Probability, Statistics and Computer Science
A.Y. 2023/2024
Learning objectives
The aim of this course is to provide the students with the basic instruments of data analysis, univariate statistics and informatics needed to store, manage and statistically analyse real data. The course is divided into 2 modules
Part 1: Descriptive statistics; introduction to probability and random variables; inferential Statistics; computer lab case studies.
Part 2: Introduction to Informatics; hardware and software; elements of scientific programming.
Part 1: Descriptive statistics; introduction to probability and random variables; inferential Statistics; computer lab case studies.
Part 2: Introduction to Informatics; hardware and software; elements of scientific programming.
Expected learning outcomes
At the end of the course the student will have acquired the basic knowledge related to the descriptive statisitca, the probability, the inferential statisitca, the computer science and the scientific programming. The student will acquire skills that will allow him to independently perform simple data analysis, formalize a real problem in mathematical or probabilistic terms, and develop simple programming codes.
Lesson period: Second semester
Assessment methods: Esame
Assessment result: voto verbalizzato in trentesimi
Single course
This course can be attended as a single course.
Course syllabus and organization
Single session
Responsible
Lesson period
Second semester
Course syllabus
MODULE 1: Probability and Statistics.
Descriptive statistics:
1)Sampling from populations. Types of data and variables.
2)Partitioning of data into classes and construction of frequency tables. Histograms and bar charts.
3)Centrality indexes (mean, mode, median, midrange). Dispersion indices (range, standard deviation, variance), percentiles, quartiles. Outliers, boxplots.
Probability and random variables:
4)Sample space, events, probability of events
5)Probability of union and intersection of events. Complementary events. Independent events. Conditional probability. Bayes theorem. Factorials and binomial coefficients.
6)Random variables. Expected value, variance and standard deviation of discrete r.v.
7)Discrete r.v.'s: binomial and Poisson. Continuous r.v.'s: uniform and normal.
8)Standardization and properties of normal distribution. Normal approximation of the binomial distribution.
Inferential statistics:
9)Fundamental concepts: population, sample, parameter, statistics, estimator. Behaviour of the sample mean: law of large numbers and central limit theorem. Punctual estimate.
10)Confidence intervals: general concepts. Confidence interval for a proportion.
11)Confidence interval for the mean, both with known and unknown standard deviation. T Student distribution.
12)Statistical hypothesis testing. General concepts: null and alternate hypotheses, first and second type errors, significance level, power function, p value, test statistics, critical region.
13)Hypothesis test on a proportion. Hypothesis tests on the mean (both with known and unknown variance)
14)Inference for two samples: inference for two proportions. Inference for two means, both for paired or independent samples.
15)One and two way ANOVA
Bivariate statistics:
16)Test of independence and of fit. Chi squared distribution.
Computer lab
17)Illustrative examples of applications of descriptive, inferential and predictive statistics on real data, through the use of simple statistical softwares.
MODULE 2: Informatics
The module consists of theoretical lectures and labs.
Theory:
1) The meaning of Computer Science, algorithms and programs;
2) Computer architecture and digital information;
3) Low and high level programming: compilers and interpreters;
4) Foundations of structured programming;
5) The Python language: data types, control structures, functions and files.
Lab:
1) Operating systems and file system;
2) Programming environment and tools;
3) Programming activity related to theoretical topics above presented.
Descriptive statistics:
1)Sampling from populations. Types of data and variables.
2)Partitioning of data into classes and construction of frequency tables. Histograms and bar charts.
3)Centrality indexes (mean, mode, median, midrange). Dispersion indices (range, standard deviation, variance), percentiles, quartiles. Outliers, boxplots.
Probability and random variables:
4)Sample space, events, probability of events
5)Probability of union and intersection of events. Complementary events. Independent events. Conditional probability. Bayes theorem. Factorials and binomial coefficients.
6)Random variables. Expected value, variance and standard deviation of discrete r.v.
7)Discrete r.v.'s: binomial and Poisson. Continuous r.v.'s: uniform and normal.
8)Standardization and properties of normal distribution. Normal approximation of the binomial distribution.
Inferential statistics:
9)Fundamental concepts: population, sample, parameter, statistics, estimator. Behaviour of the sample mean: law of large numbers and central limit theorem. Punctual estimate.
10)Confidence intervals: general concepts. Confidence interval for a proportion.
11)Confidence interval for the mean, both with known and unknown standard deviation. T Student distribution.
