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Computer games AND schoolwork
Have you ever wondered why kids who rebel at doing homework can play video games
for hours on end? We are puzzled especially when considering that the skills
needed to master a video game are the same skills needed for educational
pursuits -- problem solving, communicating with other players, and developing
strategies. Schoolwork that's perceived as difficult does not interest them, yet
hard games requiring the same skills enchant them. Why is that so and what can
we do?
I'm calling this article "Hard Fun", because no young person would spend any
time on a game that did not challenge him or her to the limit. A young person
typically invests over 40 hours to master a video game. That investment of time
lets us know what dedication kids can apply when properly motivated.
I hope to build on the interest in computer games so students can be as good in
academics as they are in computer games. With the right direction, our student's
enthusiasm for computer games can be extended to academic achievement. First
students can discuss games why they enjoy them. Students can develop their
analytical skills by reflecting and sharing their experience playing games. Then
students can study how computer games are constructed and make "pen and paper"
designs of new games. This reverse engineering can make academic studies more
relevant. They can then build computer games of their own design in a practical
application of their math, writing, and problem solving skills.
Contructivism
MIT Professor Seymour Papert developed the theory of "constructivism" to explain
why children learn more by doing, as opposed to abstract rote learning. Paula
Hooper, a Ph.D. graduate of MIT, is using "constructivism learning" with an
African-centered community school, Paige Academy in Boston. The school was
"organized to support a problem-solving approach to learning, with extensive
reliance on the arts as a natural form of expression and exploration".
A student named Shamia learned how to make a rainbow by writing a computer
program that automatically drew half-circles. In the process she learned about
fractions, angles and geometry, not because she set out to, but because she was
determined to make her rainbow. Shamia used a computer program called Logo to
make the problems concrete and meaningful. Logo was designed by Professor Papert
to enable young students to build things and in the process apply abstract
concepts in math and programming.
Enlightening uses of interactive media really excite me as a developer of
interactive media tools. Lingo, the computer programming language behind
Shockwave, allows creative people who may not be technically oriented to create
interactive experiences for the Internet. Lingo permits more people to express
themselves without being limited by their knowledge of programming. Can students
use Lingo and Shockwave to build their own games? First let's get a better
understanding of why games are so popular.
What works
Let's briefly examine the popular game Pokemon that is all the rage. The
cartridge plays on a $70 portable computer equipped with captivating sound,
animation, and color. The developers of Pokemon succeed in breaking challenges
into small pieces that keep the player involved for the 80 to 120 hours it takes
to collect the 150 Pokemon characters. At every stage, "Professor Oak" is
available to explain what is happening. The player gains a sense of
accomplishment by "training" each character. Once trained, the Pokemon
characters are traded with other trainers. Players practice economics by winning
"dollars" that are traded for Pokemon accessories such as vehicles, tickets,
ropes, maps and other tools required to surmount the challenges. A marketing
blitz of must-have trading cards, board games and toys supplement the computer
game.
Every level of Pokeman presents new challenges, new scenarios, new characters
and new hurdles that the player must overcome in new ways. The tasks become more
difficult as the player progresses. There is constant immediate feedback on
performance using negative and positive reinforcement. Players share their
experiences with their friends and help each other beat the game by swapping
strategies.
What parents can do
Parents can translate Pokeman or any other computer game mania into academics by
encouraging children to discuss various games so that they can describe,
analyze, and compare the thinking processes, strategies and mechanics employed
in the games. You may be surprise at the depth of knowledge your children have
about their games. By talking about it both you and your child will be more
aware of the mental discipline required to move up the levels in a game. A child
is discouraged by challenging work at school can be encouraged by pointing out
their demonstrated ability in beating a game.
Children naturally include what they enjoy in their creative drawing and
story-making. My sons (age 9 & 7) draw and write to augment Pokeman
characters and recreate game scenarios. They avidly trade cards and calculate
points. Their imaginations will not allow them to blindly digest Pokeman as it
is, they are compelled to add their own flavor. Parents can encourage the
naturally tendency for children to envision their own versions of computer
games. You can explain to them that there is an entire industry behind the game
itself and they can aspire to a career as a game maker. In future articles I
will describe the various career options in the game development industry and
what school preparation is needed.
What schools can learn
One of the differences between academic achievement and computer game mastery is
the immediate reward for meeting the small progressive challenges in computer
games. In school, the rewards have less immediate value and require long range
vision to realize the tangible benefits. However, the long-term process of game
development more closely mirrors the persevering road to real life success while
still dispensing the immediate reinforcement of games. Another difference is the
audio, visual and kinesthetic sensory neurological links that computer games
stimulate. Traditional academics do not make use of these neural pathways. By
building games students can learn with a greater variety of senses. Of course,
just as instruments are needed for writing, new tools are needed for creating
computer games.
Shockwave is the primary way to present interactive games on the Internet. The
majority of web users have already encountered Shockwave. What is not widely
known is Shockwave can be a used by young people to create interactive material,
such a games. Let's take a closer look at the three facets of Shockwave. The
first the web site www.shockwave.com, where people can enjoy free games,
cartoons and music in the same manner that one can now tune a radio to receive
freely broadcast music.
The second facet is Shockwave, the player. The Shockwave player is a means of
viewing interactive material such as games. Disney, America Online, Microsoft
and other companies use the Shockwave format to play interactive media. Much the
same way that one can now choose between cassette and CD audio formats, The
Shockwave format consists of animation, graphics, and sound that can be played
in a straight linear mode. Shockwave's Lingo computer language makes possible
on-screen buttons that the user clicks to alter the sequence of events just as
the remote control permits the user to program a CD player.
The third facet is the Shockwave Construction kit for students. With it a
student can create their own games, improve existing games, or build an
interactive illustration of a homework assignment. Students can integrate visual
arts, music, and movement into their academic subjects using Shockwave. The kit
is a special version of the same Macromedia Director program used by over
300,000 professionals to create games and other interactive content. Students
now have access to the same powerful tool used to create material for the
www.shockwave.com web site. To learn how to use the kit students can start with
the documentation and tutorials that come with the kit. They can also use of the
several dozen books on the topic (search for "Macromedia Director" on the
www.amazon.com web site). There are also many web sites, such as my own
www.JohnHenry1.com, that provide advise and learning examples.
Finding information about the kit is a bit of a challenge. It is buried on the
www.macromedia.com web site under the code name "Director 7 K-12 Edition."
Challenge a young person who loves computer games and has access to the Internet
to move to the next level by getting this kit and creating their own games.
The Next Level
Students have three powerful strategies for learning from computer games. They
can discuss and analyze the games they enjoy. Using simple pen and paper they
can design their own games. Finally, they can turn their game sketches into the
real thing using the Shockwave construction kit.
To give direction and focus to the aspiring game creator, in the next
installment I give a behind the scenes view of the game industry and what skills
are needed on a game development team.
Copyright © 2001 John Henry Thompson.
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2. The Art of Learning‎ > ‎
