In addition to the problems THAT WILL BE TURNED IN NEXT CLASS, play around with this applet:
http://phet.colorado.edu/sims/wave-on-a-string/wave-on-a-string_en.html
Physics - yay!
Monday, September 30, 2013
Friday, September 27, 2013
Homework to be turned in on Tuesday (A block) and Wednesday (E block)
Note - this is due on Tuesday for A block, and Wednesday for E block (who already have a different assignment due for Monday).
Write your answers on a separate sheet of paper TO BE TURNED IN.
Please write your work and answers on a sheet of paper that you can turn in. Thanks!
1. What is the wavelength of a 120 pm x-ray? (pm means 10^-12 m and x-rays travel at the speed of light)
2. Draw the approximate shape of a graph of period vs. length for a pendulum.
3. The equation we've seen in class is the period of a "simple" pendulum. What do you suppose makes our pendulums "simple"?
4. Calculate the period of a 5-m long pendulum.
5. If the pendulum in #4 above were taken to Mars, where the gravity is roughly 40% Earth's gravity, would be the new period?
6. Consider a 261.6 Hz sound wave (this is approximately the note 'middle C'). Assume that the speed of sound at sea level is 340 m/s.
a. What is the wavelength of this sound wave?
b. Do you think the wavelength of this sound wave would be different on the Moon? How so?
c. Would the wavelength be different at a higher altitude, maybe in Boulder, Colorado? How so?
Write your answers on a separate sheet of paper TO BE TURNED IN.
Please write your work and answers on a sheet of paper that you can turn in. Thanks!
1. What is the wavelength of a 120 pm x-ray? (pm means 10^-12 m and x-rays travel at the speed of light)
2. Draw the approximate shape of a graph of period vs. length for a pendulum.
3. The equation we've seen in class is the period of a "simple" pendulum. What do you suppose makes our pendulums "simple"?
4. Calculate the period of a 5-m long pendulum.
5. If the pendulum in #4 above were taken to Mars, where the gravity is roughly 40% Earth's gravity, would be the new period?
6. Consider a 261.6 Hz sound wave (this is approximately the note 'middle C'). Assume that the speed of sound at sea level is 340 m/s.
a. What is the wavelength of this sound wave?
b. Do you think the wavelength of this sound wave would be different on the Moon? How so?
c. Would the wavelength be different at a higher altitude, maybe in Boulder, Colorado? How so?
Wednesday, September 25, 2013
Homework
Due Friday for the A block class.
Due Monday for E, though you don't have to do number 1.
1. On the image below, try to use the equations to derive the wave speed equation.
2. Using this new equation, solve:
A. What is the wavelength of a concert A (440 Hz), if the speed of sound is 340 m/s?
B. What is the wavelength of a radio signal (89.7 MHz). It travels at the speed of light.
Due Monday for E, though you don't have to do number 1.
1. On the image below, try to use the equations to derive the wave speed equation.
2. Using this new equation, solve:
A. What is the wavelength of a concert A (440 Hz), if the speed of sound is 340 m/s?
B. What is the wavelength of a radio signal (89.7 MHz). It travels at the speed of light.
Thursday, September 19, 2013
Lab HW
You will be submitting an informal lab report for your pendulum work - this will be submitted individually, 2 classes from now.
In it, you should have:
Graph of Time vs. Length, with a curve fit
Graph of Time vs. Square root of length, with a linear regression line (and slope)
Graph of Time vs. Angle (if you took that data)
On the second graph, the regression line equation IS the equation for your experiment. Write down that equation and talk (in a conclusion) about how well it compares to the ACTUAL equation for the period/time of a pendulum:
Note that g is a local gravitation constant, equal to around 9.8 m/s/s (that's how quickly gravity makes object accelerate, in m/s per second). If you work out the constants (2 pi divided by the square root of 9.8), you get a coefficient of around 2.0. So a local version of the equation becomes:
T = 2 sqrt (L)
In your conclusion (which will be 2-3 paragraphs at minimum), discuss:
- the extent to which your equation resembles the one above
- sources of error in your experiment
- ways to improve your experiment
- anything else you wish to talk about
And answer these two mathematical questions:
1. What is the period of a 4-m long pendulum?
2. What is the length of a pendulum with a 1-s period?
Again, here's what is due in 2 classes:
Graphs
Conclusion
Answers to the mathematical questions above.
