Basal reinforcement
Indian Geotechnical Conference – 2010, GEOtrendz
December 16–18, 2010
IGS Mumbai Chapter & IIT Bombay
Pseudo-static Seismic Stability of Basal Reinforced
Embankment with Oblique Pull
Chakravarthi, V.K.
Ramu, K.1
Associate Professor e-mail: vkchakravarthi@yahoo.com
Associate Professor e-mail: ramu_k@lycos.com
Department of Civil Engineering, GMR Institute of Technology, Rajam
1
Department of Civil Engineering, JNTU Kakinada, Kakinada
ABSTRACT
Seismic stability of embankments on soft soils has been addressed by many researchers in the past with approximation for pseudo-static condition with and without reinforcement but based on consideration of axial pull in the reinforcement. The kinematics of deformation of typical failure of reinforced embankment dictates oblique pull in the reinforcement due to sliding mass. This oblique pull mobilizes additional normal stresses resulting in higher shear resistance and addition normal force than mobilized with consideration of axial pull only. This paper analyses seismic stability with oblique pull for a basal reinforced embankment on non-homogeneous soft soil based on pseudo-static approach. Results indicate that the stability of the embankment is underestimated in the conventional approach that uses axial pull.
1. INTRODUCTION
Stability is a concern for embankments on soft ground because of the low strength of the foundation soil. A layer of geosynthetics material extending for the full width of the embankment is provided in basal reinforced embankments at the interface of the embankment and ground. The basal reinforcement resists some or all of the destabilizing forces and restricts the lateral deformations of the foundation
(Jewell 1988).
Stability of Geosynthetic - Reinforced Embankment on Non-homogeneous Soils
Limit equilibrium methods developed have been used to assess short term (undrained) stability of reinforced embankments constructed on soft foundations .Geometry of embankment and thickness of soft soil, drainage conditions, rate of construction of embankment, strain in and tensile strength of reinforcement, type of soil, etc. influence the stability of the embankment (Rowe et al.
2005).
Seismic Stability of Embankments
Pseudo-static and pseudo-dynamic analyses are commonly adopted for analyzing stability of embankments under seismic conditions. In pseudo-static analysis the earthquake induced forces (inertia forces) are represented by a constant horizontal/ vertical force equal to the weight of the potential
sliding mass multiplied by a non-dimensional seismic coefficients, kh and kv (Ling et al.1997). Pseudo-dynamic analysis is carried-out considering the phase difference in shear and primary waves (Nimbalkar et al. 2006). These studies are limited to internal stability without considering displacement and reduction of soil strength.
2. KINEMATICS OF REINFORCEMENTBACKFILL RESPONSE -OBLIQUE PULL
Kinematics of deformation (Fig. 1) dictates typical failure of reinforced soil structures. At failure of soil mass the reinforcement is subjected to pull. Almost all the available design methods incorporate only the axial pullout mechanism (Fig. 2). However, in actual case at failure reinforcement is subjected oblique pull (Fig. 3). Under the action of oblique force or displacement, the soil beneath the reinforcement mobilizes additional normal stresses as the reinforcement deforms transversely. Madhav and
Umashanker (2003, 2005) developed the governing equations for linear and nonlinear sub grade responses.
Normalized normal component of tensile force in the reinforcement is computed for normalized free end displacement ratios ranging from 0 to 0.1. The contribution of oblique pull in reinforcement on the stability of geosynthetic reinforced wall is quantified by Narasimha
Reddy et al. (2008).
246
V.K. Chakravarthi and K. Ramu
Fig.1: Kinematics of Reinforcement - Soil Interaction
Fig. 4: Embankment on Non-homogeneous Ground
Table 1: Embankment Properties
Parameter
Top width
Bottom width
Side slope (1:n)
Height of embankment, He
Range
20 m
38 m
1:2
4.5 m
Table 2: Embankment Fill Properties
Fig. 2: Horizontal Pullout Force
Parameter ce φe
Unit weight, γe
Range
-370
20 kN/m3
Table 3: Foundation Soil Properties
Parameter
Thickness H cu(0) φ
Unit weight, γ
Fig. 3: Postulated Shape of Reinforcement Adjacent to the
Failure Surface (After Gourc et al. 1986)
3. PROBLEM STATEMENT AND ANALYSIS
A basal reinforced embankment of height, H, equal to 4.5 m rests on non-homogeneous foundation soil 10 m thick.
