Thursday, March 19, 2020

ETERNAL FREEDOM Essays - Candle Lights, Fishing Village, Night Wind

ETERNAL FREEDOM Essays - Candle Lights, Fishing Village, Night Wind ETERNAL FREEDOM The time to escape did come! He had been waiting for it for several months. Taking advantage of the careless of the guards, he dipped himself in water while the prisoners were passing across the stream to go back to the camp after an exhausting working day in the field. The first part of his plan went exactly as desired. Being sure they went far enough, he quickly jumped out of the stream and headed for the woods. He knew there was a highway nearby so that he could hitch-hike to go to the coast where he could easily find a boat and escape farther. It was almost midnight. He had been going about five miles, but found nothing. The cold night wind touched him, increasing his nervousness. He looked back again to make sure that nobody followed him. In a nearby small village flickered some candle lights. Cautiously, he went around the village, trying not to make any noises. Suddenly, a farmer's dog sensed him from a distance and began to bark, then followed the other dogs in the village. He was very upset but could do nothing. Some farmers came out of their houses to see what happened. Seeing nothing, they spoke harshly to their dogs, then returned to their houses. He signed a deep sign of relief and carefully went away. By dawn he still did not see the highway. He felt a little paniced. However, as inhaling the fresh air, listening to the birds, looking up the broad blue sky, he felt more comfortable. Freedom was really precious! There was a stream nearby. He wanted to take a bath. Being a son of a fisherman, he had swum very well since he was a kid. Fresh water reminded him of the days he had lived with his lovely wife and son in a fishing village on the coast of Yellow Sea. Because he was a patriotic Manchurian who had protested the assimilation of the Japanese on his people, the Japanese put him in jail. He had left his wife and son in his home village. Thinking of the day he could re-unite them, he smiled a happy smile. Suddenly, his thoughts were cut off by a lot of barking noises of dogs. The noises came closer and closer. Like a machine, he hurrily went ashore. He realized that the noises were certainly from the search party, and that he might be caught again easily. It was too late! In the distance appeared some yellow uniforms of the Japanese soldiers. He changed his mind and decided to swim offshore. "Freeze!" shouted one of the soldiers. The escaped prisoner did not want to stop swimming. He did not want to be captured again. A volley of bullets sounded in the sky. He still swam and swam. This time, a strange feeling suddenly came to him. He felt that his limbs were benumbed with something which he did not know. Then, at that moment, he suddenly saw his lovely pictures of his life- his wife, his son, his parents, and his beloved fishing village. All of them displayed and disappeared in a very short moment. Then he really felt free.

