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Course: FEMA 7119, Fall 2009School: U. Memphis
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1.0 Chapter - General Provisions 1.0 1.1 General Provisions Scope Handbook Basis This Handbook is based on the NEHRP Handbook for Seismic Evaluation of Existing Buildings (FEMA 178). This Handbook was written to: reflect advancements in technology, incorporate design professional experience, incorporate lessons learned during recent earthquakes, be nationally applicable, and provide evaluation techniques for...
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1.0 Chapter - General Provisions
1.0
1.1
General Provisions
Scope
Handbook Basis This Handbook is based on the NEHRP Handbook for Seismic Evaluation of Existing Buildings (FEMA 178). This Handbook was written to: reflect advancements in technology, incorporate design professional experience, incorporate lessons learned during recent earthquakes, be nationally applicable, and provide evaluation techniques for varying levels of building performance. Since the development and publication of FEMA 178, numerous significant earthquakes have occurred: the 1985 Michoacan Earthquakes that affected the Mexico City area, the 1989 Loma Prieta Earthquake in the San Francisco Bay Area, the 1994 Northridge Earthquake in the Los Angeles area, and the 1995 Hyokogen-Nanbu Earthquake in the Kobe area. While each earthquake validated the fundamental assumptions underlying the procedures presented in FEMA 178, each also offered new insights into the potential weaknesses in certain systems that should be mitigated. (It should be noted that while the publication of FEMA 178 occurred after the Mexico City and Loma Prieta Earthquakes, data and lessons learned from them were unable to be incorporated into the document prior to publication.) Extent of Application Model building codes typically exempt certain classes of buildings from seismic requirements pertaining to new construction. This is most often done because the building is unoccupied or it is of a style of construction that is naturally earthquake resistant. It is reasonable to expect that these classes of buildings may be exempt from the requirements of this Handbook as well. No buildings are automatically exempt from the evaluation provisions of this Handbook; exemptions
This Handbook provides a three-tiered process for seismic evaluation of existing buildings in any region of seismicity. Buildings are evaluated to either the Life Safety or Immediate Occupancy Performance Level. Use of this Handbook and mitigation of deficiencies identified using this Handbook are voluntary or as required by the authority having jurisdiction. The design of mitigation measures is not addressed in this Handbook. This Handbook does not preclude a building from being evaluated by other well-established procedures based on rational methods of analysis in accordance with principles of mechanics and approved by the authority having jurisdiction. Commentary: This Handbook provides a process for seismic evaluation of existing buildings. A major portion is dedicated to instructing the evaluating design professional on how to determine if a building is adequately designed and constructed to resist seismic forces. All aspects of building performance are considered and defined in terms of structural, nonstructural and foundation/geologic hazard issues. Prior to using this Handbook, a rapid visual screening of the building may be performed to determine if an evaluation is needed using the following document: Rapid Visual Screening of Buildings for Potential Seismic Hazards: A Handbook (FEMA 154 and 155). Mitigation strategies for rehabilitating buildings found to be deficient are not included in this Handbook; additional resources should be consulted for information regarding mitigation strategies.
FEMA 310
Seismic Evaluation Handbook
1-1
Chapter 1.0 - General Provisions
exemptions should be defined by public policy. However, based on the exemption contained in the codes for new buildings, jurisdictions may exempt the following classes of construction: Detached one- and two-family dwellings located where the design short-period spectral response acceleration parameter, SDS , is less than 0.4g. Detached one- and two-family wood frame dwellings located where the design short-period response acceleration parameter, SDS , is equal to or greater than 0.4g that satisfy the light-frame construction requirements of the 1997 NEHRP Recommended Provisions for Seismic Regulations for New Buildings; and Agricultural storage structures that are intended only for incidental human occupancy. Application to Historic Buildings Although the principles for evaluating historic structures are similar to those for other buildings, special conditions and considerations may exist of which the design professional should be aware. Historic structures often include archaic materials, systems, and details. It may be necessary to look at handbooks and building codes from the year of construction to determine details and material properties. Another unique aspect of historic building evaluation is the need to consider architectural elements or finishes. Testing that damages the historic character of the building generally is not acceptable. In addition, an appropriate level of performance for historic structures needs to be chosen that is acceptable to the local jurisdiction. Some feel that historic buildings should meet the safety levels of other buildings since they are a subset of the general seismic safety needs. Others feel that historic structures, because of their value to society, should meet a higher level of performance. And in some cases a reduced level of performance has
some cases a reduced level of performance has been allowed to avoid damaging historic fabric. The following resources may be useful when evaluating historic structures: Secretary of the Interior's Standards for the Treatment of Historic Properties, and National Park Service Catalog of Historical Preservation Publications. Alternative Methods Alternative documents that may be used to evaluate existing buildings include: Uniform Code for Building Conservation (UCBC, 1997), Los Angeles Division 91, Los Angeles Division 95, and Seismic Evaluation and Retrofit of Concrete Buildings. Some users have based the seismic evaluation of buildings on the provisions of new buildings. While this may seem appropriate, it must be done with full knowledge of the inherent assumptions. Codes for new buildings contain three basic types of requirements including strength, stiffness, and detailing. The strength and stiffness requirements are easily transferred to existing buildings; the detailing provisions are not. If the lateral-force-resisting elements of an existing building do not have the proper details of construction, the basic expectations of the other strength and stiffness provisions will not be met. Lateral-force-resisting elements that are not properly detailed should be omitted during an evaluation using a code for new buildings. ATC-14 offered the first technique for adjusting the evaluation for the lack of proper detailing by using a three-level acceptance criteria, FEMA 178 used reduced R-factors to accomplish the same thing. FEMA 273 contains the most comprehensive procedure with its element-based approach. This Handbook follows the lead of FEMA 273 with a new style of analysis procedure tailored to the Tier 1 and Tier 2 evaluation levels.