The non-homogeneity of foundation soil is expressed with its strength increasing with depth, z, as cu(z) = cu(0){1+ αz/
H} where cu(z), cu(0) and á are the undrained strength at any depth z, undrained strength at the top, and nonhomogeneity parameter respectively. Stability of the embankment is computed with reinforcement tensile capacity, ‘T’ available at the fill-foundation soil interface for the full base width. Seismic conditions under different acceleration coefficients are considered. GeoSlope program using Bishop’s method is used to compute the factor of safety and to identify critical slip circle for both unreinforced and reinforced embankment considering only axial force in the reinforcement. Cross-section of the embankment and the ranges of properties considered are given in Figure 4 and
Tables 1-5.
Range
10 m
25 kPa
-17 kN/cu.m
Non-homogeneity Parameter, α
Modulus of subgrade reaction,
Ks
0, 0.5 & 1 kPa/m
5000 kN/m3
Table 4: Reinforcement Details
Parameter
Range
Location
interface of fill and ground
Length
entire base
Tensile capacity(T)
100 kN/m
Transfer efficiency
100%
370
Interface friction, φr
Table 5: Seismic Coefficients
Parameter
Range
0, 0.05, 0.1, 0.15
Horizontal coefficient, αh
0.5
αv/αh
Analysis for Basal Reinforcement - Transverse Pull
As shown in Figure 5, the geosynthetics layer, at the intersection with slip surface, deforms at an oblique angle α due to kinematics. The vertical component of the force, T,
Pseudo-static Seismic Stability of Basal Reinforced Embankment with Oblique Pull
causes transverse displacement, while the horizontal component is the axial pullout. This vertical component of
T, i.e., the normal reaction develops additional normal stresses on the reinforcement.
Fig. 5: Kinematics of Basal Reinforced Embankment
The transverse downward force at the end B (Fig. 6) in the normalized form is (Madhav & Manoj 2003)
P• =
w 1 W + 1 n
P
=µ o 1
+ ∑ Wi
L n 2 γDL i =2
(1)
The horizontal component of maximum tension (i.e. the pullout force) is non-dimensionalised as
247
with slip surface, effective length of reinforcement, Le , transverse force and additional axial force are computed.
For various rotations ranging from 0.001rad to 0.01 rad normalized transverse displacements, wol and transverse force, P, are computed from the expressions given above.
Additional axial force due to P will be obtained as 2P tan
Φ r for double shear. Additional resisting moments due to these forces are computed from the lever arm with respect to center. The following are the notations used for different factors of safety along with their computations:
Fsu - Factor of safety for unreinforced embankment.
Fsc - Factor of safety for reinforced embankment with conventional axial pull.
Fs (Addi. Axial), FsA = (MR + MA) / MD
Fs (Addi. Axial+ Transverse), FsAP = (MR + MA+ MP) / MD where MR = Resisting moment developed with conventional axial pull; MA = Resisting moment with addi. Axial force;
MP = Resisting moment with addi. Axial+ Transverse force; and MD = Driving moment developed with axial pull.
4. RESULTS AND DISCUSSION
The variations of Fsu, Fsc, FsA & FsAP with seismic coefficient kh are shown in Figures 8 and 9. To quantify the effect of oblique pull over conventional axial pull, ratios, Rf, as defined below are computed and the results shown in Figure 10.
RfT = FsA/ Fsc RfTP = FsAP/ Fsc
Rfoblique = FsAP/Fsu Rfa = FsA/ Fsu
Fig. 6: Definition Sketch for Transverse Pull
(Madhav and Manoj 2003)
Fig. 8: Fs variation with kh- Effect of Non-homogeneity
Fig. 7: Equilibrium of Elements
•
Tmax cos θ n +1 =
Tn +1 cos θ n +1
= Tn•+1 cos θ n +1
2γDL tan φr
(2)
The normalized normal component of maximum tension is •
Tmax sin θ n +1 =
Tn +1 sin θ n +1
= 2Tn•+1 sin θ n +1 tan φr γDL (3)
Computations of Factors of Safety with Transverse Pull
(Fig. 7).
