Vince Young was born on May 18, 1983 in Houston, Texas. He has always been known as a great athlete, and this stems back to his early playing career. Standing at 6 foot 5 inches and weighing nearly 230 pounds, it is easy to see why Young is one of the best quarterbacks in the world. When you combine this with a high level of athleticism and a rocket arm, Young is very hard to stop.

Young played his high school football at Madison High School in Houston for head coach Ray Seals. During his high school career Young started for three years, and during that time amassed 12,987 yards of total offense. With stats like this, it is easy to see why Young could have chosen to play at any college in the entire country. Young also competed in track and basketball while in high school.

After his senior season, Young signed with the University of Texas in 2002. He redshirted his first year which gave him the opportunity to learn the entire playbook. In his first season in college, Young played in 12 games and started seven of them. As a sophomore he emerged as a true dual threat quarterback, and led the Longhorns to an 11-1 record.

Young led the Longhorns to a National Championship during this junior season. During this year he passed for more than 3,000 yards, and ran for more than 1,000. This was good enough to take home second in the Heisman Trophy voting.

After his junior season Young declared himself eligible for the 2006 NFL Draft. He was selected with the third pick in the first round by the Tennessee Titans. During his first year in the NFL, Young passed for 2,199 yards and ran for 552 more. It is safe to say that he is going to be the Titans starting quarterback for the foreseeable future.

There’s alot more than just studying hard that you can do as a college or university student, that will help when it comes to getting the best job or career after graduation. We take a look at the top 20, from playing a team sport to learning to give a compliment.

1. Get out of the library. “You can have a degree and a huge GPA and not be ready for the workplace. A student should plan that college is four years of experience rather than 120 credits,” says William Coplin, professor at Syracuse University and author of the book, “10 Things Employers Want You to Learn in College.”

2. Start a business in your dorm room. It’s cheap, Google and Yahoo are dying to buy your website, and it’s better than washing dishes in the cafeteria. Note to those who play poker online until 4 a.m.: Gambling isn’t a business. It’s an addiction.

3. Don’t take on debt that is too limiting. This is not a reference to online gambling, although it could be. This is about choosing a state school over a pricey private school. Almost everyone agrees you can get a great education at an inexpensive school. So in many cases the debt from a private school is more career-limiting than the lack of brand name on your diploma.

4. Get involved on campus. When it comes to career success, emotional intelligence—social skills to read and lead others—get you farther than knowledge or job competence, according to Tiziana Casciaro, professor at Harvard Business School. Julie Albert, a junior at Brandeis University, is the director of her a capella group and head of orientation this year. She hones her leadership skills outside the classroom, which is exactly where to do it.

5. Avoid grad school in the liberal arts. One in five English Phd’s find stable university jobs, and the degree won’t help outside the university: “Schooling only gives you the capacity to stand behind a cash register,” says Thomas Benton, a columnist at the Chronicle of Higher Education (who has an English degree from Yale and a tenure-track teaching job.)

6. Skip the law-school track. Lawyers are the most depressed of all professionals. Stress itself does not make a job bad, says Alan Kreuger, economist at Princeton University. Not having control over one’s work does make a bad job, though, and lawyers are always acting on behalf of someone else. Suicide is among the leading causes of premature death among lawyers.

7. Play a sport. People who play sports earn more money than couch potatoes, and women executives who played sports attribute much of their career success to their athletic experience, says Jennifer Cripsen of Sweet Briar College in Virginia. You don’t need to be great at sports, you just need to be part of a team.Continued…

8. Separate your expectations from those of your parents. “Otherwise you wake up and realize you’re not living your own life,” says Alexandra Robbins, author of the popular new book “The Overachievers.” (Note to parents: If you cringe as you read this list, then you need to read this book.)

9. Try new things that you’re not good at. “Ditch the superstar mentality that if you don’t reach the top, president, A+, editor in chief, then the efforts were worthless. It’s important to learn to enjoy things without getting recognition,” says Robbins.

10. Define success for yourself. “Society defines success very narrowly. Rather than defining success as financial gain or accolades, define it in terms of individual interests and personal happiness,” says Robbins.

11. Make your job search a priority. Jobs do not fall in your lap, you have to chase them. Especially a good one. It’s a job to look for a job. Use spreadsheets to track your progress. And plan early. Goldman Sachs, for example, starts its information sessions in September.

12. Take a course in happiness. Happiness study is revolutionizing how we think of psychology, economics, and sociology. How to be happy is a science that 150 schools teach. Preview: Learn to be more optimistic. This class will show you how.

13. Take an acting course. The best actors are actually being their most authentic selves, says Lindy Amos of communications coaching firm TAI Resources. Amos teaches executives to communicate authentically so that people will listen and feel connected. You need to learn to do this, too, and you may as well start in college.

14. Learn to give a compliment. The best compliments are specific, so “good job” is not good, writes Lisa Laskow Lahey, psychologist at Harvard and co-author of “How the Way We Talk Can Change the Way We Work.” Practice on your professors. If you give a good compliment the recipient will think you’re smarter: Big payoff in college, but bigger payoff in the work world.