1.2
1-2 Seismic Evaluation Handbook
Basic
FEMA 310
Chapter 1.0 - General Provisions
Mitigation Strategies Potential seismic deficiencies in existing buildings may be identified using this Handbook. If the evaluation is voluntary, the owner may choose to accept the risk of damage from future earthquakes rather than upgrade, or demolish the building. If the evaluation is required by a local ordinance for a hazard-reduction program, the owner may have to choose between rehabilitation, demolition, or other options. The following documents may be useful in determining appropriate rehabilitation or mitigation strategies: NEHRP Handbook of Techniques for the Seismic Rehabilitation of Existing Buildings (FEMA 172), NEHRP Benefit-Cost Model for the Seismic Rehabilitation of Buildings (FEMA 227 and 228), NEHRP Typical Costs for Seismic Rehabilitation of Existing Buildings (FEMA 156 and 157), and NEHRP Guidelines and Commentary for the Seismic Rehabilitation of Buildings (FEMA 273 and 274).
For those buildings identified in Section 3.4, a Full-Building Tier 2 Evaluation or a Tier 3 Evaluation shall be performed upon completion of the Tier 1 Evaluation. For those buildings not identified in Section 3.4 as requiring a Full Building Tier 2 Evaluation or a Tier 3 Evaluation, but for which potential deficiencies were identified in Tier 1, a Deficiency-Only Tier 2 Evaluation may be performed. For a Deficiency-Only Tier 2 Evaluation, only the procedures associated with non-compliant checklist statements need be completed. Potential deficiencies shall be summarized upon completion of the Tier 2 Evaluation. Alternatively, the design professional may choose to end the investigation and report the deficiencies in accordance with Chapter 1. A Tier 3 evaluation shall be performed in accordance with the requirements of Chapter 5 for buildings identified in Section 3.4 or when the design professional chooses to further evaluate buildings for which potential deficiencies were identified in Tier 1 or Tier 2. Potential deficiencies shall be summarized upon completion of the Tier 3 Evaluation. After a seismic evaluation has been performed, a final report shall be prepared. As a minimum, the report shall identify: the building and its character, the tier(s) of evaluation used, and the findings. The three-tiered process for seismic evaluation of buildings is depicted in Figure 1-1.
Requirements
Prior to conducting the seismic evaluation, the evaluation requirements of Chapter 2 shall be met. A Tier 1 evaluation shall be conducted for all buildings in accordance with the requirements of Chapter 3. Checklists, as applicable, of compliant/non-compliant statements related to structural, nonstructural and foundation conditions, shall be selected and completed in accordance with the requirements of Section 3.3 for a Tier 1 Evaluation. Potential deficiencies shall be summarized upon completion of the Tier 1 evaluation. Structural Tier 1 checklists are not provided for unreinforced masonry bearing wall buildings with flexible diaphragms. The structural evaluation of unreinforced masonry bearing wall buildings with flexible diaphragms shall be completed using the Tier 2 Special Procedure of Section 4.2.6; a Tier 1 Evaluation for foundations and non-structural elements remains applicable for this type of building.
FEMA 310
Commentary: Prior to conducting the seismic evaluation based on this Handbook, the design professional should understand the evaluation process and the basic requirements specified in this section. The evaluation process consists of the following three tiers, which are shown in Figure 1-1: Screening Phase (Tier 1), Evaluation Phase (Tier 2), and Detailed Evaluation Phase (Tier 3). As indicated in Figure 1-1, the design professional may choose to (i) report deficiencies and screening
Seismic Evaluation Handbook
1-3
Chapter 1.0 - General Provisions
recommend mitigation or (ii) conduct further evaluation, after any tier of the evaluation process. The screening phase, Tier 1, consists of 3 sets of checklists that allow a rapid evaluation of the structural, nonstructural and foundation/geologic hazard elements of the building and site conditions. It shall be completed for all building evaluations conducted in accordance with this Handbook. The purpose of a Tier 1 evaluation is to screen out buildings that comply with the provisions of this Handbook or quickly identify potential deficiencies. In some cases "Quick Checks" may be required during a Tier 1 evaluation, however, the level of analysis necessary is minimal. If deficiencies are identified for a building using the checklists, the design professional may proceed to Tier 2 and conduct a more detailed evaluation of the building or conclude the evaluation and state that potential deficiencies were identified. In some cases a Tier 2 or Tier 3 evaluation may be required. Based on the ABK research (ABK, 1984), unreinforced masonry buildings with flexible diaphragms were shown to behave in a unique manner. Special analysis procedures provided in Section 4.2.6 were developed to predict the behavior. Since this special procedure does not lend itself to the checklist format of Tier 1, no Structural Checklists are provided. The design professional must perform the Tier 2 Special Procedure as the first step of the evaluation. The Special Procedure only applies to the structural aspects of the building; Tier 1 Checklists provided for the nonstructural elements and for the foundation and geologic hazards issues still apply. For Tier 2, a complete analysis of the building that addresses all of the deficiencies identified in Tier 1 shall be performed. Analysis in Tier 2 is limited to simplified linear analysis methods. As in Tier 1, evaluation in Tier 2 is intended to identify buildings not requiring rehabilitation. If deficiencies are identified during a Tier 2 evaluation, the design professional may choose to either conclude the evaluation and report the deficiencies or proceed to Tier 3 and conduct a detailed seismic evaluation.
Available methods and references for conducting a Tier 3 detailed evaluation are described in Chapter 5 of this Handbook. Recent research has shown that certain types of complex structures can be shown to be adequate using nonlinear analysis procedures even though other common procedures do not. While these procedures are complex and expensive to carry out, they often result in construction savings equal to many times their cost. The use of Tier 3 procedures must be limited to appropriate cases. The final report serves to communicate the results to the owner and record the process and assumptions used to complete the evaluation. Each section should be carefully written in a manner that is understandable to its intended audience. The extent of the final report may range from a letter to a detailed document. The final report should include at least the following items: 1) Scope and Intent: a list of the tier(s) followed and level of investigation conducted; Site and Building Data: General building description (number of stories and dimensions), Structural system description (framing, lateral load resisting system, floor and roof diaphragm construction, basement, and foundation system), Nonstructural element description (nonstructural elements that could interact with the structure and affect seismic performance) Building type, Performance Level, Region of Seismicity, Soil Type, Building Occupancy, and Historic Significance; List of Assumptions: material properties, site soil conditions; Findings: list of deficiencies; Recommendations: mitigation schemes or further evaluation; Appendix: references, preliminary calculations.