For the critical circle in axial pullout case knowing the geometry of slip circle, intersection point of reinforcement
Fig. 9: Variation of Fs with kh- Effect of Rotation for α=0
248
The variation of factors of safeties with the horizontal seismic coefficient is presented in Figures 8 and 9. From
Figure 8, it is observed that due to seismic effect, the factor of safety for unreinforced embankment on homogeneousground decreases from 1.56 to 0.86 and from
1.66 to 0.94 & 1.74 to 1.01 respectively for nonhomogeneous ground for α equal to 0.5 and 1.0. The effect of non-homogeneity factor α on Fs is considerable. Fs
(unreinforced) increases from 1.563 to 1.73 due to increase of α from 0 to 1.0. Similar trend is observed for reinforced embankment also.
The effect of oblique pull on Fs is evident from Figure
9 for both static and seismic cases. Fs increases significantly with rotation. The increase in Fs with rotation is because of mobilization of larger forces in the reinforcement. For homogeneous soil under static condition FsA increases from
1.671 to 2.19 while FsAP increases from 1.67 to 2.63. Similar trend is observed for increasing α value. Similar trend is observed for seismic condition also.
Figure 10 details the quantification of oblique pull over conventional axial pull. Due to oblique pull Fs increases up to 1.3 to 1.6 times over Fs considering axial pull and 1.07 to
1.7 than that for unreinforced case.
Fig. 10: Variation of Rf with kh α =0, Rotation = 0.01rad.
5. CONCLUSIONS
In the present work a comparative study is made between conventional factor of safety with axial pull, Fsc and factor of safety with increase in tension due to oblique force, FsA, and FsAP. The effect of oblique pull in reinforcement is quantified through Fs values and ratios, Rf. It can be concluded that;
V.K. Chakravarthi and K. Ramu
(i) The induced oblique force in reinforcement contributes to increase of Fs over conventional axial pull. An increase of 1.3 to 1.7 times axial pull is observed with oblique pull.
(ii) The effect of seismic coefficient on Fs ratio Rf is almost linear and marginal. The transverse force contribution is significant over additional axial force. REFERENCES
Gourc, J.P., Ratel, A. and Delmas, P. (1986). Design of fabric retaining walls: The displacement method. Proc. 3rd Int.
Conf. on Geotextiles, Geomembranes and other
Products, Vienna, II, 289-294.
Jewell, R. A. (1988). The mechanics of reinforced embankments on soft soils. Geotextiles and
Geomembranes, 7, 237–273.
Ling, H.I., Leshchinsky, D. and Perry, E.B. (1997). Seismic
Design and Performance of Geosynthetic-Reinf. Soil
Structures, Géotechnique, 47(5), 933 –952.
Manoj, T. P. (2003). Response of Sheet reinforcement to Large Transverse force/Displacement, M.Tech. Thesis,
IIT Kanpur.
Madhav, M.R. and Umashankar, B. (2003). Analysis of inextensible sheet reinforcement subjected to transverse displacement/force: linear subgrade response, Geotext.
& Geomembranes, 21, 69-84.
Madhav, M.R. and Umashankar, B. (2005). Analysis of inextensible sheet reinforcement subjected to transverse displacement/pull, Journal of South East Asian
Geotechnical Society, 133-143.
Narasimha Reddy, G.V., Madhav, M. R. and Saibaba Reddy,
E. (2008). Pseudo- static seismic analysis of reinforced soil wall - effect of oblique displacement, Geotextile and Geomembranes, 26(5), 393-403.
Nimbalkar, S.S, Choudary, D. and Mandal, J.N. (2006).
Seismic stability of reinforced soil-wall by Pseudo dynamic method, Geosynthetic Int., 13(3), 111-119.
Rowe, R.K. and Li, L.L. (2005). Geosynthetic-reinforced embankments over soft foundations. Geosynthetics
International, Special Issue on the Giroud Lectures,
12(1), 50–85.
References: Gourc, J.P., Ratel, A. and Delmas, P. (1986). Design of fabric retaining walls: The displacement method Jewell, R. A. (1988). The mechanics of reinforced embankments on soft soils Ling, H.I., Leshchinsky, D. and Perry, E.B. (1997). Seismic Design and Performance of Geosynthetic-Reinf Manoj, T. P. (2003). Response of Sheet reinforcement to Large Transverse force/Displacement, M.Tech Madhav, M.R. and Umashankar, B. (2003). Analysis of inextensible sheet reinforcement subjected to transverse Madhav, M.R. and Umashankar, B. (2005). Analysis of inextensible sheet reinforcement subjected to transverse Nimbalkar, S.S, Choudary, D. and Mandal, J.N. (2006). Rowe, R.K. and Li, L.L. (2005). Geosynthetic-reinforced embankments over soft foundations
December 16–18, 2010
IGS Mumbai Chapter & IIT Bombay
Pseudo-static Seismic Stability of Basal Reinforced
Embankment with Oblique Pull
Chakravarthi, V.K.
