5 inches lower than your shoulders. Preferably using spotters, position your hands evenly on the bar and, with your feet squarely under the bar lift the bar from the rack with the legs. Step back just enough to avoid bumping the rack during the exercise, and position your feet at a comfortable width – this is called the “athletic stance,” where your force output capability is at its maximum – usually a bit more than shoulder width. Your weight should remain centered over the back half of your feet throughout the descent and ascent not on your toes. Descend by first pushing your hips back and then following through by bending your knees. Descend with control into a position where the tops of your thighs are at parallel or a bit below, keeping your torso and back erect so that your hips remain under the bar at all times. Do not allow your knees to drift inward or your torso to incline forward. Vigorously rise out of the squat position following the same path that you descended – the torso and back remain erect and the hips remain under the bar throughout the exercise.

Jump Squat- Assuming the squat stance and position using a weight from 10-30% of your maximum squat descend down into a ¼ squat position and jump up as high as

possible. When landing immediately bend the knees and jump again- Repeat for the desired # of repetitions. The exercise should be executed smoothly and in a rhythmic fashion.

Iso-ballistic jump squat- This is another version of the jump squat – the only difference is rather then being executed rhythmically in non-stop fashion the iso-ballistic squat is executed with a pause (from 3-10 seconds) just above the parallel position before each jump. Reactive Squat- Using 20-50% of your max squat and starting from an athletic “jumping” stance with your hands pulling the bar tightly across your shoulders, from a standing position drop quickly down into a deep squat position and quickly reverse direction, reverse the downward momentum and explosively drive the weight back up. The emphasis here is on rebounding out of the bottom of the hole, not necessarily jumping up. Deadlift- Maintain a flat back, bend your knees and grip the bar at shoulder width, one hand is palm-forward and the other hand is palm-facing back (so the bar won’t roll from your grip – called a mixed grip) Push directly into the ground with your leg muscles while stabilizing with your back muscles – do not pull with your back initially use the power of your legs and butt to drive the bar off the ground. When the bar is just about knee height, begin pulling with your back to finish the movement, stand erect – do not lean backward at the finish of the movement. To lower the bar look up while pushing your hips back and let the bar to the ground at a fairly quick pace.

Leg curls- Lying face down on a leg curl machine, curl the padded lever upward using your hamstrings. Make an effort to point dorsi-flex your ankles while doing the curl by pointing your toes up towards your knee. This movement can and should be substituted with a glute-ham raise if you have access to one.

Glute Ham raise

Barbell or Dumbell Lunge- Begin with your feet hip-width apart, torso erect -take a slow controlled step either forward (dynamic) or backward. From this position, lower your hips so that your forward thigh drops below parallel with the floor. At the fullest stretch, your forward knee will be positioned slightly ahead of your ankle, with your foot pointing straight ahead or slightly in. Allow your trailing knee to drop to a point just before it touches the floor. Continue the exercise by pushing off your front foot until your knee is straight, then step back to the start. Execute all the repetitions for one leg before performing the reps for the other leg.

Barbell or dumbell split squat- Also known as the Bulgarian squat. Performed exactly like the lunge described above, but this time you elevate your back leg on a block or

bench anywhere from 6-18 inches high. This allows for greater range of motion and thus greater activation of all muscle groups.

Romanian Deadlift- also known as semi-stiff legged deadlift – this exercise stresses the hamstrings and gluteals and sues the lower back in a supporting role. With bar in hands and keeping the back tight and arched bend the knees slightly and maintain this bend the entire movement. Bend forward and attempt to push your hips back behind you while slowly lower the bar to just below your knees. You should feel a slight stretch in the hamstrings and glutes as you descend. Make sure to keep the back arched the entire time. When rising concentrate on pushing your feet down and back, like a bull pawing at the ground. Your feet won’t actually move but if you concentrate on that it makes the exercise much more effective.

Calf raise- Using a special calf machine stand on block with the balls of your feet and keep your knees locked. Raise up on your toes as high as possible, hold position momentarily, then return to starting positing letting the heels descend down until you feel a good stretch in the calf.

One-legged weighted calf raises- Standing on a block and holding a dumbell in one hand and holding onto something else with the other hand for support keep the knee locked and descend down until you feel a good stretch. Rise up on your toes as high as possible, hold position momentarily, then return to starting position. Repeat with other leg.

One-legged squat- Although the one-legged squat is usually not done with weights I decided to put it here as it is included in many of the programs including weights. To perform it you start by placing your non-working hand on an object for balance. Extend your non-working leg in front of you and VERY slowly bend your working leg as far as comfortable into a full squat and then return to the start. I’ve found it helpful to start using something to sit back on like a low chair or steps. As this become easier, you can make the exercise more challenging by not holding onto an object for balance, and by using dumbbells.

BODYWEIGHT STRENGTH TRAINING EXERCISES

Ski-Squat- This exercise gets its name because it’s a favorite of competitive skiers who use it to develop awesome quadriceps strength and endurance. Place your feet shoulderwidth apart, about two feet out from the wall, and lean your back against the wall. Bend your knees to a half-squat position. This is position one. After a specified time of 10-20 seconds lower down to position two, about two inches lower. After the specified time, lower another two inches down to position three. You should be about thigh parallel by now. Use another two lower positions, with position five being about as far as you can bend at the knees. The five positions should be done with no rest between them. That' s one set. It can also be done with one leg at a time.

Peterson step-up- Stand on the edge of a low block or bench (1/3 to 1/2 the height of normal bench height). Have the weak leg on the box and the strong leg off the edge of the box. With your hands on your hips, bend at the knee of the weak side, lowering down (two to three seconds) until the sole of your feet almost brushes the floor. Keep the foot parallel to the ground. Pause for one second and return to full extension in about one to two seconds. If possible, don'hold onto anything during the set—the challenge of having t to balance yourself will add to the fatigue. However, you may wish to do this near a wall or squat stand, just in case. Repeat with the other leg.