15. Use the career center. These people are experts at positioning you in the workforce and their only job is to get you a job. How can you not love this place? If you find yourself thinking the people at your college’s career center are idiots, it’s probably a sign that you really, really don’t know what you’re doing.
16. Develop a strong sense of self by dissing colleges that reject you. Happy people have “a more durable sense of self and aren’t as buffeted by outside events,” writes Sonja Lyubomirsky of the University of California-Riverside. When bad things happen, don’t take it personally. This is how the most successful business people bounce back quickly from setback.

17. Apply to Harvard as a transfer student. Sure people have wild success after going to an Ivy League school but this success is no more grand than that of the people who applied and got rejected. All people who apply to Ivy League schools seem to have similar high self-confidence and ambition, even if they don’t get in, according to a study by Kreuger.

18. Get rid of your perfectionist streak. It is rewarded in college, but it leads to insane job stress and an inability to feel satisfied with your work. And for all of you still stuck on number 6, about ditching the law school applications: The Utah Bar Journal says that lawyers are disproportionately perfectionists.

19. Work your way though college. Getting involved in student organizations counts, and so does feeding children in Sierra Leone or sweeping floors in the chemistry building. Each experience you have can grow into something bigger. Albert was an orientation leader last year, and she turned that experience into a full-time summer job that morphed into a position managing 130 orientation leaders. A great bullet on the resume for a junior in college.

20. Make to do lists. You can’t achieve dreams if you don’t have a plan to get there.

Provided by The Student Zone

Accounting is the language of business. Its knowledge is fundamental to any businessperson that seeks to plan expenditure and strive for a profit. Most business professionals are therefore required to study some accounting. Accounting professionals interact with all levels of a business and for many it’s a very interesting job.

Eligibility

-Individuals with an analytical approach and technical expertise of accounting, good mathematical aptitude, knowledge of the technicalities of a business system and those who are well versed with computers.
-Basic eligibility is 4 years of college for a professional degree in accounting or a related field.
-A Bachelor’s degree with a minor in another subject from an accredited college or university to apply for the Master’s in accounting.
-People who have done their course in accounting over the Internet are also eligible for jobs in the accounting industry.
-In terms of job, prior experience as a trainee auditor or accountant can also help.
-Different courses and licenses require accreditations and licenses of certain organizations. For example, Certified Public Accountants (CPA) should have a license by the State Board of Accountancy (STA).
-A certain number of semester hours plus work hours are considered for 4-year bachelor’s degree.
-Public accountants are taken as trainees. Management Accountants start as junior internal auditors or cost accountants.
-A master’s degree in business administration (MBA) is preferred by many companies.

Types Of Accounting Jobs

-After a degree in accounting, one could qualify for a certified public accountant (CPA) or registered public accountant (RPA) license. Even though many do not have a license, they do get jobs as auditors or accountants in government offices or private companies.
-In the long run, one could excel to a position like chief financial officer (CFO).
-A certified accounting professional could become an auditor, financial officer, management accountant, budget analyst, or tax accountant. Tax accountants are preferred with a legal background.
-An independent job could prosper if the individual has a good network of contacts.
-There are specializations in accounting; for example, the forensic accounting where the accountant investigates the different crimes breeding on the company’s finances.
-Teaching accounting can also be a good career option.

Tips On Starting a Career in Accounting

Following are a few tips on getting started

1.Decide which field of accounting you would like to get into.
2.Research related information and shortlist colleges and universities for the given courses.
3.Consult accountants or even teachers who have knowledge of the subject.
4.Enroll in a bachelor’s degree or course in accounting.
5.Start off as a trainee after getting a degree from a college. Most of the companies look for an accredited college.
6.Keep looking for hiring by the major companies of the industry.
7.Update your work knowledge according to the industry standards.

Accountants have a decisive role in the future of a company. Budgeting and adjusting according to the current market trends is one of the analytical decisions an accountant makes. Because they are problem solvers, the company can rely on an accountant to sort out any financial problems.

Beach vacations with my family were an annual ritual of packing and planning for my parents, and daydreaming for me. I grew up in England, a small country where you’re never more than an hour or two from the beach, but we used to go a little further afield. Our beach vacation destination was always Guernsey, one of the Channel Islands off the coast of France. My parents went there on their honeymoon, fell in love with it, and returned every year to spend the summer there.

When I was in college I spent my junior year in Santa Barbara, where I discovered a whole new world of fun on the beach. I was used to the cold and grey days that so often marred the English summer, so the clear blue skies and warm water of California beaches were a revelation. Sadly, my pale and puffy-looking English skin was a similar revelation to Californians, but I quickly bronzed up in an attempt to blend in. Alas, I never did learn to surf though.

Now I’m older I still enjoy family beach vacations, but now it’s my job to make the plans and preparations … including the choice of destination. Particularly if you have kids of various ages, it can be a challenge to find the perfect spot to please everyone. You and your spouse want a tucked-away cafe to share a leisurely meal; your teenagers want some nightlife so they can work on their socializing; and your young ones want to splash in the ocean all day and then eat ice cream till it comes out of their ears. Where can you go that will be fun for everyone?

