random sample
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出典(authority):フリー百科事典『ウィキペディア（Wikipedia）』「2013/05/13 05:14:00」(JST)
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[Wiki en表示]In statistics, quality assurance, and survey methodology, sampling is concerned with the selection of a subset of individuals from within a statistical population to estimate characteristics of the whole population. Acceptance sampling is used to determine if a production lot of material meets the governing specifications. Two advantages of sampling are that the cost is lower and data collection is faster than measuring the entire population.
Each observation measures one or more properties (such as weight, location, color) of observable bodies distinguished as independent objects or individuals. In survey sampling, weights can be applied to the data to adjust for the sample design, particularly stratified sampling (blocking). Results from probability theory and statistical theory are employed to guide practice. In business and medical research, sampling is widely used for gathering information about a population.
The sampling process comprises several stages:
 Defining the population of concern
 Specifying a sampling frame, a set of items or events possible to measure
 Specifying a sampling method for selecting items or events from the frame
 Determining the sample size
 Implementing the sampling plan
 Sampling and data collecting
Contents

Population definition [edit]
Successful statistical practice is based on focused problem definition. In sampling, this includes defining the population from which our sample is drawn. A population can be defined as including all people or items with the characteristic one wishes to understand. Because there is very rarely enough time or money to gather information from everyone or everything in a population, the goal becomes finding a representative sample (or subset) of that population.
Sometimes that which defines a population is obvious. For example, a manufacturer needs to decide whether a batch of material from production is of high enough quality to be released to the customer, or should be sentenced for scrap or rework due to poor quality. In this case, the batch is the population.
Although the population of interest often consists of physical objects, sometimes we need to sample over time, space, or some combination of these dimensions. For instance, an investigation of supermarket staffing could examine checkout line length at various times, or a study on endangered penguins might aim to understand their usage of various hunting grounds over time. For the time dimension, the focus may be on periods or discrete occasions.
In other cases, our 'population' may be even less tangible. For example, Joseph Jagger studied the behaviour of roulette wheels at a casino in Monte Carlo, and used this to identify a biased wheel. In this case, the 'population' Jagger wanted to investigate was the overall behaviour of the wheel (i.e. the probability distribution of its results over infinitely many trials), while his 'sample' was formed from observed results from that wheel. Similar considerations arise when taking repeated measurements of some physical characteristic such as the electrical conductivity of copper.
This situation often arises when we seek knowledge about the cause system of which the observed population is an outcome. In such cases, sampling theory may treat the observed population as a sample from a larger 'superpopulation'. For example, a researcher might study the success rate of a new 'quit smoking' program on a test group of 100 patients, in order to predict the effects of the program if it were made available nationwide. Here the superpopulation is "everybody in the country, given access to this treatment"  a group which does not yet exist, since the program isn't yet available to all.
Note also that the population from which the sample is drawn may not be the same as the population about which we actually want information. Often there is large but not complete overlap between these two groups due to frame issues etc. (see below). Sometimes they may be entirely separate  for instance, we might study rats in order to get a better understanding of human health, or we might study records from people born in 2008 in order to make predictions about people born in 2009.
Time spent in making the sampled population and population of concern precise is often well spent, because it raises many issues, ambiguities and questions that would otherwise have been overlooked at this stage.
Sampling frame [edit]
In the most straightforward case, such as the sentencing of a batch of material from production (acceptance sampling by lots), it is possible to identify and measure every single item in the population and to include any one of them in our sample. However, in the more general case this is not possible. There is no way to identify all rats in the set of all rats. Where voting is not compulsory, there is no way to identify which people will actually vote at a forthcoming election (in advance of the election). These imprecise populations are not amenable to sampling in any of the ways below and to which we could apply statistical theory.
As a remedy, we seek a sampling frame which has the property that we can identify every single element and include any in our sample ^{[1]} ^{[2]} ^{[3]} .^{[4]} The most straightforward type of frame is a list of elements of the population (preferably the entire population) with appropriate contact information. For example, in an opinion poll, possible sampling frames include an electoral register and a telephone directory.
Probability and nonprobability sampling [edit]
A probability sampling is one in which every unit in the population has a chance (greater than zero) of being selected in the sample, and this probability can be accurately determined. The combination of these traits makes it possible to produce unbiased estimates of population totals, by weighting sampled units according to their probability of selection.
Example: We want to estimate the total income of adults living in a given street. We visit each household in that street, identify all adults living there, and randomly select one adult from each household. (For example, we can allocate each person a random number, generated from a uniform distribution between 0 and 1, and select the person with the highest number in each household). We then interview the selected person and find their income. People living on their own are certain to be selected, so we simply add their income to our estimate of the total. But a person living in a household of two adults has only a oneintwo chance of selection. To reflect this, when we come to such a household, we would count the selected person's income twice towards the total. (The person who is selected from that household can be loosely viewed as also representing the person who isn't selected.)