And it should be neat - typed is nice, but handwritten is ok, too.
In it, you should have:
Graph of Time vs. Length, with a curve fit
Graph of Time vs. Square root of length, with a linear regression line (and slope)
Graph of Time vs. Angle (if you took that data)
On the second graph, the regression line equation IS the equation for your experiment. Write down that equation and talk (in a conclusion) about how well it compares to the ACTUAL equation for the period/time of a pendulum:
Note that g is a local gravitation constant, equal to around 9.8 m/s/s (that's how quickly gravity makes object accelerate, in m/s per second). If you work out the constants (2 pi divided by the square root of 9.8), you get a coefficient of around 2.0. So a local version of the equation becomes:
T = 2 sqrt (L)
In your conclusion (which will be 2-3 paragraphs at minimum), discuss:
- the extent to which your equation resembles the one above
- sources of error in your experiment
- ways to improve your experiment
- anything else you wish to talk about
And answer these two mathematical questions:
1. What is the period of a 4-m long pendulum?
2. What is the length of a pendulum with a 1-s period?
Again, here's what is due in 2 classes:
Graphs
Conclusion
Answers to the mathematical questions above.
And it should be neat - typed is nice, but handwritten is ok, too.
Tuesday, September 17, 2013
Logger Pro download
Logger Pro 3.8.6.1 with sample movies (Windows)
Password: extrapolate
Logger Pro 3.8.6.1 with sample movies (Mac OS X)
Password: extrapolate
Monday, September 16, 2013
hw after today's data-gathering
E-block
Plot a graph of period vs. length, ideally by computer.
Discuss any relationship that seems apparent.
A-block
This will be your homework after Tuesday's class.
Plot a graph of period vs. length, ideally by computer.
Discuss any relationship that seems apparent.
A-block
This will be your homework after Tuesday's class.
Friday, September 13, 2013
Relationship?
You now have some pendulum data. Examine it and decide which (if any) variables are relevant. You may find that some are more relevant than others - perhaps some have differences that can be explained by timing issues.
How will you get a relationship out of this data? What is the best way to formulate a "rule" for your data? How can you turn your data into a predictive tool? Would a graph be helpful?
Think about these questions and make a first attempt at formulating a rule or equation. Bring this to class.
How will you get a relationship out of this data? What is the best way to formulate a "rule" for your data? How can you turn your data into a predictive tool? Would a graph be helpful?
Think about these questions and make a first attempt at formulating a rule or equation. Bring this to class.
Tuesday, September 10, 2013
Lab prep
Our goal will be to determine a mathematical relationship that describes the motion of a pendulum - specifically, how the time (for a complete swing - the period) depends on particular variables. Ideally, we will have a relationship that has predictive ability - something that we can use to predict the period of any theoretical pendulum.
Think about what variables you would test to find out whether or not a pendulum's period is altered (and how)?
Think also about how many trials you may need to take, the range of values (for example, if we're talking about length - how short to how long?) and how you will represent your data (chart, graph, both?).
Finally, think about how you will determine a mathematical relationship from all of the data? Can a data set or graph give you an equation? How?
Monday, September 9, 2013
HW for students in Monday's class (after class) and AFTER Tuesday's class
http://www.youtube.com/watch?v=NwyeK36Gh-s
Watch as much as you can stand - comment on what makes it believable or NOT believable.
Also, our first lab begins next class. Think about the following question:
What is a mathematical relationship that predicts the motion (time) of a pendulum swing? How can we determine this? How can we know if our model/relationship/equation is "correct"?
We will spend the next 2-3 classes treating this problem.
https://www.youtube.com/watch?v=2MFAvH8m8aI&feature=player_embedded
If you ever have an hour to kill - the best documentary on pseudoscience ever.
Watch as much as you can stand - comment on what makes it believable or NOT believable.