There are hundreds of beach vacation destinations to explore, but let me suggest three that will keep the whole family happy.

The Cayman Islands aren’t the biggest islands in the Caribbean, but their intimacy only adds to their allure. Most of the hotels are on the largest of the three islands, Grand Cayman, which is also the location of Seven Mile Beach. This much-loved destination for snorkelers offers clear water, and the chance to explore reefs and shipwrecks. The wrecks are a reminder of the Caribbean’s pirate history, celebrated each year at the Pirates Week Festival with fireworks and pirate landings!

South Carolina’s Myrtle Beach may be less exotic than the Caribbean, but it’s very beautiful—and much easier on the wallet. There are a range of hotels that cater to families, some which offer suites, and many of the hotels have organized activities for children. The nightlife can be a little wild during Spring Break season, so you and your family may prefer to avoid that time. Throughout the year, however, Myrtle Beach has a great nightlife with clubs, bars, and restaurants to suit every taste.

Laguna Beach in California is midway between San Diego and Los Angeles. There are many family-friendly hotels along the seven miles and thirty beaches that make up this lovely beach vacation destination. The Montage Resort, the Ritz-Carlton Laguna Niguel, and the Laguna Riviera Resort are amongst the nicest, but spend some time looking online, where you’ll find many tempting choices. You and your family will have a wonderful time playing on Laguna’s beautiful beaches, and for a change of pace, explore some of the art galleries in town—there are more than 100! If you visit during the summer months don’t miss the Pageant of the Masters, a live recreation of famous works of art.

Wherever you choose to visit, you’ll be making memories that will last a lifetime. Talk to your family about what they want from the trip, plan ahead, and you can be sure that your family’s beach vacation is one to remember.

I. Introduction

You can’t achieve what you can’t conceive.

-Author unknown

The United States of America may lose its supremacy as a superpower if our children of today can’t grasp the technologies of tomorrow. The trend has already been set. High-level engineering jobs are currently being outsourced to other nations, not only because of cheaper costs, but inadequacies of filling them in the states. Let’s face it; there are not too many Americans who strive to have a doctrine in Electrical Engineering to do research and development. To other countries like Korea, many students see Math as the universal language and foresee a technically based doctorate level diploma as a necessity for excelling in their country. To many, this is the only road out of poverty. American children, stereotypically, do not have this fear to motivate them. Many children in this superior country just view mathematics as something needed to pass a proficiency test. Its value is discarded. The implementations are unseen. The desire of children to follow this type of career path is decreasing. Obviously, these future implications are disturbing and may some day be detrimental to the foundation of our country. However, I believe nurturing children’s enthusiasm in needing to use math may be the answer. Not surprisingly as stated in Robots for Kids, Robots rank right up there with dinosaurs when it comes to grabbing the attention of elementary school students . Hence, I predict an interest, active participation, and proper guidance in robotics will increase nationally recorded math scores.

II. Staggering Math Scores

The facts don’t lie. According to the US Department of Education in 1999 , the United States ranked 12th among 4th graders, a staggering 28th among 8th graders, and just 19th among seniors in nationally recorded math scores. How can poverty stricken and problematic country like Israel be three rankings ahead of us with 8th graders? Clearly, money isn’t the answer. Nor do I believe Israelis have fewer fears about violence than our inner city children do to distract them. Although I’m a bit perplexed by the answer, I believe solution lies in a child’s own aspirations and inner desires. Many of our youth dream to be professional athletes or pop singers. That’s what they see. That’s what they know. That’s what they love. These young easily influenced children view these avenues not only as fun, but also as a means for financial freedom. With mathematics being the universal language children in other countries may see this as the only way to break through levels of poverty and thrive in life. Let’s face it; math can be a difficult subject to grasp. Unless one either has the first name Albert or discovers motivational reasons to put forth extra effort, the scores will suffer. The Third International Mathematics and Science Study (TIMSS) has found that students who agreed that they like math and that math was useful for solving problems, scored higher than students who disagreed. To no surprise, many educators have already taken this as a given. The question that now arises is how to motivate the children? Or better yet, how does one follow a handed-down curriculum while taking advantage of today’s enticing technologies? As stated by Druin and Hendler, I believe the desire for learning has to do with an animating idea or an engaging project. New technologies enable students of all ages to pursue richer, far more complex learning experiences. With robots, students can truly be scientists, engineers, designers, and builders.

