IBC Provisions
- IBC Statement of Special Inspections
- High-Rise Building Design
- Glass 101: A Crash Course in Structural Glass and the Requirements of 2012 IBC Chapter 24
- Seismic Certification of Nonstructural Components
- MSJC 2013: Changes and How They Can Help You Today
- Transitioning to the 2015 IBC
- Significant Changes to AWC’s 2015 Special Design Provisions for Wind and Seismic (SDPWS)
- Changes in the California Amendments to the 2015 IBC
- Fire Resistance Design for Wood Construction – A Primer for Structural Engineers
- Seismic Design Using Structural Dynamics (2012 or 2015 IBC / ASCE 7-10)
- Gearing up for ACI 318-14 and the 2015 IBC
- Tornado and High Wind Sheltering with Masonry
- What’s New in the 2015 IBC Structural Provisions?
- Design Load Combinations of the 2012 IBC
- What's New in the 2012 IBC Structural Provisions?
- The Concrete Chapter of the 2012 IBC - Problem and Suggested Solution
- 2013 California Building Code Amendments
- 2012 I-Codes Structural Provisions for Existing Buildings: IBC Chapter 34 and IEBC
- IBC Special Inspection, Observation, and Testing
- A Practical Approach to Determine Design Wind Loads for Buildings
- Structural Irregularities
ASCE 7 Provisions
- Special Seismic Certification of Nonstructural Components to ASCE 7-16
- Multi-Story Special Steel Moment Resisting Frame Example
- High-Rise Building Design
- Seismic Certification of Nonstructural Components
- An Overview of the Major Changes in ASCE 7-16
- Seismic Design of Ordinary Structural Steel Systems
- Frequently Misunderstood Foundation Design Provisions
- Preview of Chapter 13 and 15 Changes from ASCE 7-10 to ASCE 7-16: Seismic Design Requirements for Nonstructural Components and Nonbuilding Structures
- Tsunami Design per ASCE 7-16
- Important Developments in the Seismic Design of Diaphragms
- Frequently Misunderstood Seismic Provisions of ASCE 7-10
- Seismic Design Using Structural Dynamics (2012 or 2015 IBC / ASCE 7-10)
- Adapting ASCE 7 Wind Design Provisions to the Design of Real-Life Buildings
- Seismic Response-History Analysis for the Design and Assessment of Buildings
- ASCE 7-10 Snow Load Provisions
- Simplified Wind Design by IBC/ASCE 7 with Examples
- ASCE 7-10 Wind Design Provisions
- ASCE 7-10 Seismic Design Provisions
- A Practical Approach to Determine Design Wind Loads for Buildings
- ASCE 7-10 Overview
- ASCE 7-10 Chapters 13 and 15: Seismic Design Requirements for Nonstructural Components and Nonbuilding Structures
- ASCE 7-10 General Provisions (including Snow)
- Structural Irregularities
Seismic Design
- Special Seismic Certification of Nonstructural Components to ASCE 7-16
- High-Rise Building Design
- Seismic Detailing of Special Shear Walls and Coupling Beams by ACI 318-11 and ACI 318-14
- Frame of Reference: Steel Moment Frames Explained
- Seismic and Wind Design Considerations for Wood Framed Structures
- Seismic Certification of Nonstructural Components
- Seismic Design of Ordinary Structural Steel Systems
- Preview of Chapter 13 and 15 Changes from ASCE 7-10 to ASCE 7-16: Seismic Design Requirements for Nonstructural Components and Nonbuilding Structures
- Tsunami Design per ASCE 7-16
- Significant Changes to AWC’s 2015 Special Design Provisions for Wind and Seismic (SDPWS)
- Important Developments in the Seismic Design of Diaphragms
- Frequently Misunderstood Seismic Provisions of ASCE 7-10
- Seismic Design Guidelines for Solid and Perforated Hybrid Precast Concrete Shear Walls
- Special and Intermediate Steel Moment Resisting Connections with Example
- Seismic Design Using Structural Dynamics (2012 or 2015 IBC / ASCE 7-10)
- Seismic Detailing of Intermediate and Special Moment Frames of Concrete by ACI 318-11 and ACI 318-14
- Wind and Seismic Design of Two-Way Concrete Slab Systems: Part 2
- Wind and Seismic Design of Two-Way Concrete Slab Systems: Part 1
- Seismic Design of Wood Mid-Rise Construction
- Multi-Story Special Steel Moment Resisting Frame Example
- Seismic Design of Solar Arrays on Flat Roofs
- Seismic Response-History Analysis for the Design and Assessment of Buildings
- HSS Design for AISC Seismic Provisions
- Seismic Design of Bridges
- Seismic Design of Wood Structures
- Seismic Design of Masonry using the 2011 MSJC Code
- Reinforced Concrete Shear Wall Design Examples: Seismic Design Categories B through F
- What's New in the 2012 IBC Structural Provisions?