Ramu, K.1
Associate Professor e-mail: vkchakravarthi@yahoo.com
Associate Professor e-mail: ramu_k@lycos.com
Department of Civil Engineering, GMR Institute of Technology, Rajam
1
Department of Civil Engineering, JNTU Kakinada, Kakinada
ABSTRACT
Seismic stability of embankments on soft soils has been addressed by many researchers in the past with approximation for pseudo-static condition with and without reinforcement but based on consideration of axial pull in the reinforcement. The kinematics of deformation of typical failure of reinforced embankment dictates oblique pull in the reinforcement due to sliding mass. This oblique pull mobilizes additional normal stresses resulting in higher shear resistance and addition normal force than mobilized with consideration of axial pull only. This paper analyses seismic stability with oblique pull for a basal reinforced embankment on non-homogeneous soft soil based on pseudo-static approach. Results indicate that the stability of the embankment is underestimated in the conventional approach that uses axial pull.
1. INTRODUCTION
Stability is a concern for embankments on soft ground because of the low strength of the foundation soil. A layer of geosynthetics material extending for the full width of the embankment is provided in basal reinforced embankments at the interface of the embankment and ground. The basal reinforcement resists some or all of the destabilizing forces and restricts the lateral deformations of the foundation
(Jewell 1988).
Stability of Geosynthetic - Reinforced Embankment on Non-homogeneous Soils
Limit equilibrium methods developed have been used to assess short term (undrained) stability of reinforced embankments constructed on soft foundations .Geometry of embankment and thickness of soft soil, drainage conditions, rate of construction of embankment, strain in and tensile strength of reinforcement, type of soil, etc. influence the stability of the embankment (Rowe et al.
2005).
Seismic Stability of Embankments
Pseudo-static and pseudo-dynamic analyses are commonly adopted for analyzing stability of embankments under seismic conditions. In pseudo-static analysis the earthquake induced forces (inertia forces) are represented by a constant horizontal/ vertical force equal to the weight of the potential
sliding mass multiplied by a non-dimensional seismic coefficients, kh and kv (Ling et al.1997). Pseudo-dynamic analysis is carried-out considering the phase difference in shear and primary waves (Nimbalkar et al. 2006). These studies are limited to internal stability without considering displacement and reduction of soil strength.
2. KINEMATICS OF REINFORCEMENTBACKFILL RESPONSE -OBLIQUE PULL
Kinematics of deformation (Fig. 1) dictates typical failure of reinforced soil structures. At failure of soil mass the reinforcement is subjected to pull. Almost all the available design methods incorporate only the axial pullout mechanism (Fig. 2). However, in actual case at failure reinforcement is subjected oblique pull (Fig. 3). Under the action of oblique force or displacement, the soil beneath the reinforcement mobilizes additional normal stresses as the reinforcement deforms transversely. Madhav and
Umashanker (2003, 2005) developed the governing equations for linear and nonlinear sub grade responses.
Normalized normal component of tensile force in the reinforcement is computed for normalized free end displacement ratios ranging from 0 to 0.1. The contribution of oblique pull in reinforcement on the stability of geosynthetic reinforced wall is quantified by Narasimha
Reddy et al. (2008).
246
V.K. Chakravarthi and K. Ramu
Fig.1: Kinematics of Reinforcement - Soil Interaction
Fig. 4: Embankment on Non-homogeneous Ground
Table 1: Embankment Properties
Parameter
Top width
Bottom width
Side slope (1:n)
Height of embankment, He
Range
20 m
38 m
1:2
4.5 m
Table 2: Embankment Fill Properties
Fig. 2: Horizontal Pullout Force
Parameter ce φe
Unit weight, γe
Range
-370
20 kN/m3
Table 3: Foundation Soil Properties
Parameter
Thickness H cu(0) φ
Unit weight, γ
Fig. 3: Postulated Shape of Reinforcement Adjacent to the
Failure Surface (After Gourc et al. 1986)
3. PROBLEM STATEMENT AND ANALYSIS
A basal reinforced embankment of height, H, equal to 4.5 m rests on non-homogeneous foundation soil 10 m thick.