In the above example, not everybody has the same probability of selection; what makes it a probability sample is the fact that each person's probability is known. When every element in the population does have the same probability of selection, this is known as an 'equal probability of selection' (EPS) design. Such designs are also referred to as 'selfweighting' because all sampled units are given the same weight.
Probability sampling includes: Simple Random Sampling, Systematic Sampling, Stratified Sampling, Probability Proportional to Size Sampling, and Cluster or Multistage Sampling. These various ways of probability sampling have two things in common:
 Every element has a known nonzero probability of being sampled and
 involves random selection at some point.
Nonprobability sampling is any sampling method where some elements of the population have no chance of selection (these are sometimes referred to as 'out of coverage'/'undercovered'), or where the probability of selection can't be accurately determined. It involves the selection of elements based on assumptions regarding the population of interest, which forms the criteria for selection. Hence, because the selection of elements is nonrandom, nonprobability sampling does not allow the estimation of sampling errors. These conditions give rise to exclusion bias, placing limits on how much information a sample can provide about the population. Information about the relationship between sample and population is limited, making it difficult to extrapolate from the sample to the population.
Example: We visit every household in a given street, and interview the first person to answer the door. In any household with more than one occupant, this is a nonprobability sample, because some people are more likely to answer the door (e.g. an unemployed person who spends most of their time at home is more likely to answer than an employed housemate who might be at work when the interviewer calls) and it's not practical to calculate these probabilities.
Nonprobability sampling methods include accidental sampling, quota sampling and purposive sampling. In addition, nonresponse effects may turn any probability design into a nonprobability design if the characteristics of nonresponse are not well understood, since nonresponse effectively modifies each element's probability of being sampled.
Sampling methods [edit]
Within any of the types of frame identified above, a variety of sampling methods can be employed, individually or in combination. Factors commonly influencing the choice between these designs include:
 Nature and quality of the frame
 Availability of auxiliary information about units on the frame
 Accuracy requirements, and the need to measure accuracy
 Whether detailed analysis of the sample is expected
 Cost/operational concerns
Simple random sampling [edit]
In a simple random sample (SRS) of a given size, all such subsets of the frame are given an equal probability. Each element of the frame thus has an equal probability of selection: the frame is not subdivided or partitioned. Furthermore, any given pair of elements has the same chance of selection as any other such pair (and similarly for triples, and so on). This minimises bias and simplifies analysis of results. In particular, the variance between individual results within the sample is a good indicator of variance in the overall population, which makes it relatively easy to estimate the accuracy of results.
However, SRS can be vulnerable to sampling error because the randomness of the selection may result in a sample that doesn't reflect the makeup of the population. For instance, a simple random sample of ten people from a given country will on average produce five men and five women, but any given trial is likely to overrepresent one sex and underrepresent the other. Systematic and stratified techniques, discussed below, attempt to overcome this problem by using information about the population to choose a more representative sample.
SRS may also be cumbersome and tedious when sampling from an unusually large target population. In some cases, investigators are interested in research questions specific to subgroups of the population. For example, researchers might be interested in examining whether cognitive ability as a predictor of job performance is equally applicable across racial groups. SRS cannot accommodate the needs of researchers in this situation because it does not provide subsamples of the population. Stratified sampling, which is discussed below, addresses this weakness of SRS.
Simple random sampling is always an EPS design (equal probability of selection), but not all EPS designs are simple random sampling.
Systematic sampling [edit]
Systematic sampling relies on arranging the study population according to some ordering scheme and then selecting elements at regular intervals through that ordered list. Systematic sampling involves a random start and then proceeds with the selection of every kth element from then onwards. In this case, k=(population size/sample size). It is important that the starting point is not automatically the first in the list, but is instead randomly chosen from within the first to the kth element in the list. A simple example would be to select every 10th name from the telephone directory (an 'every 10th' sample, also referred to as 'sampling with a skip of 10').
As long as the starting point is randomized, systematic sampling is a type of probability sampling. It is easy to implement and the stratification induced can make it efficient, if the variable by which the list is ordered is correlated with the variable of interest. 'Every 10th' sampling is especially useful for efficient sampling from databases.
For example, suppose we wish to sample people from a long street that starts in a poor area (house No. 1) and ends in an expensive district (house No. 1000). A simple random selection of addresses from this street could easily end up with too many from the high end and too few from the low end (or vice versa), leading to an unrepresentative sample. Selecting (e.g.) every 10th street number along the street ensures that the sample is spread evenly along the length of the street, representing all of these districts. (Note that if we always start at house #1 and end at #991, the sample is slightly biased towards the low end; by randomly selecting the start between #1 and #10, this bias is eliminated.
