The course "Fluid Flow, Heat and Mass Transfer," course number ta3220, is third-year BSc course in the program of Applied Earth Sciences at Delft University of Technology. Students in this class have already taken a course in "Transport Phenomena" in the second year, and "Fluid Flow Heat and Mass Transfer" is designed as a follow-up to that class, with an emphasis on topics of importance in applied earth sciences, and in particular to Petroleum Engineering, groundwater flow and mining.
In practice, however I start over again with first principles with this class, because the initial concepts of the shell balance are difficult for students to grasp and can always use a second time through. The course covers simple fluid mechanics problems (rectilinear flow) using shell balances, for Newtonian and power-law fluids and Bingham plastics. Turbulence for Newtonian fluids is covered in the context of friction factors for flow in pipes, flow around spheres and flow in packed beds.

What do collapsed buildings, infected hospital patients, and crashed airplanes have in common? If you know the causes of these events and conditions, they can all be prevented.

In this course, you will learn how to use the TU Delft mind-set to investigate the causes of such events so you can prevent them in the future.

When, for instance, hundreds of hospital patients worldwide got infected after having gall bladder treatments, forensic engineering helped reveal how the design and use of the medical instruments could cause such widespread infections. As a result, changes were made to the instrument design and the procedural protocols in hospitals. Learning from failure in this case benefitted patient health and safety across the world.

After taking this course you will have an understanding of failures and the investigation processes used to find their causes. You will learn how to apply lessons gained from investigating previous failures into new designs and procedures.

In this second edition, which is the result of numerous revisions, updates, and additions, the authors cover the basic concepts of fracture mechanics for both the linear elastic and elastic-plastic regimes. The fracture mechanics parameters K, G, J and CTOD are treated in a basic manner along with the test methods to determine critical values. The development of failure assessment based on elastic-plastic fracture mechanics is reflected in a comprehensive treatment.

Three chapters are devoted to the fracture mechanics characterisation of crack growth. Fatigue crack growth is extensively treated, and attention is paid to the important topic of the initiation and growth of short fatigue cracks. Furthermore, sustained load fracture and dynamic crack growth are discussed, including various test techniques, e.g., the determination of the crack arrest toughness.

Finally, there are two chapters dealing with mechanisms of fracture and the ways in which actual material behaviour influences the fracture mechanics characterisation of crack growth.

This textbook is intended primarily for engineering students. It will be useful to practising engineers as well, since it provides the background to several test and design methods and to criteria for material selection.

Is a good, solid argument enough to make an impact? How would your data improve the stance that man-made global warming is just an “opinion”? How would you explain your opinion on school tests, budget cuts, crime, immigration, safety and security issues? No doubt that your persuasiveness relies on your arguments. But your ability to influence and convince critically depends on the way you frame your message.

In today’s world, you often need to reduce a complex reality to a concise and convincing message. Framing is an approach that deals with the way we convey our message: our words, images, and metaphors. To take one basic characteristic, a good frame engages the listeners’ values and emotions – it is easy to remember and it is something that people will usually agree with intuitively.

When you enter into a debate, you might be faced with frames of your opponents – and you will have to reframe the debate. This game of framing and reframing makes the debate to look like a chessboard made out of words. Of course, politicians play this game, trying to pull the debate towards their own words and metaphors in order to win their audience. But the game can be found everywhere: in the world of business, science, media – even at home.

We invite you to join our journey of learning the game of framing and reframing. You will discover how this game is played, and how you can play it yourself.

This course suits people who are engaged with and interested in public and political debates. Not only people from the public sector will find it useful, but also engineers, consultants, managers and anyone who wants to make an impact in discussions and debates.

This book serves as a comprehensive roadmap for navigating the realm of Operations Research (OR). From laying down fundamental mathematical principles to crafting precise modeling techniques and their solution methods, it culminates in a panoramic view of OR models mirroring real-world operations. Delving into diverse applications-from assignment problems to network problems like graph coloring and minimum spanning trees, and navigating through routing problems that are very common in logistics-the book equips readers with practical insights. Each model is accompanied by meticulously detailed examples, seamlessly integrated with hyperlinked codes accessible via an open repository. Moreover, it introduces an engaging dimension with hyperlinks to three serious games replicating some cornerstone OR models, offering a playful yet educational environment for solo or group experimentation.

