جستجوی مقالات مرتبط با کلیدواژه « شیروانی » در نشریات گروه « عمران »

Understanding the behavior of the pile group near the slope is an important factor in designing a structure adjacent to the slope. There are very little research on the vertical capacity and efficiency coefficients of pile group near slope, so the study about the behavior of pile group adjacent of the slope is very important. The purpose of this study is to investigate and compare the bearing capacity and efficiency coefficient of vertical pile group under axial loading in the near sandy slopes in two modes of free horizontal movement and no free horizontal pile movement by testing the physical model of pile group. Also in the this study, horizontal force applied to the pile group with free lateral movement is investigated with the FLAC3D software. For this purpose, a series of experiments were performed on the physical model of 2 × 2, 2 × 1, 3 × 1 and 3×3 pile groups adjacent to the dry sandy slope without horizontal displacement and the results were obtained with previous research of other researchers in which the lateral displacement of the pile group has been free, compared. The results of the physical model tests show that the bearing capacity and efficiency coefficient of the pile group is dependent on the pile distance, the pile group configuration, and the liner pile-group direction relative to the slope direction. Also, the results of the physical model tests show that the bearing capacity and efficiency coefficient of the pile group with free lateral movement have higher values than the pile group without lateral movement. Numerical analysis results show that the lateral force applied to the pile group decreases by increasing the spacing of the piles, and the ratio of horizontal force to axial force in the linear pile group decreases with increasing number of piles.

Construction of road foundations or embankments on soft soil bed, due to bearing capacity, usually causes bed rupture with high subsidence. Soil reinforcement using geocell has been proposed by various researchers as a suitable solution. In the present study, experiments have been performed to investigate the behavior of armed slopes by changing the geocell position as well as the change in the percentage of soil moisture. A total of seven laboratory samples were designed and built, and the test program was designed according to two variables. These two variables are reinforcement (geocell) and moisture content. For moisture content, the values of 10%, 15%, and 20% were considered, and the geocell was examined in both the middle, and end modes of the work. The results show the positive performance of Geocell in increasing shear strength, load-bearing and flexural strength, and finally reducing displacement and increasing gable stability. The positive effect of geocell presence can be expressed according to the triple action mechanism of geocell in the reinforced soil mass. The results show that with increasing soil suction with the location of the geocell layer is constant, the displacement changes are reduced by about thirty percent, but by changing the location of the geocell layer (u/h=1 to u/h=0.5) in constant moisture, the amount decreases. Settlement and displacement is about fifteen percent.

The purpose of this research is to investigate the performance and efficiency of reinforced slope in the stability of geocell layers in unsaturated soil conditions. Slope reinforced with geocell, due to the fact that the geocell has a height (three-dimensional), acts as a beam in the soil, and because of its flexural properties, it has a moment of inertia as well as bending strength, which reduces the displacement and increases the coefficient reliability of the slope. Considering unsaturated conditions of soil contributes a lot to make results close to reality. One of the well-known models among elastoplastic mod-els for modeling unsaturated soils is Barcelona's basic model, which has been added to the FLAC2D software by codification. Changes in thickness, length, and the number of geocell layers are remarkably effective on slope stability. The results show that the geocell's reinforcing efficiency depends on the number of layers and the depth of its placement. As the depth of the geocell's first layer increases, the lateral and vertical side elevation of the upper part of the slope increases with respect to the elevation. Load capacity increases with increasing geocell length. By increasing the length of the geocell lay-er, the joint strength, the tensile strength of the mobilized, and the bending moment are increased. Also, by increasing the thickness of the geocell, the amount of moment of the inertia increases, and as a result, the amount of geocell reinforcement bending moment increases.

Location of floating piles is one of the main factors influencing on their optimal performance with respect to slope stability improvement. Many studies have been devoted to this concern using different analytical methods. Due to the importance of this issue in seismic conditions, still more studies are necessary and therefore, the location of floating piles has been investigated in this research using finite element method under seismic conditions. Three parameters including soil arching, crest settlement and pile bending moment has been considered in investigations. Using load transfer factor, soil arching can be suitably quantified and then utilized in numerical analyses. A comprehensive coupled numerical analysis has been carried out in order to examine the optimal location. With the purpose of considering soil's increasing elasticity modulus in depth, a FORTRAN code was developed. To obtain authentic results, modeling has been verified by comparing numerical results with an experimental research which was performed previously. The results showed that the optimal location which causes the highest stability level is the first middle of up-slope (XP/LH = 0.5 - 0.75).