However, systematic sampling is especially vulnerable to periodicities in the list. If periodicity is present and the period is a multiple or factor of the interval used, the sample is especially likely to be unrepresentative of the overall population, making the scheme less accurate than simple random sampling.
For example, consider a street where the oddnumbered houses are all on the north (expensive) side of the road, and the evennumbered houses are all on the south (cheap) side. Under the sampling scheme given above, it is impossible to get a representative sample; either the houses sampled will all be from the oddnumbered, expensive side, or they will all be from the evennumbered, cheap side.
Another drawback of systematic sampling is that even in scenarios where it is more accurate than SRS, its theoretical properties make it difficult to quantify that accuracy. (In the two examples of systematic sampling that are given above, much of the potential sampling error is due to variation between neighbouring houses  but because this method never selects two neighbouring houses, the sample will not give us any information on that variation.)
As described above, systematic sampling is an EPS method, because all elements have the same probability of selection (in the example given, one in ten). It is not 'simple random sampling' because different subsets of the same size have different selection probabilities  e.g. the set {4,14,24,...,994} has a oneinten probability of selection, but the set {4,13,24,34,...} has zero probability of selection.
Systematic sampling can also be adapted to a nonEPS approach; for an example, see discussion of PPS samples below.
Stratified sampling [edit]
Where the population embraces a number of distinct categories, the frame can be organized by these categories into separate "strata." Each stratum is then sampled as an independent subpopulation, out of which individual elements can be randomly selected.^{[1]} There are several potential benefits to stratified sampling.
First, dividing the population into distinct, independent strata can enable researchers to draw inferences about specific subgroups that may be lost in a more generalized random sample.
Second, utilizing a stratified sampling method can lead to more efficient statistical estimates (provided that strata are selected based upon relevance to the criterion in question, instead of availability of the samples). Even if a stratified sampling approach does not lead to increased statistical efficiency, such a tactic will not result in less efficiency than would simple random sampling, provided that each stratum is proportional to the group's size in the population.
Third, it is sometimes the case that data are more readily available for individual, preexisting strata within a population than for the overall population; in such cases, using a stratified sampling approach may be more convenient than aggregating data across groups (though this may potentially be at odds with the previously noted importance of utilizing criterionrelevant strata).
Finally, since each stratum is treated as an independent population, different sampling approaches can be applied to different strata, potentially enabling researchers to use the approach best suited (or most costeffective) for each identified subgroup within the population.
There are, however, some potential drawbacks to using stratified sampling. First, identifying strata and implementing such an approach can increase the cost and complexity of sample selection, as well as leading to increased complexity of population estimates. Second, when examining multiple criteria, stratifying variables may be related to some, but not to others, further complicating the design, and potentially reducing the utility of the strata. Finally, in some cases (such as designs with a large number of strata, or those with a specified minimum sample size per group), stratified sampling can potentially require a larger sample than would other methods (although in most cases, the required sample size would be no larger than would be required for simple random sampling.
 A stratified sampling approach is most effective when three conditions are met
 Variability within strata are minimized
 Variability between strata are maximized
 The variables upon which the population is stratified are strongly correlated with the desired dependent variable.
 Advantages over other sampling methods
 Focuses on important subpopulations and ignores irrelevant ones.
 Allows use of different sampling techniques for different subpopulations.
 Improves the accuracy/efficiency of estimation.
 Permits greater balancing of statistical power of tests of differences between strata by sampling equal numbers from strata varying widely in size.
 Disadvantages
 Requires selection of relevant stratification variables which can be difficult.
 Is not useful when there are no homogeneous subgroups.
 Can be expensive to implement.
 Poststratification
Stratification is sometimes introduced after the sampling phase in a process called "poststratification".^{[1]} This approach is typically implemented due to a lack of prior knowledge of an appropriate stratifying variable or when the experimenter lacks the necessary information to create a stratifying variable during the sampling phase. Although the method is susceptible to the pitfalls of post hoc approaches, it can provide several benefits in the right situation. Implementation usually follows a simple random sample. In addition to allowing for stratification on an ancillary variable, poststratification can be used to implement weighting, which can improve the precision of a sample's estimates.^{[1]}
 Oversampling
Choicebased sampling is one of the stratified sampling strategies. In choicebased sampling,^{[5]} the data are stratified on the target and a sample is taken from each stratum so that the rare target class will be more represented in the sample. The model is then built on this biased sample. The effects of the input variables on the target are often estimated with more precision with the choicebased sample even when a smaller overall sample size is taken, compared to a random sample. The results usually must be adjusted to correct for the oversampling.
