Back To The Beginning

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It was just over three years ago that I wrote a short article called "The Sports Cognition Framework" for my squeaky new blog.  It was one of the first five articles I had ever written and it shows.  However, it captured the core of my passion and interest which is reflected in the name I chose for this blog, Sports Are 80 Percent Mental.  Learning about the connections between skill, psyche, and tactics in sports remains my goal.

Between that simple start and today's post (#185 for those scoring at home), I have wandered all across the spectrum of sports science, sports medicine, sports psychology and fitness research.  Along the way, there was a weekly column for Livescience.com and a few dozen articles for Life's Little Mysteries.

However, the focus of my writing has become blurred.  In a quest to get freelance articles placed online and expand the readership of this blog, I've tried covering an ever-increasing universe of sports research.  As with many endeavors, it is time to refocus on the original intent of this project.  It is time to get back to the beginning.

Most importantly, I value and appreciate your loyal visits to this site and your tweeting, liking and linking of the articles you enjoy.  I hope that will continue but wanted to give you a heads-up that future articles will be centered on the core concept of sports cognition.  Focused quality over quantity will be my mantra.

To that end, what questions do you have?  Have you thought about this stuff, too?  To be more specific, currently in the sports training world there is the popular, yet more general theory of "practice makes perfect" skill development, along with practical mental coaching tips and tricks.  What drives me, though, is drilling down much further into the brain-body connection and picking apart the root causes of sports expertise.

The research is there, buried in academic journals.  If it can be extracted, explained and extended out to coaches, parents and players, then we can break down some traditional training myths while developing a better understanding of the sports we love.

So, my humble request is that you give the more specific 80% Mental a chance by visiting, keeping your RSS subscription, and joining the conversation both here and on our Facebook page.

Thanks!
Dan

P.S. My breakthrough to re-purpose my work was inspired by a new manifesto from Steven Pressfield, appropriately titled, Do The Work.  The Kindle version is now selling at the very reasonable price of free, thanks to Seth Godin and the Domino Project.  I highly recommend it!

Top Athletes Can React Quicker

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A study conducted by scientists at Brunel University and at the University of Hong Kong has found that expert sportsmen are quicker to observe and react to their opponents' moves than novice players, exhibiting enhanced activation of the cortical regions of the brain.

The results of the study, which appear in the most recent issue of NeuroReport, show that more experienced sports players are better able to detect early anticipatory clues from opposing players' body movements, giving them a split second advantage in preparing an appropriate response.
 
Recent studies have demonstrated how expertise affects a range of perceptual-motor skills, from the imitation of hand actions in guitarists, to the learning of action sequences in pianists and dancers. In these studies, experts showed increased activation in the cortical networks of the brain compared with novices.

Fast ball sports are particularly dependent on time-critical predictions of the actions of other players and of the consequences of those actions, and for several decades, sports scientists have sought to understand how expertise in these sports is developed.

This most recent study, headed by Dr Michael Wright, was carried out by observing the reaction time and brain activity of badminton players of varying degrees of ability, from recreational players to international competitors. Participants were shown video clips of an opposing badminton player striking a shuttlecock and asked to predict where the shot would land.

In all participants, activation was observed in areas of the brain previously associated with the observation, understanding and preparation of human action; expert players showed enhanced brain activity in these regions and responded more quickly to the movements of their opponents.

Expertise in sports is not only dependent on physical prowess, then, but also on enhanced brain activity in these key areas of the brain. The observations made during this study will certainly have implications for how we perceive the nature of expertise in sport and perhaps even change the way athletes train.

See also: The Cognitive Benefits of Being a Sports Fan and How To See A 130 MPH Tennis Serve

Source:  Wolters Kluwer Health / Lippincott Williams & Wilkins and Functional MRI reveals expert-novice differences during sport-related anticipation : Neuroreport

Inside An Olympian's Brain

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Michael Phelps, Nastia Liukin, Misty May-Treanor and Lin Dan are four Olympic athletes who have each spent most of their life learning the skills needed to reach the top of their respective sports, swimming, gymnastics, beach volleyball and badminton (you were wondering about Lin, weren't you...) Their physical skills are obvious and amazing to watch. For just a few minutes, instead of being a spectator, try to step inside the heads of each of them and try to imagine what their brains must accomplish when they are competing and how different the mental tasks are for each of their sports.


On a continuum from repetitive motion to reactive motion, these four sports each require a different level of brain signal to muscle movement. Think of Phelps finishing off one more gold medal race in the last 50 meters. His brain has one goal; repeat the same stroke cycle as quickly and as efficiently as possible until he touches the wall. There isn't alot of strategy or novel movement based on his opponent's movements. Its simply to be the first one to finish. 

What is he consciously thinking about during a race? In his post-race interviews, he says he notices the relative positions of other swimmers, his energy level and the overall effort required to win (and in at least one race, the level of water in his goggles.) At his level, the concept of automaticity (as discussed in a previous post) has certainly been reached, where he doesn't have to consciously "think" about the components of his stroke. In fact, research has shown that those who do start analyzing their body movements during competition are prone to errors as they take themselves out of their mental flow.


Moving up the continuum, think about gymnastics. Certainly, the skills to perform a balance beam routine are practiced to the point of fluency, but the skills themselves are not as strictly repetitive as swimming. There are finer points of each movement being judged so gymnasts keep several mental "notes" about the current performance so that they can "remember" to keep their head up or their toes pointed or to gather speed on the dismount. There also is an order of skills or routine that needs to be remembered and activated.