Split squat- also known as the “bulgarian squat” Face away from a normal height bench and place your rear leg up on the bench. You can check your distance by ensuring that you keep a relatively vertical shin throughout the movement. Keep your chest and trunk vertical throughout. Lower the body down by bending the knee of the lead leg until the knee of the back leg is almost on the ground. Use a slow speed of execution – something like 5 seconds down, pause for 2 seconds, and 3 seconds up. Keep the knee aligned over the foot during the entire movement. After you' exhausted the weak leg, repeat with the ve other leg.

One legged-deadlift- Stand on one leg. Keep the other foot off the ground but roughly parallel with the leg doing the supporting. Bend the knee of the leg supporting your weight slightly, but remember not to change that knee angle during the exercise (get a partner to watch for this, as it will be tempting!). Now, bend at the waist while allowing the back to round and reach slowly toward the floor. If your range allows, touch the floor with the fingertips and return to the starting position. Use a speed of three seconds down, pause for one second at the top and bottom, and three seconds up. You may struggle with balance, but persist—you' also be developing the muscles in the foot! The first time you ll do this, you may find that you' touching down with the non-supporting foot regularly to re avoid falling over. That' okay, but try to minimize this in later workouts. s

One-legged good morning- This is exactly the same as the one-legged deadlift, except you start with a broomstick or other object on your shoulders as you would while doing a conventional good morning exercise. Hold onto the broomstick/bar with your hands in the normal fashion standing on one leg. Now bend forward and down as if you were going to touch your toes only you won’t be touching your toes because your hands will be holding onto the broomstick. Don'panic if five reps is your starting situation, and do t the weak-side first.

King Deadlift- This exercise gets its name from its inventor – Australian strength coach Ian King. Stand on one leg (starting with the weak side) and bend the other leg up until the lower leg is parallel to the ground. Place your hands on the hips or by your side. The aim is to bend the knee of the supporting leg until the knee of the non-supporting leg is brushing the ground. In reality, you may have to settle for a shorter range (you' ll understand why as soon as you do this workout). If the aforementioned is the case—and I expect that it will be—look to increase the range from workout to workout. You' re allowed to flex (bend) forward at the waist as much as you want, and doing so will increase the gluteal involvement. Keep the working knee aligned neutrally throughout the movement. Take three seconds to lower, a one-second pause at each end, and two seconds to lift.

Cross Body off box lunge- With a slightly narrower than shoulder-width stance, stand on top of a 12 to 18 inch step or block. Make sure there' extra floor space on the sides. With s one leg, step down and behind you and across the body to the floor. Next, push with the elevated foot so that the "crossed-under" foot can return to shoulder-width position on the step. Scissor hip extension- Lie on your back with your feet elevated on either a high bench or pressed firmly against a wall. The legs should be slightly bent. Perform two movements at the same time. First, bring the non-working leg towards your chest (hip flexion and knee flexion). Second, lift your hips off the ground by concentrating on driving the working leg down. Both movements must be executed as fast as possible.

Natural glute-ham raise- Kneel down and lock your feet under something solid and heavy (a partner can do just fine, but he must be able to hold you down). The trunk is upright and the arms are alongside the body. Find a pad or something to rest your knees on. A towel will work just fine for most. Without rounding your back Lower yourself towards the ground as slowly as possible. To do so you must produce a powerful hamstring contraction or else you' find yourself embedded in the floor! If you' able to ll re bring yourself back up on your own, do so, but most guys will need a little push-off with the arms to get moving.

Slow tempo lunge- Standing with your feet hip width apart take a large step forward with one leg and descend down very slowly until your front knee is well over your toes

and the back knee is just shy of the ground. Pause for 2-3 seconds and slowly rise back up but don’t move your feet. Stay in that position and complete all the reps for that leg before moving onto the other leg. Standing hip abduction- This exercises strengthens the outer hips and glutes. Find something to lean against and take the opposite leg and slowly raise it as high as possible and try to hold that position for 3-5 seconds. The finished position would appear as if you’re kicking something. Bring the leg back down slowly and repeat.

Jump in place + land in deep lunge- With your feet shoulder width apart and standing erect take a moderate jump in the air and land in a deep lunge position. Attempt to “stick” the landing without any bouncing or unnecessary movement. Try to absorb the impact with both legs so that your lead knee doesn’t absorb all the stress. This places the majority of the stress on the hamstrings and glutes. From the landing position stand up and repeat.

THE ROUTINES Plyometric routinesThe plyometric programs are designed for those who wish to perform a program without any concurrent weight training or for those who want to supplement their weight training. These programs, unlike most plyometric programs, address multiple aspects of explosiveness. Not only do they increase your traditional plyometric ability, but they also consist of exercises to improve your rate of force development, short response reactivity, full rom strength, full rom reactivity, and starting strength. The combination of exercises and training means in these programs has proven very effective. For those who wish to perform their own weight training programs along with the plyometric programs this can be done very successfully but I recommend the volume of plyometrics be reduced to no more then 2 days per week. The flow of the plyometric routines will carry you from one level to the next and from less advanced exercises into more advanced exercises. Upon first glance it may appear that there are just a bunch of exercises lumped together into each routine without a specific purpose, but what you should understand is that each

exercise is done for a specific purpose to address a certain function. Each exercise, each workout, each week, and each phase of every program is designed to carry you forward into the next workout, week, exercise, phase, or program. It helps to understand the natural progression of exercises and different types of exercises. Here is a general overview of each category of exercise along with some exercises in each category. Keep in mind, however, that there is always going to be considerable overlap in between exercises and/or types of exercises but we can make a general divide and outline the progression for each type. The types of exercises and their focus can be divided up into 6 different categories. These areas are: 1. 2. 3. 4. 5. 6. Lower intensity plyometric drills General mixed jump exercises Exercises specifically for rate of force development and power Medium to high intensity reactive methods Exercises to enhance full range plyometric strength and power Short response reactive methods

