# I. Introduction

ccording to the nonlinear static procedure (NSP), also known as pushover analysis, seismic demands of a building can be computed by pushing the building with a specific height wise distribution lateral load pattern to reach a predetermined target displacement. NSP's suffer from some shortages. Among them, invariant load pattern is one of the most important limits and it causes higher modes effects being neglected during pushover analysis. Besides, in original NSP's, all methods were limited to planar structural models and so, torsional effects are not considered directly and effectively. Recently, attempts have been made to overcome these limits and extend the applicability of simplified methods to asymmetric structures, which require a 3D analysis and consider higher modes effects in the analysis e.g. (Ayala and Tavera 2002), (Aydinoglu, 2003), (Chopra and Goel, 2004), (Fujii et al., 2004), (Yu et al., 2004) and (Zárate and Ayala, 2004).

This paper deals with the extension of the consecutive modal pushover (CMP) analysis which was proposed by (Poursha et al., 2009). The CMP procedure contains multi-stage and single-stage pushover analysis and is able to take higher modes effects into account. In the original version of the CMP method, 2D models were used and so, torsional effects were neglected. In the Author: University of Texas at Arlington. e-mail: Babak.hm@gmail.com paper, the extended CMP method is summarized and applied to four ten story buildings with 0%, 5%, 10% and 20% eccentricities in Y direction. The results are compared with results of nonlinear response history analysis (NL-RHA).


# II. Discription of the Consecutive

Modal Pushover (cmp)

The CMP procedure benefits from consecutive implementation of modal pushover analysis and uses limited number of modes to develop results (Poursha et al., 2009). This procedure contains a multi-stage and a single-stage pushover analysis. When the first stage of the multi-stage pushover analysis is performed completely, the next stage starts with initial structural state which is the same as the state at the end of the first stage. Numbers of modes which are considered in the multi-stage pushover analysis depend on the fundamental period of the structure. If the fundamental period of the structure exceeds 2.2 seconds, then, three modes shapes being used in analysis otherwise, two modes shapes would be enough. The displacement increment at the roof in each stage of multi-stage pushover analysis, u ri , is calculated as follows:
?? ???? = ?? ?? ?? ?? (2.1)
In which, ?? ?? = ?? ?? , for stages before the last stage (2.2) and,
?? ?? = 1 ? ? ?? ?? ?????1 ?? =1
, for the last stage (2.3)

Where ? t is the total target displacement at the roof, and N s is the number of stages considered in the multi-stage pushover analysis. Also, ? n is the effective modal mass ratio for the n th mode, which is defined as the ratio between the effective modal participating mass for the n th mode divided by total mass of the structure. The target displacement can be obtained through different methods e.g. capacity spectrum method (ATC-40, 1996), displacement coefficient approach (FEMA356, 2000), N2 method (Fajfar, 2000) and dynamic analysis of the structure (Moghadam, 2002). As mentioned before, the CMP procedure uses singlestage pushover analysis to develop results. Hence, a pushover analysis with a triangular or a uniform load distribution is performed separately. Seismic demands can be obtained by enveloping the peak responses derived from the multi-stage and the single-stage pushover analysis. The CMP procedure as proposed by Poursha (2009) is summarized below in a sequence of steps: a) Calculate natural frequencies, ? n and mode-shapes, ? n . These properties are computed by Eigen values obtained from linearly elastic building analysis. Mode-shapes are normalized so that the roof component of ? n equals unity (? rn =1).

b) Compute ?? ?? * = ???? ?? (Chopra and Goel, 2004), where ?? ?? * shows the distribution of incremental lateral forces over the height of the structure for the n th mode. c) Compute the total target displacement of the structure at the roof, ? t . d) The CMP procedure consists of single-stage and multi-stage pushover analysis. First, Gravity analysis should be implemented and then, pushover analyses are performed according to the following sub-steps i. Perform the single-stage pushover analysis with the triangular load pattern for low to mid-rise building and the uniform load pattern for highrise building until the control node at the roof of the building reaches the predetermined target displacement.