Probabilityproportionaltosize sampling [edit]
In some cases the sample designer has access to an "auxiliary variable" or "size measure", believed to be correlated to the variable of interest, for each element in the population. These data can be used to improve accuracy in sample design. One option is to use the auxiliary variable as a basis for stratification, as discussed above.
Another option is probabilityproportionaltosize ('PPS') sampling, in which the selection probability for each element is set to be proportional to its size measure, up to a maximum of 1. In a simple PPS design, these selection probabilities can then be used as the basis for Poisson sampling. However, this has the drawback of variable sample size, and different portions of the population may still be over or underrepresented due to chance variation in selections. To address this problem, PPS may be combined with a systematic approach.
Example: Suppose we have six schools with populations of 150, 180, 200, 220, 260, and 490 students respectively (total 1500 students), and we want to use student population as the basis for a PPS sample of size three. To do this, we could allocate the first school numbers 1 to 150, the second school 151 to 330 (= 150 + 180), the third school 331 to 530, and so on to the last school (1011 to 1500). We then generate a random start between 1 and 500 (equal to 1500/3) and count through the school populations by multiples of 500. If our random start was 137, we would select the schools which have been allocated numbers 137, 637, and 1137, i.e. the first, fourth, and sixth schools.
The PPS approach can improve accuracy for a given sample size by concentrating sample on large elements that have the greatest impact on population estimates. PPS sampling is commonly used for surveys of businesses, where element size varies greatly and auxiliary information is often available  for instance, a survey attempting to measure the number of guestnights spent in hotels might use each hotel's number of rooms as an auxiliary variable. In some cases, an older measurement of the variable of interest can be used as an auxiliary variable when attempting to produce more current estimates.^{[6]}
Cluster sampling [edit]
Sometimes it is more costeffective to select respondents in groups ('clusters'). Sampling is often clustered by geography, or by time periods. (Nearly all samples are in some sense 'clustered' in time  although this is rarely taken into account in the analysis.) For instance, if surveying households within a city, we might choose to select 100 city blocks and then interview every household within the selected blocks.
Clustering can reduce travel and administrative costs. In the example above, an interviewer can make a single trip to visit several households in one block, rather than having to drive to a different block for each household.
It also means that one does not need a sampling frame listing all elements in the target population. Instead, clusters can be chosen from a clusterlevel frame, with an elementlevel frame created only for the selected clusters. In the example above, the sample only requires a blocklevel city map for initial selections, and then a householdlevel map of the 100 selected blocks, rather than a householdlevel map of the whole city.
Cluster sampling generally increases the variability of sample estimates above that of simple random sampling, depending on how the clusters differ between themselves, as compared with the withincluster variation. For this reason, cluster sampling requires a larger sample than SRS to achieve the same level of accuracy  but cost savings from clustering might still make this a cheaper option.
Cluster sampling is commonly implemented as multistage sampling. This is a complex form of cluster sampling in which two or more levels of units are embedded one in the other. The first stage consists of constructing the clusters that will be used to sample from. In the second stage, a sample of primary units is randomly selected from each cluster (rather than using all units contained in all selected clusters). In following stages, in each of those selected clusters, additional samples of units are selected, and so on. All ultimate units (individuals, for instance) selected at the last step of this procedure are then surveyed. This technique, thus, is essentially the process of taking random subsamples of preceding random samples.
Multistage sampling can substantially reduce sampling costs, where the complete population list would need to be constructed (before other sampling methods could be applied). By eliminating the work involved in describing clusters that are not selected, multistage sampling can reduce the large costs associated with traditional cluster sampling.^{[6]}
Quota sampling [edit]
In quota sampling, the population is first segmented into mutually exclusive subgroups, just as in stratified sampling. Then judgement is used to select the subjects or units from each segment based on a specified proportion. For example, an interviewer may be told to sample 200 females and 300 males between the age of 45 and 60.
It is this second step which makes the technique one of nonprobability sampling. In quota sampling the selection of the sample is nonrandom. For example interviewers might be tempted to interview those who look most helpful. The problem is that these samples may be biased because not everyone gets a chance of selection. This random element is its greatest weakness and quota versus probability has been a matter of controversy for many years.
Accidental sampling [edit]
Accidental sampling (sometimes known as grab, convenience or opportunity sampling) is a type of nonprobability sampling which involves the sample being drawn from that part of the population which is close to hand. That is, a population is selected because it is readily available and convenient. It may be through meeting the person or including a person in the sample when one meets them or chosen by finding them through technological means such as the internet or through phone. The researcher using such a sample cannot scientifically make generalizations about the total population from this sample because it would not be representative enough. For example, if the interviewer were to conduct such a survey at a shopping center early in the morning on a given day, the people that he/she could interview would be limited to those given there at that given time, which would not represent the views of other members of society in such an area, if the survey were to be conducted at different times of day and several times per week. This type of sampling is most useful for pilot testing. Several important considerations for researchers using convenience samples include:
 Are there controls within the research design or experiment which can serve to lessen the impact of a nonrandom convenience sample, thereby ensuring the results will be more representative of the population?