Limit equilibrium method, strength reduction method and Finite Difference Methods are the most prevalently used methods for soil and rock slope stability analysis. However, it can be mention that those have some limitations in practical application. In the Limit equilibrium method, the constitutive model cannot be considered and many assumptions are needed between slices of soil and rock. The strength reduction method requires iterative and continual calculations and does not give the slip surface directly. For slope stability analysis a new method based on the numerical Manifold method and Graph theory is this research developed that can directly calculate the potential critical slip surface and minimum safety factor according to the stress results of numerical simulation. This method is based on current stress state and can overcome the disadvantages mentioned above in those three traditional methods.

In this study, we are using to help optimize the combination of neural networks and genetic algorithms (GA), slip threshold and volume stability of optimal operation Gables earth embankment dams be determined. Also, the stability coefficient of r Gables earth dam with a neural network to determine and outputs Plaxis finite element software has been compared. For neural network training data from 150 models in the earth dam Plaxis finite element software is used. Sustainability analysis to determine confidence gable at the desired level of slip and rupture process of determining the most likely and the least confidence about it, is done, the application of genetic algorithms in this research, the process of determining the most likely slip rupture threshold (minimum coefficient sure) is. Also, another study uses genetic algorithms in optimal amounts of dam embankment operations are such that the minimum safety factor (sliding threshold) is achieved. In this research easier for engineers to use the dimensions proposed, using different Azmshkhsat weir dam in the soil, for different heights and the results of analysis took the form of graphs and tables provided, the use of these charts can be optimized dimensions and volume of concrete Without referring directly to the program won.

Piano Key Weir (PKW) is a flow control structure and it is a developed version of non-linear weirs that has a high discharge capacity, so that, for a specified discharge rate, the flow head above the weir is small, which may increase the likelihood of woody debris collection. In this study, the discharge capacity were investigated through 5 different geometry of the weir with the ratio exit to entrance lengh overhang with the values Bo/Bi=0, 0.5, 1, 1.25 and 1.5 and also the probability of woody debris collection using five models wood ad the location of the critical zone for obstructing the debris in the said weir was studied. The results indicate that increasing the length of the spillway crest increased discharge capacity, so that PKW1.5 than to PKW0 has increase discharge capacity to 26 percent. Also at a constant discharge PKW1.25 than other models in this study is less sensitive to ocllecion. And likelihood of trunk woody debris collection at this model relative to the models with ratios of Bo/Bi=0, 0.5, 1 and 1.5 has 7/18, 2/39, 9/38 and 8/7 percent less respectively. Also in all models most obstruction was occurred in the entrance region of exit keys.

In this study, slope's stability was examined by soil deep mixing method with parametric analyses. To perform the required analyses, the finite element numerical method and PLAXIS software were used, and then the results of this method were compared with the results of limit equilibrium method obtained from Slope/w software. These parameters include the effect of the location of the first row of deep mixing columns along slope foundation, area replacement ratio along foundation slope, length, diameter, coefficient of cohesion, distance between deep mixing columns, position of the water level in the foundation, as well as the effect of the surcharge load. According to the obtained results of the analyzed model with both finite element and limit equilibrium methods, the factor of safety of slope stability constantly increases upon the increase of parameters such as amounts of area replacement ratio, diameter, materials viscosity (cohesion of soil deep mixing materials), length of deep mixing columns, and depth of groundwater level to the level of slope foundation.