  Grade 4 Grade 8 Grade 12

Rank Nation Score Nation Score Nation Score

1 Singapore 625 Singapore 643 Netherlands 560

2 Korea 611 Korea 607 Sweden 552

3 Japan 597 Japan 605 Denmark 547

4 Hong Kong 587 Hong Kong 588 Switzerland 540

5 Netherlands 577 Belgium 565 Iceland 534

6 Czech Republic 567 Czech Republic 564 Norway 528

7 Austria 559 Slovak Republic 547 France 523

8 Slovenia 552 Switzerland 545 New Zealand 522

9 Ireland 550 Netherlands 541 Australia 522

10 Hungary 548 Slovenia 541 Canada 519

11 Australia 546 Bulgaria 540 Slovenia 518

12 United States 545 Austria 539 Germany 495

13 Canada 532 France 538 Hungary 483

14 Israel 531 Hungary 537 Italy 476

15 Latvia 525 Russian Fed. 535 Russian Fed. 471

16 Scotland 520 Australia 530 Lithuania 469

17 England 513 Ireland 527 Czech Republic 466

18 Cyprus 502 Canada 527 United States 461

19 Norway 502 Belgium 526 Cyprus 446

20 New Zealand 499 Sweden 519 South Africa 356

21 Greece 492 Thailand 522    

22 Thailand 490 Israel 522    

23 Portugal 475 Germany 509    

24 Iceland 474 New Zealand 508    

25 Iran 429 …(28th)United States 500

   

Figure 1: Third International Mathematics and Science Study (TIMMS) of 1999 Math scores [2].

Figure 2: Average mathematics scores by students that state I like math.

Figure 3: Average mathematics scores by students that state Mathematics is useful for solving everyday problems [3].

III. Robots in the Media

Television may be lending a helping hand in the educational pursuit of sparking kid’s interest in robots. Maybe the eyes have been blessed to see Honda’s commercial of a 4 foot robot walking down the driveway to pickup a Sunday paper. This completely autonomous robot, which appears to be wearing a space suit, is currently on tour around the world. This Advanced Step in Innovative Mobility, or better known as ASIMO, is the result of a robotics program that began in 1986. Being the most advanced humanoid robot in existence, this intriguing creation walks on two legs, has 26 degrees of freedom, can walk up steps, and is currently on a North American Educational Tour. Recently, this technological marvel visited the Bronx schools in an attempt to encourage the interest in the study of robotics and science. Even a section on the website is dedicated to teacher’s resources for children. With ASIMO, Honda is truly giving our youth the power of dreams’.

Sony is also doing its part to change the way you see the world. AIBO has become a pet of the future for many while the SDR-4X II is all the rave. AIBO is an autonomous dog that can learn, do tricks, and express feelings. This approximately $2000 piece of entertainment is completely programmable for upgrading and educational purposes. Be prepared for the pet to express 6 different types of feelings, act according to its environment and attention it’s receiving, seek out its toys, and without human help it will wake up and fall asleep on a charging station. Not only does the dog mature overtime, but also it won’t dirty the carpets as a puppy! The SDR-4X II, on the other hand, literally has become the rave among youngsters. This humanoid can be caught raving (a techno dance technique), throwing balls, doing tai chi, and even jogging. Even better, the video clips available on the Internet and television demonstrate five of them doing it in unison. And it gets better! This robot also has face recognition, a 20,000-word vocabulary for speech recognition and synthesis, color recognition, and still finds time to map out a room for optimum placement to show off. Now only if this thing didn’t need to be charged. Oh, did I mention work is already being done on that ?

The stated robots do a wonderful job of creating attention for themselves and portraying to youngsters cool jobs to have when they grown up. However, I believe the television show Robot Wars is a driving force for inspiring them to begin building. I can vouch as living proof of that statement. Turn on TechTV and you will have the pleasure of watching robots battle to the death in an arena that has gusts of fire, pits to oblivion, and flippers that launch unfortunate robots through the air to their doom. Combine this with hundreds if not over a thousand screaming children in the stands and this show becomes a quick favorite. The program’s website even provides a daily quench for the thirst of building. Direct links are provided on how to start creating robots from home. GI Joes begin to look like baby toys in comparison to a 500 pound robot that shoots fire, spins blades, has crushing pinchers, and is moving strictly to survive and destroy someone else’s creation. Inside this 20- by 54-foot arena is the ultimate in robot combat and competition. Children love it!

IV. Creative Avenues

A common place many turn to when compelled to build a bot is David Cook’s book, Robot Building for Beginners. Following these instructions, not only will a line following robot be built, but math is unavoidably used and pursued. In order to understand speed, one must first understand Revolutions Per Minute, trade offs between speed and torque, battery levels, friction, robot mass and ways to manipulate these values with different voltages, gear ratios, and tire sizes. Trial and error is always an option and, might I add, a popular one amongst beginners. Remember, robotics is something that making a mistake is OK and a tremendous amount of the learning results from these mistakes. However, this is where a teacher steps in and provides a bag of tricks to the knowledge hungry children. I believe Miller and Stein say it best when they detail reactions from a second grade class:

Several students will stare with awe and admiration at the one or two students who know their multiplication tables and can predict how many times a motor needs to turn to make the wheel on their robot turn once. All of a sudden radii, circles, circumferences, and so on have utility as one of our students suddenly loudly exclaimed, so that’s what pi is for!.

Wow, all that to just determine speed. Lets not forget that the person reading the book is going to learn about materials science (i.e. textile strength), basic electronics (voltage = current * resistance), mechanics (loads and stress), diodes, resisters, capacitors, LEDs, and all the tools and procedures to use them effectively. At first glance, this may seem like a lot to learn for a child. Remember this: it’s not the teacher’s lessons being forced on the kids, it’s their own! What child becomes enthused with a question stating, if Jack is half as old as Jill, and Jill is one third as old as Jan? Then how old is Jack on Jan’s 60 birthday? Building robots is a teacher’s dream–true problem solving with the added benefit of enthusiasm [9].