 While swimming and gymnastics are battles against yourself and previously rehearsed movements, sports like beach volleyball and badminton require reactionary moves directly based on your opponents' movements. Rather than being "locked-in" to a stroke or practised routine, athletes in direct competition with their opponents must either anticipate or react to be successful.



So, what is the brain's role in learning each of these varied sets of skills and what commands do our individual neurons control? Whether we are doing a strictly repetitive movement like a swim stroke or a unique, "on the fly" move like a return of a serve, what instructions are sent from our brain to our muscles? Do the neurons of the primary motor cortex (where movement is controlled in the brain) send out signals of both what to do and how to do it?

Researchers at the McGovern Institute for Brain Research at MIT led by Robert Ajemian designed an experiment to solve this "muscles or movement" question. They trained adult monkeys to move a video game joystick so that a cursor on a screen would move towards a target. While the monkeys learned the task, they measured brain activity with functional magnetic resonance imaging (fMRI) to compare the actual movements of the joystick with the firing patterns of neurons. 

The researchers then developed a model that allowed them to test hypotheses about the relationship between neuronal activity that they measured in the monkey's motor cortex and the resulting actions. They concluded that neurons do send both the specific signals to the muscles to make the movement and a goal-oriented instruction set to monitor the success of the movement towards the goal. Here is a video synopsis of a very similar experiment by Miguel Nicolelis, Professor of Neurobiology at Duke University:


To back this up, Andrew Schwartz, professor of neurobiology at the McGowan Institute for Regenerative Medicine at the University of Pittsburgh School of Medicine, and his team of researchers wanted to isolate the brain signals from the actual muscles and see if the neuron impulses on their own could produce both intent to move and the movement itself. They taught adult monkeys to feed themselves using a robotic arm while the monkey's own arms were restrained. Instead, tiny probes the width of a human hair were placed in the monkey's motor cortex to pick up the electrical impulses created by the monkey's neurons. These signals were then evaluated by software controlling the robotic arm and the resulting movement instructions were carried out. The monkeys were able to control the arm with their "thoughts" and feed themselves food. Here is a video sample of the experiment:

"In our research, we've demonstrated a higher level of precision, skill and learning," explained Dr. Schwartz. "The monkey learns by first observing the movement, which activates his brain cells as if he were doing it. It's a lot like sports training, where trainers have athletes first imagine that they are performing the movements they desire."


It seems these "mental maps" of neurons in the motor cortex are the end goal for athletes to achieve the automaticity required to either repeat the same rehearsed motions (like Phelps and Liukin) or to react instantly to a new situation (like May-Treanor and Dan). Luckily, we can just practice our own automaticity of sitting on the couch and watching in a mesemerized state.

ResearchBlogging.org

R AJEMIAN, A GREEN, D BULLOCK, L SERGIO, J KALASKA, S GROSSBERG (2008). Assessing the Function of Motor Cortex: Single-Neuron Models of How Neural Response Is Modulated by Limb Biomechanics Neuron, 58 (3), 414-428 DOI: 10.1016/j.neuron.2008.02.033

Meel Velliste, Sagi Perel, M. Chance Spalding, Andrew S. Whitford, Andrew B. Schwartz (2008). Cortical control of a prosthetic arm for self-feeding Nature, 453 (7198), 1098-1101 DOI: 10.1038/nature06996

Imagine Winning Gold In Beijing

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Imagine winning a gold medal at the Beijing Olympics.  No really, go ahead, close your eyes and visualize it.  What did you see?  Were you standing on the medal platform looking out at the crowd, waving and taking in the scene through your own eyes, or were you a spectator in the crowd watching yourself getting the medal put around your neck?  This choice between "first-person" or "third-person" visualization actually makes a difference on our motivation to achieve a future goal.


Noelia A. Vasquez, at York University and Roger Buehler, at Wilfrid Laurier University wanted to see if there was a link between our visualization perspective and our motivation level to achieve the imagined goal.  They asked 47 university students to imagine the successful completion of a performance task that was in their near future, whether it be a speech in a class or an upcoming athletic competition.  They were also asked to assume that the task went extremely well.  One group of students were asked to imagine this scene "through their own eyes" seeing the environment as they would actually experience it.  The second group was told to use the third-person perspective, pretending they were "in the crowd" watching themselves as others would see them achieving this goal.  Next, they were given a survey that asked each group how motivated they were to now go make this successful scene a reality. 


As hypothesized, the group that saw the scene through their audience's eyes (third-person) ranked their motivation to now succeed significantly higher than those that imagined it through their own eye (first-person).  The authors' explanation for this is the perceived additional importance attached to the task when we consider other peoples' opinion of us and our natural desire to increase our status in our peer group.  Seeing this newly elevated social acceptance and approval of ourselves from the eyes of our peers motivates us even more to reach for our goals.


The road to achievements like an Olympic gold medal is a long one with many steps along the way.  Over the years, as athletes maintain their training regimen, they can keep imagining the future goal, but they may need to also look back and recognize the improvements they have made over time.  This "progress to date" assessment will also provide motivation to keep going once they realize the hard work is actually having the desired effect and moving them along the desired path.  So, as they review their past to present progress, does the first or third person perspective make a difference there as well?