2)
3) 4) 5) 6)
1-4
Seismic Evaluation Handbook
FEMA 310
Chapter 1.0 - General Provisions
Understand the Evaluation Process
General Provisions
Ch. 1
1) Collect Data and Visit Site 2) Determine Region of Seismicity 3) Determine Level of Performance
Evaluation Requirements
Ch. 2
Benchmark Building? OR 1) Complete the Structural Checklist(s). 2) Complete the Foundation Checklist. 3) Complete the Nonstructural Checklist(s).
QUICK CHECKS
Tier 1: Screening Phase
Ch. 3
no
Deficiencies?
yes
Further Eval?
no
yes
FULL BUILDING or DEFICIENCY-ONLY EVALUATION
EVALUATE Building using one of the following procedures: 1) Linear Static Procedure 2) Linear Dynamic Procedure 3) Special Procedure
ANALYSIS
Tier 2: Evaluation Phase
Ch. 4
no
Deficiencies?
yes
Further Eval?
no
yes
Comprehensive Investigation (Nonlinear Analysis)
Tier 3: Detailed Evaluation Phase
Building Complies
Ch. 5
no
Deficiencies?
yes
Building does NOT Comply
Final Evaluation and Report
Ch. 1
Mitigate
Figure 1-1. Evaluation Process
FEMA 310
Seismic Evaluation Handbook
1-5
Chapter 1.0 - General Provisions
Judgment by the Design Professional While this Handbook provides very prescriptive direction for the evaluation of existing buildings, it is not to be taken as the only direction. This Handbook provides direction for common details, deficiencies and behavior observed in past earthquakes that are found in common building types. However, every structure is unique and may contain features and details not covered by this Handbook. It is important that the design professional use judgment when applying the provisions of this Handbook. The design professional should always be looking for uncommon details and behavior about the structure not covered by this Handbook that may have the potential for damage or collapse.
CAPACITY: The permissible strength or deformation for a component action. COLLECTOR: A member that transfers lateral forces from the diaphragm of the structure to vertical elements of the lateral-force resisting system. CROSS WALL: A wood-framed wall sheathed with lumber, structural panels, or gypsum wallboard. DEFICIENCY-ONLY TIER 2 EVALUATION: An evaluation, beyond the Tier 1 Evaluation, that investigates only the non-compliant checklist evaluation statements. DESIGN EARTHQUAKE: See Maximum Considered Earthquake. DIAPHRAGM: A horizontal structural system that serves to interconnect the building and acts to transmit lateral forces to the vertical resisting elements. DIAPHRAGM EDGE: The intersection the of horizontal diaphragm and a shear wall. DISPLACEMENT-CONTROLLED ACTION: An action that has an associated deformation that is allowed to exceed the yield value of the element being evaluated. The extent of permissible deformation beyond yield is based on component modification factors (m-factors). EXPECTED STRENGTH: The actual strength of a material, not the specified minimum or nominal strength. For purposes of an evaluation using this Handbook, the expected strength shall be taken equal to the nominal strength multiplied by 1.25. Alternatively, actual statistically based test data may be used. FLEXIBLE DIAPHRAGM: A diaphragm where the maximum lateral deformation along its length is more than twice the average inter-story drift. FORCE-CONTROLLED ACTION: An action that has an associated deformation that is not allowed to exceed the yield value of the element being evaluated. The action is not directly related to the pseudo seismic forces used in the evaluation, rather it is based on the maximum action that can be delivered to the element by the yielding structural system.
FEMA 310
1.3
Definitions
ACTION: Forces or moments that cause displacements and deformations. ASPECT RATIO: Ratio of full height to length for shear walls; ratio of span to depth for horizontal diaphragms. BASIC NONSTRUCTURAL CHECKLIST: Set of evaluation statements that shall be completed as part of the Tier 1 Evaluation. Each statement represents a potential nonstructural deficiency based on performance in past earthquakes. BASIC STRUCTURAL CHECKLIST: Sets of evaluation statements that shall be completed as part of the Tier 1 Evaluation. Each statement represents a potential structural deficiency based on performance in past earthquakes. BENCHMARK BUILDING: A building designed and constructed or evaluated to a specific performance level using an acceptable code or standard listed in Table 3-1. BUILDING TYPE: A building classification defined in Section 2.6, that groups buildings with common lateral-force-resisting systems and performance characteristics in past earthquakes.
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Chapter 1.0 - General Provisions
FULL-BUILDING TIER 2 EVALUATION: An evaluation beyond a Tier 1 Evaluation that involves a complete analysis of the entire lateral-force-resisting system of the building using the Tier 2 analysis procedures defined in Section 4.2. While special attention should be given to the potential deficiencies identified in the Tier 1 evaluation, all lateral force resisting elements must be evaluated. This evaluation is required when triggered by Table 3-3. GEOLOGIC SITE HAZARDS AND FOUNDATIONS CHECKLIST: Set of evaluation statements that shall be completed as part of the Tier 1 Evaluation. Each statement represents a potential foundation or site deficiency based on the performance of buildings in past earthquakes. IMMEDIATE OCCUPANCY PERFORMANCE LEVEL: Building performance that includes very limited damage to both structural and nonstructural components during the design earthquake. The basic vertical and lateral-force-resisting systems retain nearly all of their pre-earthquake strength and stiffness. The level of risk for life-threatening injury as a result of damage is very low. Although some minor repairs may be necessary, the building is fully habitable after a design earthquake, and the needed repairs may be completed while the building is occupied. LATERAL FORCE RESISTING SYSTEM: The collection of frames, shear walls, bearing walls, braced frames and interconnecting horizontal diaphragms that provides earthquake resistance to a building. LIFE SAFETY PERFORMANCE LEVEL: Building performance that includes significant damage to both structural and nonstructural components during a design earthquake, though at least some margin against either partial or total structural collapse remains. Injuries may occur, but the level of risk for life-threatening injury and entrapment is low.