The non-homogeneity of foundation soil is expressed with its strength increasing with depth, z, as cu(z) = cu(0){1+ αz/
H} where cu(z), cu(0) and á are the undrained strength at any depth z, undrained strength at the top, and nonhomogeneity parameter respectively. Stability of the embankment is computed with reinforcement tensile capacity, ‘T’ available at the fill-foundation soil interface for the full base width. Seismic conditions under different acceleration coefficients are considered. GeoSlope program using Bishop’s method is used to compute the factor of safety and to identify critical slip circle for both unreinforced and reinforced embankment considering only axial force in the reinforcement. Cross-section of the embankment and the ranges of properties considered are given in Figure 4 and
Tables 1-5.
Range
10 m
25 kPa
-17 kN/cu.m
Non-homogeneity Parameter, α
Modulus of subgrade reaction,
Ks
0, 0.5 & 1 kPa/m
5000 kN/m3
Table 4: Reinforcement Details
Parameter
Range
Location
interface of fill and ground
Length
entire base
Tensile capacity(T)
100 kN/m
Transfer efficiency
100%
370
Interface friction, φr
Table 5: Seismic Coefficients
Parameter
Range
0, 0.05, 0.1, 0.15
Horizontal coefficient, αh
0.5
αv/αh
Analysis for Basal Reinforcement - Transverse Pull
As shown in Figure 5, the geosynthetics layer, at the intersection with slip surface, deforms at an oblique angle α due to kinematics. The vertical component of the force, T,
Pseudo-static Seismic Stability of Basal Reinforced Embankment with Oblique Pull
causes transverse displacement, while the horizontal component is the axial pullout. This vertical component of
T, i.e., the normal reaction develops additional normal stresses on the reinforcement.
Fig. 5: Kinematics of Basal Reinforced Embankment
The transverse downward force at the end B (Fig. 6) in the normalized form is (Madhav & Manoj 2003)
P• =
w 1 W + 1 n
P
=µ o 1
+ ∑ Wi
L n 2 γDL i =2
(1)
The horizontal component of maximum tension (i.e. the pullout force) is non-dimensionalised as
247
with slip surface, effective length of reinforcement, Le , transverse force and additional axial force are computed.
For various rotations ranging from 0.001rad to 0.01 rad normalized transverse displacements, wol and transverse force, P, are computed from the expressions given above.
Additional axial force due to P will be obtained as 2P tan
Φ r for double shear. Additional resisting moments due to these forces are computed from the lever arm with respect to center. The following are the notations used for different factors of safety along with their computations:
Fsu - Factor of safety for unreinforced embankment.
Fsc - Factor of safety for reinforced embankment with conventional axial pull.
Fs (Addi. Axial), FsA = (MR + MA) / MD
Fs (Addi. Axial+ Transverse), FsAP = (MR + MA+ MP) / MD where MR = Resisting moment developed with conventional axial pull; MA = Resisting moment with addi. Axial force;
MP = Resisting moment with addi. Axial+ Transverse force; and MD = Driving moment developed with axial pull.
4. RESULTS AND DISCUSSION
The variations of Fsu, Fsc, FsA & FsAP with seismic coefficient kh are shown in Figures 8 and 9. To quantify the effect of oblique pull over conventional axial pull, ratios, Rf, as defined below are computed and the results shown in Figure 10.
RfT = FsA/ Fsc RfTP = FsAP/ Fsc
Rfoblique = FsAP/Fsu Rfa = FsA/ Fsu
Fig. 6: Definition Sketch for Transverse Pull
(Madhav and Manoj 2003)
Fig. 8: Fs variation with kh- Effect of Non-homogeneity
Fig. 7: Equilibrium of Elements
•
Tmax cos θ n +1 =
Tn +1 cos θ n +1
= Tn•+1 cos θ n +1
2γDL tan φr
(2)
The normalized normal component of maximum tension is •
Tmax sin θ n +1 =
Tn +1 sin θ n +1
= 2Tn•+1 sin θ n +1 tan φr γDL (3)
Computations of Factors of Safety with Transverse Pull
(Fig. 7).