Researchers from Cornell, Yale and Ohio State, led by Thomas Gilovich, professor of psychology at Cornell, designed an experiment to find out.  They recruited a group of university students who had described their high-school years as "socially awkward" to now recall those years and compare them with their social skill in college.  The first group was asked to recall the past from a first-person perspective, just as their memories would provide them.  The second group was asked to remember themselves through the perspective of their classmates (third-person).  Next, each group was asked to assess the personal change they had accomplished since then.


As predicted, the group that had recalled their former selves in the third person reported greater progress and change towards a more social and accepted person in college than the group that remembered in the first-person.  "We have found that perspective can influence your interpretation of past events. In a situation in which change is likely, we find that observing yourself as a third person -- looking at yourself from an outside observer's perspective -- can help accentuate the changes you've made more than using a first-person perspective," says Gilovich.  "When participants recalled past awkwardness from a third-person perspective, they felt they had changed and were now more socially skilled," said Lisa K. Libby, an assistant professor of psychology at Ohio State University. "That led them to behave more sociably and appear more socially skilled to the research assistant."


So, whether looking forward or backward, seeing yourself through other's eyes seems to provide more motivation to not only continue the road to success, but to appreciate the progress you have made. 


Then the actual day of competition arrives.  It is one hour before you take your position on the starting blocks at the "Bird's Nest" stadium in Beijing or on the mat at the National Indoor Stadium for the gymnastics final.  Should you be imagining the medal ceremony and listening to your country's national anthem at that point?  In a recent Denver Post article, Peter Haberl, senior sports psychologist for the U.S. Olympic Committee says, "It takes a great deal of ability and skill to stay focused on the task at hand."  

He distinguishes between an "outcome" goal, (receiving the medal) and "performance" (improving scores/times) and "process" (improving technique) goals.  "The difference is that these types of goals are much more under the control of the athlete," explains Haberl. "The process goal, in particular, directs attention to the here and now, which allows the athlete to totally focus on the doing of the activity; this is key to performing well.  This sounds simple but it really is quite difficult because the mind takes you to the past and the future all the time, particularly in the Olympic environment with its plethora of distractions and enticing rewards." 


Mental imagery is a well-known tool for every athlete to make distant and difficult goals seem attainable.  By seeing your future accomplishments through the eyes of others, you can attach more importance and reward to achieving them.  Just imagine yourself in London in 2012!

ResearchBlogging.org

Vasquez, N.A. (2007). Seeing Future Success: Does Imagery Perspective Influence Achievement Motivation?. Personality and Social Psychology Bulletin, 33(10), 1392-1405.


Libby, L.K., Eibach, R.P., Gilovich, T. (2005). Here's Looking at Me: The Effect of Memory Perspective on Assessments of Personal Change.. Journal of Personality and Social Psychology, 88(1), 50-62. DOI: 10.1037/0022-3514.88.1.50

Does Practice Make Perfect?

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For years, sport science and motor control research has added support to the fundamental assertions that "practice makes perfect" and "repetition is the mother of habit".  Shooting 100 free throws, kicking 100 balls on goal or fielding 100 ground balls must certainly build the type of motor programs in the brain that will only help make the 101st play during the game.  K. Anders Ericsson, the "expert on experts", has defined the minimum amount of "deliberate practice" necessary to raise any novice to the level of expert as 10 years or 10,000 hours.

However, many questions still exist as to exactly how we learn these skills.  What changes happen in our brains when we teach ourselves a new task?  What is the most effective and efficient way to master a skill?  Do we have to be actually performing the skill to learn it, or could we just watch and learn? 

Then, once we have learned a new skill and can repeat it with good consistency, why can't we perform it perfectly every time?  Why can't we make every free throw, score with every shot on goal, and field each ground ball with no errors?  We would expect our brain to just be able to repeat this learned motor program with the same level of accuracy.
To answer these questions, we look at two recent studies.  The first, by a team at Dartmouth's Department of Psychological and Brain Sciences, led by Emily Cross, who is now a post-doc at Max Planck Institute for Cognitive and Brain Sciences in Leipzig, Germany, wanted to know if we need to physically perform a new task to learn it, or if merely observing others doing it would be enough. 

The "task" they chose was to learn new dance steps from a video game eerily similar to "Dance, Dance Revolution".  If you (or your kids) have never seen this game, its a video game that you actually get up off the couch and participate in, kind of like the Nintendo Wii.  In this game, a computer screen (or TV) shows you the dance moves and you have to imitate them on a plastic mat on the floor connected to the game.  If you make the right steps, timed to the music, you score higher.

Cross and the team "taught" their subjects in three groups.  The first group was able to view and practice the new routine.  The second group only was allowed to watch the new routine, but not physically practice it.  The third group was a control group that did not get any training at all.  The subjects were later scanned using functional magnetic resonance imaging (fMRI) while they watched the same routine they had either learned (actively or passively) or not seen (the control group).

 As predicted, they found that the two trained groups showed common activity in the Action Observance Network (AON) in the brain (see image on left), a group of neural regions found mostly in the inferior parietal and premotor cortices of the brain (near the top of the head) responsible for motor skills and some memory functions.  In other words, whether they physically practised the new steps or just watched the new steps, the same areas of the brain were activated and their performance of the new steps were significantly similar.  The team put together a great video summarizing the experiment.  