Low intensity drills These drills are lower in intensity and generally done earlier in the training session to progress from the warm-up into the more intense exercises. They tend to be fairly low intensity in nature and address movement efficiency. The general flow of exercises in this category is: 1. 2. 3. 4. 5. 6. Ankle bounce Slalom jumps Ricochet jumps 4-star drill Bent over donkey ankle bounces Unilateral (1-legged) varieties of the previous

General Jump Exercises These exercises are fairly general in nature and can train a good mix of different strength qualities, depending on how they are performed. In the routines listed you will often seen these exercises prescribed with varying recommendations to work on different aspects of power. They are also frequently prescribed in higher volume fashion to contribute towards muscular growth and some power endurance. The general flow of exercises in this category goes: 1. 2. 3. 4. Squat Jumps (from either ¼, ½, or full squat) Paused Squat jumps Consecutive broad jumps Leapfrog jumps

5. Double leg bounding

Power and Rate of Force Development These exercises are characterized by a very large focus on moving your body at high force from nearly a dead stop or a paused position. Fundamentally these drills aren’t really “plyometric” drills, because of the lack of movement preceded by accelerated muscular stretching, but they are still often lumped into this category. For most of these movements, the focus is on generating as much voluntary force as possible as quickly as possible without much bouncing or cheating. Exercises in this category are very effective at enabling you to develop peak power from a near standstill. The general flow of exercises in this category goes: 1. 2. 3. 4. 5. 6. Star jump Standing broad jump 1-leg step-up jump On-box jump Box squat jump 3 step lead into on-box jump

General Plyometric Exercises These are typically the types of exercises people think of when they hear “plyometrics”. I won’t bore you to death explaining plyometric training methods again! The general flow of exercises in this category goes: 1. Rim jumps 2. Low side to side box jumps 3. Lateral cone jumps 4. Low box depth jumps for height 5. Low box depth jump (18 inches) Leap frog jumps Week#1 3x30 (per leg) 3x20 yards 3x6 3x5(per leg) 3x6 3x25 yards Week#2 4x30 4x20 yards 4x5 4x5 4x5 3x25 yards Week#3 3x30 3x20 yards 3x5 3x5 3x5 3x25 yards

INTERMEDIATE PLYOMETRIC PROGRAM This program is for the intermediate trainee who chooses to embark on a program of plyometric training without following one of the strength training routines. This program should not be done at the same time as the other intermediate routines because those routines already incorporate both strength-training and plyometrics. Following one of those programs while also attempting to perform this program could possibly lead to over-training. If someone wanted to follow this program in conjunction with a strength training program it can be coupled with the Novice strength training program with fantastic results! If you take a look at the program you might notice the frequency is 2 times per week for the entire duration of the phase. If you’re like many you may be asking the question, “well if it’s an intermediate program then why is the frequency less than the beginners program?” This is a good question. The reason is mainly because the drills used throughout the program are of the more intense varieties with more depth jumps and other highly stressful/reactive exercises. These exercises take longer to recover from. Another reason for this is because intermediate athletes, due to their enhanced athletic capabilities, are capable of applying more intensity into their exercises and often take longer to recover from that intensity. The more advanced one becomes the better their muscular recruitment capabilities, the more damage they can inflict on their body. Any individual can rapidly improve their performance, but their capacity to recover from that activity doesn’t advance so rapidly. To get a better grasp on this concept think of this. Which athlete puts more stress on their body, the athlete who performs a 40-inch vertical leap or the athlete who performs a 20inch vertical leap? For this reason novice athletes can not only get away with, but also respond to more volume in their training because they are not creating as deep of an inroad into their system. The more advanced you become, at least initially, the longer you need to recover from highly intense training and thus a frequency of 2 times per

week is optimal on this program. As you become more advanced your system will gradually adapt to more volume. Intermediate Plyometrics program guidelines: Goals: A large focus on improving reactive strength Intensity: Moderately High to High Length: 4 phases with each phase 3 weeks in duration Frequency: 2 times per week with at least 2 full days between workouts. On the final week of each phase test first and then perform the workout. At the conclusion of the entire program take an entire week off then re-test. Rest Intervals: 2 minutes for most exercises. At least 3 minutes between sets on depth jumps and sprints. Phase I Exercise Bent over straight legged donkey ankle bounce 1-2-3 jump Rhythmic ¼ jump squat Broad Jump Low box depth jumps 20 yard sprints (rest 5 minutes after depth jumps before performing) Low squat ankle jumps Phase II Exercise 4-star drill (try to keep legs straight and emphasize speed) Lateral cone jump (use cone or object high enough to be challenging) 1-leg step-up jump (use high box on 1st 2 sets – lower box on last 2) Power Skipping Medium box depth jump (box around 18 inches) 30 yard sprints (rest 5 minutes after depth jumps Week#1 3x10 4x10 4x8 (per leg) 4x40 yards 4x5 4 Week#2 3x10 4x8 4x8 4x40 yards 5x4 5 Week#3 3x10 3x8 3x8 3x40 yards 4x4 4 Week#1 4x30 4 sets – 4 jumps per leg per set 4x8 4x6 4x5 4 4x40 Week#2 Week#3 4x30 3x30 4 sets 4x8 4x5 4x5 5 4x40 4 sets 3x6 3x5 3x5 4 3x40

before performing) Double Leg Bounding (hold hands behind head and descend into ½ squat position prior to each jump) Phase III Exercise 1-leg slalom jump Barrier jump On-box jump Low side to side box jump Rhythmic lunge jump 1-leg speed hop 40 yard sprints (rest 5 minutes after 1 leg hops before sprinting) Phase IV Exercise One legged bent over donkey ankle bounce Low box jumps for height Box squat jump (2 sets jumping up followed by 2 sets jumping out – preferably jump up or over boxes) 3 steps + jump off 1 leg for height High drop jump followed by 5 knees to chest tuck jumps (absorb the shock and hold the landing for 3 seconds and then execute the tuck jumps) 40 yard acceleration runs (stride 15 yards into a max 40 yard sprint – rest 5 minutes after the previous exercise before sprinting) Rhythmic full squat jumps Advanced Plyometrics Program