Quantum information is the foundation of the second quantum revolution. With classical computers and the classical internet, we are always manipulating classical information, made of bits. On the other hand, quantum computing and quantum communication consist in the processing of quantum information, made of qubits.

Take away the hardware, and all quantum computers work the same way, through the clever manipulation of quantum information and entanglement. This course provides a deeper understanding of some of the topics covered in our Quantum 101 program, namely, the representation and manipulation of quantum information at the level of abstract quantum circuits. Specifically, single and multi-qubit gates and circuits are introduced, and basic algorithms and protocols such as quantum state teleportation, superdense coding, and entanglement swapping are discussed. The course also presents quantum gate sets, their universality, and compilations between different gate expressions. These concepts are then made concrete with the Quantum Inspire simulator (a cloud-based quantum computing platform, created and maintained by QuTech at TU Delft), and the physics and operations with spin qubits will be detailed. The course concludes with an examination of quantum supremacy and near-term quantum devices, also known as "noisy-intermediate scale" (NISQ) quantum computing.

The course is a journey of discovery, so we encourage you to bring your own experiences, insights and thoughts to discuss on the forum!

This course is authored by experts from the QuTech research center at Delft University of Technology. In the center, scientists and engineers work together to drive research and development in quantum technology. QuTech Academy's aim is to inspire, share and disseminate knowledge about the latest developments in quantum technology.

De transport- en overdrachtsprocessen van warmte, massa en impuls worden naar hun analogie behandeld. De processen worden beschreven met behulp van macro- en microbalansen die in veel gevallen leiden tot differentiaalvergelijkingen. Ook veel aspecten van stromingsleer komen op deze manier aan de orde en zo bereidt het boek ook voor op moderne Computational Fluid Dynamics technieken. Het doel van het boek is ook studenten te trainen in het oplossen van problemen waarbij transportverschijnselen centraal staan. Daartoe bevat het boek bijna 100 uitgewerkte vraagstukken.

Geo-information has proven to be extremely helpful in many aspects of risk and disaster management: locational and situational awareness, monitoring of hazards, damage detection, sharing of information, defining vulnerability areas, etc. This course aims to provide knowledge on risk and disaster management activities, demonstrate use of geo-information technologies in emergency response, outline current challenges and motivate young geo-specialist to seek for advanced solutions. The course is organised as lectures and practicals. The practicals will be in the form of group assignments. Some excursions and guest lectures will be organised as well.

The course contents is general knowledge of the system Earth, tools for the 3D geometric representation of geological objects and methods and techniques for the recognition of fundamental minerals and rocks. The Geology 1 course is composed of three parts dedicated to 1) general knowledge of the system Earth, 2) tools for the 3D geometric representation of geological objects and 3) methods and techniques for the recognition of fundamental minerals and rocks.

Are you fascinated by Geosciences and willing to take the challenge of predicting the nature and behavior of the Earth subsurface? This is your course!

In a voyage through the Earth, Geoscience: the Earth and its Resources will explore the Earth interior and the processes forming mountains and sedimentary basins. You will understand how the sediments are formed, transported, deposited and deformed.

You will develop knowledge on the behavior of petroleum and water resources.

The course has an innovative approach focusing on key fundamental processes, exploring their nature and quantitative interactions. It will be shown how this acquired knowledge is used to predict the nature and behavior of the Earth subsurface.

This is your ideal first step as a future Geoscientists or professional to upgrade your knowledge in the domain of Earth Sciences.

Building adequate housing is a pressing issue worldwide. With close to a billion people currently living in slums, accommodating a growing population, and improving dwelling conditions is a critical issue for society.

This challenge cannot be solved with a one-size-fits-all approach. Every city, region and country demand their own housing models and prototypes. That’s why housing design needs to negotiate many aspects simultaneously to achieve sustainable urban environments and inclusive dwelling communities.