With DC robots, the sky is the limit on how technical the project will become. However, sometimes quicker and less complex solutions may be more appropriate. BEAM technology uses solar energy to power very simplistic, yet captivating, robots. This acronym for Biology Electronics Aesthetics Mechanics represents an area of robotics using no computational power, inspirations from Mother Nature, a focus on designs that appeal to the eye, while making it all work with the small amount of power given from a solar panel. There are rarely circuit boards used, no programming is involved, and just a few inexpensive are parts needed. My first BEAM robot involved a paper clip, a pager motor, a solar panel, a capacitor, and a little solder. In about 20 minutes, the 5 parts came to life! The beauty of these robots is the simplicity to build, the parts are cheap to buy or easily found in techno junk around the house, and only a soldering iron is necessary to build them. While these robots generally take the form of a bug or some other small creature, they have a large appeal to children. Projects are very quick. This fact alone adheres to those with a short attention span who want immediate feedback on their progresses. In addition, many of the basic principals of science and biology are incorporated in the design and can be discussed with respect to solar energy. Visits to the zoo will become more educational as children will seek out animals to mimic their moments and appearance. Construction material and project ideas that appeal to a broad range of interests allow multiple entry points into science, mathematics, engineering, design, art and music for all types of learners. These materials not only make new knowledge domains accessible, but also provide new ways for children to relate to domains of knowledge to which they have already been exposed. In addition, an obvious challenge of this solar technology is to minimize the current used and find ways of storing (capacitors) what little energy that is available. Hence, young robotists will learn the importance of reading and comprehending part data sheets in order to choose the appropriate parts wisely. Naturally, some of the most basic problem solving techniques are utilized at its finest .

When the pupil is young or the soldering skills have not quite matured, Lego Mindstorms is always an exceptional choice. Actually, anyone of any age will find this technical and robotic line of Legos a wise investment. Not only are the parts reusable and nonexclusive to a particular project, but also they can be programmed in various languages on a computer from Visual Basic to Lego’s own object oriented programming language. No cables are needed either. All of this can be done via an infrared transmitter! It’s difficult to fathom how Legos have walked hand-in-hand with technology. For example, let’s take a closer look at the kit Robotics Invention System 2.0. This set includes a battery operated RCX Microcomputer used to store programs and connect all the peripherals, 718 pieces which include 2 motors, 2 touch sensors, and 1 light sensor, a USB infrared tower, and a simple yet powerful picture based programming language on CD. Of course, all the Legos from any of the prior kits can be used in conjunction with this educational tool. In addition, at the Mindstorms website, there is a free online program in which to create projects choosing any Lego in existence. This 3D virtual environment is ideal for posting creations on the web or experimenting with Legos that have yet to be purchased .

As a result of the software included, children can have their first robot built in less than an hour after purchase. There are a slew of practice lessons, training sessions, and missions included on the CD. Each of these training sessions teaches a specific capability of the Robotics System while describing various ways to test, troubleshoot, and tweak the constructions. Eventually, the lessons will escalate into such capabilities as: using sensors to interact with the environment, programming with icons that represent blocks of code, and create environmental responses for the robot to do anything its creator desires. By the time the CD is completed, nearly all the fundamental techniques necessary to complete projects will have been covered .

Already, there are over a dozen books written about Lego Mindstorms with detailed how-tos of creating everything from a scanner, musical instrument, and a picture creator, to a spy bot, fingernail polisher, and M&M color sorter. I even own books that describe the creations of an ATM machine, card dealer, elephants that squirt water, and even a robot that does the work of cleaning the Legos from the floor. By completing these projects, according to Cole and O’Conner, (educational) benefits include helping children to improve their concentration skills, work with instructions, problem solve, and develop patience. This line of Legos created by MIT professors is currently being used with thousands of educators across the world. Since most children only view the robot as a toy, they tend to stay highly focused and engaged throughout the lessons. Thus allowing more productive group settings, more creative and in depth solutions to given scenarios, and development of interpersonal skills and team-building skills. All of this is accomplished without the use of a pencil!

V. Case Study

If something can’t be measured, then I believe it cannot be proven or improved. My hypothesis is that with an interest, active participation, and proper guidance in robotics, the TIMMS scores on average will increase at least 10 points over a year’s time. Since the tests are taken at 4th, 8th, and 12th grade years respectively, this undertaking would need to involve an entire school system and then relate the scores to the years prior. Remember, the content of an experience, and not so much the tools, are what is vital to learning. Hence, the roles, guidance, and trainings of the teachers and designated robot/BEAM/Lego Mindstorms experts cannot be stressed enough. It is naive to consider placing a computer in front of a person and expecting one to be capable of building a network, creating a webpage, or becoming fluent in a programming language. The same goes for robotics. When launching this curriculum upgrade in the beginning of a fall school year, it is essential to educate the teachers during the prior summer. Obviously, this time will be spent to understand the equipment, discuss and personalize previously created and borrowed lesson plans, and provide an entire summer of uninhibited experimentation. However, this is also a period to overcome any fears or dislikes of technology and change. For example, some people uncomfortable with new ways can replicate the old ways by using technology. It is a safe way to sneak up on change. Some teachers, who have little experience with new technologies in their classroom, have been known to force-fit new technologies to well-worn curricula. For this case study to be effective, educators must embrace breaking through the mold of old school comfortable habits and adhere to the potentials of what technology can foster. This is, of course, the pursuit of richer, far more complex learning experiences .