3x25 yards

3x25 yards

3x25 yards

Week#1 4x30 (per leg) 4x8 4x5 4x8 4x10 (5 per leg) 4x25 yards 5

Week#2 4x30 4x8 4x5 3x8 4x10 4x25 yards 5

Week#3 3x30 3x8 3x5 3x8 3x10 3x25 yards 4

Week#1 3x30 (per leg) 4x5 4x6 3x4 jumps per leg 4 sets

Week#2 3x 30 4x5 4x6 3x4 jumps per leg 4 sets

Week#3 3x 30 3x5 3x6 3x4 jumps per leg 3 sets

4 2x15

4 2x15

4 2x15

This program is for the advanced athlete who wants to do a plyometrics routine in the absence of any additional strength training. It is designed for someone who is already at the advanced level or for someone who has worked his way up through the previous workouts.

Goals: Improve Reactive ability Intensity: High Length- 4 Phases with each phase 3 weeks in duration Frequency- Two times per week with at least 2 days between workouts Rest- 1-3 minutes between exercises Phase I Exercise Bent over donkey ankle bounce Hurdle barrier jumps 1-leg step up jump 1-leg speed hop Shock lunges 30-yd acceleration runs Paused Squat jump Phase II Exercise Ricochet jump Side to side box jump On-box jump Low squat jump into jump lunge 1-2-3 jump 30 yd acceleration runs Consecutive broad jumps Phase III Exercise 1-leg 4 star drill Barrier jumps Box squat jump Drop jump into ½ squat Straight leg bounding (power skipping with an emphasis on straighter legs) 40 yd accelerations Double leg bounding Week #1 2 x 10 (around and back equals 1 rep) 4x8 3x6 3x5 3x50 yards 3 3 x 25 yards Week#2 2 x 10 4x8 3x6 3x5 3 x 50 yards 3 3 x 25 Week#3 2x5 2x6 3x6 3x5 3 x 50 yards 3 3 x 25 Week#1 3 x 50 4 x 10 3x8 3 x 5/leg 3 x 5 jumps/leg 4 3x8 Week#2 3 x 50 4 x 10 3x8 3 x 5/leg 3 x 5 jumps/leg 4 3x8 Week#3 3 x 50 2 x 10 2x8 3 x 5/leg 3 x 5 jumps/leg 4 3x8 Week#1 3 x 50 4x6 4x6 3 x 25 yards 4 x 5/leg 3 2 x 10 Week#2 3 x 50 4x6 4x6 3 x 25 yards 4 x 5/leg 3 2 x 10 Week#3 3 x 50 2x6 2x6 3 x 25 yards 2 x 5/leg 3 2 x 10

yards Phase IV Exercise Bent over donkey ankle bounce 2/1 (Jump off 2 legs land with one and alternate) Medium height depth jumps (box about 18 inches) On box jump with 3 step lead in Drop jump into lunge position Sprint into 1-leg speed hop 40 yard accelerations Leap frog jumps Week #1 3x20 4x3 4x3 4 x 3/leg 3 x 20 yards 4 3 x 25 yards Week #2 3 x 20 4x3 4x3 4 x 3/leg 3 x 20 yards 4 3 x 25 yards

yards

Week#3 3 x 20 4x3 4x3 4 x 3/leg 3 x 20 yards 4 eliminate

BODYWEIGHT STRENGTH TRAINING PROGRAM This is a 12-week strength-training program that utilizes bodyweight exercises. It is an excellent means of increasing general leg strength for those who don’t have easy access to a weight-room. Although the program utilizes bodyweight exercises, it is still not only very effective, but you will be amazed how stressful working with your own bodyweight can be as anyone who’s ever used it or does use it will attest to! This program can be used along with any of the other plyometric programs or even by itself. If done in conjunction with one of the plyometric programs it will be most effective if done on the same day but can also be done on the plyometrics off-days if time constraints are an issue. Bodyweight strength training program guidelines: Goals: Improve general leg strength, balance, and coordination Intensity: Low to moderate Length: 4 phases with each phase 3 weeks in duration Frequency: 2 times per week Rest Intervals: generally about 1-minute in between sets Tempo: On the workout tables you will see a box marked “tempo” that will have number that look similar to this “3-0-2” This tells you how fast to perform the movement. The first number is the negative portion, the 2nd number is the pause, and the 3rd number is the positive portion. So, if you were doing a squat and the tempo prescribed was “3-02” you would take 3 seconds to lower yourself down, pause for 0 seconds, and take 2

seconds to rise up. Exercises marked with an “x” should be done with an explosive concentric. PHASE I Exercise Low Peterson step-up (try to raise box each week) 2-leg ski squat Split squat Cross body off-box lunge Standing hip abduction Scissor hip extension Bodyweight squats (go all the way down) Phase II Exercise High Peterson step-up 2-leg ski squat One-leg squat (hold onto something for balance) Scissor hip extension Side to side twisting lunge 1-leg straight leg deadlift Burnout complex: squat, alternating lunge (per leg), alternating step-up jumps, jump squats Phase III Exercise 1-leg ski squat Tempo 5 positions with 5 second pause at each position Week#1 2 sets Week#2 3 sets Week#3 3 sets Tempo 3-0-2 5 positions – hold each position 15 seconds 3-0-2 3-3-x (pause 3 seconds at the top) 3-0-2 3-0-2 Perform 20 reps of each in succession Week#1 2x20 2 sets 2x10 2x20 per leg 2x25 2x10 per leg 2 sets Week#2 Week#3 4x20 3x20 4 sets 3 sets 4x10 4x20 3x25 4x10 2 sets 3x10 3x20 3x25 3x10 2 sets Tempo 3-1-2 10 second pause at each position with 5 positions 5-2-2 3-2-2 3-2-2 3-0-x 1-0-x Week#1 2x25 (per leg) 2 sets 2x15(per leg) 2x20 (per leg) 2x25 (per leg) 2x20(per leg) 2x100 Week#2 Week#3 3x25 3x25 3 sets 3x15 3x20 3x25 3x20 3x100 3 sets 3x20 3x20 3x25 3x20 3x100