One of the themes from this study is that, indeed, learning a motor skill takes place in the brain.  This may seem like an obvious statement, but its important to accept that the movements that our limbs make when performing a skill are controlled by the instructions provided from the brain.  So, what happens when the skill breaks down?  Why did the quarterback throw behind the receiver when we have seen him make that same pass accurately many times?  

To stay true to our theme, we have to blame the brain.  It may be more logical to point to a mechanical breakdown in the player's form or body movements, but the "set-up" for those movements starts with the mental preparation performed by the brain.

In the second study, electrical engineers at Stanford University took a look at these questions to try to identify where the inconsistencies of movement start.  They chose to focus on the "mental preparation" stage which occurs just before the actual movement.  During this stage, the brain plans the coordination and goal for the movement prior to initiating it.  The team designed a test where monkeys would reach for a green dot or a red dot.  If green, they were trained to reach slowly for the dot; if red, to reach quickly.  By monitoring the areas of the monkeys' brains through fMRI, they observed activity in the AON prior to the move and during the move.  

Over repeated trials, changes in reach speed were associated with changes in pre-movement activity.  So, instead of perfectly consistent reach times by the monkeys, they saw variation, like we might see when trying to throw strikes with a baseball many times in a row.  Their conclusion was that this planning activity in the brain does have an effect on the outcome of the activity.  Previously, research had focused only on breakdowns during the actual move and in the mechanics of muscles.  This study shows that the origin of the error may start earlier.

As electrical engineering Assistant Professor Krishna Shenoy stated, "the main reason you can't move the same way each and every time, such as swinging a golf club, is that your brain can't plan the swing the same way each time."  
Postdoctoral researcher and co-author Mark Churchland added, "The nervous system was not designed to do the same thing over and over again.  The nervous system was designed to be flexible. You typically find yourself doing things you've never done before." 
The Stanford team also has made a nice short video synopsis of their study.

Does practice make perfect?  First, we must define "practice".  We saw that it could be either active or passive.  Second, we know sports skills are never "perfect" all the time, and need to understand where the error starts before we can begin to fix it.

Getting Sport Science Out Of The Lab And Onto The Field

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You are a coach, trying to juggle practice plans, meetings, game prep and player issues while trying to stay focused on the season's goals.  At the end of another long day, you see this in your inbox:

MEMO
To:           All Head Coaches
From:      Athletic Director
Subject:  Monthly Reading List to Keep Up with Current Sport Science Research 
-  Neuromuscular Activation of Triceps Surae Using Muscle Functional MRI and EMG
-  Positive effects of intermittent hypoxia (live high:train low) on exercise performance are not mediated primarily by augmented red cell volume
-  Physiologic Left Ventricular Cavity Dilatation in Elite Athletes
-  The Relationships of Perceived Motivational Climate to Cohesion and Collective Efficacy in Elite Female Teams

Just some light reading before bedtime...  This is an obvious exaggeration (and weak attempt at humor) of the gap between sport science researchers and practitioners.  While those are actual research paper titles from the last few years under the heading of "sport science", the intended audience was most likely not coaches or athletes, but rather fellow academic peers.  The real question is whether the important conclusions and knowledge captured in all of this research is ever actually used to improve athletic performance?  How can a coach or athlete understand, combine and transfer this information into their game?

David Bishop of the Faculty of Exercise and Sport Science at the University of Verona has been looking at this issue for several years.  It started with a roundtable discussion he had at the 2006 Congress of the Australian Association for Exercise and Sports Science with several academic sport scientists (see: Sports-Science Roundtable: Does Sports-Science Research Influence Practice? )  He asked very direct questions regarding the definition of sport science and whether the research always needs to be "applied" versus establishing a "basic" foundation.  The most intriguing question was whether there already is ample research that could applied, but it suffered from the lack of a good translator to interpret and communicate to the potential users - coaches and athletes.  The panel agreed that was the missing piece, as most academic researchers just don't have the time to deliver all of their findings directly to the field.

In a follow-up to this discussion, Bishop recently published his proposed solution titled, "An Applied Research Model for the Sport Sciences" in Sports Medicine (see citation below).  In it, he calls for a new framework for researchers to follow when designing their studies so that there is always a focus on how the results will directly improve athletic performance.  He calls for a greater partnership role between researchers and coaches to map out a useful agenda of real world problems to examine.  He admits that this model, if implemented, will only help increase the potential for applied sport science.  The "middleman" role is still needed to bring this information to the front lines of sports.

The solution for this "gathering place" community seems perfect for Web 2.0 technology.  One specific example is an online community called iStadia.com.  Keith Irving and Rob Robson, two practicing sport science consultants, created the site two years ago to fill this gap.  Today, with over 600 members, iStadia is approaching the type of critical mass that will be necessary to bring all of the stakeholders together.  Of course, as with any online community, the conversations there are only as good as the participants want to make it.  But, with the pressure on coaches to improve and the desire of sport scientists to produce relevant knowledge, there is motivation to make the connection.

Another trend favoring more public awareness of sport science is the additional, recent media attention, especially related to the upcoming Beijing Olympics.  In an earlier post, Winning Olympic Gold With Sport Science, I highlighted a feature article from USA Today.  This month's Fast Company also picks up on this theme with their cover article, Innovation of Olympic Proportions, describing several high-tech equipment innovations that will be used at the Games.  Each article mentions the evolving trust and acceptance of sport science research by coaches and athletes.  When they see actual products, techniques and, most importantly, results come from the research, they cannot deny its value.



