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Welcome! The 2010 Event Information ! |
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CVRSF Teacher and
Student Handbook I.
Research Projects: Students
design research projects that provide quantitative data through experimentation followed by analysis and application of that
data. Students pursuing
grade-level 9-12 science coursework are considered Senior Level science
fair participants. Seventh
and eighth grade students not pursuing Senior Level coursework can carry
out a research project if approved by the CVRSF committee.
Students may choose to do an individual or team research project.
No more than three students make up a team.
The ISEF and Affiliated Fairs are research (data) driven.
Only research projects qualifying at our fair will be eligible for
the Tri Region Science and
Engineering Fair. Winners
from the CVRSF will be eligible
to participate in TRSEF. II.
Demonstration Projects: Demonstration projects may
include working models or demonstrations that can be used to clearly
articulate a scientific concept. At
CVRSF, only students in Junior Level 7-8th grade course work
are eligible to present demonstration projects.
Demonstration projects are not eligible to move on to the Tri
Region Science and Engineering Fair.
Demonstration projects provide opportunities for students to
explore a particular topic of interest which in turn may stimulate further
investigation at the Senior Level. All projects
must have an adult sponsor. Each
student project must be registered with CVRSF.
Completed Student/School Registration Forms are due by the
indicated deadlines. Each
student project registration will be reviewed by the Safety Review
Committee. You will be
notified of any concerns about the project or of project approval. NO
chemical or biological agents are allowed at the fair.
Please see the SRC rules and guidelines for complete details.
Research
Based Projects: Science
Research and the Process of Science Research is
a process by which people discover or create new
knowledge about the world in which they live. Questioning is probably the
most important part of a scientific investigation and is often
followed by an “if... then” statement. Students are encouraged to
design ‘controlled’ experiments,
ones that allow them to set up a standard and then change only one
variable at a time to see how
that variable might affect the original condition tested as
the standard. Thus, questioning usually leads to experiments or
observations. Good
scientists, both young and old, frequently use a process to study what
they see in the world. This process has been referred as the ‘Scientific
Method’ or more recently as
the ‘Inquiry Cycle’. The following stages listed below
will help you produce a good scientific experiment: 1) Be curious, choose a limited subject, ask a question; identify or originate/define a problem. It is important that this question be a ‘testable’ question – one in which data is taken and used to find the answer. A testable question can further be identified as one in which one or more variables can be identified and tested to see the impact of that variable on the original set of conditions. The question should not merely be an ‘information’ question where the answer is obtainable through literature research. 2)
Review published materials related to your problem or question.
This is called background research. 3) Evaluate possible solutions and guess why you think it will happen (hypothesis). 4) Experimental design (procedure). In designing the experiment, it is critical that only one variable – a condition that may affect the results of the experiment – is changed at a time. This makes the experiment a ‘controlled’ experiment. 5) Challenge and test your hypothesis through your procedure of experimentation (data collection) and analysis of your data. Use graphs to help see patterns in the data. 6) Draw conclusions based on empirical evidence from the experiment. 7)
Prepare your report and exhibit. 8)
Review and discuss the findings with peer group/ professional
scientists 9) New question(s) may arise from your discussions. This sets the stage for another research project as new questions are raised from others and the process repeats itself. The hypothesis often changes during the course of the experiment. Supporting or not supporting your hypothesis is secondary to what is learned and discovered during the research. Getting
Started 1)
Pick your topic: This is perhaps the most difficult
part. Get an idea of what you want to
study or learn about. Ideas should come from things in your area of
interest. A hobby might lead you
to a good topic. What is going on in the world that you would like to know
more about? Most importantly,
pick a question or problem that is not too broad and that can be answered through scientific investigation. 2) Research your topic: Go to the library or internet to learn more about your topic. Always ask Why or What if.... Look for unexplained or unexpected results. Also, talk to professionals in the field. 3) Organize: Organize everything you have learned about your topic. At this point, you should narrow your thinking by focusing on a particular idea. 4) Make a time table: Choose a topic that not only interests you, but can be done in the amount of time you have. Identify your ‘testable question’. Develop a time line to manage your time efficiently. You will need time to fill out the necessary forms and to review the Research Plan with your sponsor. Certain projects will require more time because they need prior Scientific Review Committee (SRC) or Institutional Review Board (IRB) approval. Allow plenty of time to experiment and collect data. You will also need time to write a paper and put together a display or ‘board’. 5) Plan Your Experiment: Give careful thought to experimental design. Once you have a feasible project idea, write a research plan. This plan should explain how you will do your experiments and exactly what will be involved. Remember you must design your experiment so that it is a ‘controlled’ experiment. This is one in which only one variable is changed at a time. The results are then compared to the ‘standard’ data you take originally before you change that one variable. Thus, you have designed an investigation with adequate control and limited variables to investigate a question. Also, in your experimental design, make sure you include sufficient numbers in both control ( if applicable) and experimental groups to be statistically valid. The experimental design should also include a list of materials. Once finished with the experimental design (called ‘procedure’) all students are required to fill out the appropriate forms. 6) Consult with Your Adult Sponsor and get Approvals: You are required to discuss your research plan with an Adult Sponsor and obtain a signature of approval. In reviewing your research plan, you should determine if additional forms and prior approval are needed. 7)
Conduct your experiment: During
experimentation, keep detailed
notes of each and every experiment, measurement and observation in a log book. Do not rely on memory. Besides,
judges love logbooks! Use data tables or charts to record your quantitative data. 8) Analyze
Your Results: When you complete your experiments, examine and organize
your findings. Use appropriate graphs
to make ‘pictures’ of your data. Identify patterns
from the graphs. This will help you answer your testable question. Did your experiments give you the expected
results? Why or why not? Was your experiment preformed
with the exact same steps each time? Are there other explanations that you had not considered or observed?