King deadlift Low squat ankle jump into paused lunge 1-leg good morning 1-leg squat on box

3-0-2 Explosive- hold the landing for 3 seconds 3-0-2 3-0-x (place low box behind you and sit down and back on it) 3-0-2 on split squats, explosive on step-up jumps and one legged hops

2 sets of as many reps as possible 2 x 6 per leg 2x max reps 2x10

3 sets of A.M.R.A.P. 3 x 6 per leg 3x max reps 3x10

3 sets of A.M.R.A.P 3x6 per leg 3x max reps 3x10

Burnout complex: perform 20 reps of each in non-stop fashion 1 leg at a time: split squat, step-up jump, one legged hop in place Phase IV

2 sets per leg

2 sets per leg 2 sets per leg

Exercise Split squat (pause at the bottom and explode up) Jumping King deadlift 1-legged ski-squat Natural glute-ham raise Free standing 1-legged squat Scissor hip extension Burnout complex: perform 20 reps each non-stop of squat, alternating lunge, alternating step-up jump, jump squat

Tempo 5-3-x 1-0-x 5 positions- 10 second pause at each position Lower slowly and push yourself back up 3-0-2 2-0-x Explosive

Week#1 3x8 3x max reps 2 sets (per leg) 2x15 2x10 2x20 2 sets

Week#2 4x8 4x max reps 3 sets 3x15 3x10 3x20 2 sets

Week#3 3x8 3x max reps 3 sets 3x15 3x10 3x20 3 sets

NOVICE WEIGHTS PROGRAM This is a strength-training program designed for someone who is either a beginner or has less than 1 year of consistent weight training experience. The routine is designed to not only prepare and condition your body but also dramatically increase your strength in the

lower body. It does this by focusing on the largest “bang for the buck” exercises, those being the barbell squat and deadlift. The routine is not overly fancy or dramatic as most effective strength training programs tend to share one thing in common and that is lots of basic hard, heavy exercises. The program calls for 2 training days per week with at least 2 days rest between workouts. The program works really nice when the novice plyometrics program is added in during the last 2 phases, which would call for 2 plyometric workouts per week and 2 strength training workouts per week. Ideally you would perform the plyometrics program on the same days that you weight train but this is not absolutely necessary. You could set it up any number of ways as long as you have 2 whole days rest in between weight training workout. For example you might set it up like this: Option #1 Monday- Lower body workout #1 + plyometrics Tuesday- Off Wednesday- Plyometrics Thursday- Off Friday- Lower body workout #2 Saturday and Sunday- Off Option #2 (this would be ideal but not absolutely necessary) Monday-Off Tuesday-Lower Body workout #1 + plyometrics Wednesday Off Thursday- Off Friday Lower Body workout #2 + plyometrics Saturday and Sunday- Off Option #3 Monday- Lower body workout #1 Tuesday- plyometrics

Wednesday-off Thursday- Lower body workout #2 Friday-off Saturday- plyometrics Sunday- Off Option #4 (this option calls for only 1 plyometrics training day per week – this will still allow you to benefit and I actually suggest this option if you really need to work on your strength because you will be a lot fresher throughout the week) Monday- Lower body workout #1 Tuesday- off Wednesday- Plyometrics Thursday- off Friday- Lower body workout #2 Just make sure you only add the plyos in on the last 2 phases. Program guidelines: Goals: Dramatically increase lower body strength Intensity: moderately heavy loading Length: 4 phases with each phase 3 weeks in duration Frequency: 2 times per week Rest Intervals: 3 minutes between sets of most exercises – no specific need to monitor rest intervals – simply go whenever you’re ready and make sure you are fresh so that you can hoist the heavy iron! PHASE I (Week 1-3) Exercise Workout A: Squat Sets/reps 3x10 Remarks Do 2-3 prior warm-up sets of 8-10 reps adding weight to the bar with each set. Once you build up to your working

Leg curl or glute ham raise Calf raise Workout B: Deadlift Barbell lunge 1-legged calf raise

4x8 3x20 3x8 3x8 (per leg) 3x20

weight try to stay with the same weight for all 3 sets

Do 2-3 prior warm-up sets of 6-8 reps adding weight to the bar with each set. Once you build up to your working weight try to stay with the same weight for all sets Perform all the reps with 1 leg before advancing to the other leg. Follow the weak-side rule and work the weaker leg first Hold dumbell

Phase II (Week 4-6) Exercise Workout A: Squat Explosive squat Leg curl Calf raise Workout B: Barbell Split Squat Romanian Deadlift Glute-Ham raise 1-legged calf raise Sets/Reps Remarks 4x8 2x5 4x8 4x20 Using 50% of the weight you used in your heaviest squat attempt perform 2 sets of 5 reps trying to explode up as fast as possible

4x8 4x8 3x15 3x20/leg

Elevate back leg on a bench approximately 12-18 inches high Focus on keeping back arched and pushing hips back Lower yourself slowly and use your arms to push yourself back up

Phase III (Week 7-9) Exercise Workout A Squat 1 and 1/3 squat Leg curl Sets/reps Remarks 4x6 2x8 4x6 Squat all the way down come up 1/3 of the way then go back down and then come all the way up = 1 rep

Calf raise Workout B: Platform Deadlift Barbell lunge 1-leg calf raise

3x20

4x5 4x8/leg 3x20/leg

Stand on a very low box or plate for a greater range of motion.