ii. Perform two-stage pushover analysis for those buildings which their fundamental periods are less than 2.2s. In the first stage, a pushover analysis is performed by using the incremental lateral forces, ?? 1 * = ???? 1 , until the control node reaches ?? ??1 = ?? 1 ?? ?? , (Eqn. 2.1, for i=1). Then, second stage should be performed. In this stage, a pushover analysis is implemented by using the incremental lateral forces, ?? 2 * = ???? 2 , until the control node reaches ?? ??2 = ?? 2 ?? ?? , (Eqn. 2.3, for N s =2 and i=2). iii. Perform three-stage pushover analysis for those buildings which have fundamental period more than 2.2s. The first stage are exactly is the same with the first stage of the two-stage pushover analysis. Next pushover analysis is performed by using, ?? 2 * = ???? 2 , until the control node reaches ?? ??2 = ?? 2 ?? ?? (Eqn. 2.1, for i=2). Then, last pushover analysis is implemented by using ?? 3 * = ???? 3 until the control node reaches ?? ??3 = ?? 3 ?? ?? , (Eqn. 2.3, for N s =3 and i=3). e) Calculate peak responses of desired values in each pushover analysis. In the paper the one-, two-and three-stage pushover response are denoted by r 1 , r 2 and r 3 respectively.

f) Calculate the ultimate responses as follows:
?? = ??????{?? 1 , ?? 2 } , ð??"ð??"ð??"ð??"??ð??"ð??" < 2.2?? (2.4) ?? = ??????{?? 1 , ?? 2 , ?? 3 } , ð??"ð??"ð??"ð??"??ð??"ð??" ? 2.2??(2.5)

# III. Analytical Models, Assumptions and Types of Analysis

Four ten-story reinforced concrete building with 0%, 5%, 10% and 20% eccentricity in Y direction are considered as models as shown in Fig. 3.1. Lateral load resisting systems of buildings are concrete moment resistant frame with medium ductility. All frames consist of 4*5m bays in each direction and a story height of 3.0m is assumed. Some brief characteristics of buildings are listed in Table 3.  The OpenSEES program is used to create and analyze models. The DD+50%LL load combination are assumed in gravity analysis where DD, is the dead load and LL, is the live load. The CMP procedure is carried out for models. The P-? effects are neglected in all pushover analyses. Two modes are considered in the CMP procedure to develop responses and pushover analyses are implemented in X direction only. Each mode-shapes consists of two transitional (X,Y) and a rotational (rotation about Z) components. Since, models have eccentricities in Y direction as shown in Fig. 3.1., only X and rotational component of each mode-shape is considered and mode-shapes are normalized to 1 at top in X component. The target displacements are obtained as the maximum top floor displacement computed by NL-RHA. Seven far field ground motion records are selected from the ground motion database of the Pacific Earthquake Engineering Research Center (PEER) to run NL-RHA. A minimum 15 km distance from the station to surface rupture is considered to select record and soil type is B according to USGS classification system. All records are normalized to 0.35g before processing. Some detail characteristics of ground motion are listed in Table 3 IV.


# Discussion of Results

The drift ratio is defined as the ratio between relative displacements of two story divided by height of the story and calculated as follows: , the height-wise distribution of story drifts derived from the CMP is similar to NL-RHA. Additionally, the pushover analysis by using triangular lateral load pattern, underestimates drift ratios in higher levels in comparison with NL-RHA results. 


# V. Conclusion

Since higher-modes play significant role in tall building, The Consecutive Modal Pushover (CMP) procedure is proposed to consider higher-mode effects in the pushover analysis. It is assumed that dynamic characteristic of a structure are invariable during analysis and so, they are obtained through linearlyelastic analysis. The CMP procedure employs force distribution load pattern and consists of single-stage and multi-stage pushover analysis. The single-stage pushover analysis can be performed either by triangular or uniform load pattern. The multi-stage pushover analysis can be performed in two or three stages based on the height of the structure. Both single-stage and multi-stage pushover analysis are considered to develop results. The CMP procedure benefits from consecutive implementation of modal pushover analysis and uses limited number of modes to develop results. The CMP procedure estimates the height-wise distribution of drift ratio well, and their results are similar to results obtained by NL-RHA.
31![Figure 3.1 : Typical Plan of buildings considered (units in meters)](image-2.png "Figure 3 . 1 :")
![i , d 1+1 and H are the displacement of the i th , (i+1) th story and the height of the story respectively. Story drift ratios are computed by the CMP, Triangular load pattern and NL-RHA and shown in Fig. 4.1 to 4.4. Figures illustrate that the CMP procedures estimate drift ratios for 10 story buildings well in comparison with NL-RHA results. As seen in Fig 4.1. to 4.4.](image-3.png "")