This course uncovers how social, economic and environmental factors are interrelated in the design of housing settlements. For this, the course dives into three key aspects that anyone involved in housing design should take into consideration: time, environment, and community. Each of these aspects will be examined through a specific design approach, respectively:

Incrementality: how dwelling environments should be able to accommodate growth and change through time.
Typology Mix: how design can be responsive to different patterns of inhabitation, aspirations and cultural backgrounds, creating inclusive dwelling environments.
Clustering: what methods and strategies can shape the association of dwelling units in order to create meaningful communities.

Software engineering operates ever more frequently in globally distributed settings, in a practice that is known as Globally Distributed Software Engineering (GDSE). In this course, you will obtain a practical overview of the organization and operation of software engineering of this practice. As such, it is aimed at professionals in distributed software development teams, and executives setting up and leading such teams who would like to develop the required technical and organizational skills.

The course covers the subject in an accessible and practical manner. Through video lectures, group assignments and exercises, you will be familiarized with the advantages and disadvantages of GDSE, the practical consequences of GDSE and its technological feasibilities and infeasibilities. You will learn about real-world experiences of users and examples of GDSE applications such as outsourcing, offshore software development, near-shoring and multi-partner systems development.

You will apply the knowledge gained through hands-on experience with GDSE by working together with team members from different countries as a distributed team; and through analysis of best-practice examples. Together with other course participants you will prepare a number of artefacts that build on the body of knowledge of GDSE and so have the chance to contribute to this growing field of knowledge.

Guest lectures from industry experts and researchers will be an integral part of the course. These lectures will demonstrate how GDSE is handled in industry, how decision-makers lead their teams in this context, and what is the state-of-the-art in GDSE research

Are you interested in taking your first steps in robotics? Do you seek a practical approach and want to learn by doing? Join our course and learn how to program a complete real-world robotic system with ROS!

The Robot Operating System (ROS) enables you to quickly build robotic applications through access to a large set of open-source software and tools. Over the years, ROS has become the essential tool for roboticists. A large community surrounds ROS and there has been extensive input from industrial users in the development of these tools.

Many of the new advanced robot capabilities for manipulation, perception, and navigation have been developed using ROS. Companies such as Airbus and Boeing are using ROS for several of their applications. And Delft University of Technology’s Team Delft Robotic System won two challenges at the Amazon Robotics Challenge 2016 with robots developed with ROS.

In this course, you will learn to use different ROS tools to create a complete robotic application. You will be working with your own standalone Ubuntu-Linux installations and with industrial and mobile robots on the physics-based simulation engine, Gazebo. You will learn to program and configure basic robotic tasks such as pick-and-place objects, and navigate through obstacles. You will then integrate all this knowledge to build an industrial production line with two robotic arms and a mobile robot.

Do you want to start or grow your own business, go international, or avoid bankruptcy?

In this business and management course, you will learn the key steps to take to design or innovate your own business model. You will learn about the trade-offs to be made, and the design issues that are critical for a viable and sustainable business model.

This course will help you answer questions like, how do I create a simple business model in a structured way, how do I engage my users and how do I create value for my customers as well as revenue for my company.

"The Human Controller" presents and discusses design and evaluation issues of human-machine interaction. The focus is on understanding human perception-action couplings (limitations, preferences, adaptation) and on quantifying control behavior of humans in the direct manual control loop of vehicles, robots or other man-made tools. Case studies from automotive, aviation, medical and tele-operation applications are discussed, with a special focus on the importance of including and enhancing haptics (=the sense of touch) during manual control.

