"Earthquake engineering is an interdisciplinary branch of engineering that designs and analyzes structures, such as buildings and bridges, with earthquakes in mind."
Study of the behavior of soil and rock during earthquakes and how to design structures to resist earthquake forces.
Seismic Hazard Analysis: This involves studying the potential for earthquakes in a given area based on historical records, geologic conditions, and seismological data.
Engineering Seismology: This is the study of how earthquakes affect the ground and structures, including how seismic waves are generated, propagated, and amplified.
Seismic Design Principles: This involves understanding how structures must be designed to withstand earthquakes, including concepts such as seismic isolation and energy dissipation.
Soil Structure Interaction: This involves studying how soil responds to seismic loads and how structures interact with the soil, including the effects of soil liquefaction.
Earthquake-Resistant Design Codes and Standards: This includes knowledge of international earthquake-resistant building codes and standards, such as the International Building Code (IBC), American Society of Civil Engineers (ASCE 7), and Eurocode 8.
Seismic Retrofitting and Rehabilitation Techniques: This involves methods and techniques for modifying existing structures to make them more earthquake-resistant.
Geotechnical Earthquake Engineering: This field involves the study of how soil and rock behave during earthquakes and how structures can be designed and constructed to protect against soil-related hazards.
Ground Motion Analysis: This involves predicting how the ground will behave during an earthquake, including the duration, frequency, and amplitude of seismic waves.
Dynamic Analysis of Structures: This includes methods for analyzing how structures behave under dynamic loads, such as earthquake ground motions.
Hazard Mitigation Strategies: This involves developing strategies for reducing the consequences and potential damage from earthquakes, including land-use planning, emergency response plans, and public awareness campaigns.
Seismic Hazard Analysis: Seismic hazard analysis is the study of the potential for future seismic events to occur in a specific area.
Seismic Design: Seismic design is the process of designing structures that can withstand the ground motion caused by an earthquake.
Site Classification: Site classification refers to the process of determining the soil type and properties of a site, which can affect the behavior of structures during an earthquake.
Seismic Retrofitting: Seismic retrofitting is the process of modifying structures that were not originally designed to withstand seismic forces, to improve their resistance to earthquakes.
Soil Dynamics: Soil dynamics involves the study of how soils respond to seismic forces and the effects of soil properties on the behavior of structures during an earthquake.
Earthquake Risk Assessment: Earthquake risk assessment involves the analysis of the potential consequences of an earthquake, including damage to infrastructure, economic losses, and loss of life.
Ground Motion Analysis: Ground motion analysis involves the study of seismic waves and their effects on structures, including the evaluation of structural response.
Seismic Performance Evaluation: Seismic performance evaluation refers to the process of assessing the behavior of structures during an earthquake, including damage, collapse, and safety.
Structural Dynamics: Structural dynamics involves the study of how structures respond to seismic forces, including the effects of damping, resonance, and structural properties on structural behavior during an earthquake.
Earthquake Code Development: Earthquake code development involves the development of building codes and standards that aim to ensure the safety of structures during earthquakes.
"Its overall goal is to make such structures more resistant to earthquakes."
"An earthquake engineer aims to construct structures that will not be damaged in minor shaking and will avoid serious damage or collapse in a major earthquake."
"A properly engineered structure does not necessarily have to be extremely strong or expensive."
"It has to be properly designed to withstand the seismic effects while sustaining an acceptable level of damage."
"Earthquake engineering designs and analyzes structures, such as buildings and bridges."
"Earthquake engineering is an interdisciplinary branch of engineering."
"Earthquake engineering designs and analyzes structures... with earthquakes in mind."
"Its overall goal is to make such structures more resistant to earthquakes."
"An earthquake engineer aims to construct structures that will not be damaged in minor shaking..."
"...and will avoid serious damage or collapse in a major earthquake."
"It has to be properly designed to withstand the seismic effects while sustaining an acceptable level of damage."
"Earthquake engineering designs and analyzes structures, such as buildings and bridges."
"...more resistant to earthquakes. An earthquake engineer aims to construct structures..."
"It has to be properly designed to withstand the seismic effects..."
"...and analyzes structures, such as buildings and bridges."
"An earthquake engineer aims to construct structures that will not be damaged in minor shaking..."
"A properly engineered structure does not necessarily have to be extremely strong or expensive."
"Its overall goal is to make such structures more resistant to earthquakes."
"It has to be properly designed to withstand the seismic effects while sustaining an acceptable level of damage."