 Is there good reason to believe that a particular convenience sample would or should respond or behave differently than a random sample from the same population?
 Is the question being asked by the research one that can adequately be answered using a convenience sample?
In social science research, snowball sampling is a similar technique, where existing study subjects are used to recruit more subjects into the sample. Some variants of snowball sampling, such as respondent driven sampling, allow calculation of selection probabilities and are probability sampling methods under certain conditions.
Lineintercept sampling [edit]
Lineintercept sampling is a method of sampling elements in a region whereby an element is sampled if a chosen line segment, called a "transect", intersects the element.
Panel sampling [edit]
Panel sampling is the method of first selecting a group of participants through a random sampling method and then asking that group for (potentially the same) information several times over a period of time. Therefore, each participant is interviewed at two or more time points; each period of data collection is called a "wave". The method was developed by sociologist Paul Lazarsfeld in 1938 as a means of studying political campaigns.^{[7]} This longitudinal samplingmethod allows estimates of changes in the population, for example with regard to chronic illness to job stress to weekly food expenditures. Panel sampling can also be used to inform researchers about withinperson health changes due to age or to help explain changes in continuous dependent variables such as spousal interaction.^{[8]} There have been several proposed methods of analyzing panel data, including MANOVA, growth curves, and structural equation modeling with lagged effects.
Replacement of selected units [edit]
Sampling schemes may be without replacement ('WOR'  no element can be selected more than once in the same sample) or with replacement ('WR'  an element may appear multiple times in the one sample). For example, if we catch fish, measure them, and immediately return them to the water before continuing with the sample, this is a WR design, because we might end up catching and measuring the same fish more than once. Another example, the resampling process of a dataset of (n) years can be represented by having (n) balls of different colors in a box. Essentially, bootstrap resampling with replacement is to randomly pick a ball from the box, record its color and return the ball to the box. This process is repeated many times until a new time series is generated out of the original sample, the box of colored balls.^{[9]} However, if we do not return the fish to the water (e.g. if we eat the fish), this becomes a WOR design.
Sample size [edit]
Formulas, tables, and power function charts are well known approaches to determine sample size.
Steps for using sample size tables [edit]
 Postulate the effect size of interest, α, and β.
 Check sample size table^{[10]}
 Select the table corresponding to the selected α
 Locate the row corresponding to the desired power
 Locate the column corresponding to the estimated effect size.
 The intersection of the column and row is the minimum sample size required.
Sampling and data collection [edit]
Good data collection involves:
 Following the defined sampling process
 Keeping the data in time order
 Noting comments and other contextual events
 Recording nonresponses
Errors in sample surveys [edit]
Survey results are typically subject to some error. Total errors can be classified into sampling errors and nonsampling errors. The term "error" here includes systematic biases as well as random errors.
Sampling errors and biases [edit]
Sampling errors and biases are induced by the sample design. They include:
 Selection bias: When the true selection probabilities differ from those assumed in calculating the results.
 Random sampling error: Random variation in the results due to the elements in the sample being selected at random.
Nonsampling error [edit]
Nonsampling errors are other errors which can impact the final survey estimates, caused by problems in data collection, processing, or sample design. They include:
 Overcoverage: Inclusion of data from outside of the population.
 Undercoverage: Sampling frame does not include elements in the population.
 Measurement error: e.g. when respondents misunderstand a question, or find it difficult to answer.
 Processing error: Mistakes in data coding.
 Nonresponse: Failure to obtain complete data from all selected individuals.
After sampling, a review should be held of the exact process followed in sampling, rather than that intended, in order to study any effects that any divergences might have on subsequent analysis. A particular problem is that of nonresponse.
Two major types of nonresponse exist: unit nonresponse (referring to lack of completion of any part of the survey) and item nonresponse (submission or participation in survey but failing to complete one or more components/questions of the survey).^{[11]}^{[12]} In survey sampling, many of the individuals identified as part of the sample may be unwilling to participate, not have the time to participate (opportunity cost),^{[13]} or survey administrators may not have been able to contact them. In this case, there is a risk of differences, between respondents and nonrespondents, leading to biased estimates of population parameters. This is often addressed by improving survey design, offering incentives, and conducting followup studies which make a repeated attempt to contact the unresponsive and to characterize their similarities and differences with the rest of the frame.^{[14]} The effects can also be mitigated by weighting the data when population benchmarks are available or by imputing data based on answers to other questions.