Relation of purpose of data to data requirements. Relation of data to costs.
Accuracy requirements of measurements and error propagation:
Related to a problem the required accuracy of measurements and the consequences for accuracy in the final result are discussed. Different types of errors are handled. Propagation of errors; for dependent and independent measurements, from mathematical relations and regression is demonstrated. Recapitulated is the theory of regression and correlation.
Interpretation of measurements, data completion: By standard statistical methods screening of measured data is performed; double mass analysis, residual mass, simple rainfall-runoff modelling. Detection of trends; split record tests, Spearman rank tests. Methods to fill data gaps and do filtering on data series for noise reduction.
Methods of hydrological measurements and measuring equipment: To determine quantitatively the most important elements in the hydrological cycle an overview is presented of most common hydrological measurements, measuring equipment and indirect determination methods i.e. for precipitation, evaporation, transpiration, river discharge and groundwater tables. Use, purpose and measurement techniques for tracers in hydrology is discussed.
Advantages and disadvantages and specific condition/application of methods are discussed. Equipment is demonstrated and discussed.
Areal distributed observation: Areal interpolation techniques of point observations: inverse distance, Thiessen, contouring, Kriging. Comparison of interpolation techniques and estimation of errors. Correlation analysis of areal distributed observation of rainfall
Design of measuring networks: Based on correlation characteristics from point measurements (e.g. rainfall stations) and accuracy requirements the design of a network of stations is demonstrated.

-De hydrologie van Nederland in historisch perspectief en de rol van de mens daarin (de vroege geschiedenis; waterbeheersing van af het begin van de 17e eeuw; grote werken);-Hydrologie van Nederland (geologie; neerslag en verdamping; oppervlaktewater; gro

The course deals with the principles of hydrology of catchment areas, rivers and deltas. The students will learn:

1). to understand the relations between hydrological processes in catchment areas
2?. to understand and to calculate the propagation of flood waves
3). to understand hydrological processes in deltas
4). to draft frequency analysis of extremes under different climatological conditions.

In dit college wordt een introductie gegeven van een groot aantal facetten van de scheepshydromechanica en hun onderlinge samenhang zoals die later in de studie meer als geisoleerde onderwerpen aan bod komen. Behandeld worden: de hydrostatica, de geometrie beschrijving van het schip, inleiding lijnenplan, het begrip stabiliteit, de stabiliteit van drijvende lichamen, eenvoudige stabiliteit berekening bij kleine helling hoeken, de weerstand van lichamen onder water en aan het oppervlak, eenvoudige weerstand benaderings methoden voor schepen, de model wetten in de hydromechanica, de extrapolatie methode van Froude, de lift van een vleugel, de vleugel karakteristieken, de toepassing hiervan bij voortstuwing en bij scheepsschroeven, de schroef karakteristieken en een eenvoudige schroef berekening, en tenslotte de fysica van het zeilen en zeilvoortstuwing. Leerdoelen De student kan: 1. de basis van systeem analyse beschrijven (buitenwereld, interfaces, beperkingen, objecten, relaties enz.) 2. maritieme systemen zoals schip/motor/schroef beschrijven en modelleren met behulp van beperkte systeem analyse methodologie; eenvoudige maritieme systemen modelleren door onderverdeling in subsystemen en componenten 3. evenwicht condities van maritieme systemen bepalen en kwalitatief analyseren 4. de definities en belangrijkste karakteristieken van weerstand, voortstuwing en manoeuvreren (snelheid, weerstand, vermogen, RPM, draaicapaciteit) begrijpen en toepassen 5. de relaties tussen algemeen vloeistof dynamica en scheepshydromechanica (bijv. lift/aerodynamica/zeilen; visceuze stroming/Reynolds getal/volgstroomvelden/voortstuwingsrendement; laminair & visceuze stroming/weerstand; niet visceuze stroming/golf patronen/weerstand) beschrijven 6. de achtergrond van de belangrijkste schaal regels (Newton, Froude, Reynolds) d.m.v dimensie analyse uitleggen 7. schaalregels voor schaalmodel experimenten in een sleeptank toepassen en potentiĚÇle complicaties identificeren

Fenomenologische beschrijving van de stroming om een schip classificatie van weerstandscomponenten en parametrische methoden voor de berekening van de scheepsweerstand. Daarnaast wordt uitgelegd hoe de scheepsweerstand experimenteel bepaald kan worden.

Voor scheepsschroeven wordt aangegeven hoe de complete geometrie beschreven kan worden, hoe de stuwkracht en koppel uit een parametrische beschrijving kan worden berekend m.b.v. een systematische schroevenserie en via een ideaal stromings model (actuator schijf). Een introductie in cavitatie (vorming van waterdamp gebieden) is onderdeel van de cursus.