Data Science

Admission requirements

No formal requirements.

The course builds on concepts from the bachelor courses Statistics (Ba2) and Data Mining (Ba3). Students are expected to program in Python.

Description

Data Science places data mining, machine learning and statistics in context, both experimentally and socially. If you want to correctly deploy data mining techniques, you must be able to translate a (broadly formulated) question by a customer or a co-worker into an experimental set-up, to make the right choices for the methods you use, and to be able to process the data in the right form to apply those methods. After performing your experiments, you should not only be able to evaluate the results but also interpret and translate it back to the original question (e.g. by visualization). Socially, data science is of great importance because the media simplify many data-driven results and statistical research, often making mistakes. Thus, a lot of nonsense comes down on us and it is up to you, the data scientists of the future, to recognize, explain and correct that nonsense. This course is a combination of lectures and practical sessions, in which you take a hands-on approach to solving real-world data science problems.

Course objectives

A. Knowledge

• You can explain the following machine learning concepts: supervised learning, unsupervised learning, classification, regression

• You can list two advantages and two disadvantages of rule-based methods and of machine learning methods

• You know and can explain the following experimental and statistical principles in your own words: bias, overfitting, cross validation, high-dimensional data, sparseness, dimensionality reduction, feature extraction, class imbalance.

• You can describe typical use cases for Decision trees, kNN, SVM, Naïve Bayes and deep neural networks

• You can explain the purpose and principles of feature extraction from semi-structured data, text data, image data, graph data and sensor data.

• You can explain the difference between engineered features and raw features, in content and in dimensionality.

• You know and can explain different types of missing data and how to handle them.

• You know and can explain the use and importance of measuring the quality and reliability of human-labeled data.

• You can give the definitions of the most important evaluation measures: Accuracy, Mean Squared Error, Precision, Recall, F1 and Mean Average Precision.

• You know and can explain the benefits and challenges of big data.

• You know and can explain the principles of responsible data science.

• You know what explainable AI is and can name some methods that help in analysing ML models.

B. Skills

• You can recognize statistical nonsense in the media and erroneous visualizations, explain and correct it.

• After completing the course, you can independently take the steps to set up and execute an experiment within data science, given a (broadly formulated) question:

1. Task definition: You can create a clear definition of a task based on a general description of a task, consisting of (a) the research question, (b) whether the task is supervised or unsupervised, (c) whether it is a classification, regression or ranking task (or something else), (d) what the data are and (e) what the labels are;
2. Data collection: If answering the question requests data is not given, then you can define what data you need and how to collect it. If you need explicit labels, you can set up a data annotation task for human raters;
3. Data exploration: You can collect and visualize statistics about the data. You can calculate and interpret the inter-annotator agreement for annotated data.
4. Pre-processing and feature extraction: You can write a Python script to read and process the data, extract features and store the feature vectors. You know how to engineer a low-dimensional feature set
5. Model learning: You can apply unsupervised and supervised models to your data. You know how to make an informed decision on the type of classifier given the feature set. You can generate output for unseen data.
6. Evaluation: You can correctly set up your model evaluation with a train / test split and cross validation if necessary. You can evaluate your output against human data. You know which evaluation measures you should use given the type of data and model. You can perform significance testing. You can do a sensible error analysis and feature analysis.

Timetable

In MyTimetable, you can find all course and programme schedules, allowing you to create your personal timetable. Activities for which you have enrolled via MyStudyMap will automatically appear in your timetable.

Additionally, you can easily link MyTimetable to a calendar app on your phone, and schedule changes will be automatically updated in your calendar. You can also choose to receive email notifications about schedule changes. You can enable notifications in Settings after logging in.

Questions? Watch the video, read the instructions, or contact the ISSC helpdesk.

Note: Joint Degree students from Leiden/Delft need to combine information from both the Leiden and Delft MyTimetables to see a complete schedule. This video explains how to do it.

Mode of instruction

•• 14 lectures, 2x45 minutes

• 1st 45 minutes: lecture

• 2nd 45 minutes: practical session (working on data science problems in Python)

Assessment method

The assessment of the course consists of a multiple choice exam (60% of course grade) and a practical part (40% of course grade). The practical part is subdivided in three assignments. The weights for the assignments are 10%, 10% and 20% respectively for assignment 1 to 3 (of the total grade). The grade for the written exam should be 5.5 or higher in order to complete the course. The weighted average grade for the practical assignments should be 5.5 or higher in order to complete the course. If one of the tasks is not submitted the grade for that task is 0.

The teacher will inform the students how the inspection of and follow-up discussion of the exams will take place.

Reading list

You are expected to read 5 research papers during the course. The papers are announced during the lectures and will be published on Brightspace. The other materials are the course slides and the practical session instructions.

Registration

As a student, you are responsible for enrolling on time through MyStudyMap.

In this short video, you can see step-by-step how to enrol for courses in MyStudyMap.
Extensive information about the operation of MyStudyMap can be found here.

There are two enrolment periods per year:

• Enrolment for the fall opens in July

• Enrolment for the spring opens in December

See this page for more information about deadlines and enrolling for courses and exams.

Note:

• It is mandatory to enrol for all activities of a course that you are going to follow.

• Your enrolment is only complete when you submit your course planning in the ‘Ready for enrolment’ tab by clicking ‘Send’.

• Not being enrolled for an exam/resit means that you are not allowed to participate in the exam/resit.

Contact

Niki van Stein

Education coordinator LIACS bachelors

Remarks

Software
Starting from the 2024/2025 academic year, the Faculty of Science will use the software distribution platform Academic Software. Through this platform, you can access the software needed for specific courses in your studies. For some software, your laptop must meet certain system requirements, which will be specified with the software. It is important to install the software before the start of the course. More information about the laptop requirements can be found on the student website.