LINEAR DYNAMIC PROCEDURE (LDP): A Tier 2 response spectrum based modal analysis procedure shall be used for buildings taller than 100 feet, buildings with vertical or geometric irregularities, and buildings where the distribution of the lateral forces departs from that assumed for the Linear Static Procedure. LINEAR STATIC PROCEDURE (LSP): A Tier 2 lateral force analysis procedure where the pseudo lateral force is equal to the force required to impose the expected actual deformation of the structure in its yielded state when subjected to the design earthquake motions. It shall be used for buildings for which the Linear Dynamic or the Special Procedure is not required. MAXIMUM CONSIDERED EARTHQUAKE: An earthquake with a 2% probability of exceedance in 50 years with deterministic-based maximum values near known fault sources. MOMENT-RESISTING FRAME (MRF): A frame capable of resisting horizontal forces because the members (beams and columns) and joints are capable of resisting forces primarily by flexure. PRIMARY COMPONENT: A part of the lateral-force-resisting system capable of resisting seismic forces. PSEUDO LATERAL FORCE (V): The calculated lateral force used for the Tier 1 Quick Checks and for the Tier 2 Linear Static Procedure. The pseudo lateral force represents the force required, in a linear analysis, to impose the expected actual deformation of the structure in its yielded state when subjected to the design earthquake motions. It does not represent an actual lateral force that the building must resist in traditional code design. QUICK CHECK: Analysis procedure used in Tier 1 Evaluations to determine if the lateral-force-resisting system has sufficient strength and/or stiffness. REGION OF LOW SEISMICITY CHECKLIST: Set of evaluation statements that shall be completed as part of the Tier 1 Evaluation for buildings in regions of low seismicity being evaluated to the Life Safety Performance Level.
FEMA 310
Seismic Evaluation Handbook
1-7
Chapter 1.0 - General Provisions
REGION OF SEISMICITY: An area with similar expected earthquake hazard. For this Handbook, all regions are categorized as low, moderate, or high, based on mapped acceleration values and site amplification factors as defined in Section 2.5. RIGID DIAPHRAGM: A diaphragm where the maximum lateral deformation is less than half the average inter-story drift associated with the story. SECONDARY COMPONENT: An element that is capable of resisting gravity loads, but is not able to resist seismic forces it attracts, though is not needed to achieve the designated performance level. SITE CLASS: Groups of soil conditions that affect the site seismicity in a common manner. The soil types used are defined in Section 3.5.2.3.1; designated as A, B, C, D, E, or F. SPECIAL PROCEDURE: Analysis procedure, used for unreinforced masonry bearing wall buildings with flexible diaphragms, that properly characterizes the diaphragm motion, strength and damping. SPECIAL PROCEDURE TIER 2 EVALUATION: An evaluation procedure specifically written for unreinforced masonry bearing wall buildings with flexible diaphragms using the special procedure. STIFF DIAPHRAGM: A diaphragm that is not classified as either flexible or rigid. STORY SHEAR FORCE: Portion of the pseudo lateral force carried by each story of the building. SUPPLEMENTAL NONSTRUCTURAL CHECKLIST: Set of nonstructural evaluation statements that shall be completed as part of the Tier 1 Evaluation for buildings in regions of moderate or high seismicity being evaluated to the Immediate Occupancy Performance Level. SUPPLEMENTAL STRUCTURAL CHECKLIST: Set of evaluation statements that shall be completed as part of the Tier 1 Evaluation for buildings in regions of moderate seismicity being evaluated to the Immediate Occupancy Performance Level, and for buildings in regions of high seismicity.
TIER 1 EVALUATION: Completion of checklists of evaluation statements that identifies potential deficiencies in a building based on performance in past earthquakes. TIER 2 EVALUATION: The specific evaluation of potential deficiencies to determine if they represent actual deficiencies that may require mitigation. Depending on the building type, this evaluation may be a Full-Building Tier 2 Evaluation, Deficiency-Only Tier 2 Evaluation, or a Special Procedure Tier 2 Evaluation. TIER 3 EVALUATION: A comprehensive building evaluation implicitly or explicitly recognizing nonlinear response.
1.4
ap A br Ac
Notation
Component amplification factor, Average cross-sectional area of the diagonal brace, Summation of the cross-sectional area of all columns in the story under consideration, Area of net mortared/grouted section (in2 ), Summation of the horizontal cross-sectional area of all shear walls in the direction of loading, Amplification factor to account for accidental torsion, Modification factor to relate expected maximum inelastic displacements calculated for linear elastic response, Compliant, Horizontal force factor, Modification factor, based on earthquake records, used to adjust the building period to account for the characteristics of the building system, Vertical distribution factor, based on story weights and heights, that defines a triangular loading pattern,
An Aw
Ax C
C Cp Ct
Cvx
1-8
Seismic Evaluation Handbook
FEMA 310
Chapter 1.0 - General Provisions
D DCR Dp DR, Dr E Fa fbr Fi Fpx Fv Fwx Fx Fy h hi ,hx hn H I IO j J k kb kc L L br LS m Mg
FEMA 310
In-plane width dimension of masonry (in.) or depth of diaphragm (ft.), Demand-capacity ratio, Relative displacement, Drift ratio, Modulus of Elasticity; Site Coefficient defined in Table 3-6, Average axial stress in diagonal bracing elements, Lateral force applied at floor level i, Total diaphragm force at level x, Site Coefficient defined in Table 3-5, Force applied to a wall at level x (lb.), Total story force at level x, Yield Stress, Story height, Height (ft.) from the base to floor level i or x, Height (in feet) above the base to the roof level, Least clear height of opening on either side of pier (in.), Moment of Inertia, Immediate Occupancy Performance Level, number of story level under consideration, Force-delivery reduction factor, Exponent related to the building period, Stiffness of a representative beam (I/L); Stiffness of a representative column (I/h); Length; Average length of the diagonal brace, Life-Safety Performance Level, Component modification factor, Moment in girder (k-ft),
n, N N/A Nbr
number of stories above ground, Not Applicable, Number of diagonal braces in tension and compression if the braces are designed for compression; Number of diagonal braces in tension if the braces are designed for tension only, Total number of columns, Total number of frames, Non-Compliant, No Limit, Expected gravity compressive force applied to a wall or pier component stress, Superimposed dead load at the top of the pier under consideration (lb.), Weight of wall (lb.), Expected strength, Actions due to effective dead load, Actions due to earthquake loads, Actions due to effective gravity load, Actions due to effective live load, Actions due to effective snow load, Deformation-controlled design actions, Force-controlled design actions, Component response modification factor, Average span length of braced spans (ft.), Response spectral acceleration, Design short-period spectral response acceleration parameter, Design spectral response acceleration parameter at a one-second period, Short-period spectral response acceleration parameter, Spectral response acceleration parameter at a one-second period, Thickness of wall (in.)