Nonresponse is particularly a problem in internet sampling. Reasons for this problem include improperly designed surveys,^{[12]} oversurveying (or survey fatigue),^{[8]}^{[15]} and the fact that potential participants hold multiple email addresses, which they don't use anymore or don't check regularly.
Survey weights [edit]
In many situations the sample fraction may be varied by stratum and data will have to be weighted to correctly represent the population. Thus for example, a simple random sample of individuals in the United Kingdom might include some in remote Scottish islands who would be inordinately expensive to sample. A cheaper method would be to use a stratified sample with urban and rural strata. The rural sample could be underrepresented in the sample, but weighted up appropriately in the analysis to compensate.
More generally, data should usually be weighted if the sample design does not give each individual an equal chance of being selected. For instance, when households have equal selection probabilities but one person is interviewed from within each household, this gives people from large households a smaller chance of being interviewed. This can be accounted for using survey weights. Similarly, households with more than one telephone line have a greater chance of being selected in a random digit dialing sample, and weights can adjust for this.
Weights can also serve other purposes, such as helping to correct for nonresponse.
Methods of producing random samples [edit]
 Random number table
 Mathematical algorithms for pseudorandom number generators
 Physical randomization devices such as coins, playing cards or sophisticated devices such as ERNIE
History [edit]
Random sampling by using lots is an old idea, mentioned several times in the Bible. In 1786 Pierre Simon Laplace estimated the population of France by using a sample, along with ratio estimator. He also computed probabilistic estimates of the error. These were not expressed as modern confidence intervals but as the sample size that would be needed to achieve a particular upper bound on the sampling error with probability 1000/1001. His estimates used Bayes' theorem with a uniform prior probability and assumed that his sample was random. Alexander Ivanovich Chuprov introduced sample surveys to Imperial Russia in the 1870s.^{[citation needed]}
In the USA the 1936 Literary Digest prediction of a Republican win in the presidential election went badly awry, due to severe bias [1]. More than two million people responded to the study with their names obtained through magazine subscription lists and telephone directories. It was not appreciated that these lists were heavily biased towards Republicans and the resulting sample, though very large, was deeply flawed.^{[16]}^{[17]}
See also [edit]
Statistics portal 
Wikiversity has learning materials about Sampling (statistics) 
 Acceptance sampling
 Data collection
 Official statistics
 Ratio estimator
 Replication (statistics)
 Sample (statistics)
 Sampling (case studies)
 Sampling error
 Gy's sampling theory
 Horvitz–Thompson estimator
Notes [edit]
The textbook by Groves et alia provides an overview of survey methodology, including recent literature on questionnaire development (informed by cognitive psychology) :
 Robert Groves, et alia. Survey methodology (2010) Second edition of the (2004) first edition ISBN 0471483486.
The other books focus on the statistical theory of survey sampling and require some knowledge of basic statistics, as discussed in the following textbooks:
 David S. Moore and George P. McCabe (February 2005). "Introduction to the practice of statistics" (5th edition). W.H. Freeman & Company. ISBN 071676282X.
 Freedman, David; Pisani, Robert; Purves, Roger (2007). Statistics (4th ed.). New York: Norton. ISBN 0393929728.
The elementary book by Scheaffer et alia uses quadratic equations from highschool algebra:
 Scheaffer, Richard L., William Mendenhal and R. Lyman Ott. Elementary survey sampling, Fifth Edition. Belmont: Duxbury Press, 1996.
More mathematical statistics is required for Lohr, for Särndal et alia, and for Cochran (classic):
 Cochran, William G. (1977). Sampling techniques (Third ed.). Wiley. ISBN 047116240X.
 Lohr, Sharon L. (1999). Sampling: Design and analysis. Duxbury. ISBN 0534353614.
 Särndal, CarlErik, and Swensson, Bengt, and Wretman, Jan (1992). Model assisted survey sampling. SpringerVerlag. ISBN 0387406204.
The historically important books by Deming and Kish remain valuable for insights for social scientists (particularly about the U.S. census and the Institute for Social Research at the University of Michigan):
 Deming, W. Edwards (1966). Some Theory of Sampling. Dover Publications. ISBN 048664684X. OCLC 166526.
 Kish, Leslie (1995) Survey Sampling, Wiley, ISBN 0471109495
References [edit]
 ^ ^{a} ^{b} ^{c} ^{d} Robert M. Groves, et al. Survey methodology. ISBN 0470465468.
 ^ Lohr, Sharon L. Sampling: Design and analysis.
 ^ Särndal, CarlErik, and Swensson, Bengt, and Wretman, Jan. Model Assisted Survey Sampling.
 ^ Scheaffer, Richard L., William Mendenhal and R. Lyman Ott. Elementary survey sampling.