ResearchBlogging.org



Bishop, D. (2008). An Applied Research Model for the

Sport Sciences. Sports Medicine, 38(3), 253-263.

Teaching Tactics and Techniques In Sports

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You have probably seen both types of teams. Team A: players who are evenly spaced, calling out plays, staying in their positions only to watch them dribble the ball out of bounds, lose the pass, or shoot wildly at the goal. Team B: amazing ball control, skillful shooting and superior quickness, speed and agility but each player is a "do-it-yourselfer" since no one can remember a formation, strategy or position responsibility. Team A knows WHAT to do, but can't execute. Team B knows HOW to do it, but struggles with making good team play decisions. This is part of the ongoing balancing act of a coach. At the youth level, teaching technique first has been the tradition, followed by tactical training later and separately. More recently, there has been research on the efficiency of learning in sports and whether there is a third "mixed" option that yields better performance.


Earlier, we took an initial look at Dr. Joan Vickers' Decision Training model as an introduction to this discussion. In addition, Dr. Markus Raab of the Institute for Movement Sciences and Sport, University of Flensburg, Germany, (now of the Institute of Psychology, German Sport University in Cologne), took a look at four major models of teaching sports skills that agree that technical and tactical skills need to be combined for more effective long-term learning.Each of the four models vary in their treatment of learning along two different dimensions; implicit vs. explicit learning and domain-specific vs. domain-general environments. 


Types of Learning

Imagine two groups of boys playing baseball. The first group has gathered at the local ball diamond at the park with their bats, balls and gloves. No coaches, no parents, no umpires; just a group of friends playing an informal "pick-up" game of baseball. They may play by strict baseball rules, or they may improvise and make their own "home" rules, (no called strikes, no stealing, etc.). In the past, they may have had more formal coaching, but today is unstructured.


The second group is what we see much more often today. A team of players, wearing their practice uniforms are driven by their parents to team practice at a specific location and time to be handed off to the team coaches. The coaches have planned a 90 minute session that includes structured infield practice, then fly ball practice, then batting practice and finally some situational scrimmages. Rules are followed and coaching feedback is high. Both groups learn technical and tactical skills during their afternoon of baseball. They differ in the type of learning they experience.

The first group uses "implicit" learning while the second group uses "explicit" learning. Implicit learning is simply the lack of explicit teaching. It is "accidental" or "incidental" learning that soaks in during the course of our play. There is no coach teaching the first group, but they learn by their own trial and error and internalize the many if-then rules of technical and tactical skills. Explicit learning, on the other hand, is directed instruction from an expert who demonstrates proper technique or explains the tactic and the logic behind it.



An interesting test of whether a specific skill or piece of knowledge has been learned with implicit or explicit methods is to ask the athlete to describe or verbalize the details of the skill or sub-skill. If they cannot verbalize how they know what they know, it was most likely learned through implicit learning. However, if they can explain the team's attacking strategy for this game, for example, that most likely came from an explicit learning session with their coach.



Types of Domains

The other dimension that coaches could use in choosing the best teaching method is along the domain continuum. Some teaching methods work best to teach a skill that is specific to that sport's domain and the level of transferability to another sport is low. These methods are known as domain-specific. For more general skills that can be useful in several related sports, a method can be used known as domain-general.

Why would any coach choose a method that is not specific to their sport? There has been evidence that teaching at a more abstract level, using both implicit and explicit "play" can enhance future, more specific coaching. Also, remember our discussion about kids playing multiple sports.Based on these two dimensions, Dr. Raab looked at and summarized these four teaching models:
  • Teaching Games for Understanding (TGFU)
  • Decision Training (DT)
  • Ball School (Ball)
  • Situation Model of Anticipated Response consequences of Tactical training (SMART)
TGFU

The TGFU approach, (best described by Bunker, D.; Thorpe, R. (1982) A model for the teaching of games in the secondary school, Bulletin of Physical Education, 10, 9–16), is known for involving the athlete early in the "cognition" part of the game and combining it with the technical aspect of the game. Rather than learn "how-to" skills in a vacuum, TGFU argues that an athlete can tie the technical skill with the appropriate time and place to use it and in the context of a real game or a portion of the game.

This method falls into the explicit category of learning, as the purpose of the exercise is explained. However, the exercises themselves stress a more domain-general approach of more generic skills that can be transferred between related sports such as "invasion games" (soccer, football, rugby), "net games" (tennis, volleyball), "striking/fielding games" (baseball, cricket) and "target games" (golf, target shooting). 



Decision Training

The DT method, (best described by Vickers, J. N., Livingston, L. F., Umeris-Bohnert, S. & Holden, D. (1999) Decision training: the effects of complex instruction, variable practice and reduced delayed feedback on the acquisition and transfer of a motor skill, Journal of Sports Sciences, 17, 357–367), uses an explicit learning style but with a domain-specific approach. Please see my earlier post on Decision Training for details of the approach. 


Ball School

The Ball School approach, (best described by Kroger, C. & Roth, K. (1999) Ballschule: ein ABC fur Spielanfanger [Ball school: an ABC for game beginners] (Schorndorf, Hofmann), starts on the other end of both spectrums, in that it teaches generic domain-general skills using implicit learning. It emphasizes that training must be based on ability, playfullness, and skill-based. Matching the games to the group's abilities, while maintaining an unstructured "play" atmosphere will help teach generic skills like "hitting a target" or "avoiding defenders". 