Monday, March 2, 2020

Confidence Interval for the Difference of Two Population Proportions

Confidence Interval for the Difference of Two Population Proportions Confidence intervals are one part of inferential statistics.   The basic idea behind this topic is to estimate the value of an unknown population  parameter by using a statistical sample.   We can not only estimate the value of a parameter, but we can also adapt our methods to estimate the difference between two related parameters.   For example we may want to find the difference in the percentage of the male U.S. voting population who supports a particular piece of legislation compared to the female voting population. We will see how to do this type of calculation by constructing a confidence interval for the difference of two population proportions.   In the process we will examine some of the theory behind this calculation.   We will see some similarities in how we construct a confidence interval for a single population proportion as well as a confidence interval for the difference of two population means. Generalities Before looking at the specific formula that we will use, lets consider the overall framework that this type of confidence interval fits into.   The form of the type of confidence interval that we will look at is given by the following formula: Estimate /- Margin of Error Many confidence intervals are of this type. There are two numbers that we need to calculate.   The first of these values is the estimate for the parameter.   The second value is the margin of error.   This margin of error accounts for the fact that we do have an estimate.   The confidence interval provides us with a range of possible values for our unknown parameter. Conditions We should make sure that all of the conditions are satisfied before doing any calculation. To find a confidence interval for the difference of two population proportions, we need to make sure that the following hold: We have two simple random samples from large populations.   Here large means that the population is at least 20 times larger than the size of the sample. The sample sizes will be denoted by n1 and n2.Our individuals have been chosen independently of one another.There are at least ten successes and ten failures in each of our samples. If the last item in the list is not satisfied, then there may be a way around this.   We can modify the plus-four confidence interval construction and obtain robust results.   As we go forward we assume that all of the above conditions have been met. Samples and Population Proportions Now we are ready to construct our confidence interval.   We start with the estimate for the difference between our population proportions. Both of these population proportions are estimated by a sample proportion.   These sample proportions are statistics that are found by dividing the number of successes in each sample, and then dividing by the respective sample size. The first population proportion is denoted by p1.   If the number of successes in our sample from this population is k1, then we have a sample proportion of k1 / n1. We denote this statistic by  pÌ‚1.   We read this symbol as p1-hat because it looks like the symbol p1 with a hat on top. In a similar way we can calculate a sample proportion from our second population.   The parameter from this population is p2.   If the number of successes in our sample from this population is k2, and our sample proportion is   pÌ‚2 k2 / n2. These two statistics become the first part of our confidence interval. The estimate of p1 is pÌ‚1.   The estimate of p2 is pÌ‚2.   So the estimate for the difference p1 - p2 is pÌ‚1 - pÌ‚2. Sampling Distribution of the Difference of Sample Proportions Next we need to obtain the formula for the margin of error.   To do this we will first consider the   sampling distribution of   pÌ‚1  . This is a binomial distribution with probability of success p1 and  n1 trials. The mean of this distribution is the proportion p1.   The standard deviation of this type of random variable has variance of p1  (1 - p1  )/n1. The sampling distribution of pÌ‚2 is similar to that of pÌ‚1  .   Simply change all of the indices from 1 to 2 and we have a binomial distribution with mean of p2 and variance of p2 (1 - p2 )/n2. We now need a few results from mathematical statistics in order to determine the sampling distribution of pÌ‚1 - pÌ‚2.   The mean of this distribution is p1 - p2.   Due to the fact that the variances add together, we see that the variance of the sampling distribution is p1  (1 - p1  )/n1 p2 (1 - p2 )/n2.   The standard deviation of the distribution is the square root of this formula. There are a couple of adjustments that we need to make.   The first is that the formula for the standard deviation of pÌ‚1 - pÌ‚2 uses the unknown parameters of p1 and p2.   Of course if we really knew these values, then it would not be an interesting statistical problem at all.   We would not need to estimate the difference between p1 and  p2..   Instead we could simply calculate the exact difference. This problem can be fixed by calculating a standard error rather than a standard deviation.   All that we need to do is to replace the population proportions by sample proportions.   Standard errors are calculated from upon statistics instead of parameters. A standard error is useful because it effectively estimates a   standard deviation.   What this means for us is that we no longer need to know the value of the parameters p1 and p2.   .Since these sample proportions are known, the standard error is given by the square root of the following expression: pÌ‚1 (1 -  pÌ‚1 )/n1   pÌ‚2 (1 -  pÌ‚2 )/n2. The second item that we need to address is the particular form of our sampling distribution.   It turns out that we can use a normal distribution to approximate the sampling distribution of  pÌ‚1  - pÌ‚2.   The reason for this is somewhat technical, but is outlined in the next paragraph.   Both   pÌ‚1 and   pÌ‚2   have a sampling distribution that is binomial.   Each of these binomial distributions may be approximated quite well by a normal distribution.   Thus pÌ‚1  - pÌ‚2 is a random variable.   It is formed as a linear combination of two random variables.   Each of these are approximated by a normal distribution.   Therefore the sampling distribution of pÌ‚1  - pÌ‚2 is also normally distributed. Confidence Interval Formula We now have everything we need to assemble our confidence interval.   The estimate is (pÌ‚1 - pÌ‚2) and the margin of error is z* [ pÌ‚1 (1 -  pÌ‚1 )/n1   pÌ‚2 (1 -  pÌ‚2 )/n2.]0.5.   The value that we enter for z* is dictated by the level of confidence C.  Ã‚  Commonly used values for z* are 1.645 for 90% confidence and 1.96 for 95% confidence.   These values for  z* denote the portion of the standard normal distribution where exactly  C percent of the distribution is between -z* and z*.   The following formula gives us a confidence interval for the difference of two population proportions: (pÌ‚1 - pÌ‚2) /- z* [ pÌ‚1 (1 -  pÌ‚1 )/n1   pÌ‚2 (1 -  pÌ‚2 )/n2.]0.5