The procedure itself is laid out in a similar pattern amongst the different grade zones. Months prior to the start of the school year, a letter detailing the curriculum changes should be sent out to all the parents. This letter should brief the intentions and communicate resources that a parent could turn to for pre-exposure to themselves and their children with the upcoming technologies. Parental support and involvement are essential to exceeding expectations in this new process.

A. Elementary School

Beginning with the elementary level, grades 1-5, the year should begin with a speaker. Here, Lego Mindstorms will be introduced and accompanied with a display case full of inventions. Demonstrations will be shown to all. This will incite interest and curiosity amongst the listeners. Also, leaving these creations in a strategic trophy-case-like display will perpetuate the excitement and foster a desire for involvement. Lego Mindstorms will be added to the curriculum. This time invested can be substituted for some of the weekly sciences and designated math time slots. When executed properly, the lesson plans of different mathematical principals can be shared as helpful hints to the students. Also, in replacement of the annual science fair, a Lego Fair could be established. This will provide for more parental involvement regarding the Mindstorms. How many projects are really done 100% by the student anyway? Also, a sense of pride and achievement will be attained in the ownership of a creation on display for everyone to see. In addition, having the student stand by the project during showing to answer questions and provide detailed descriptions and demonstrations will solidify the understanding, theories, and principles used in the creation process.

Just as in high school, I believe tenure and seniority should have its perks. Assuming the continuation of this curriculum advancement, 4th and 5th graders would eventually have 3 and 4 years of Mindstorms experience under their belts. Thus, allowing for more advanced projects and deeper problem solving capabilities. To add fuel to this fire, a monthly competition could be established solely for the upper class people. This could involve creating a solution to build a robot that follows a line and picks up Legos, a race around a track following a line, or even a robot that can navigate through a simple maze. Whatever the challenge; a secret agenda should be accomplished. Carefully choose a project that is best solved using principles that coincide with the forecasted science or mathematical lesson plans that month. I believe this would serve as an honor to be old enough to participate in these activities. Student involvement would inevitably increase as a result. Also, what’s better than having a child seeking out mathematical tricks from the teacher, i.e. how to use fractions for simplification of programming timings, in an attempt to gain a competitive advantage over a fellow classmate? Stated in business terms, competition fosters innovation. Then last of all, administer the TIMMS tests and compare the scores to a prior non-Lego integrated year.

B. Middle and Junior High School

In a similar fashion, grades 6th through 8th will experience robotics with a heightened level of technical skills necessary to complete the projects. The main differences are the integration of electrical components, basic electrical principles, soldering techniques, and solar technology used in the foundation of BEAM technology. A guest will also be brought in at the start of the school year for the technical overview and exhibitions of a display-case amount of BEAM robots. However, this speaker will also be an electrical engineer. This expert will relay the pertinence of the BEAM skills to be learned as they are utilized in the real world. Also, the professional should state the educational path best taken in math and science to prepare for a college major in this field. As with the elementary children, the creations will be left on display and questions will be welcomed both during the presentation and on a one-on-one basis.

Since students will more than likely be changing classes for the different subjects, the science labs should be equipped with the necessary tools for the solar robots. This robotics class will need to be slotted in a certain portion of the week in replacement of the sciences. In addition, a yearly BEAM robot fair should also be created. Robots that interact, seek out light, and intertwine independent ideas (as apposed to just following directions out of a book) should be suggested. A new twist will be added to this fair though. Students will be required to provide a write-up that details schematics, electrical calculations, and descriptions of the robot. This should even include how light transforms to energy for the motor. This insures that the student is actually understanding the creation and learning the principles not just excelling in the field of directions following. If the Beam Robot Fair is the yearly event for all grades, the monthly projects for the privileged 8th graders could be a robot race. I would like to better name these functions, The Solar Roller Races. Here, students will create solar powered drag cars to race their fellow classmates. These simple creations will be entered into a bracketing system in which the monthly winners will have their names engraved on an annual plaque. Winners could be encouraged to retire that car and work on a new one for the next month. This will encourage continued devotion to these races from everyone. And as the last step in this process would be, TIMMS test should be administered to the students and compared to prior non-robot years.

C. High School

With no surprise, the most involved, demanding, and in depth robotic projects will be asked of those in high school. The sky is the limit on the complexity of any project here. Also, in hopes of keeping the robotics program alive for many years, those who began with the Lego Mindstorms will be able to utilize their skills since first grade on the projects. Robot bases can easily be made of Legos and light can also be used as a power source. Students will eventually learn there are advantages and disadvantages to every decision they make.