Phase IV (Week 10-12) Exercise Workout A: Squat ¼ squat Leg curl Calf raise Workout B: Sets/reps Remarks 4x4 2x4 4x5 4x15 After your regular squats add additional weight to the bar and do 2 sets of 4 reps using a much shorter range of motion

Deadlift from 4x4 blocks Regular Deadlift Dumbell lunge 1-leg calf raise 2x4 3x8 3x20/leg

Put blocks, boxes, or plates under the plates to elevate the bar about 8 inches higher than normal. After elevation the bar should be just below your knees. Strip some weight off the bar and perform 2 sets of regular deadlifts

INTERMEDIATE WEIGHTS + PLYOMETRICS PROGRAM (FOCUS ON STRENGTH) This program is for the intermediate athlete who needs more focus on strength. It is a complete program utilizing both weights and plyometrics, however more emphasis is placed on developing strength. For this reason this program should not be used in conjunction with any other plyometrics or strength training programs. When you look over the program the first thing you will notice is the volume of weight-room work is much higher than the volumes of plyometric work. The reason for this is due to the fact that the tests will indicate this trainee already has reactive (plyometric) capabilities that are ahead of his basic strength. I have included enough plyometric work to allow one to

continue enhancing and increasing this aspect of his performance without interfering with increases in strength. The program calls for 2 fairly high volume weight room session and included in these sessions is a low volume of plyometric work as well. On a separate day each week there is a program consisting of plyometrics exercises. So, basically, on this program you will train with high volume weights/low volume plyometrics 2 days per week and on a separate day perform a higher volume plyometrics session. It is important to note that during the 4th week of each phase the plyometrics session is dropped. This is perfectly fine and will actually enhance your explosiveness as the lower volume will allow you to fully recover and you will actually find yourself feeling most explosive heading into the 1st week of each phase. Some individuals will need to drop the once/weekly plyometrics session throughout the duration of the entire program if this extra workout is being detrimental to their strength gains. This is quite easy to determine. If you are not gaining strength and able to add weight to the bar each week in the weight room then there’s a good chance you’re overtraining so in order to promote better recovery cut out the plyometrics session. Intermediate strength focused program guidelines: Goals: The number 1 goal is to dramatically increase basic strength by focusing on compound movements such as squats and deadlifts. The #2 goal is to increase reactive (plyometric) strength and efficiency. Intensity: Moderately High to High Length: 4 phases with each phase 4 weeks in length for a total of 16 weeks Frequency: 2 weight training sessions per week with 1 plyometrics session. The plyometrics session is termed the “B” workout and should ideally fall in between the “A” and “C” workouts during the week. So you might do Workout A on Monday, Workout B on Wednesday, and Workout C on Friday or Workout A on Tuesday, Workout B on Thursday and Workout C on Saturday. Rest Intervals: Generally 2-3 minutes between sets Testing: Retest prior to the 2nd workout every 4th week. Phase I (weeks 1-4) Exercise Workout A: Single leg onoff box jumps Week#1 2x10 Week#2 3x10 Week#3 4x10 Week#4 Remarks 3x10 Per leg – start off with low box and try to slightly increase the height each week

Lateral cone jump

2x10

3x10 4x10

4x10 4x10

3x10 3x10

Single leg squat 3x10

Dumbell Split Squat Barbell Squat

3x10 3x8

4x8 4x6

5x6 6x4

3x6 3x5

Use fairly low cone or other obstacle – Do not try to go 100% Start off holding onto an object for balance – try to progress into performing the movement unassisted Perform 2 lighter warm-up sets before counting the working sets. Try to stick with the working weight for all sets.

Leg Curl Calf raise Workout B: Plyometrics 1-leg slalom jump Standing broad jump 1-leg step-up jump Low box depth jump 1-leg speed hop (1-legged bounds) Workout C: Leg curl Dumbell lunge Deadlift Leg extension 1-leg calf raise Single leg onoff box jumps Lateral cone jumps

3x10 3x20 2x15 2x8 2x8 2x6 2x20 yards 3x10 3x10 3x8 3x15 3x20 2x10

4x8 4x15 2x15 2x8 2x8 2x6 2x20 yards 4x8 4x8 4x6 4x12 4x15 3x10

4x6 4x15 2x15 2x8 2x8 2x6 2x20 yards 5x6 4x6 5x5 4x10 4x20 4x10

3x6 3x20 N/a N/a N/a N/a N/a

Eliminate this session during week #4 Per leg Box less than 18 inches

3x6 3x6 3x5 3x8 3x20 3x10

2x10

3x10

4x10

3x10

Per leg – start off with low box and try to slightly increase the height each week

Phase II (weeks 5-8) Exercise Workout A: Week#1 Week#2 Week#3 Week#4 Remarks

Jump rope

3x1 minute

3x2 minutes

3x3 minutes

3x3 minutes

Squat Dynamic Lunge (barbell or dumbbell) Leg curl Calf raise Drop jumps (shock jumps or altitude landings)

3x8 3x10

4x6 4x8

6x4 4x6

3x5 3x6

Start off doing 3 sets of 1 minute increase the duration 1 minute each week until you get to 3 minutes Step forward and push forcefully back to starting position. Alternate legs Use a high box at least 20% higher than your best vertical. Attempt to “stick” the landing landing in ¼ squat position. Eliminate this workout during the 4th week Per leg – use low box or stairs 6-8 inches. Be fast and move reflexively fully extend the plant leg at ground contact Use a box placing you in ¼ to ½ squat position when sitting back. Jump up as high as possible for 2 sets and out as far as possible for 2 sets. Per leg Use a box of challenging height – jump on step off and repeat for 6 repetitions.

