Earthquake engineering is an independent scientific discipline that has come into being
along with engineering seismology over the past 100 years and is therefore still evolving,as happens in every new scientific field.
It started as a framework of codified rules for the seismic design of buildings at the begin-
ning of the twentieth century, after the catastrophic San Francisco earthquake of 1906.
This design procedure was based, on one hand,
on a framework of empirical rules for avoiding seismic damage observed in previous earthquakes, and on the other,
on the simulation of the seismic action on a set of lateral forces equal to a percentage of the gravity loads of the building.
This loading pattern constituted one additional load case, the ‘seismic loading’.
The above simulation was based on the fact that the acceleration of the masses of a building
due to earthquake causes inertial lateral forces proportional to the masses of the building,
and in this respect proportional to the gravity loads.
The considerations of earthquake engineering briefly presented above will be adapted and applied in the forthcoming chapters to buildings with a structural system made of reinforced concrete,
which constitute the major part of the building stock of the built environment in developed countries.
The material of this book has been formulated into three main parts:
In the first part, seismic demand issues are examined (Chapters 2 through 6).
More par-ticularly, this part includes at the outset a short overview of basic issues of structural dynamics,
which have been considered of special importance for the comprehension of the material of subsequent chapters.
It also includes the procedure for the determination of the seismic actions and the ductility coefficients.
The description of the acceptable methods for seismic analysis, and the application of the capacity design rules to the seismic effects (internal forces) are included in this part as well.
Finally, the conceptual design of building structural systems is also examined in detail, and guidelines are given for the proper structural system for various types of buildings.
[su_button url=”https://drive.google.com/open?id=1EQ3nh2zzmjwhwbwXp6iQbt5W6KkN-kvP” size=”7″ center=”yes”] Download Link[/su_button]
How Artificial intelligence (AI) can optimize bridges design? Introduction: Bridges are important pieces of infrastructure that connect communities and…
How AI can help in Highways and Railways design? Introduction: Artificial Intelligence (AI) has emerged as a transformative…
Enhancing Road Modeling Efficiency : Leveraging ChatGPT with Civil3D Introduction: Road modeling is a critical component of civil engineering and…
What are Stirrups and Why we Use Them? Steel reinforcement is an essential component of reinforced concrete, providing tensile…
Why Are Spiral Curves Important? Benefits And Elements Of Spiral Curve 1. Introduction: Spiral curves are an important…
The Main Types Of Tunnels Tunnels have been used for various purposes throughout history, from transportation and infrastructure to…
This website uses cookies.