1-9
nc nf NC NL PCE PD PW QCE QD QE QG QL QS QUD QUF Rp s Sa SDS SD1 SS S1 t
Seismic Evaluation Handbook
Chapter 1.0 - General Provisions
T T1 T2 T3 v avg v me vu v te V Va Vc Vca
Fundamental period of vibration of the building, Tier 1 Evaluation, Tier 2 Evaluation, Tier 3 Evaluation, Average shear stress, Expected masonry shear strength (psi), Unit shear strength for a diaphragm (lb./ft.), Average bed-joint shear strength (psi), not to exceed 100 psi, Pseudo lateral force, Shear strength of an unreinforced masonry pier (lb.), Column shear force, Total shear capacity of cross walls in the direction of analysis immediately above the diaphragm level being investigated (lb.), Total shear capacity of cross walls in the direction of analysis immediately below the diaphragm level being investigated (lb.), Diaphragm shear (lb.), Story shear force, Shear force on an unreinforced masonry wall pier (lb.), Pier rocking shear capacity of an unreinforced masonry wall or wall pier (lb.), Total shear force resisted by a shear wall at the level under consideration (lb.), Portion of the total building weight assigned to floor level i or x, Total seismic weight, Total dead load tributary to a diaphragm (lb.), Total seismic weight of all stories above level j, Component operating weight,
Ww
Total dead load of an unreinforced masonry wall above the level under consideration or above an open front of a building, Dead load of an unreinforced masonry wall assigned to level x halfway above and below the level under consideration (lb.), Height in structure of highest point of attachment of component, Height of lower support attachment at level x or y as measured from grade, Diaphragm displacement, In-plane wall displacement, the maximum dispalcement at any point of diaphragm at level x, the algebraic average of displacements at the extreme points of the diaphragm at level x, Deflection at building level x or y of building A, Deflection at building level x of building B, Volumetric ratio of horizontal confinement reinforcement in a joint.
Wwx
x X,Y d w avg max
Vcb
, yA xA xB ''
Vd Vj Vp Vr
Vwx wi , wx W Wd Wj Wp
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Seismic Evaluation Handbook
FEMA 310
Chapter 1.0 - General Provisions
1.5
References
ACI, 1995, Building Code Requirements for Reinforced Concrete, ACI 318-95, American Concrete Institute, Detroit, Michigan. AISC, 1993, Load and Resistance Factor Design Specification for Structural Steel Buildings, American Institute of Steel Construction, Inc., Chicago, Illinois. ASCE, 1995, ASCE 7-95, Minimum Design Loads for Buildings and Other Structures, American Society of Civil Engineers, New York, New York. BOCA, 1993, National Building Code, Building Officials and Code Administrators International, Country Club Hill, Illinois. CBSC, 1995, California Building Code (Title 24), California Building Standards Commission, Sacramento, California. FEMA, 1998, Seismic Map Package, Federal Emergency Management Agency, Washington D.C. ICBO, 1994, Uniform Building Code, International Conference of Building Officials, Whittier, California. MSS, 1993, Pipe Hangers and Supports: Materials, Design and Manufacture, SP-58, Manufacturers Standardization Society of the Valve and Fitting Industry, Vienna, Virginia. NFPA, 1996, Standard for the Installation of Sprinkler Systems, NFPA-13, National Fire Protection Association, Quincy, Massachusetts. SBCC, 1993, Standard Building Code, Southern Building Code Congress International, Birmingham, Commentary: ABK, 1984, Methodology for Mitigation of Seismic Hazards in Existing Unreinforced Masonry Buildings: The Methodology, Topical Report 08, National Science Foundation, Washington, D.C. Alabama.
BSSC, 1992a, NEHRP Handbook for the Seismic Evaluation of Existing Buildings, developed by the Building Seismic Safety Council for the Federal Emergency Management Agency (Report No. FEMA 178), Washington, D.C. BSSC, 1992b, NEHRP Handbook of Techniques for the Seismic Rehabilitation of Existing Buildings, developed by the Building Seismic Safety Council for the Federal Emergency Management Agency (Report No. FEMA 172), Washington, D.C. BSSC, 1995, NEHRP Recommended Provisions for Seismic Regulations for New Buildings, 1994 Edition, Part 1: Provisions and Part 2: Commentary, developed by the Building Seismic Safety Council for the Federal Emergency Management Agency (Report No. FEMA 222A and 223A), Washington, D.C. BSSC, 1997, NEHRP Guidelines for the Seismic Rehabilitation of Buildings, developed by the Buildings Seismic Safety Council for the Federal Emergency Management Agency (Report No. FEMA 273), Washington, D.C. BSSC, 1997, NEHRP Commentary for the Seismic Rehabilitation of Buildings, developed by the Buildings Seismic Safety Council for the Federal Emergency Management Agency (Report No. FEMA 274), Washington, D.C. SAC, 1995, Interim Guidelines: Evaluation, Repair, Modification and Design of Steel Moment Frames, developed by the SAC Joint Venture (Report No. SAC-95-02) for the Federal Emergency Management Agency (Report No. FEMA 267), Washington, D.C. SAC, 1997, Interim Guidelines Advisory No. 1: Supplement to FEMA 267, developed by the SAC Joint Venture (Report No. SAC-96-03) for the Federal Emergency Management Agency (Report No. FEMA 267A), Washington, D.C. SEAOC, 1996, Recommended Lateral Force Requirements and Commentary, Sixth Edition, Structural Engineers Association of California, Sacramento, California.