S‌o‌i‌l s‌t‌r‌e‌n‌g‌t‌h p‌r‌o‌p‌e‌r‌t‌i‌e‌s a‌r‌e i‌n‌h‌e‌r‌e‌n‌t‌l‌y v‌a‌r‌i‌a‌b‌l‌e, d‌u‌e t‌o t‌h‌e n‌a‌t‌u‌r‌e o‌f t‌h‌e‌i‌r f‌o‌r‌m‌a‌t‌i‌o‌n. S‌l‌o‌p‌e s‌t‌a‌b‌i‌l‌i‌t‌y p‌r‌o‌b‌l‌e‌m‌s a‌r‌e a‌m‌o‌n‌g t‌h‌e m‌o‌s‌t i‌m‌p‌o‌r‌t‌a‌n‌t i‌s‌s‌u‌e‌s i‌n g‌e‌o‌t‌e‌c‌h‌n‌i‌c‌a‌l e‌n‌g‌i‌n‌e‌e‌r‌i‌n‌g, a‌n‌d t‌h‌e‌y a‌r‌e i‌n‌v‌e‌s‌t‌i‌g‌a‌t‌e‌d i‌n t‌h‌i‌s s‌t‌u‌d‌y c‌o‌n‌s‌i‌d‌e‌r‌i‌n‌g t‌h‌e e‌f‌f‌e‌c‌t o‌f h‌e‌t‌e‌r‌o‌g‌e‌n‌e‌i‌t‌y a‌n‌d a‌n‌i‌s‌o‌t‌r‌o‌p‌y o‌f s‌o‌i‌l s‌t‌r‌e‌n‌g‌t‌h p‌r‌o‌p‌e‌r‌t‌i‌e‌s i‌n l‌o‌n‌g t‌e‌r‌m b‌e‌h‌a‌v‌i‌o‌r. T‌o t‌h‌i‌s a‌i‌m, t‌h‌e r‌a‌n‌d‌o‌m f‌i‌e‌l‌d t‌h‌e‌o‌r‌y c‌o‌m‌b‌i‌n‌e‌d w‌i‌t‌h t‌h‌e f‌i‌n‌i‌t‌e d‌i‌f‌f‌e‌r‌e‌n‌c‌e m‌e‌t‌h‌o‌d h‌a‌s b‌e‌e‌n a‌d‌o‌p‌t‌e‌d i‌n t‌h‌e f‌r‌a‌m‌e o‌f M‌o‌n‌t‌e-C‌a‌r‌l‌o s‌i‌m‌u‌l‌a‌t‌i‌o‌n‌s. T‌h‌e f‌a‌c‌t‌o‌r o‌f s‌a‌f‌e‌t‌y o‌f t‌h‌e s‌l‌o‌p‌e h‌a‌s b‌e‌e‌n c‌a‌l‌c‌u‌l‌a‌t‌e‌d b‌y t‌h‌e $C-p‌h‌i$ r‌e‌d‌u‌c‌t‌i‌o‌n m‌e‌t‌h‌o‌d a‌n‌d t‌h‌e p‌r‌o‌b‌a‌b‌i‌l‌i‌t‌y o‌f f‌a‌i‌l‌u‌r‌e h‌a‌s t‌h‌e‌n b‌e‌e‌n i‌n‌v‌e‌s‌t‌i‌g‌a‌t‌e‌d t‌h‌r‌o‌u‌g‌h M‌o‌n‌t‌e-C‌a‌r‌l‌o s‌i‌m‌u‌l‌a‌t‌i‌o‌n‌s. D‌i‌f‌f‌e‌r‌e‌n‌t s‌t‌o‌c‌h‌a‌s‌t‌i‌c p‌a‌r‌a‌m‌e‌t‌e‌r‌s w‌e‌r‌e c‌o‌n‌s‌i‌d‌e‌r‌e‌d i‌n o‌r‌d‌e‌r t‌o s‌t‌u‌d‌y t‌h‌e‌i‌r e‌f‌f‌e‌c‌t o‌n t‌h‌e s‌t‌a‌b‌i‌l‌i‌t‌y o‌f n‌a‌t‌u‌r‌a‌l s‌l‌o‌p‌e‌s i‌n l‌o‌n‌g t‌e‌r‌m s‌c‌h‌e‌m‌e‌s o‌r u‌n‌d‌e‌r d‌r‌a‌i‌n‌e‌d c‌o‌n‌d‌i‌t‌i‌o‌n‌s. T‌h‌e c‌o‌e‌f‌f‌i‌c‌i‌e‌n‌t o‌f v‌a‌r‌i‌a‌t‌i‌o‌n o‌f t‌h‌e c‌o‌h‌e‌s‌i‌o‌n a‌n‌d i‌n‌t‌e‌r‌n‌a‌l f‌r‌i‌c‌t‌i‌o‌n a‌n‌g‌l‌e r‌e‌p‌r‌e‌s‌e‌n‌t‌i‌n‌g s‌t‌r‌e‌n‌g‌t‌h p‌r‌o‌p‌e‌r‌t‌i‌e‌s, s‌c‌a‌l‌e o‌f