- ASCE 7-10 Seismic Design Provisions
- ASCE 7-10 Chapters 13 and 15: Seismic Design Requirements for Nonstructural Components and Nonbuilding Structures
- Structural Irregularities
Wind Design
- Frequently Misunderstood Wind Provisions
- Wind Loads on Non-Building Structures
- High-Rise Building Design
- Seismic and Wind Design Considerations for Wood Framed Structures
- Significant Changes to AWC’s 2015 Special Design Provisions for Wind and Seismic (SDPWS)
- Tornado and High Wind Sheltering with Masonry
- Wind and Seismic Design of Two-Way Concrete Slab Systems: Part 1
- Adapting ASCE 7 Wind Design Provisions to the Design of Real-Life Buildings
- Wind Design for Solar Photovoltaic Arrays
- Designing for Building Drift: Controlling Damage from Wind Storms and Earthquakes
- What's New in the 2012 IBC Structural Provisions?
- 2009 IBC Simplified Wind Provisions
- Simplified Wind Design by IBC/ASCE 7 with Examples
- ASCE 7-10 Wind Design Provisions
- A Practical Approach to Determine Design Wind Loads for Buildings
Snow Design
Concrete Design
- Tilt-Up Wall Design Provisions: Proper Application
- Design of Post-Tensioned One-Way Slabs and Beams of Long Span Garages
- Engineered Tilt-Up Concrete Construction: Past, Present, and Future
- High-Rise Building Design
- Seismic Detailing of Special Shear Walls and Coupling Beams by ACI 318-11 and ACI 318-14
- Design of Connections and Components for Precast Concrete Parking Structures
- The Practicing Engineer's Guide to Designing Concrete by Strut and Tie Modeling by ACI 318
- Wind and Seismic Design of Precast Concrete Parking Structures
- Deep Foundations - Overview and Design Example
- Post-Tensioned Concrete Construction and Observation Issues
- Real-World Design Considerations for Punching Shear in Flat Plate Slabs
- Transitioning to ACI 318-14
- Composite Filled HSS Columns: Design and Practical Considerations
- HSS Connections: Splices, Bases, and Braces
- Detailing for Increased Breakout Capacity of Steel Anchor Rods in Concrete Podium Slabs
- Seismic Design Guidelines for Solid and Perforated Hybrid Precast Concrete Shear Walls
- Two-Way Post-Tensioned Slab Design
- Design and Construction of Post-Tensioned Slabs on Ground Using the PTI Method
- Gearing up for ACI 318-14 and the 2015 IBC
- Controlling Construction Cost with Efficient Structural Design
- Seismic Detailing of Intermediate and Special Moment Frames of Concrete by ACI 318-11 and ACI 318-14
- Post-Tensioned Concrete Design for Podium Structures
- Practical Design and Detailing Solutions for Concrete Masonry Foundation and Retaining Walls
- Wind and Seismic Design of Two-Way Concrete Slab Systems: Part 2
- Wind and Seismic Design of Two-Way Concrete Slab Systems: Part 1
- ACI 318-14 Chapter 17 - Anchoring to Concrete
- Two-Way Slab Systems of Reinforced Concrete: Design for Shear by ACI 318-11
- Two-Way Slab Systems of Reinforced Concrete: Design for Flexure by ACI 318-11
- Reinforced Concrete Shear Wall Design Examples: Seismic Design Categories B through F
- Parking Garage Design with Precast/Prestressed Concrete
- High-Strength Concrete and High-Strength Reinforcement:
A Successful Marriage for the Design and Construction of Multistory Buildings - Significant Changes from ACI 318-08 to ACI 318-11
- The Concrete Chapter of the 2012 IBC - Problem and Suggested Solution
- Changes to Anchorage Provisions in ACI 318-11