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U. Memphis - FEMA - 7119
Recommended Seismic Design Criteria for New Steel Moment-Frame BuildingsFEMA-350 SAC Project ParticipantsSAC Phase II Project ParticipantsFEMA Project Officer Michael Mahoney Federal Emergency Management Agency 500 C St. SW, Room 404 Washington,
U. Memphis - FEMA - 7119
Recommended Seismic Design Criteria for New Steel Moment-Frame BuildingsFEMA-350 References, Bibliography, and AcronymsREFERENCES, BIBLIOGRAPHY, AND ACRONYMSThis section contains references, additional bibliography and acronyms that are generall
U. Memphis - FEMA - 7119
Chapter 2.0 - Evaluation Requirements2.0 Evaluation Requirements2.1 Generalvalues for material properties shall not be used. Material property data shall be obtained from building codes from the year of construction of the building being evaluate
U. Memphis - FEMA - 7119
Chapter 3.0 - Screening Phase (Tier 1)3.0 Screening Phase (Tier 1)3.1GeneralA Tier 1 Evaluation shall be conducted for all buildings after the evaluation requirements of Chapter 2 have been completed. Tier 1 of the evaluation process is shown
U. Memphis - FEMA - 356
FEDERAL EMERGENCY MANAGEMENT AGENCYFEMA 356 / November 2000PRESTANDARD AND COMMENTARY FOR THE SEISMIC REHABILITATION OF BUILDINGSFEDERAL EMERGENCY MANAGEMENT AGENCYFEMA 356 / November 2000PRESTANDARD AND COMMENTARY FOR THE SEISMIC REHABILIT
U. Memphis - FEMA - 7119
FEDERAL EMERGENCY MANAGEMENT AGENCYFEMA 356 / November 2000PRESTANDARD AND COMMENTARY FOR THE SEISMIC REHABILITATION OF BUILDINGSFEDERAL EMERGENCY MANAGEMENT AGENCYFEMA 356 / November 2000PRESTANDARD AND COMMENTARY FOR THE SEISMIC REHABILIT
U. Memphis - FEMA - 7119
Chapter 5.0 - Detailed Evaluation Phase (Tier 3)5.0 Detailed Evaluation Phase (Tier 3)5.1 GeneralFor buildings requiring further investigation, a Tier 3 Evaluation shall be completed in accordance with this Chapter. A Tier 3 Evaluation shall be p
U. Memphis - FEMA - 356
AcronymsAcronymsAAMA ABK ACI AISC AISI ANSI APA API ASCE ASHRAE ASME ASTM ATC AWS AWWA BNC BOCA BRANZ BSE-1 BSE-2 BSO BSSC CBF CISCA American Architectural Manufacturers Association Agbabian, Barnes and Kariotis joint venture American Concrete Ins
U. Memphis - FEMA - 7119
AcronymsAcronymsAAMA ABK ACI AISC AISI ANSI APA API ASCE ASHRAE ASME ASTM ATC AWS AWWA BNC BOCA BRANZ BSE-1 BSE-2 BSO BSSC CBF CISCA American Architectural Manufacturers Association Agbabian, Barnes and Kariotis joint venture American Concrete Ins
U. Memphis - CE - 7119
CIVL7119/8119 Homework Set 13The portal frame in the figure is located in Memphis (35.11 Lat. -89.94 Long.). Compute the confidence levels on having: Less that 5% probability of a performance poorer that Collapse Prevention (CP) in 50 years life cy
U. Memphis - CE - 7119
CIE 619 Earthquake Engineering and Structural Dynamics IIInstructor: Andrew WhittakerMODULE 01.INTRODUCTION TO EARTHQUAKE ENGINEERING1.1 Course Content and General Information The course is presented as a series of linked modules. Modules tha
U. Memphis - CE - 7119
CIE 619 Earthquake Engineering and Structural Dynamics IIInstructor: Andrew WhittakerSECTION 1. ENGINEERING CHARACTERIZATION OF EARTHQUAKES1.1 Introduction This section presents information on engineering seismology and engineering characterizat
U. Memphis - CE - 7119
CIE 619 Earthquake Engineering and Structural Dynamics IIInstructor: Andrew WhittakerSEISMIC PROTECTIVE SYSTEMSThis module presents information on seismic protective systems and new and retrofit building construction using seismic protective sys
U. Memphis - CE - 7119
CIVL 7119/8119 1. Write a paper of size 1 or 2 page(s) on one of the following earthquakes: a. Northridge Earthquake in LA, 1994 b. Loma Prieta Earthquake c. Mexico Earthquake of 1985 d. Chilean Earthquake e. Philippine Earthquake f. Iranian Earthqua
U. Memphis - CE - 7117
Structural DynamicsIntroduction This chapter provides an elementary introduction to time-dependent problems. We will introduce the basic concepts using the single-degree-of-freedom springmass system. We will include discussion of the stress analysis
U. Memphis - CE - 7117
Development of the Plane Stress and Plane Strain Stiffness EquationsIntroduction In Chapters 2 through 5, we considered only line elements. Line elements are connected only at common nodes, forming framed or articulated structures such as trusses, f
U. Memphis - FIR - 7410
How Securities Are TradedChapter 3McGraw-Hill/IrwinCopyright 2005 by The McGraw-Hill Companies, Inc. All rights reserved.Primary vs. Secondary Security SalesPrimaryNew issue Key factor: issuer receives the proceeds from the sale.Secondary
U. Memphis - FIR - 7410
The Term Structure of Interest RatesChapter 15McGraw-Hill/IrwinCopyright 2005 by The McGraw-Hill Companies, Inc. All rights reserved.Overview of Term StructureThe relationship between yield to maturity and maturity. Information on expected fut
U. Memphis - FIR - 7410
Managing Bond PortfoliosChapter 16McGraw-Hill/IrwinCopyright 2005 by The McGraw-Hill Companies, Inc. All rights reserved.Basic StrategiesActive strategyTrade on interest rate predictions Trade on market inefficienciesPassive strategyContr
U. Memphis - FIR - 7410
Futures and Swaps: A Closer LookChapter 23McGraw-Hill/IrwinCopyright 2005 by The McGraw-Hill Companies, Inc. All rights reserved.Foreign Exchange FuturesFutures marketsChicago Mercantile (International Monetary Market) London International Fi