SMART

Dr. Raab's own SMART model, (best described in Raab, M. (2003) Decision making in sports: implicit and explicit learning is affected by complexity of situation, International Journal of Sport and Exercise Psychology, 1, 406–433), blends implicit and explicit learning within a domain-specific environment. The idea is that different sports' environmental complexity may demand either an implicit or explicit learning method. Raab had previously shown that skills learned implicitly work best in sport enviroments with low complexity. Skills learned explicitly will work best in highly complex environments. Complexity is measured by the number of variables in the sport. So, a soccer field has many moving parts, each with its own variables. So, the bottom line is to use the learning strategy that fits the sport's inherent difficulty. So, learning how to choose from many different skill and tactical options would work best if matched with the right domain-specific environment.  



Bottom-Line for Coaches

What does all of this mean for the coach? That there are several different models of instruction and that one size does not fit all situations. Coaches need an arsenal of tools to use based on the specific goals of the training session. In reality, most sports demand both implicit and explicit learning, as well as skills that are specific to one domain, and some that can transfer across several sport domains. Flexibility in the approach taken goes back to the evidence based coaching example we gave last time. Keeping an open mind about coaching methods and options will produce better prepared athletes.



ResearchBlogging.org


(2007). Discussion. Physical Education & Sport Pedagogy, 12(1), 1-22. DOI: 10.1080/17408980601060184

Single Sport Kids - When To Specialize

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So, your grade school son or daughter is a good athlete, playing multiple sports and having fun at all of them. Then, you hear the usual warning, either from coaches or other parents; "If you want your daughter to go anywhere in this sport, then its time to let the other sports go and commit her full-time to this one." The logic sounds reasonable. The more time spent on one sport, the better she will be at that sport, right? Well, when we look at the three pillars of our Sports Cognition Framework, motor skill competence, decision making ability, and positive mental state, the question becomes whether any of these would benefit from playing multiple sports, at least in the early years of an athlete (ages 3-12)? It seems obvious that specific technical motor skills, (i.e. soccer free kicks, baseball bunting, basketball free throws) need plenty of practice and that learning the skill of shooting free throws will not directly make you a better bunter. On the other end, learning how to maintain confidence, increase your focus, and manage your emotions are skills that should easily transfer from one sport to another. That leaves the development of tactical decision making ability as the unknown variable. Will a young athlete learn more about field tactics, positional play and pattern recognition from playing only their chosen sport or from playing multiple related sports?

Researchers at the University of Queensland, Australia learned from previous studies that for national team caliber players there is a correlation between the breadth of sport experiences they had as a child and the level of expertise they now have in a single sport. In fact, these studies show that there is an inverse relation between the amount of multi-sport exposure time and the additional sport-specific training to reach expert status. In plain English, the athletes that played several different (but related) sports as a child, were able to reach national "expert" level status faster than those that focused only one sport in grade school . Bruce Abernethy, Joseph Baker and Jean Cote designed an experiment to observe and measure if there was indeed a transfer of pattern recognition ability between related sports (i.e. team sports based on putting an object in a goal; hockey, soccer, basketball, etc.)

They recruited two group of athletes; nationally recognized experts in each of three sports (netball, basketball and field hockey) who had broad sports experiences as children and experienced but not expert level players in the same sports whose grade school sports exposure was much more limited (single sport athletes). (For those unfamiliar with netball, it is basically basketball with no backboards and few different rules.) The experiment showed each group a video segment of an actual game in each of the sports. When the segment ended the groups were asked to map out the positions and directions of each of the players on the field, first offense and then defense, as best they could remember from the video clip. The non-expert players were the control group, while the expert players were the experimental groups. First, all players were shown a netball clip and asked to respond. Second, all were shown a basketball clip and finally the hockey clip. The expectation of the researchers was that the netball players would score the highest after watching the netball clip (no surprise there), but also that the expert players of the other two sports would score higher than the non-expert players. The reasoning behind their theory was that since the expert players were exposed to many different sports as a child, there might be a significant transfer effect between sports in pattern recognition, and that this extra ability would serve them well in their chosen sport.

The results were as predicted. For each sport's test, the experts in that sport scored the highest, followed by the experts in the other sports, with the non-experts scoring the poorest in each sport. Their conclusion was that there was some generic learning of pattern recognition in team sports that was transferable. The takeaway from this study is that there is benefit to having kids play multiple sports and that this may shorten the time and training needed to excel in a single sport in the future.

So, go ahead and let your kids play as many sports as they want. Resist the temptation to "overtrain" in one sport too soon. Playing several sports certainly will not hurt their future development and will most likely give them time to find their true talents and their favorite sport.

ResearchBlogging.org
Source:
Abernethy, B., Baker, J., Côté, J. (2005). Transfer of pattern recall skills may contribute to the development of sport expertise. Applied Cognitive Psychology, 19(6), 705-718. DOI: 10.1002/acp.1102

The Coach's Curse - Mental Mistakes

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"Donadoni rues Italian 'mistakes' against Dutch"

"Mental errors cost Demons in regional quarterfinal"

"Mental mistakes doom Rays in loss to Cardinals"

 
Every day, there is always a new variety of stories linked to the phrase, "mental mistakes".  Either the writer recaps a game, calling out the mistakes or a coach or player claims that mistakes were made. It has become sort of a throwaway phrase, "...we made a lot of mental mistakes out there today, that we need to avoid if we want to get to the playoffs..." The million dollar question then is HOW to reduce these mental mistakes. And, to answer that, we need to define WHAT is a mental mistake?