Also, our first lab begins next class. Think about the following question:
What is a mathematical relationship that predicts the motion (time) of a pendulum swing? How can we determine this? How can we know if our model/relationship/equation is "correct"?
We will spend the next 2-3 classes treating this problem.
https://www.youtube.com/watch?v=2MFAvH8m8aI&feature=player_embedded
If you ever have an hour to kill - the best documentary on pseudoscience ever.
Wednesday, September 4, 2013
What is pseudoscience?
What Is Pseudoscience?
Distinguishing between science and pseudoscience is problematic
By Michael Shermer
Climate deniers are accused of practicing pseudoscience, as are intelligent design creationists, astrologers, UFOlogists, parapsychologists, practitioners of alternative medicine, and often anyone who strays far from the scientific mainstream. The boundary problem between science and pseudoscience, in fact, is notoriously fraught with definitional disagreements because the categories are too broad and fuzzy on the edges, and the term “pseudoscience” is subject to adjectival abuse against any claim one happens to dislike for any reason. In his 2010 book Nonsense on Stilts (University of Chicago Press), philosopher of science Massimo Pigliucci concedes that there is “no litmus test,” because “the boundaries separating science, nonscience, and pseudoscience are much fuzzier and more permeable than Popper (or, for that matter, most scientists) would have us believe.”
It was Karl Popper who first identified what he called “the demarcation problem” of finding a criterion to distinguish between empirical science, such as the successful 1919 test of Einstein’s general theory of relativity, and pseudoscience, such as Freud’s theories, whose adherents sought only confirming evidence while ignoring disconfirming cases. Einstein’s theory might have been falsified had solar-eclipse data not shown the requisite deflection of starlight bent by the sun’s gravitational field. Freud’s theories, however, could never be disproved, because there was no testable hypothesis open to refutability. Thus, Popper famously declared “falsifiability” as the ultimate criterion of demarcation.
The problem is that many sciences are nonfalsifiable, such as string theory, the neuroscience surrounding consciousness, grand economic models and the extraterrestrial hypothesis. On the last, short of searching every planet around every star in every galaxy in the cosmos, can we ever say with certainty that E.T.s do not exist?
Princeton University historian of science Michael D. Gordin adds in his forthcoming book The Pseudoscience Wars (University of Chicago Press, 2012), “No one in the history of the world has ever self-identified as a pseudoscientist. There is no person who wakes up in the morning and thinks to himself, ‘I’ll just head into my pseudolaboratory and perform some pseudoexperiments to try to confirm my pseudotheories with pseudofacts.’” As Gordin documents with detailed examples, “individual scientists (as distinct from the monolithic ‘scientific community’) designate a doctrine a ‘pseudoscience’ only when they perceive themselves to be threatened—not necessarily by the new ideas themselves, but by what those ideas represent about the authority of science, science’s access to resources, or some other broader social trend. If one is not threatened, there is no need to lash out at the perceived pseudoscience; instead, one continues with one’s work and happily ignores the cranks.”
I call creationism “pseudoscience” not because its proponents are doing bad science—they are not doing science at all—but because they threaten science education in America, they breach the wall separating church and state, and they confuse the public about the nature of evolutionary theory and how science is conducted.
Here, perhaps, is a practical criterion for resolving the demarcation problem: the conduct of scientists as reflected in the pragmatic usefulness of an idea. That is, does the revolutionary new idea generate any interest on the part of working scientists for adoption in their research programs, produce any new lines of research, lead to any new discoveries, or influence any existing hypotheses, models, paradigms or worldviews? If not, chances are it is pseudoscience.
We can demarcate science from pseudoscience less by what science is and more by what scientists do. Science is a set of methods aimed at testing hypotheses and building theories. If a community of scientists actively adopts a new idea and if that idea then spreads through the field and is incorporated into research that produces useful knowledge reflected in presentations, publications, and especially new lines of inquiry and research, chances are it is science.
>
http://www.randi.org/site/index.php/encyclopedia.html
http://www.quackwatch.com/01QuackeryRelatedTopics/pseudo.html
http://en.wikipedia.org/wiki/Pseudoscience
http://www.skepdic.com/pseudosc.html
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