f‌l‌u‌c‌t‌u‌a‌t‌i‌o‌n o‌f t‌h‌e p‌a‌r‌a‌m‌e‌t‌e‌r‌s, c‌r‌o‌s‌s c‌o‌r‌r‌e‌l‌a‌t‌i‌o‌n b‌e‌t‌w‌e‌e‌n s‌t‌r‌e‌n‌g‌t‌h p‌a‌r‌a‌m‌e‌t‌e‌r‌s a‌n‌d h‌e‌t‌e‌r‌o‌g‌e‌n‌e‌i‌t‌y a‌n‌i‌s‌o‌t‌r‌o‌p‌y, a‌r‌e a‌m‌o‌n‌g a‌l‌l s‌t‌o‌c‌h‌a‌s‌t‌i‌c p‌a‌r‌a‌m‌e‌t‌e‌r‌s i‌n‌v‌e‌s‌t‌i‌g‌a‌t‌e‌d i‌n t‌h‌i‌s s‌t‌u‌d‌y. T‌h‌r‌e‌e d‌i‌f‌f‌e‌r‌e‌n‌t v‌a‌l‌u‌e‌s o‌f 10, 50 a‌n‌d 90 f‌o‌r t‌h‌e C‌o‌V o‌f p‌a‌r‌a‌m‌e‌t‌e‌r‌s w‌e‌r‌e c‌o‌n‌s‌i‌d‌e‌r‌e‌d, i‌n o‌r‌d‌e‌r t‌o c‌o‌v‌e‌r b‌o‌t‌h l‌o‌w a‌n‌d h‌i‌g‌h v‌a‌r‌i‌a‌b‌i‌l‌i‌t‌y. D‌i‌f‌f‌e‌r‌e‌n‌t v‌e‌r‌t‌i‌c‌a‌l c‌o‌r‌r‌e‌l‌a‌t‌i‌o‌n l‌e‌n‌g‌t‌h‌s, r‌a‌n‌g‌i‌n‌g f‌r‌o‌m 0.1 t‌o 50m, a‌r‌e c‌o‌n‌s‌i‌d‌e‌r‌e‌d t‌o c‌o‌v‌e‌r a w‌i‌d‌e r‌a‌n‌g‌e, f‌r‌o‌m f‌u‌l‌l‌y u‌n‌c‌o‌r‌r‌e‌l‌a‌t‌e‌d t‌o f‌u‌l‌l‌y c‌o‌r‌r‌e‌l‌a‌t‌e‌d p‌a‌r‌a‌m‌e‌t‌e‌r‌s. T‌h‌e F‌i‌r‌s‌t O‌r‌d‌e‌r S‌e‌c‌o‌n‌d M‌o‌m‌e‌n‌t (F‌O‌S‌M), t‌h‌e F‌i‌r‌s‌t O‌r‌d‌e‌r R‌e‌l‌i‌a‌b‌i‌l‌i‌t‌y M‌e‌t‌h‌o‌d (F‌O‌R‌M), a‌n‌d t‌h‌e R‌a‌n‌d‌o‌m F‌i‌n‌i‌t‌e D‌i‌f‌f‌e‌r‌e‌n‌c‌e M‌e‌t‌h‌o‌d (R‌F‌D‌M) w‌e‌r‌e a‌d‌o‌p‌t‌e‌d t‌o i‌n‌v‌e‌s‌t‌i‌g‌a‌t‌e t‌h‌e p‌r‌o‌b‌a‌b‌i‌l‌i‌t‌y o‌f f‌a‌i‌l‌u‌r‌e. T‌h‌e l‌a‌t‌t‌e‌r w‌a‌s i‌n‌v‌o‌k‌e‌d b‌y a c‌o‌m‌b‌i‌n‌a‌t‌i‌o‌n o‌f r‌a‌n‌d‌o‌m f‌i‌e‌l‌d t‌h‌e‌o‌r‌y w‌i‌t‌h t‌h‌e f‌i‌n‌i‌t‌e d‌i‌f‌f‌e‌r‌e‌n‌c‌e m‌e‌t‌h‌o‌d t‌h‌r‌o‌u‌g‌h M‌o‌n‌t‌e-C‌a‌r‌l‌o s‌i‌m‌u‌l‌a‌t‌i‌o‌n‌s b‌y F‌I‌S‌H p‌r‌o‌g‌r‌a‌m‌m‌i‌n‌g i‌n F‌L‌A‌C s‌o‌f‌t‌w‌a‌r‌e. T‌h‌e r‌e‌s‌u‌l‌t‌s s‌h‌o‌w t‌h‌a‌t c‌o‌n‌s‌i‌d‌e‌r‌i‌n‌g h‌e‌t‌e‌r‌o‌g‌e‌n‌e‌i‌t‌y c‌a‌u‌s‌e‌s v‌a‌r‌i‌a‌b‌i‌l‌i‌t‌y i‌n r‌e‌s‌u‌l‌t‌s. T‌h‌e c‌o‌e‌f‌f‌i‌c‌i‌e‌n‌t o‌f v‌a‌r‌i‌a‌t‌i‌o‌n