In a previous post, I introduced the "Sports Cognition Framework", which is a trio of elements needed for success in sports. These three elements are:

- decision-making ability (knowing what to do)

- motor skill competence (being physically able to do it)

- positive mental state (being motivated and confident to do it)

Most of the time, a mental mistake is thought of as a breakdown of decision-making ability. The center fielder throws to the wrong base, the tight end runs the wrong route, or the defender forgets to mark his man, etc. These scenarios describe poor decisions or even memory lapses during the stress of the game. They are not necessarily the lack of skill to execute a play or the lack of confidence or motivation to want to do the right thing. It is a recognition, in hindsight, that the best option was not chosen. In addition to glaring negative plays, there are also missed opportunities on the field (i.e. taking a contested shot on goal, instead of passing to the open teammate).

So, back to the payoff question: HOW do we reduce mental mistakes and poor decisions? Just as we practice physical skills to improve our ability to throw, catch, shoot, run, etc., we need to practice making decisions using a a training system that directly exposes the athlete to these scenarios. Dr. Joan Vickers, who we met during our discussion of the Quiet Eye, has created a new system which she calls the "Decision-Training Model", and is the focus of the second half of her book, "Perception, Cognition, and Decision Training". As opposed to traditional training methods that separate skill training from tactical decision making training, the Decision-Training model (D-T) forces the athlete to couple her skill learning with the appropriate tactical awareness of when to use it.

So, instead of an "easy-first" breakdown of a skill, and then build it up step by step, D-T begins with a "hard-first" approach putting the "technique within tactics" demanding a higher cognitive effort right up front. The theory behind D-T is that the coach is not on the field with the player during competition, so the player must learn to rely on their own blended combination of skill and game awareness. Research from Vickers and others shows that D-T provides a more lasting retention of knowledge, while more traditional bottom-up training with heavy coach feedback delivers a stronger short-term performance gain, but that success in practice does not often translate later in games. Practice and training need to mirror game situations as often and as completely as the real thing.

There are three major steps to Decision-Training (p. 167):

1. Identify a decision the athlete has to make in a game, using one of the seven cognitive skills (anticipation, attention, focus/concentration, pattern recognition, memory, problem solving and decision making)

2. Create a drill(s) that trains that decision using one of the seven cognitive triggers (object cues, location cues, Quiet Eye, reaction-time cues, memory cues, kinesthetic cues, self-coaching cues)

3. Use one or more of the seven decision tools in the design of the drill (variable practice, random practice, bandwidth feedback, questioning, video feedback, hard-first instruction, external focus of instruction)

This post was just to serve as an introduction to D-T. Dr. Vickers and her team at University of Calgary offer full courses for coaches to learn D-T and apply it in their sport. Combined with the visual cues of the playing environment provided by the Quiet Eye gaze control, D-T seems to offer a better tactical training option for coaches and athletes. Coming up, we will continue the discussion of decision-making in sports with a look at some other current research. Please give me your thoughts on D-T and the whole topic of mental mistakes!

The Map of Sport Skills

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One of the most common sense categorizations of sport skills that I have run across is from Successful Coaching, 3rd Edition by Rainer Martens. By the way, I highly recommend this book as a complete reference to the basics of coaching. On page 182-3, The "Celestial Map of Sport Skill" shows six areas that an athlete has to develop to be a complete player. I'll paraphrase them here:

Technical Skills - similar to the "Motor Skill Competence" that I list in the Sports Cognition Framework (SCF), these are the generic sport skills that cross several different sports:
- Hitting
- Fielding
- Shooting
- Passing
- Kicking
- Guarding
- Throwing
- Running
- Jumping

Tactical Skills - like "decision-making ability" referenced in the SCF, these are the "in-game" abilities to choose the right thing to do in different scenarios
- Rules of the game
- Reading the situation
- Situation tactics
- Self awareness of skills
- Game plan and strategy
- Decision-making skills

Mental Skills - "Positive Mental State" in the SCF, these skills make up the emotional and motivational state of the athlete. Often included in the field of Sport Psychology
- Motivation
- Emotional control
- Concentration
- Confidence

Physical Skills - this set of skills is the raw athletic skills that are needed to perform the technical skills
- Speed
- Power
- Flexibility
- Quickness
- Balance
- Agility
- Strength
- Acceleration
Character - to build a complete athlete and person, these skills are necessary
- Respect
- Fairness
- Honesty
- Responsibility
- Leadership

As I have mentioned previously, my focus in this blog will be on the first three skill sets, leaving Physical Skills to the many practitioners and exercise facilities for athletes and Character to other life-learning environments.

The Sports Cognition Framework

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So, why should athletes and coaches be interested in all of this cognitive science stuff? They have been playing and coaching these sports for years, practicing with the same drills and routines and having success. Some may say, "if it ain't broke..." At the same time, all players and coaches are looking for the "the Edge"; the practice technique, game strategy, player development skill that will help the bottom line; winning. The physical training attributes still need to be developed in terms of raw speed, acceleration, agility, strength and balance. Hours are spent in the training rooms and gyms improving these variables. The game preparation process is still there; watching film, breaking down strengths and weaknesses of the opponent, tactical planning, etc. Some may say that is the "mental preparation" needed for competition. That's true, it is a plan for success, but the key is in execution of the plan. At the exact moment in the game when execution is needed, will each player know the right thing to do and be able to do it? That is the essence of what I call the "Sports Cognition Framework". It is the combination of the three themes: decision-making competence (knowing what to do), motor skill competence (being physically able to do it), and positive mental state (being motivated and confident to do it). There seem to be many, deep areas of research into each of these topics. My job is to dig into each of these areas and look for relevant research that you will find practical to include in your training or your coaching.