U. Memphis - FIR - 7721
SwapsChapter 7Options, Futures, and Other Derivatives 6th Edition, Copyright John C. Hull 20057.1Nature of SwapsA swap is an agreement to exchange cash flows at specified future times according to certain specified rulesOptions, Futures, a
U. Memphis - FIR - 7410
Bond Prices and YieldsChapter 14McGraw-Hill/IrwinCopyright 2005 by The McGraw-Hill Companies, Inc. All rights reserved.Bond CharacteristicsFace or par value Coupon rateZero coupon bondCompounding and paymentsAccrued Interest Invoice price
U. Memphis - FIR - 7410
Options Markets: IntroductionChapter 20McGraw-Hill/IrwinCopyright 2005 by The McGraw-Hill Companies, Inc. All rights reserved.Option TerminologyBuy - Long Sell - Short Call Put Key ElementsExercise or Strike Price Premium or Price Maturity o
U. Memphis - FIR - 7410
Portfolio Performance EvaluationChapter 24McGraw-Hill/IrwinCopyright 2005 by The McGraw-Hill Companies, Inc. All rights reserved.IntroductionComplicated subject Theoretically correct measures are difficult to construct Different statistics or
U. Memphis - FIR - 7721
Mechanics of Options MarketsChapter 8Options, Futures, and Other Derivatives 6th Edition, Copyright John C. Hull 20058.1Review of Option TypesAcall is an option to buy A put is an option to sell A European option can be exercised only at
U. Memphis - FIR - 7410
Optimal Risky PortfoliosChapter 8McGraw-Hill/IrwinCopyright 2005 by The McGraw-Hill Companies, Inc. All rights reserved.Risk Reduction with DiversificationSt. DeviationUnique RiskMarket Risk Number of Securities8-2Two-Security Portfoli
U. Memphis - FIR - 7410
Risk and Risk AversionChapter 6McGraw-Hill/IrwinCopyright 2005 by The McGraw-Hill Companies, Inc. All rights reserved.Risk - Uncertain Outcomesp = .61W = 150 Profit = 50 W = 100 1-p = .41 2 2W = 80 Profit = -20E(W) = pW + (1-p)W = 6 (
U. Memphis - FIR - 7721
Properties of Stock OptionsChapter 9Options, Futures, and Other Derivatives 6th Edition, Copyright John C. Hull 20059.1Notation c : European call option price p : European put option price S0 : Stock price today K : Strike price T : L
U. Memphis - FIR - 7410
The Theory of Active Portfolio ManagementChapter 27McGraw-Hill/IrwinCopyright 2005 by The McGraw-Hill Companies, Inc. All rights reserved.Lure of Active ManagementAre markets totally efficient?Some managers outperform the market for extended
U. Memphis - FIR - 7410
Index ModelsChapter 10McGraw-Hill/IrwinCopyright 2005 by The McGraw-Hill Companies, Inc. All rights reserved.Advantages of the Single Index ModelReduces the number of inputs for diversification. Easier for security analysts to specialize.10
U. Memphis - FIR - 7410
Financial Statement AnalysisChapter 19McGraw-Hill/IrwinCopyright 2005 by The McGraw-Hill Companies, Inc. All rights reserved.OverviewPurpose Tools UsedStatements Ratio AnalysisLimitations19-2Financial StatementsBalance SheetCommon Si
U. Memphis - FIR - 7721
UNIVERSITY OF MEMPHIS Fogelman College of Business AdministrationFall 2006 FIR 7721/8721 Financial Derivatives Classroom: FCB 365, Tuesday 7:10-10:10pm Instructor: Dr. Robert Wood 678-2670 rwood@memphis.edu Office Hours: Mondays 5:00 6:30pm, Tues
U. Memphis - FIR - 7410
UNIVERSITY OF MEMPHIS Fogelman College of Business AdministrationFall 2006 FIR 7410 Investment Theory and Portfolio Management Classroom: FCB 365, Monday 7:10-10:10pm Instructor: Dr. Robert Wood Office Hours: Mondays 5:00 6:30pm, Tuesdays 4-5pm, o
U. Memphis - ISDS - 3711
Chapter 4 Regression Analysis: Model Buildings s s s sGeneral Linear Model Determining When to Add or Delete Variables VariableSelection Procedures Residual AnalysisMultiple Regression Approach to Analysis of Variance and Experimental D
U. Memphis - ISDS - 3711
Forecasting Models19.1 Introduction to Time Series Forecasting Forecasting is the process of predicting the future. Forecasting is an integral part of almost all business enterprises. Examples Manufacturing firms forecast demand for their prod
U. Memphis - ISDS - 3711
Slides Prepared byJOHN S. LOUCKSST. EDWARD S UNIVERSITY2005Thomson/SouthWestern Slide 1Chapter12,PartA WaitingLineModelss s s s s s s sStructureofaWaitingLineSystem QueuingSystems QueuingSystemInputCharacteristics QueuingSystemOperatingCh
U. Memphis - ISDS - 3711
Slides Prepared byJOHN S. LOUCKSST. EDWARD S UNIVERSITY2005Thomson/SouthWestern Slide 1Chapter14 DecisionAnalysiss s s s s sProblemFormulation DecisionMakingwithoutProbabilities DecisionMakingwithProbabilities RiskAnalysisandSensitivityAn
U. Memphis - ISDS - 3711
Chapter 7 Linear Programming: Sensitivity Analysis and Interpretation of Solutions s s sIntroduction to Sensitivity Analysis Graphical Sensitivity Analysis Sensitivity Analysis: Computer Solution Simultaneous Changes 2005 Thomson/SouthWeste
U. Memphis - ISDS - 7476
ISDS 7120 University of Memphis Thursday Assignment July 13, 2006Michael Racer Summer 2006Raw Materials Your company has finally been forced to close its doors. Only one month from now, you will close down the business. Your goal in production th
Minnesota - CFAN - 1501
Name_ Biotechnology, Society and the Environment (ScAg 1501) Final Exam-May 5, 2004 Multiple Choice. Choose the best answer for each of the following questions. (2 pts./question; 48 pts. total). 1. The chromosome number of a species: a. Haplotype b.