Were there experimental errors in your data taking,
experimental design or observations? Remember, that understanding
errors is a key skill scientists must develop. In addition, reporting that a suspected variable did not change
the results can be valuable information. That is just as
much a ‘discovery’ as if there was some change due to the variable. In
addition, statistically analyze your data using the statistics that you
can understand and explain their meaning. 9) Draw Conclusions: Did the variable(s) tested cause a change when compared to the standard you are using? What patterns do you see from your graph analysis that exist between your variables? Which variables are important? Did you collect enough data? Do you need to conduct more experimentation? Keep an open mind – never alter results to fit a theory. If your results do not support your hypothesis, that’s ok and in some cases good! Try to explain why you obtained different results than your literature research predicted for you. Were there sources of error that may have caused these differences? If so, identify them. Even if the results do differ, you still have accomplished successful scientific research because you have taken a question and attempted to discover the answer through quantitative testing. This is the way knowledge is obtained in the world of science. Think of practical applications that can be made from this research. How could this project be used in the real world? Finally, explain how you would improve the experiment and what would you do differently. Additional
Requirements for Research Projects I.
Project Data Book A project data book is your most
treasured piece of work. Accurate and detailed notes make a logical and
winning project. Good notes show consistency and thoroughness to the
judges and will help you when writing your research paper. Data tables are
also helpful. They may be a little ‘messy’ but be sure the
quantitative data recorded is accurate and that units are included in the
data tables. Make sure you date each entry.
A research paper should be prepared and
available along with the project data book and any necessary forms or
relevant written materials. A research paper helps organize data as well
as thoughts. A good paper includes the following sections.
Resources for APA formatting: APA
(American Psychological Association) Style : http://apastyle.apa.org/
http://owl.english.purdue.edu/owl/resource/560/01/ This resource, revised according to the 5th edition of the APA manual, offers examples for the general format of APA research papers, in-text citations, endnotes/ footnotes, and the reference page. Works Cited page. Citation
Machine is an online tool that
will be helpful when formatting but always check for any nuances of the
particular type of citation that may not be recognized by this software.
It can be found at http://www.citationmachine.net/
Douglas
Library at Clinton Community
College has excellent examples for online and print citations including
media (video, motion picture, and sound).
It can be accessed from this link http://www.clinton.edu/douglaslibrary/apamlaguides.cxml
III.
Abstract After
finishing research and experimentation, you need to write an
abstract. The abstract needs to be a maximum of 250 words on one
page. An abstract should include the a) purpose of the experiment, b)
procedures used, c) data, and conclusions. It also may
include any possible research applications. Only minimal reference
to previous work may be included. The abstract must focus
on work done in the current year and should not include a)
acknowledgments, or b) work or procedures done by the mentor.
See below for an example of an appropriately written abstract.
Sample Abstract
IV.
Visual Display You
want to attract and inform. Make it easy for interested spectators
and judges to assess your study and the results you have obtained. You
want to ‘catch the eye’ of the judges and convince them that
the research is of sufficient quality to deserve closer scrutiny. Most
displays or boards have three sections
and are free standing. For the most part, the displays are put on a table.
Most judges get a chance to look
at the board before the interviews. Make the most
of your space using clear and concise displays. You never
get a second chance to make a first impression! Finalists' projects inclusive of all materials and supports are limited to the following dimensions: Depth (front to back) 30 in. (76 cm) The
maximum height of your poster display (table to top) cannot exceed 72 in.