The school year for grades 9-12 will follow in line with K-8 and begin with a visit from a speaker. This speaker will be an Electrical Engineer fluent in the field of robotics. Again an overview will be given, creations will be demonstrated, a Q/A session will take place, career paths will be detailed, and specific class routes will be suggested. Although the speaker descriptions appear to just be reiterations of other grade levels, the importance cannot be stressed enough. Many teenagers begin career paths based upon what they enjoy. Hopefully, those who become passionate about robotics understand the importance of accelerated classes for technical majors in college. This fact cannot be forgotten. The classes specific to robotics will be offered to each grade level with increasingly more in depth coverage for the higher grades.

Also, instead of a yearly robot fair, I desire the yearly event to be participation in FIRST. For Inspiration in Science and Technology is a 6 week long competition modeled after an MIT 2.70 mechanical engineering class . As described on the FIRST website:

The FIRST Robotics Competition is a national engineering contest which immerses high school students in the exciting world of engineering. Teaming up with engineers from businesses and universities, students get a hands-on inside look at the engineering profession. In six intense weeks, students and engineers work together to brainstorm, design, construct and test their champion robot. With only six weeks, all jobs are critical path. The teams then compete in a spirited, no-holds-barred tournament complete with referees, cheerleaders and time clocks.

The partnerships developed between schools, businesses, and universities provide an exchange of resources and talent, highlighting mutual needs, building cooperation, and exposing students to new career choices. The result is a fun, exciting and stimulating environment in which all participants discover the important connection between classroom lessons and real world applications.

Each year, the competition is different, so returning teams always have a new challenge to look forward to. However, the details are kept secret until the unveiling at the Kick-Off workshop. This provides a high level of excitement as everyone sees the new challenge for the first time and ideas immediately being forming in people’s minds.

Upper class people will also have their privileges in high school. The monthly event open to 10th and 11th graders could be robot sumo. Here, students will create completely autonomous robots and mimic the rules of one of Japan’s most popular sports, sumo. Instead, the idea is for the size and weight class restricted robots to push each other out of a circular ring. Robot sumo has already made its way into many robot clubs, high schools, and universities. The popularity of this event can be credited to its low part costs and simplicity of rules. In 2001 alone, more than 4,000 robots competed in a 4-month season in Japan and those numbers are growing at an exponential rate. Innovation is what keeps this game growing in numbers and proves invaluable for student participation and educational advancement.

Naturally, in order to prove my hypothesis, the high school students would also need to be administered an internationally recognized TIMMS exam. These scores would then need to be compared to non-robotic years.

VI. Conclusions

Although the robotic case study has not been implemented to test my hypothesis, I will make predictions on the findings. As forethought, I also believe the conclusions to be correct to a high amount of accuracy. There are many ingredients to this success and I will attempt to touch on most of what I consider obvious outcomes. However, as a person of science, I admit that these ideas are not factual and even incomplete without the study actually taking place.

Public displays of projects and competitions have fostered extraordinary outcomes. So does the cooperative participation with all students. In time, I believe this will portray robotics as a cool thing to do in school. This being the case, some of the educational barriers will be hurdled in the process. Especially during the competitions, students will be working with the adults and not for them. Realizations that it is not the gender, race, creed, sex, or social status that matters in reference to partnering in robotics, but what they know and can contribute to the cause is a vital lesson. The differences in people will be grayed out while their possibly unknown qualities will shine. Robotics gives a chance for people who generally wouldn’t have associated with each other to seek each other out for their robotic potential .

Specifically looking at gender differences, it is important to note the participation of females in robotics. A finding from Robocamp states, it appears that girls in particular may need encouragement and a formal structure in order to experiment and be creative. They would do more advanced exercises only when specifically asked. Another finding exhumed from the book Robots for Kids details finding at an elementary school in Reston, Virginia. Believing the importance of ideas to be best left in the author’s words,

We (KISS Institute for Practical Robotics) distributed flyers to the fifth and sixth graders (ages 10-11), and the next day 30 registrations appeared: 29 boys and 1 girl.

This overwhelming imbalance highlighted an obvious need to reach out to girls, and this inspired immediate action on our part. We received permission to present short robot demos for second graders. During these demos, students were invited to push buttons, flip levers, and otherwise interact with a couple of real robots. We then distributed flyers to the second graders for an after-school robotics class. This time we had enough response to form two classes, and about 40 percent of the registrants were girls.

Four years later when this group became sixth graders, we again offered a fifth/sixth-grade class. This time half the students who signed up were female. None of this resembles an actual scientific study (why we are developing); however, there was a fairly strong indication that when students had a fun experience with robots at an early age, they were much more likely to pursue that topic at a later point in their life. Presumably, the same effect would occur later in life, in that students would be more likely to choose college courses and/or career paths further down the line after having been exposed to fun experiences with robotics in middle and high school.

Along with the proposed findings that more students will choose a technical career later in life, I believe that local robotics clubs will also begin forming in the community. This will lead to in depth community involvement of older more experienced people volunteering for robotics help in the local schools. Hence, this cycle will lead to better teachings and of course better projects. Also, I believe this will help perpetuate a more enjoyable school experience for children. This can be proven just by a jump in attendance. Another way to validate the statement is to look at the children’s Christmas/birthday lists. I believe they will include more robotic related materials than before.