Minnesota - CFAN - 1501
`CFAN 1501 MIDTERM 2, 2007BIOTECHNOLOGY, PEOPLE, AND THE ENVIRONMENT (CFANS 1501) Microbial Biotechnology Section MidTerm Exam: March 23, 2007I ( PRINT name) _ promise to adhere to the University of Minnesota scholastic code, which explicitly pr
Minnesota - TEACHING - 3001
Class Schedule 2007 Date February 19 February 21 February 23 February 26 Class/Lab Topic Readings Lecture 1: Class requirements and goals; introduction to plant diseases Readings: Lucas 1-25; 30-38 and Agrios 3-7; 25-33 Lecture 2: Pathogen groups: st
Minnesota - TEACHING - 3001
SordariaSordaria is a saprophytic fungus and is not known to cause disease in plants. Observe the flask-like structure called perithecium. Using a pencil eraser, gently press down on the cover slip to break open the contents of the perithecium. Insi
Minnesota - CFAN - 1501
SCAG 1501 EXAM 1, 2003SCAG 1501: Biotechnology, People and the Environment Midterm Exam I Friday, February 21, 2003 Name (print) _ I (name) _ promise to adhere to the University of Minnesota scholastic code, which explicitly prohibits any form of p
Minnesota - CFAN - 1501
Name_ Biotechnology, Society and the Environment (CFANS 1501) Animal & Medical Biotechnology Exam-May 4, 2007 Multiple Choice. Choose the best answer for each of the following questions. (2 pts./question; 48 pts. total). 1. ES cells grown in vitro ca
Minnesota - CFAN - 1501
AGRI 1501 EXAM 1, 2005AGRI 1501: Biotechnology, People and the Environment Midterm Exam #1; Wednesday, February 16, 2005 Name (please print) _ I promise to adhere to the University of Minnesota scholastic code, which explicitly prohibits any form o
Minnesota - CFAN - 1501
Down on the ol' BiopharmDouglas N. Foster Department of Animal Science University of Minnesota Animal Improvement Conventional Animal Breeding Used to Select for Desired Traits:1. Increase rate of weight gain A. Increase efficiency (kg weight ga
Minnesota - ME - 8390
Mathematical Biosciences 190 (2004) 203220www.elsevier.com/locate/mbsModeling of arterial stenosis and its applications to blood diseasesR.N. Pralhadaa,*, D.H. SchultzbFaculty of Applied Mathematics, Institute of Armament Technology, Gir
Minnesota - ME - 8381
Minnesota - MWRIGHT - 0201
Teaching an Aesthetic Lesson Lesson Topic: German Past-Tense Length of lesson: 51 minutes Stage 1 Desired Results Content Standard(s): Standard1.1:Studentsengageinconversations,provideandobtaininformation,expressfeelings andemotions,andexchangeopi
Minnesota - MWRIGHT - 0360
RandiWeber ENGL5922 12.1.2006QuickWriteDiscussion[Short/LongDiscussion]UnderstandingByDesignBackwardsDesignProcess (DevelopedbyGrantWigginsandJayMcTighe,2002) Stage1DesiredResults ContentStandard(s):I.ReadingandLiterature D.Literature 14.Respon
Minnesota - MWRIGHT - 0026
Lissa Crombie Mary Wright Engl 5922 November 27, 2006 Course Title: English 10 Poetry is like Food Lesson Plan (You can have too much of a good thing) 1. Objectives: Students will be able to identify similes and metaphors in poems. Students will be a
Minnesota - MWRIGHT - 0002
Class: ShakespeareLesson: Short/Long Discussion of LiteratureStage 1 Desired Results Content Standard(s): I. Reading and Literature C. Comprehension The student will understand the meaning of informational, expository or pers
Minnesota - MWRIGHT - 0026
Lissa Crombie December 6, 2006 Course Title: English 10 Literature Discussion Bricks and Bones 1. Objectives: This lesson will be used to look at how figurative language enhances writing. 2. Material: a sheet of blank paper Short story called bricks
Minnesota - PETE - 2538
Julie Petersen Engl 5922 Microteaching: Language Concept November 15, 2006 Subject/Verb Agreement Mini-lesson (15 mn) Objectives: Students will be able to identify the subject and verb in a sentence. Students will understand the different rules that
Minnesota - WILL - 1367
Beth Williams Holly Nichols Lesson Topic: Social Justice: Humanity Grade level: 12th Grade Length of lesson: 1 Day Stage 1 Desired Results Content Standard(s): I. Reading and Literature: C. Comprehension D. Literature Understanding (s)/goals Stud
Minnesota - WILL - 1367
Beth Williams Holly Nichols Lesson Topic: Discussion: Crash Grade level: 12th Grade Length of lesson: 34 Days Stage 1 Desired Results Content Standard(s): III. Speaking, Listening and Viewing A. Speaking and Listening B. Media Literacy Understand
Minnesota - MWRIGHT - 0068
(Microteaching#2) LessonTopic:Whatdowe(really)know?QuizandDiscussionofTheMostDangerousGamebyRichardConnellGradelevel:9 Lengthoflesson:25min. Stage1DesiredResults ContentStandard(s): I.READINGANDLITERATURE,C.Comprehension I.READINGANDLITERATURE,D.L
Minnesota - EE - 4111
Dept. of Electrical and Computer Engineering University of Minnesota EE4111 - Spring 2009 Experiment #1 SPICE Simulation the Fundamentals Duration: Three weeks, starting the week of Monday, January 26 and to be completed by Friday, February 13. Purp
Minnesota - EE - 3161
Recitation 9EE 3161 Spring 2008 1) For the silicon pnp bipolar transistor shown below, what are T and if we include base recombination? If VEB = 0, at what VCB does the transistor reach a punchthrough condition (base region fully depleted)? How do
Minnesota - EE - 3161
Homework # 4EE 3161 - Spring 2008 Due Friday, March 28 in class 1) Problem 6.10 of Pierret. 2) Assume the ideal silicon diode below. a) Make a quantitative sketch of the carrier concentrations across the diode for forward and reverse bias. b) For a