Texas Statistics-CourseKata Alignment
- Caylor Davis
NOTE: The numbers correspond to book chapters, and JNBs stand for "Jupyter NoteBooks" -- the way we deliver our in-class data case studies.
TEKS Standards | Book ABC |
(1) Mathematical process standards. The student uses mathematical processes to acquire and demonstrate mathematical understanding. The student is expected to: |
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(A) apply mathematics to problems arising in everyday life, society, and the workplace; | 1-12*, JNBs* |
(B) use a problem-solving model that incorporates analyzing given information, formulating a plan or strategy, determining a solution, justifying the solution, and evaluating the problem-solving process and the reasonableness of the solution; | 1-12, JNBs |
(C) select tools, including real objects, manipulatives, paper and pencil, and technology as appropriate, and techniques, including mental math, estimation, and number sense as appropriate, to solve problems; | 1-12, JNBs |
(D) communicate mathematical ideas, reasoning, and their implications using multiple representations, including symbols, diagrams, graphs, and language as appropriate; | 1-12, JNBs |
(E) create and use representations to organize, record, and communicate mathematical ideas; | 1-12, JNBs |
(F) analyze mathematical relationships to connect and communicate mathematical ideas; and | 4-12, JNBs |
(G) display, explain, or justify mathematical ideas and arguments using precise mathematical language in written or oral communication. | 5-12, JNBs |
(2) Statistical process sampling and experimentation. The student applies mathematical processes to apply understandings about statistical studies, surveys, and experiments to design and conduct a study and use graphical, numerical, and analytical techniques to communicate the results of the study. The student is expected to: |
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(A) compare and contrast the benefits of different sampling techniques, including random sampling and convenience sampling methods; | 2 |
(B) distinguish among observational studies, surveys, and experiments; | 2, 4, JNBs |
(C) analyze generalizations made from observational studies, surveys, and experiments; (D) distinguish between sample statistics and population parameters; | 2, 4, JNBs |
(E) formulate a meaningful question, determine the data needed to answer the question, gather the appropriate data, analyze the data, and draw reasonable conclusions; | 2-12, JNBs |
(F) communicate methods used, analyses conducted, and conclusions drawn for a data analysis project through the use of one or more of the following: a written report, a visual display, an oral report, or a multi-media presentation; and | 2-12, JNBs |
(G) critically analyze published findings for appropriateness of study design implemented, sampling methods used, or the statistics applied. | 2-12, JNBs |
(3) Variability. The student applies the mathematical process standards when describing and modeling variability. The student is expected to: |
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(A) distinguish between mathematical models and statistical models; | 5-9 |
(B) construct a statistical model to describe variability around the structure of a mathematical model for a given situation; | 5-9 |
(C) distinguish among different sources of variability, including measurement, natural, induced, and sampling variability; and | 2, 4, 5-9 |
(D) describe and model variability using population and sampling distributions. | 3, 4, 6, 10-12 |
(4) Categorical and quantitative data. The student applies the mathematical process standards to represent and analyze both categorical and quantitative data. The student is expected to: |
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(A) distinguish between categorical and quantitative data; | 2, 3, JNBs |
(B) represent and summarize data and justify the representation; | 2, 3, 4, JNBs |
(C) analyze the distribution characteristics of quantitative data, including determining the possible existence and impact of outliers; | 2, 3, JNBs |
(D) compare and contrast different graphical or visual representations given the same data set; | 2, 3, 4, JNBs |
(E) compare and contrast meaningful information derived from summary statistics given a data set; and | 2, 4, 5, 6, 7, JNBs |
(F) analyze categorical data, including determining marginal and conditional distributions, using two-way tables. | 4, JNBs |
(5) Probability and random variables. The student applies the mathematical process standards to connect probability and statistics. The student is expected to: |
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(A) determine probabilities, including the use of a two-way table; | 4, JNBs |
(B) describe the relationship between theoretical and empirical probabilities using the Law of Large Numbers; | 3, 6, 10, JNBs |
(C) construct a distribution based on a technology-generated simulation or collected samples for a discrete random variable; and | 4, 8, 9, 10, 11, 12, JNBs |
(D) compare statistical measures such as sample mean and standard deviation from a technology-simulated sampling distribution to the theoretical sampling distribution. | 10, 11, 12, JNBs |
(6) Inference. The student applies the mathematical process standards to make inferences and justify conclusions from statistical studies. The student is expected to: |
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(A) explain how a sample statistic and a confidence level are used in the construction of a confidence interval; | 12, JNBs |
(B) explain how changes in the sample size, confidence level, and standard deviation affect the margin of error of a confidence interval; | 12, JNBs |
(C) calculate a confidence interval for the mean of a normally distributed population with a known standard deviation; | 12, JNBs |
(D) calculate a confidence interval for a population proportion; | JNBs |
(E) interpret confidence intervals for a population parameter, including confidence intervals from media or statistical reports; | 12, JNBs |
(F) explain how a sample statistic provides evidence against a claim about a population parameter when using a hypothesis test; | 10, 11, JNBs |
(G) construct null and alternative hypothesis statements about a population parameter; | 10, 11, JNBs |
(H) explain the meaning of the p-value in relation to the significance level in providing evidence to reject or fail to reject the null hypothesis in the context of the situation; | 10, 11, JNBs |
(I) interpret the results of a hypothesis test using technology-generated results such as large sample tests for proportion, mean, difference between two proportions, and difference between two independent means; and | 10, 11, JNBs |
(J) describe the potential impact of Type I and Type II Errors. | 11 |
(7) Bivariate data. The student applies the mathematical process standards to analyze relationships among bivariate quantitative data. The student is expected to: |
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(A) analyze scatterplots for patterns, linearity, outliers, and influential points; | 4 |
(B) transform a linear parent function to determine a line of best fit; | 9 |
(C) compare different linear models for the same set of data to determine best fit, including discussions about error; | 5, 9 |
(D) compare different methods for determining best fit, including median-median and absolute value; | 6 |
(E) describe the relationship between influential points and lines of best fit using dynamic graphing technology; and | JNBs |
(F) identify and interpret the reasonableness of attributes of lines of best fit within the context, including slope and y-intercept. | 9 |