 ^ Scott, A.J.; Wild, C.J. (1986). "Fitting logistic models under casecontrol or choicebased sampling". J. Roy. Statist. Soc. B 48: 170–182. JSTOR 2345712.
 ^ ^{a} ^{b}
 Lohr, Sharon L. Sampling: Design and Analysis.
 Särndal, CarlErik, and Swensson, Bengt, and Wretman, Jan. Model Assisted Survey Sampling.
 ^ Lazarsfeld, P., & Fiske, M. (1938). The" panel" as a new tool for measuring opinion. The Public Opinion Quarterly, 2(4), 596612.
 ^ ^{a} ^{b} Groves, et alia. Survey Methodology
 ^ Mohamed Helmy Mahmoud Moustafa ElsanabaryTeleconnection, Modeling, Climate Anomalies Impact and Forecasting of Rainfall and Streamflow of the Upper Blue Nile River Basin, Canada: University of Alberta, 2012, retrieved 23 January 2012
 ^ Cohen, 1988
 ^ Berinsky, A. J. (2008). Survey nonresponse. In W. Donsbach & M. W. Traugott (Eds.), The SAGE handbook of public opinion research (pp. 309321). Thousand Oaks, CA: Sage Publications.
 ^ ^{a} ^{b} Dillman, D. A., Eltinge, J. L., Groves, R. M., & Little, R. J. A. (2002). Survey nonresponse in design, data collection, and analysis. In R. M. Groves, D. A. Dillman, J. L. Eltinge, & R. J. A. Little (Eds.), Survey nonresponse (pp. 326). New York: John Wiley & Sons.
 ^ Dillman, D.A., Smyth, J.D., & Christian, L. M. (2009). Internet, mail, and mixedmode surveys: The tailored design method. San Francisco: JosseyBass.
 ^ Vehovar, V., Batagelj, Z., Manfreda, K.L., & Zaletel, M. (2002). Nonresponse in web surveys. In R. M. Groves, D. A. Dillman, J. L. Eltinge, & R. J. A. Little (Eds.), Survey nonresponse (pp. 229242). New York: John Wiley & Sons.
 ^ Porter, Whitcomb, Weitzer (2004) Multiple surveys of students and survey fatigue. In S. R. Porter (Ed.), Overcoming survey research problems: Vol. 121. New directions for institutional research (pp. 6374). San Francisco, CA: Jossey Bass.
 ^ David S. Moore and George P. McCabe. "Introduction to the Practice of Statistics".
 ^ Freedman, David; Pisani, Robert; Purves, Roger. Statistics.
Further reading [edit]
 Chambers, R L, and Skinner, C J (editors) (2003), Analysis of Survey Data, Wiley, ISBN 0471899879
 Deming, W. Edwards (1975) On probability as a basis for action, The American Statistician, 29(4), pp146–152.
 Gy, P (1992) Sampling of Heterogeneous and Dynamic Material Systems: Theories of Heterogeneity, Sampling and Homogenizing
 Korn, E.L., and Graubard, B.I. (1999) Analysis of Health Surveys, Wiley, ISBN 0471137731
 Lucas, Samuel R. (2012). "Beyond the Existence Proof: Ontological Conditions, Epistemological Implications, and InDepth Interview Research.", Quality & Quantity, doi:10.1007/s1113501297753.
 Stuart, Alan (1962) Basic Ideas of Scientific Sampling, Hafner Publishing Company, New York
 Smith, T. M. F. (1984). "Present Position and Potential Developments: Some Personal Views: Sample surveys". Journal of the Royal Statistical Society, Series A 147 (The 150th Anniversary of the Royal Statistical Society): 208–221. doi:10.2307/2981677. JSTOR 2981677. More than one of
number=
andissue=
specified (help)  Smith, T. M. F. (1993). "Populations and Selection: Limitations of Statistics (Presidential address)". Journal of the Royal Statistical Society, Series A 156 (2): 144–166. doi:10.2307/2982726. JSTOR 2982726. (Portrait of T. M. F. Smith on page 144)
 Smith, T. M. F. (2001). "Biometrika centenary: Sample surveys". Biometrika 88 (1): 167–243. doi:10.1093/biomet/88.1.167. Unknown parameter
eprint=
ignored (help)  Smith, T. M. F. (2001). "Biometrika centenary: Sample surveys". In D. M. Titterington and D. R. Cox. Biometrika: One Hundred Years. Oxford University Press. pp. 165–194. ISBN 0198509936.
 Whittle, P. (May 1954). "Optimum preventative sampling". Journal of the Operations Research Society of America 2 (2): 197–203. JSTOR 166605.