What Was He Thinking? Decision Theory in Sports

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Previously, I outlined the core framework of sports skills. Over time, my intention is to dive deep into each of those areas and present research that will be useful to you in understanding the brain-body connection. Again, the goal of my ramblings here is to examine the foundation of skills necessary to perform well across the continuum of most sports. Ongoing posts will use this framework to organize this information into categories that are easy to search and focus on what you are interested in that day.

In addition to the core skills, there seems to be another equally significant side of sports cognition known as "decision theory". There is a deep research base in this area, not only specific to sports, but across other platforms (i.e. business, medicine, etc.) Basically, the application in sports looks at how athletes make thousands of split-second decisions during a game, some which will go unnoticed, but some that will affect the outcome. While most of these decisions appear instant and somewhat random, are there layers of "conditioning" that trigger one response versus another? Let's look at some examples:
Situation 1: Mike brings the basketball up the floor during a game and makes a pass to Tom. How many factors affected Mike's decision about that pass?
- Tom appeared to be "open".
- The play that the coach called dictated that Mike pass first to Tom.
- The game was tied and time was running out, and Mike knew Tom was the best option to score.
- Mike knew that Jack, another teammate, had missed his last 5 shots and wanted to avoid giving him the ball.
- Mike had missed his last 5 shots and was afraid to shoot.
- Mike and Tom are friends and feel the rest of the team is not at their skill level.
- Mike's choice was completely random
- Is there a "correct" answer, and if not, how do we judge effectiveness of the decision?

Situation 2: Mary is playing centerfield for her softball team. There are runners on 1st and 2nd base and there is 1 out. A ground ball is hit to her, she fields the ball and now needs to make a throw to a base. How does she decide where to throw?
- What is her "pre-pitch" analysis of the game situation? Does she have a plan of where to throw?
- What is the score of the game? Does she need to prevent a run from scoring?
- What is her self-assessment of her throwing ability? Does she have confidence in her throw to any base?
- What does her visual information give her during the play? When she fields the ball and looks up, what are her eyes telling her about the changing position of the runners?
- What are her teammates and coaches instructing (yelling at) her to do?
- Is there a "correct" answer?

To me, this side of the "80% mental" equation is just as important to success in sports. It deserves alot of attention and understanding, before we can coach athletes on how to improve these decision making skills. We will add this to our outline of research.

Sorting the Skill Sets

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OK, so before I take on the whole world of cognitive psychology, kinesiology, neuromuscular patterns and the motor skill development (yikes!), I want to try to categorize the different distinct set of skills that seem obvious to my untrained eye. While each sport is different in its rules, objectives and layout, the underlying skills required of the athletes seem to overlap. My early theory is that if athletes, especially young athletes, focus on the fundamentals of each core skill set, then they will be able to transfer those "mental maps" to other sports. Also, when considering the pieces necessary to perform a skill, it will be easier to break down the variations of the skill of each sport and get to the underlying mechanics.

So, here is my "Outline of Sport Skills" that will help organize our research and discovery:

First, a definition from Merriam-Webster (M-W.com) of skill: the ability to use one's knowledge effectively and readily in execution or performance b: dexterity or coordination especially in the execution of learned physical tasks

Throwing (M-W.com: to propel through the air by a forward motion of the hand and arm) Sample sports: baseball, football, cricket, basketball, bowling, etc.
One qualifier that I would add is to throw "at a target", which would differ than just throws for distance (i.e. shot/discus/javelin). The skill is two-dimensional as it involves judgment of distance and lateral accuracy.
Research questions would include:
- How is distance to target determined?
- How is lateral accuracy determined? (i.e. right-left, up-down target accuracy)
- If we include a soccer kick in this category, how are foot-eye coordination different than hand-eye?

Catching (M-W.com: to grasp and hold on to (something in motion)) Sample sports: baseball, football, cricket, basketball, hockey, etc.
As familiar as we are with the act of catching a ball, we rarely dig deep into the true skill involved.
Research questions would include:
- How does the athlete judge the flight of the object (ball)?
- What are the visual cues that we use to reposition ourselves to meet the object at the right place and time to make the catch?
- What tactile cues to we use to close the grasp on the object?

Hitting (M-W.com: to strike (as a ball) with an object (as a bat, club, or racket) so as to impart or redirect motion) Sample sports: baseball, golf, tennis, hockey, etc.
There are two variations: hitting a stationary (golf) vs. a moving object (baseball, tennis, hockey, cricket)
Research questions would include:
- Are the object tracking skills of Catching similar to those needed in Hitting?
- How does the neuro-motor connection adjust to the use of an object?

These three sets of skills cover most of the necessary situations in most major "goal-oriented" sports as opposed to the repetitive action sports of running, swimming, cycling, etc. Learning the commonalities at a very basic level should offer ideas of how to improve these core abilities through exercises and techniques.