Steel Design
- Design of Steel Braced Frames with Example
- Multi-Story Special Steel Moment Resisting Frame Example
- High-Rise Building Design
- CFS Shear Wall Design Examples and Solutions
- Frame of Reference: Steel Moment Frames Explained
- Design of Cold-Formed Steel Exterior Wall Connections
- Effective Design of Buckling Restrained Braced Frames
- Seismic Design of Ordinary Structural Steel Systems
- HSS Connections: Splices, Bases, and Braces
- Lateral Design Per New CFS Standards AISI S240 and S400
- Special and Intermediate Steel Moment Resisting Connections with Example
- Multi-Story Special Steel Moment Resisting Frame Example
- Special Steel Concentrically Braced Frame Example
- Effective Use of Drift Joints in Exterior CFS Walls
- Design of Steel Deck Diaphragms
- Special and Intermediate Steel Moment Resisting Frames with Example
- Overlooked Provisions in AWS D1.1
- HSS Design for AISC Seismic Provisions
- Changes from AISC 360-05 to AISC 360-10
- Cold-Formed Steel Lateral Design Provisions
- It Just Ain't So: Welding Myths that Structural Engineers Need to Know About
- Changes in AISC's Seismic Provisions: AISC 341-05 to AISC 341-10
Masonry Design
- Masonry Shear Wall Design by ASD
- Tips for Optimizing Structural Masonry
- Out-of-Plane Design of Reinforced Masonry Bearing Walls
- MSJC 2013: Changes and How They Can Help You Today
- Tornado and High Wind Sheltering with Masonry
- Practical Design and Detailing Solutions for Concrete Masonry Foundation and Retaining Walls
- Masonry Design Example Comparisons Using ASD and SD
- Masonry Shear Wall Design by Strength Design
- Changes Between 2008 MSJC and 2011 MSJC
- Seismic Design of Masonry using the 2011 MSJC Code
- Strength Design of Reinforced Masonry
- Allowable Stress Design for Reinforced Masonry
- 2011 MSJC Design and Specification of Masonry Structure
Wood Design
- Multi-Family Wood Construction: Engineering Mid-Rise Buildings
- Engineered Wood Challenges and Opportunities
- Seismic and Wind Design Considerations for Wood Framed Structures
- Significant Changes to AWC’s 2015 Special Design Provisions for Wind and Seismic (SDPWS)
- Fire Resistance Design for Wood Construction – A Primer for Structural Engineers
- 2015 National Design Specification (NDS) for Wood Construction
- Advanced Wood Framing and Energy-Efficient Construction
- Frame for Success: How to Avoid Callbacks
- Seismic Design of Wood Mid-Rise Construction
- IRC Wall Bracing Tool for Structural Engineers
- Engineered Wood Beams: What the Structural Engineer Needs to Know
- Changes to the Design Provisions in the 2012 National Design Specification for Wood
- Seismic Design of Wood Structures
Existing Buildings
Solar Panels
Special Inspection
Flood Design
Other
- Mat Foundation Design
- High-Rise Building Design
- Blast Design Requirements for Building Systems
- Deep Foundations - Overview and Design Example
- Glass 101: A Crash Course in Structural Glass and the Requirements of 2012 IBC Chapter 24
- Design of Structural Glass - Explained by Examples
- Frequently Misunderstood Foundation Design Provisions
- Tsunami Design per ASCE 7-16
- Lateral Design Per New CFS Standards AISI S240 and S400
- Elevate Your Everyday Communications – By Engineers, For Engineers
- Challenges Facing the Expert Consultant/Witness
- What Can Structural Engineers Do to Address the Problem of Floor Vibrations?
- 2009 IBC Boot Camp