What are you looking for?
B1_That students have demonstrated knowledge and understanding in a field of study that is based on general secondary education, and is accustomed to finding at a level that, although with the support of advanced textbooks, also include some aspects that involve knowledge from the forefront of your field of study
B3_Students have the ability to gather and interpret relevant data (usually within their area of study), to make judgments that include reflection on relevant social, scientific or ethical issues
B4_That students can convey information, ideas, problems and solutions to both specialized and non-specialized audiences
EFB3_Ability to understand and master the basic concepts of discrete mathematics, logic, algorithms and computational complexity, and their application for solving engineering problems
T2_That students have the ability to work as members of an interdisciplinary team either as one more member, or performing management tasks in order to contribute to developing projects with pragmatism and a sense of responsibility, making commitments taking into account the available resources
Understanding and the ability to analyze random phenomena can be of great relevance in some branches of computer engineering, such as in the processing and analysis of biological information (bioinformatics). There are processes that, by their very nature, are random (such as the study of the time that can pass until a machine breaks down, or what size an animal will be, ...) which, paradoxically, does not involve that are not treatable and / or modelable phenomena.
1.-Descriptive statistics
1.1.-Concept of random variable (VA)
1.2.-Types of variables (quantitative, qualitative)
1.3.-Population and sample
1.4.-Statistics concept (centrality, dispersion)
1.5.-Concept of probability
1.6.-Probability density function
1.7.-Distribution function
2.-Probabilities
2.1.-Probabilities as sets (Venn diagrams)
2.2.-Intersection, union and conditional probabilities
2.3.-Theorem of total probabilities
2.4.-Bayes' theorem
3.-Distributions
3.1.-Bernouilli
3.2.-Binomial
3.3.-Poisson
3.4.-Exponential
3.5.-Normal
4.-Inference
4.1.-Contingency tables
4.2.-Types of errors
4.3.-Contrast of hypotheses (1 population)
4.4.-Contrast of hypotheses (2 populations)
4.5.-Analysis of variance (contrast of n populations)
5.-Regressions
5.1.-Simple linear regression
5.2.-Coefficients of the line
5.3.-Quality of adjustment (r square)
5.4.-Multiple linear regression
5.5.-Logistic regression
P = partial exam // F = final exam
70% grade => maximum(0.35 P+0.35 F, 0.7 F)
20% grade => group work
10% mark => individual questions in class
To pass the subject you must have a minimum grade of 4.5 in the exams (70% of the overall grade). If you do not reach this mark, you will have to go to the recovery exam.
The grade of the group work and the individual grade are not recoverable.
The maximum mark in the recovery exam will be 8.
The overall grade to pass the subject will be 5.
Course notes (available on the virtual campus)
Devore, Jay L. Probability and statistics for engineering and science. (9th edition). Ed. Cengage. 2016
Pena, Daniel Fundamentals of statistics. Editorial Alliance (2014).
Montgomery, Douglas C; Runger, George C. Applied statistics and probability for engineers (3rd edition). Ed. John Wiley and sons. 2003. (in English)