12)Statistical hypothesis testing. General concepts: null and alternate hypotheses, first and second type errors, significance level, power function, p value, test statistics, critical region.
13)Hypothesis test on a proportion. Hypothesis tests on the mean (both with known and unknown variance)
14)Inference for two samples: inference for two proportions. Inference for two means, both for paired or independent samples.
15)One and two way ANOVA
Bivariate statistics:
16)Test of independence and of fit. Chi squared distribution.
Computer lab
17)Illustrative examples of applications of descriptive, inferential and predictive statistics on real data, through the use of simple statistical softwares.
MODULE 2: Informatics
The module consists of theoretical lectures and labs.
Theory:
1) The meaning of Computer Science, algorithms and programs;
2) Computer architecture and digital information;
3) Low and high level programming: compilers and interpreters;
4) Foundations of structured programming;
5) The Python language: data types, control structures, functions and files.
Lab:
1) Operating systems and file system;
2) Programming environment and tools;
3) Programming activity related to theoretical topics above presented.
Prerequisites for admission
It is required the knowledge of the contents of the course Mathematics, of which it is advised to take previously the exam.
Teaching methods
Frontal lectures and computer labs
Teaching Resources
MODULE 1 - PROBABILITY AND STATISTICS:
-Triola M.M.,Triola M.F., Roy J., Fondamenti di Statistica per le discipline biomediche, 2 edizione, con MyLab, Pearson, 2017 (or English version of the same book).
-Lecture notes and slides of the teachers available on the web site of the course on ARIEL
MODULE 2 - INFORMATICS:
Textbook: Tony Gaddis, "Introduzione a Python",
Editor: Pearson
Series: Informatica
Year edition: 2016
Website of the course on ARIEL
-Triola M.M.,Triola M.F., Roy J., Fondamenti di Statistica per le discipline biomediche, 2 edizione, con MyLab, Pearson, 2017 (or English version of the same book).
-Lecture notes and slides of the teachers available on the web site of the course on ARIEL
MODULE 2 - INFORMATICS:
Textbook: Tony Gaddis, "Introduzione a Python",
Editor: Pearson
Series: Informatica
Year edition: 2016
Website of the course on ARIEL
Assessment methods and Criteria
MODULE PROBABILITY AND STATISTICS:
The final examination consists of a written exam during which the student must solve some exercises in the format of open-ended and/or multiple choice answer questions, plus comments to computer outputs with the aim of assessing the student's ability to solve simple problems in probability and statistics.
The duration of the written exam will be proportional to the number of exercises assigned, also taking into account the nature and complexity of the exercises themselves (however, the usual duration is two hours).
MODULE INFORMATICS:
The exam of the module of Informatics consists of a lab test, composed both by theoretical questions or exercises on the course programme, and in the development of a small project in Python.
The global exam is passed if both the tests of the first and second module are passed. Final marks are given using the numerical range 0-30 and is composed as the weighted mean (with credits) of the grades of the two modules. It will be available in the verbalization system of University of Milan and through the UNIMIA portal.
It is mandatory to pass the exams of both modules by the end of the academic year. Later, the tests of both modules must be taken and passed again.
The final examination consists of a written exam during which the student must solve some exercises in the format of open-ended and/or multiple choice answer questions, plus comments to computer outputs with the aim of assessing the student's ability to solve simple problems in probability and statistics.
The duration of the written exam will be proportional to the number of exercises assigned, also taking into account the nature and complexity of the exercises themselves (however, the usual duration is two hours).
MODULE INFORMATICS:
The exam of the module of Informatics consists of a lab test, composed both by theoretical questions or exercises on the course programme, and in the development of a small project in Python.
The global exam is passed if both the tests of the first and second module are passed. Final marks are given using the numerical range 0-30 and is composed as the weighted mean (with credits) of the grades of the two modules. It will be available in the verbalization system of University of Milan and through the UNIMIA portal.
It is mandatory to pass the exams of both modules by the end of the academic year. Later, the tests of both modules must be taken and passed again.
INF/01 - INFORMATICS
MAT/06 - PROBABILITY AND STATISTICS
MAT/06 - PROBABILITY AND STATISTICS
Practicals: 32 hours
Lessons: 56 hours
Lessons: 56 hours
Educational website(s)
Professor(s)
Reception:
by appointment on Tuesday and Wednesday (email)
Via Celoria 10