For the critical circle in axial pullout case knowing the geometry of slip circle, intersection point of reinforcement
Fig. 9: Variation of Fs with kh- Effect of Rotation for α=0
248
The variation of factors of safeties with the horizontal seismic coefficient is presented in Figures 8 and 9. From
Figure 8, it is observed that due to seismic effect, the factor of safety for unreinforced embankment on homogeneousground decreases from 1.56 to 0.86 and from
1.66 to 0.94 & 1.74 to 1.01 respectively for nonhomogeneous ground for α equal to 0.5 and 1.0. The effect of non-homogeneity factor α on Fs is considerable. Fs
(unreinforced) increases from 1.563 to 1.73 due to increase of α from 0 to 1.0. Similar trend is observed for reinforced embankment also.
The effect of oblique pull on Fs is evident from Figure
9 for both static and seismic cases. Fs increases significantly with rotation. The increase in Fs with rotation is because of mobilization of larger forces in the reinforcement. For homogeneous soil under static condition FsA increases from
1.671 to 2.19 while FsAP increases from 1.67 to 2.63. Similar trend is observed for increasing α value. Similar trend is observed for seismic condition also.
Figure 10 details the quantification of oblique pull over conventional axial pull. Due to oblique pull Fs increases up to 1.3 to 1.6 times over Fs considering axial pull and 1.07 to
1.7 than that for unreinforced case.
Fig. 10: Variation of Rf with kh α =0, Rotation = 0.01rad.
5. CONCLUSIONS
In the present work a comparative study is made between conventional factor of safety with axial pull, Fsc and factor of safety with increase in tension due to oblique force, FsA, and FsAP. The effect of oblique pull in reinforcement is quantified through Fs values and ratios, Rf. It can be concluded that;
V.K. Chakravarthi and K. Ramu
(i) The induced oblique force in reinforcement contributes to increase of Fs over conventional axial pull. An increase of 1.3 to 1.7 times axial pull is observed with oblique pull.
(ii) The effect of seismic coefficient on Fs ratio Rf is almost linear and marginal. The transverse force contribution is significant over additional axial force. REFERENCES
Gourc, J.P., Ratel, A. and Delmas, P. (1986). Design of fabric retaining walls: The displacement method. Proc. 3rd Int.
Conf. on Geotextiles, Geomembranes and other
Products, Vienna, II, 289-294.
Jewell, R. A. (1988). The mechanics of reinforced embankments on soft soils. Geotextiles and
Geomembranes, 7, 237–273.
Ling, H.I., Leshchinsky, D. and Perry, E.B. (1997). Seismic
Design and Performance of Geosynthetic-Reinf. Soil
Structures, Géotechnique, 47(5), 933 –952.
Manoj, T. P. (2003). Response of Sheet reinforcement to Large Transverse force/Displacement, M.Tech. Thesis,
IIT Kanpur.
Madhav, M.R. and Umashankar, B. (2003). Analysis of inextensible sheet reinforcement subjected to transverse displacement/force: linear subgrade response, Geotext.
& Geomembranes, 21, 69-84.
Madhav, M.R. and Umashankar, B. (2005). Analysis of inextensible sheet reinforcement subjected to transverse displacement/pull, Journal of South East Asian
Geotechnical Society, 133-143.
Narasimha Reddy, G.V., Madhav, M. R. and Saibaba Reddy,
E. (2008). Pseudo- static seismic analysis of reinforced soil wall - effect of oblique displacement, Geotextile and Geomembranes, 26(5), 393-403.
Nimbalkar, S.S, Choudary, D. and Mandal, J.N. (2006).
Seismic stability of reinforced soil-wall by Pseudo dynamic method, Geosynthetic Int., 13(3), 111-119.
Rowe, R.K. and Li, L.L. (2005). Geosynthetic-reinforced embankments over soft foundations. Geosynthetics
International, Special Issue on the Giroud Lectures,
12(1), 50–85.
References: Gourc, J.P., Ratel, A. and Delmas, P. (1986). Design of fabric retaining walls: The displacement method Jewell, R. A. (1988). The mechanics of reinforced embankments on soft soils Ling, H.I., Leshchinsky, D. and Perry, E.B. (1997). Seismic Design and Performance of Geosynthetic-Reinf Manoj, T. P. (2003). Response of Sheet reinforcement to Large Transverse force/Displacement, M.Tech Madhav, M.R. and Umashankar, B. (2003). Analysis of inextensible sheet reinforcement subjected to transverse Madhav, M.R. and Umashankar, B. (2005). Analysis of inextensible sheet reinforcement subjected to transverse Nimbalkar, S.S, Choudary, D. and Mandal, J.N. (2006). Rowe, R.K. and Li, L.L. (2005). Geosynthetic-reinforced embankments over soft foundations