3x10 3x15 N/a

4x8 4x12 N/a

4x6 4x10 4x6

3x6 3x15 3x5

Workout B: (Plyometrics) Single leg box jumps

2x15

2x15

2 x15

N/a

Box squat jumps

3x6

3x6

3x6

N/a

3 steps + jump for height from one leg On box jumps

3x6 2x6

3x6 2x6

3x6 2x6

N/a N/a

40 yard sprints Workout C: Jump rope

4 3x1 minute N/a

4 3x2 minutes N/a 4x6

4 3x3 minutes 4x6 6x4

N/a 3x3 minutes 3x5 3x5

Drop Jumps (shock jumps or altitude landings) Platform Deadlift 3x8

Land in ¼ squat position attempting to “stick” the landing Stand on a very low box

Barbell split squat Leg curl 1-legged calf raise

3x10 3x10 3x15

4x8 4x8 4x12

4x6 4x6 4x10

3x6 3x6 3x8

or plates about 6 inches high to increase the range of motion

Per leg

Phase III (weeks 9-12) Exercise Workout A: Ankle Jumps Knees to chest tuck jumps Deep consecutive lunge jumps Squat ¼ squat Week#1 3x15 3x8 3x8 2x8 2x8 Week#2 3x15 3x8 3x8 3x6 3x6 Week#3 3x15 3x8 3x8 4x4 4x4 Week#4 Remarks 3x15 3x8 3x8 2x5 2x5 Per leg

Jump squat (rhythmic) Leg curl Workout B: (Plyometrics) 1-leg 4 star drill Double leg bounding Lateral cone jump Standing triple jump 40 yard dash Workout C: Deadlift Deadlift from blocks

3x10

4x8

4x8

3x8

3x8 3x10 3x25 yards 3x10 6 sets 4 sets 2x8 2x8

3x6 3x10 3x25 yards 3x10 6 sets 4 sets 3x5 3x5

3x6 3x10 3x25 yards 3x10 6 sets 4 sets 4x4 4x4

3x6 N/a N/a N/a N/a N/a 2x5 2x5

Add weight to the bar after doing the regular squats and proceed to do supramaximal ¼ rep squats Use 30% of your max squat and perform ¼ jump squats in rhythmic fashion

Per leg Hands behind head- Drop into full squat position before each jump. Use fairly high cone or obstacle – make it very challenging Alternate the lead leg with each set

Use boxes to elevate the plates 6-8 inches higher

Rhythmic Jump Squat Glute-ham raise

3x10 3x15

4x8 3x15 3x15 3x8 3x8

4x8 3x15 3x15 3x8 3x8

3x8 3x15 3x15 3x8 3x8

than normal – Add additional load to the bar after the regular deadlifts Use 30% of max squat Lower yourself under control and use your arms to assist yourself back up

Ankle jump 3x15 Knees to chest 3x8 tuck jump Low squat ankle 3x8/leg jump into paused lunge

Hold the lunge position for 3 seconds

Phase IV (weeks 13-16) Exercise Workout A Jump rope ½ Squat Week#1 3x2 minutes 4x8 Week#2 3x3 minutes 4x6 Week#3 3x3 minutes 2x5 Week#4 3x3 minutes 2x5 Remarks

Jump Squat with pause (isoballistic jump squat)

3x8

4x6

5x6

3x6

Dumbell stiff legged deadlift off box

3x8

3x8

2x8

2x8

3 steps + jump for height

2x4 with 1 leg/ 2x4 with both legs

2x4 with 1 leg/2x4 with both legs

2x4 with 1 leg/2x4 with both legs

2x4 with one leg/2x4 with both

Stop 1-2 inches above parallel rather then going all the way down Use 35% of max squat – descend down and pause 3 seconds 2 inches above parallel with each rep and explode up trying to leave the ground. Use fairly light weight – slightly unlock knees – and bend down all the way for a good stretch Perform 2 sets each per leg executing a one legged takeoff and

legs High depth jumps Workout B: (Plyometrics) 3x6 Week #1 4x6 Week #2 4x6 Week #3 3x5 Eliminate this workout during week 4 N/a N/a N/a N/a N/a 3x3 minutes 3x6 2x4 with one leg/2x4 with both legs 2x5 3x6

then 2 sets of 4 reps jumping off of both legs Use a box of 18 inches or higher

Power skipping Low box jump for height Hurdle barrier jumps Low squat foot jump into lunge jump. 40 yard sprints Workout C: Jump rope High depth jumps 3-steps + jump for height

3x40 yards 3x6 3x6 3x5 4 3x2 minutes 3x6 2x4 with 1 leg/ 2x4 with both legs

3x40 yards 3x6 3x6 3x5 4 3x3 minutes 4x6 2x4 with 1 leg/2x4 with both legs

3x40 yards 3x6 3x6 3x5 5 3x3 minutes 4x6 2x4 with 1 leg/2x4 with both legs

Per leg

Romanian Deadlift Jump Squat with pause (isoballistic jump squat) Barbell lunge (step-back)

4x8 3x8

4x6 4x8

2x5 5x6

Perform 2 sets each per leg executing a one legged takeoff and then 2 sets of 4 reps jumping off of both legs On each rep pause 3 seconds 2 inches above parallel and explode up. Use 25% of maximum squat Instead of stepping forward step back with each rep. Complete all the reps for one leg before moving on

3x8

3x8

2x8

2x8

to the other

Intermediate Strength training + plyometric workout This workout is for the intermediate trainee who is fairly well balanced between strength and reactivity. The routine provides a good blend of both strength training and plyometric work and incorporates it all into the same workout for convenience. The routine calls for 2 workouts per week, “A” and “B”. It is divided up into 2 phases each 4 weeks long for a total of 8 weeks. At the conclusion of the 8-week series I would suggest one retest to determine which aspect of their power development needs more work or has responded more to the training. Most trainees make fantastic progress on this program due to the excellent combination of strength and power production it focuses on but at the conclusion you may find which side (strength or plyometric power production) responds better for you. If at the conclusion of the 8 weeks, it is determined that strength needs more work, then one could follow one of the strength- based programs. If plyometric efficiency and speed needs more work, then one of the plyometric workouts can be followed. Intermediate Strength Training + plyometrics routine guidelines: Goals: Provide a good blend of training to both increase general strength and reactive strength and rate of force development. Intensity: Progressing from moderate to high throughout each phase Length: 8 weeks total divided up into 2 separate 4-week phases Frequency: 2 days per week with at least 2 whole days between workouts.