31: Models Characteristics
Table 3.2 : Characteristics of Ground MotionsNo.NameYearMRecording StationDist. 1 (km)Component PGA(g) PGV(cm/s)1Chichi19997.6TCU04733.01N0.41340.22Imperial19796.56604 Cerro Prieto23.5H-CPE1470.16911.63Kocaali19997.4Arcelik17ARC0000.21817.74Landers19927.323 Coolwater22.8CLW-LN0.28325.65Loma Prieta19896.9Anderson Dam20AND2700.22420.36Northridge19946.724000 LA35.9OBR0900.33516.77Sanfernando19716.624278 Castaic24.2OPR0210.32415.6
			© 2014 Global Journals Inc. (US)
		
		
			

				


* 
	
		Seismic Evaluation and retrofit of concrete buildings
		ATC-40
	
	
		Applied Technology Council
		
			1
			2
			1996
		
	




* 
	
		A new approach for the evaluation of the seismic performance of asymmetric buildings
		
			AGAyala
		
		
			EATavera
		
	
	
		Proc., 7 th Nat. Conf. on Earthquake Engineering
				7 th Nat. Conf. on Earthquake EngineeringBoston
		
			EERI
			2002
		
	




* 
	
		An incremental response spectrum analysis procedure based on inelastic spectral displacements for multi-mode seismic performance evaluation
		
			MNAydinoglu
		
	
	
		Bulletin of Earthquake Engineering
		
			1
			1
			
			2003
		
	




* 
	
		A Modal Pushover Analysis Procedure to Estimate Seismic Demands for Unsymmetric-Plan Buildings
		
			GoelChopra
		
	
	
		Journal of Earthquake Engineering and Structural Dynamics
		
			33
			
			2004
		
	




* 
	
		Prestandard and Commentary for the Seismic Rehabilitation of Buildings
	
	
		Building Seismic Safety Council (BSSC)
		
			2000
		
	
	FEMA-356




* 
	
		A Nonlinear Analysis Method for Performance Based Seismic Design
		
			Fajfar
		
	
	
		Journal of Earthquake Spectra
		
			16
			3
			
			2002
		
	




* 
	
		Simplified nonlinear analysis procedure for asymmetric buildings
		
			KFujii
		
		
			YNakano
		
		
			YSanada
		
	
	
		Proc., 13 th World Conference on Earthquake Engineering
				13 th World Conference on Earthquake EngineeringVancouver, Canada
		
			2004
		
	
	Paper No. 149




* 
	
		A pushover procedure for tall buildings
		
			ASMoghadam
		
	
	
		Proc. 12 th European Conference on Earthquake Engineering
				12 th European Conference on Earthquake EngineeringLondon (United Kingdom
		
			Elsevier
			2002
		
	
	Science Ltd;. paper 395




* 
	
		A Consecutive Modal Pushover Procedure for Estimating the Seismic Demands of Tall Building
		
			Poursha
		
	
	
		Journal of Engineering Structures
		
			31
			
			2009
		
	




* 
	
		Assessment of modal pushover analysis procedure and its application to seismic evaluation of existing building
		
			QS KYu
		
		
			RPugliesi
		
		
			MAllen
		
		
			CBischoff
		
	
	
		Proc., 13 th World Conference on Earthquake Engineering
				13 th World Conference on Earthquake EngineeringVancouver, Canada
		
			2004
		
	
	Paper No. 1104




* 
	
		Validation of single storey models for the evaluation of seismic performance of multi-storey asymmetric buildings
		
			AZárate
		
		
			AGAyala
		
	
	
		Proc.,13 th World Conference on Earthquake Engineering
				,13 th World Conference on Earthquake EngineeringVancouver, Canada
		
			2004
		
	
	Paper No. 2213