All of these reasons encapsulate why math scores will improve. More specifically, I believe scores will improve by at least 10 points on the TIMMS scores as compared to non-robotic years. I say this because,

In regular classes many teachers try to use grades to motivate students, and sometimes they miss the mark. It is best for students to push themselves to excel, so teachers give exams to test student achievement and attach a grade to motivate students to do their best. But one of the real problems of education is that grading standards vary widely and continually slip downward. At the same time, students would seem to be foolishly wasting their time if they did anything more than the minimum required to get an A in a class.

Also, I foresee a higher enrollment in advanced math and science classes. This is, of course, a result of more students having their eyes opened to technical careers and taking proactive educational steps to achieve these dreams. If more students enroll in advanced math classes, then more students will score better on nationwide math based exams. In addition, lets not forget that students have been unknowingly working on problem solving skills and math based robotic inspired formulas for the duration of the year. The best part is that these processes were probably utilized in a majority of the student’s free time as projects were being created and completed. If portions of students are inspired to focus on robotics every spare hour they are free, increased math use is unavoidable. Hence, with this practice, so is improvement upon these skills. A 12-year long study of the continued robotic intervention of the 1st graders to their 12th grade testing would be interesting. The implications of perpetuated involvement in the robotics field would be fascinating.

People under the legal age of 18, or dare I categorize them as children, possess all the tenacity, creativity, and capacity to learn, as do adults. Channeling these incredible energies into something as positive and productive as robotics will have effects that ripple on beyond our comprehension. As best stated by a high school participant in FIRST, Daniel Lehrbaum shares his insight on people.

I think if students are put in a position where their opinions are valued and their designs are valued and people listen to them, suddenly they can rise to that new level. I think the one thing is that people fill the shoes that you put them in. If the engineers and advisors (that assist the team with FIRST) put them in really big shoes, they are going to fill them. They will do the things they need to do to get the job done. Especially if they are, you know, dedicated to the cause. People can do incredible things.

Associate degrees are commonly referred to as undergraduate degrees. Duration of studies is counted as units or semester credit hours. Each semester has 15 credit hours hence an Associate degree is earned once a student reaches the minimum 4 semesters, equivalent to 60 units or semester credit hours. Associate degrees are generally 2-year degrees, like those conferred at community colleges. Now, associate degrees are available online, allowing you to study whenever or wherever you want.

An associate degree is defined as, “An academic degree awarded by community colleges, junior colleges and some bachelor’s degree-granting colleges and universities upon completion of a course of study usually lasting two years.”

The program consists of three parts: general education requirements, major requirements, and electives. Online associate degrees are the same as on-campus or in-classroom associate degrees, but the degree can be taken entirely through the Internet or by distance education.

An online associate degree in business, liberal arts, and other disciplines, is widely accepted for transfer into bachelor’s degree programs throughout the country.

Types of Associate Degree Programs:
A.A. – “Associate of Arts” degree
This degree is designed to transfer to a four-year college or university.

A.A.S. – “Associate of Applied Science” degree
Designed to prepare graduates for career entry or job advancement after 2 years of college study. AAS degrees may transfer in whole or in part to 4 year colleges. A.A.S degrees may also be known by occupational specific titles such as Associate in Engineering Technology, Associate in Business, etc.

A.S. – “Associate of Science” degree
Designed to transfer to a 4 year college or university.

Occupational Degree
Also referred to as “applied” degree programs, an occupational degree program at a two-year college is designed to prepare students to enter the workforce immediately following graduation. The primary function is career preparation, however some courses and/or programs may transfer to 4 year colleges.

Online Associate Degrees
Associated degrees available nationwide include disciplines such as accounting, arts and humanities, business and management, marketing, design, graphic design, early childhood development, education, engineering, fire science, health sciences, hospitality management, human resources management, law and paralegal, criminal justice, social sciences telecommunications and technology.

Taking a degree in-classroom, online or by distance learning makes no difference except for the cost, time and place. Other than these aspects, education and programs are common to all of them, although there is less emphasis on an industry-specific competency. An Associate degree is more focused on learning the basic academic discipline, than in specialization.

All associated degrees are available through the Internet, but accelerated online programs make it easier to earn a certificate in less time. Earning an Associate degree also enables students to enter interesting professions, with minimal additional training in the field of electronics, health care and other faster growing occupations.

When you earn Associate degree online, you will not be singled out because yours was distance learning. A certificate for an Associate’s degree looks the same, regardless of whether it was earned online or on a campus. When you learn online, you will find that you can schedule work, family obligations and fun as well as learning into your busy life. Lectures can be downloaded and listened to at any time. Documents can also be read on the website, and you can turn in your homework assignments by e-mail or fax. Those who want to earn associate degree online but who are not sure how to get started should browse through various programs and locate one that is right. This requires a lot of research, but ultimately it pays off in the form of greater confidence, qualifications, and pay.