Standards [edit]
ISO [edit]
 ISO 2859 series
 ISO 3951 series
ASTM [edit]
 ASTM E105 Standard Practice for Probability Sampling Of Materials
 ASTM E122 Standard Practice for Calculating Sample Size to Estimate, With a Specified Tolerable Error, the Average for Characteristic of a Lot or Process
 ASTM E141 Standard Practice for Acceptance of Evidence Based on the Results of Probability Sampling
 ASTM E1402 Standard Terminology Relating to Sampling
 ASTM E1994 Standard Practice for Use of Process Oriented AOQL and LTPD Sampling Plans
 ASTM E2234 Standard Practice for Sampling a Stream of Product by Attributes Indexed by AQL
ANSI, ASQ [edit]
 ANSI/ASQ Z1.4
U.S. federal and military standards [edit]
 MILSTD105
 MILSTD1916


英文文献
 Predicting the need of formal care in Taiwan: Analysis of a national random sample.
 Tsai AC, Lai TM.SourceDepartment of Healthcare Administration, Asia University, 500 Liufeng Rd., Wufeng, Taichung 41354, Taiwan; Department of Health Services Management, China Medical University, Taichung 404, Taiwan.
 Archives of gerontology and geriatrics.Arch Gerontol Geriatr.2011 NovDec;53(3):298302. Epub 2011 Feb 3.
 The study aimed to examine the determinants of needing formal care and the factors impacting care arrangements in elderly Taiwanese by analyzing the 1999 and 2003 data of "The Survey of Health and Living Status of the Elderly in Taiwan", a prospective cohort study of older Taiwanese. For the purpose
 PMID 21295356
和文文献
 IV measurement of NiO nanoregion during observation by transmission electron microscopy
 Fujii Takashi,Arita Masashi,Hamada Kouichi,Kondo Hirofumi,Kaji Hiromichi,Takahashi Yasuo,Moniwa Masahiro,Fujiwara Ichiro,Yamaguchi Takeshi,Aoki Masaki,Maeno Yoshinori,Kobayashi Toshio,Yoshimaru Masaki
 Journal of Applied Physics 109(5), 053702, 20110301
 … Conduction measurements with simultaneous observations by transmission electron microscopy (TEM) were performed on a thin NiO film, which is a candidate material for resistance random access memories (ReRAMs). … To conduct nanoscale experiments, a piezocontrolled TEM holder was used, where a fixed NiO sample and a movable PtIr counter electrode were placed. …
 NAID 120003043353
関連リンク
 In statistics, a sample is a subject chosen from a population for investigation; a random sample is one chosen by a method involving an unpredictable component. Random sampling can also refer to taking a number of independent ...
関連画像
■★リンクテーブル★
関連記事  「SAMPLE」「sample」「random」「sampling」「rand」 
「SAMPLE」
 関
 二次評価、PALS
 焦点を絞った病歴聴取
S  自他覚症状  signs and symptoms  発症初期の自他覚症状 
A  アレルギー  allergies  薬物、食物、その他物質 
M  薬物  medications  常用薬、最後に投与/服用した薬物の種類と用量 
P  病歴  past medical history  出生時の状態、重要な基礎疾患、手術歴、予防接種 
L  最後の食事  last meal  摂取時刻とその内容 
E  イベント  events  現在の状態に関係する出来事、接触までの出来事 
参考
 [display]http://kensyui.com/sample.pdf
「sample」
 n.
 v.
 標本抽出する、試料採取する
WordNet ［license wordnet］
「take a sample of; "Try these new crackers"; "Sample the regional dishes"」WordNet ［license wordnet］
「a small part of something intended as representative of the whole」WordNet ［license wordnet］
「all or part of a natural object that is collected and preserved as an example of its class」PrepTutorEJDIC ［license prepejdic］
「(…の)『見本』,標本《+『of』+『名』》 / (…の)『実例』(example)《+『of』+『名』》 / (無料で進呈する)試供品,サンプル / 見本の,標本の / …‘の'見本をとる;(見本をとって)…‘を'試す(調べる,判断する) / …‘を'実際に試す」
「random」
 adj.
 ランダムな、無秩序な、無作為の
WordNet ［license wordnet］
「lacking any definite plan or order or purpose; governed by or depending on chance; "a random choice"; "bombs fell at random"; "random movements"」PrepTutorEJDIC ［license prepejdic］
「『手当たりしだいの』,任意の;行き当たりばったりの」「sampling」
 n.
WordNet ［license wordnet］
「(statistics) the selection of a suitable sample for study」WordNet ［license wordnet］
「measurement at regular intervals of the amplitude of a varying waveform (in order to convert it to digital form)」
「rand」
WordNet ［license wordnet］
「the basic unit of money in South Africa; equal to 100 cents」PrepTutorEJDIC ［license prepejdic］
「ラント(南アフリカ共和国の通貨の単位)」