(183 cm). Helpful hints
for display: a) Current Year: Make sure the board reflects the current year’s work only. Prior year’s data books are permitted at your project. b) Good Title: Your title is an extremely important attention-grabber. A good title should simply and accurately present your research and depict the nature of the project. The title should make the casual observer want to know more. c) Take Photographs: Many projects involve elements that may not be safely exhibited at the Fair, but are an important part of the project. You might want to take photographs of important parts/phases of your experiment to use in your display. Photograph or other visual images of human test subjects must have informed consent. Credit must be given for all photographs. d)
Be Organized: Make
sure your display follows a sequence and is logically presented and easy
to read. Reach out to the ‘skim-reader’. A glance should permit
anyone (particularly the judges) to
locate quickly the title, abstract, experiments, results and
conclusions. When you arrange your
display, imagine that you are seeing it for the first time. Highlight your results using key graphs that show the
relationships of the two variables tested. Use the graphs to give a ‘picture’ of the data for your viewers. These
graphs will provide an easier method of viewing the data
rather that just seeing the recorded quantitative data. e) Eye-Catching: Make your display stand out. Use neat, colorful headings, charts and graphs to present your project. Pay special attention to the labeling or graphs, charts, diagrams, photographs, and tables to ensure that each has a title and appropriate label describing what is being demonstrated. Anyone should be able to understand the visuals without further explanation. f) Correctly Presented and Well-Constructed: Be sure to adhere to the size limitations and safety rules when preparing your display. Make sure your display is sturdy, as it will need to remain intact for quite a while. You must also consider the weight of the project for shipping (if moving on to TRSEF). It can be very costly to ship a heavy board. Keep your materials light, but strong. Please Note: The judges are judging your research, not the display. So don’t spend an excessive amount of time or money on the board. You are being judged on the science V.
Judging Judges
evaluate and focus on 1) what the student did in the current
year; 2) how well a student followed scientific methodologies; 3) the detail and accuracy of research as documented
in the data book; and 4) whether experimental procedures
were used in the best possible way. Judges look for well thought-out research. They look at how significant your project is in its field; how thorough you were, and how much of the experiment thought and design is your own work. Initially, judges get their information from your board, abstract and research paper to learn what the project is about, but it is the Interview that will be the final determination of your work. Judges applaud those students who can speak freely and confidently about their work. They are not interested in memorized speeches or presentations – they simply want to talk with you about your research to see if you have a good grasp of your project from start to finish. It is important to start the interview off right. Greet the judges and introduce yourself. You want to make a good first impression. Appearance, good manners, appropriate attire, and enthusiasm for what you are doing will impress the judges. Judges often ask questions to test your insight into your projects such as: “How did you come up with this idea? “What was your role?”, “What didn’t you do?”, “What further plans do you have to continue research?” and “What are the practical applications of your project?” Remember that the judges need to see if you understand the basic principles of science behind your project or topic area. They want to determine if you have correctly measured and analyzed the data. They want to know if you can determine possible sources of error in your project and how you might apply your findings to the ‘real’ world. Finally, the judges seek to encourage you in your scientific efforts and your future goals/career in science. Relax, smile and enjoy your time to learn from them and accept their accolades for your fine work. Judging
Criteria (points)
Individual Team Creative Ability 30 25 Scientific Thought 30 25 Thoroughness 15 12 Skill 15 12 Clarity 10 10 Teamwork -- 15 Total Possible Points 100 100 Explanation of the judging criteria can be found in the Judging Criteria document. Demonstration
Projects: Junior Level
Students Demonstration
projects follow these guidelines: 1)
Projects may be
individual or team effort. Teams
of no more than three students are allowed. 2)
Projects of
demonstration type include working models and demonstrations that
can be used to clearly articulate a scientific concept. 3)
Poster
Presentation: Visual display
size will follow the same dimensions as research projects. While the student may not have a research project in
the strict sense, the display should still be appealing and informative.
The guidelines outlined above will be helpful.
The poster should support your understanding of the
scientific principle or concept you investigated, but the judges will also
be interested in how easily you can converse with them about your project.
You may also consider displaying your science journal for the
judges. 4)
Poster Components should include the following elements: a.
Title b.
Introduction What is the scientific objective? What scientific principle is embodied by the demonstration? What is the scientific significance of the demonstration? What are its current or potential applications in a specific discipline(s) or the applied sciences? How does the scientific principle demonstrated contribute to scientific research? Description of relevant
historical background of the demonstration, if applicable, would also be
appropriate. c.
Methods/Materials Description of materials and methods necessary to perform the demonstration Safety issues are noted
within the description d.
Results Include data (qualitative and quantitative) and relevant graphs or tables to clarify the results. Video or photographs of the
demonstration can be provided if they are useful and aid in telling the
story of the demonstration. No
chemical or biological agents are allowed at the fair.
All projects will be screened by the SRC for safety. e.
Conclusions Summarize results and
restate the significance of this demonstration. f.
References APA format is required. Resources can be found in the research section of this document. 5) Judging Criteria Judging criteria for demonstrations parallels that of the research projects. Judges are looking at how well students demonstrate understanding of the science they are presenting. This can be accomplishing in part through your poster, but the judges will be asking questions and listening for students’ ability to verbally articulate understanding of the scientific concepts presented. Criteria
Individual
Team Creativity 30 25 Scientific Thought 30 25 Skill and Thoroughness 15 12 Clarity 15 12 Teamwork
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16 Total 100 100 ****************************************************************** Champlain Valley Regional Science Fair is an affiliate of TRSEF. Additional research requirements have been modified from ISEF guidelines and retrieved on 7/28/07 from http://www.sciserv.org/isef/students/scientific_method.asp Student Handbook information has been modified from ISEF guidelines and retrieved on 7/28/07 from http://www.sciserv.org/isef/document/hbk2008.pdf
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