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statistics
Typology: Study Guides, Projects, Research
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Hey, there, fellow Statistical Dummies! Guess what! There are just five major statistical tests that you will want to be familiar with in your two years of Marine & Environmental Science at CBGS:
In short, each of these five tests is a statistical comparison of two (or more) MEANS, the averages that you get from each separate GROUP in your experiment or field study.
(ex) Your experiment is studying the effect of a new herbicide on the growth of the invasive grass Phragmites. You have TWO groups of plants: an Experimental Group that has been sprayed with the poison and a Control Group that has not been sprayed. After you have calculated the average growth for each of the two groups, run a t test to see if you have detected a “statistically significant” difference in their growth. The t test returns a p value that expresses the probability that this null hypothesis is wrong: Ho: GC = GE …where G stands for mean growth (control vs. experimental)
(ex) You are curious to know if depth perception is important for blue crabs in capturing small fish as prey. One day you provide a dozen hungry crabs, each in his own aquarium, with a meal of ten minnows that you release freely into the water. For each crab you record their “hit:miss” ratio, the number of times they successfully lunge with a pincher at a passing fish versus the number of times they miss the fish. You let the crabs go hungry again for several days, then repeat the procedure on the same 12 crabs, except this time you fit each crab with a little eye patch that blocks its vision in one eye and thus ruins its 3 D depth perception. You organize your results in “beforeaf ter” pairs, crab by crab, and run a Paired t test on them. The Paired t test returns a p value on the validity of this null hypothesis: Ho: SB = SA …where S stands for mean rate of successful attacks (before vs. after)
(ex) Red snapper, a favorite target of recreational fishermen in the Gulf of Mexico, often get caught in the trawl nets of shrimp boats. Recreational fishermen don’t like this! You have invented a new kind of trawl net bearing a trapdoor that is intended to let red snapper escape from the net, but without letting the shrimp escape. Shrimp boats can tow two nets simultaneously, one on each side. You rig a single shrimp boat with a traditional shrimp trawl on the starboard side and your new experimental trawl on the other side. You do a series of successive tows, counting the number of red snapper captured by each net on each tow. Afterwards you organize your data in leftr ight pairs, towbytow , and run a Paired t test on the following null hypothesis: Ho: CP = CS …where C stands for mean number of red snapper captured (port vs. starboard)
(ex) Sunlight is a composite of all the colors of the rainbow. Seawater absorbs some of these colors more quickly than others. Red light can penetrate
(ex) Young juvenile fish often reside close to the shoreline as a safe haven from larger fish that are unable to swim into shallow water. Based on this, you wonder if juvenile perch in the Bay tend to concentrate in the shallowest waters along local sandy beaches. You and a friend use a seine net to sample the population of young perch at five different depths near shore: 1 foot, 2 feet, 3 feet, 4 feet, and 5 feet. You repeat this process at a dozen different positions along the beach, for a total of 60 tows with the seine. You count the number of juvenile perch each time. Then you run a Linear Regression on the results, to test this null hypothesis:
Ho: J 1 = J 2 = J 3 = J 4 = J 5 …where J stands for the mean number of juvenile perch caught at each depth In cases of Linear Regression, an equivalent way to state the null hypothesis is to say that the Best Fit Line will be horizontal, with a slope (M) of zero: Ho: M = 0
…where M is the slope of the best fit line (in accord with y = m x + b , the traditional equation for a line)
(ex) To determine whether bloodworms are osmoconformers or osmoregulators, you subject different worms to a series of different salinities: 5, 15, 25, 35, 45, 55, and 65 ppt. You bathe nine worms in each salinity and you weigh each one before and after a twenty minute bath. Finally you run a Regression on the percent weight changes. Ho: W 5 = W 15 = W 25 = W 35 = W 45 = W 55 = W 65 …where W stands for the mean weight change at each salinity OR
Ho: M = 0 …where M is the slope of the best fit line