Phase I (Weeks 1-4) Exercise Workout A: Rim or high object jumps Rhythmic lunge jumps Depth jump Jump squat Week#1 3x10 3x10 (per leg) 3x5 3x12 Week#2 4x10 4x10 4x5 4x10 Week#3 5x10 5x10 5x5 5x8 Week#4 2x10 2x10 2x5 2x6 Comments Perform continuously – 2 minutes rest between sets 1 minute rest Use moderate box around 18 inches – 2 minutes rest Perform rhythmically and

with barbell Romanian Deadlift

(10% of max squat) 3x6 (70%)

(15%) 4x5 (75%)

(20%) 5x4 (80%)

(25%) 3x3 (85%)

Full Squat Workout B: Full Squat Romanian Deadlift Jump Squat with barbell Depth Jumps Rhythmic Lunge jumps Rim or high object jumps

3x6 (70%)

4x5 (75%) 4x5 (80%) 4x5 (80%) 4x10 (15%) 4x5 4x10 4x10

5x4 (80%) 5x4 (85%) 5x4 (85%) 5x8 (20%) 5x5 5x10 5x10

3x3 (85%) 3x3 (90%) 3x3 (90%) 2x6 (25%) 2x5 2x10 2x10

continuously – The percentage given is the % of max squat – 2 minutes rest The percentages listed are guidelines – The important thing is to add weight to the bar each week – 3 minutes rest 3 minutes rest

3x6 (75%) 3x6 (75%) 3x12 (10%) 3x5 3x10 3x10

3 minutes rest 3 minutes rest 2 minutes rest 2 minutes rest – moderately high box 1 minute rest Perform continuously – 2 minutes rest

Phase II (weeks 5-8) Exercise Workout A: One leg box Jumps Week#1 3x12 Week#2 4x12 Week#3 Week#4 Remarks 5x12 2x12 Perform rhythmically and try to keep ground contact time as short as possible with full extension of the plant leg at ground contact – use a box just below knee level in height – 1 minutes rest 2 minutes rest – from ¼ position sitting on box jump up as high as possible, preferably onto another box. Use moderately high box around 18 inches – 2 minutes rest

Box squat jumps Depth jumps

3x6

4x6

5x6

2x6

3x5

4x5

5x5

2x5

Jump squat with barbell Romanian Deadlift Full squat Workout B: Full Squat Regular Deadlift Jump squat with barbell Depth jumps Box squat jumps One leg box jumps

3x12 (15%) 3x6 (75%) 3x6 (75%) 3x6 (75%) 3x6 (80%) 3x12 (15%) 3x5 3x6 3x12

4x10 (20%) 4x5 (80%) 4x5 (80%) 4x5 (80%) 4x5 (85%) 4x10 (20%) 4x5 4x6 4x12

5x8 (25%) 2x4 (85%) 2x4 (85%) 2x4 (85%) 2x4 (90%) 5x8 (25%) 5x5 5x6 5x12

2x5 (30%) 2x3 (90%) 2x3 (90%) 2x3 (90%) 2x3 (95%) 2x5 (30%) 2x5 2x6 2x12

2 minutes rest 3 minutes rest 3 minutes rest

3 minutes rest 3 minutes rest 2 minutes rest 2 minutes rest 2 minutes rest 1 minutes rest

Intermediate Reactive Workout This workout is for the intermediate athlete who needs more focus on reactive strength, speed, and rate of force development. It also includes a good amount of regular pure strength work to continue to increase muscular strength throughout the program while prioritizing speed and plyometrics. The program calls for 2 workouts per week termed “A” and “B”. They should be performed with at least 2 entire days between workouts for example, Workout A on Monday, Workout B on Friday. The exact days really aren’t important just make sure you have at least 2 days rest between workouts. Testing should occur prior to the 2nd workout during the 4th week in each phase. So you will test every 4 weeks prior to the 2nd workout. At the conclusion of this workout you may want to move into more of a strength based phase to continue to push your levels of strength upwards. Intermediate reactive workout guidelines: Goals: Dramatically prioritize and increasing reactive strength, speed, and rate of force development while further increasing basic strength. Intensity: moderately high to high Length: 16 weeks total consisting of 4 phases – each phase 4 weeks in duration

Frequency: 2 times per week

Exercise Workout A: 4-star drill Low squat ankle jump Rhythmic lunge jumps 1,2,3 jump 20 yard sprints Squat

Week#1 2x10 3x30 3x10 (per leg) 3x5/leg 3 3x8

Week#2 4x10 5x30 5x8 4x5/leg 4 4x8

Week#3 4x10 5x30 5x6 (weighted) 4x5/leg 5 3x6

Week#4 2x10 3x30 3x6 (weighted) 2x5/leg 3 3x6

Remarks 1 minute rest 1 minute rest Add weight in the form of light dumbbells – 2 minutes rest 2 minutes rest 2 minutes rest Rest 5 minutes after the sprints before performing squats - 3 minutes rest in between sets of squats 2 minutes rest 2 minutes rest – low box

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