a‌n‌d t‌h‌e s‌c‌a‌l‌e o‌f f‌l‌u‌c‌t‌u‌a‌t‌i‌o‌n h‌a‌v‌e b‌e‌e‌n f‌o‌u‌n‌d t‌o h‌a‌v‌e t‌h‌e m‌o‌s‌t e‌f‌f‌e‌c‌t o‌n t‌h‌e p‌r‌o‌b‌a‌b‌i‌l‌i‌t‌y o‌f f‌a‌i‌l‌u‌r‌e. W‌h‌e‌n t‌h‌e c‌o‌e‌f‌f‌i‌c‌i‌e‌n‌t o‌f v‌a‌r‌i‌a‌t‌i‌o‌n o‌f s‌h‌e‌a‌r s‌t‌r‌e‌n‌g‌t‌h p‌a‌r‌a‌m‌e‌t‌e‌r‌s i‌n‌c‌r‌e‌a‌s‌e‌s, t‌h‌e m‌e‌a‌n f‌a‌c‌t‌o‌r o‌f s‌a‌f‌e‌t‌y d‌e‌c‌r‌e‌a‌s‌e‌s, a‌n‌d t‌h‌e p‌r‌o‌b‌a‌b‌i‌l‌i‌t‌y o‌f f‌a‌i‌l‌u‌r‌e i‌n‌c‌r‌e‌a‌s‌e‌s. T‌h‌e v‌e‌r‌t‌i‌c‌a‌l s‌c‌a‌l‌e o‌f f‌l‌u‌c‌t‌u‌a‌t‌i‌o‌n o‌f p‌a‌r‌a‌m‌e‌t‌e‌r‌s i‌n‌d‌u‌c‌e‌s a‌n i‌n‌c‌r‌e‌a‌s‌e i‌n v‌a‌r‌i‌a‌n‌c‌e f‌u‌n‌c‌t‌i‌o‌n, d‌u‌e t‌o i‌t‌s i‌n‌c‌r‌e‌a‌s‌e u‌p t‌o a c‌r‌i‌t‌i‌c‌a‌l v‌a‌l‌u‌e. F‌u‌r‌t‌h‌e‌r‌m‌o‌r‌e, i‌t s‌e‌e‌m‌s t‌h‌a‌t c‌r‌o‌s‌s c‌o‌r‌r‌e‌l‌a‌t‌i‌o‌n h‌a‌s l‌e‌s‌s e‌f‌f‌e‌c‌t o‌n v‌a‌r‌i‌a‌t‌i‌o‌n‌s o‌f t‌h‌e f‌a‌c‌t‌o‌r o‌f s‌a‌f‌e‌t‌y o‌f n‌a‌t‌u‌r‌a‌l s‌l‌o‌p‌e‌s.

S t r u c t u r e s، s u c h a s b u i l d i n g s، w a l l s a n d t o w e r s، a r e o f t e n l o c a t e d o n s l o p i n g g r o u n d، w h i c h m a y i n v o l v e t h e c o n s t r u c t i o n o f s h a l l o w f o u n d a t i o n s a d j a c e n t t o t h e t o p o f t h e s l o p e. T h e l i t e r a t u r e c o n c e r n e d w i t h e v a l u a t i o n o f t h e b e a r i n g c a p a c i t y f a c t o r s o f f o u n d a t i o n s i s m o s t l y l i m i t e d t o h o r i z o n t a l g r o u n d s u r f a c e s، a s w e l l a s s t a t i c c a s e s. A s s e s s m e n t o f t h e s e i s m i c b e a r i n g c a p a c i t y o f s t r i p f o u n d a t i o n s h a s b e e n t h e c o n c e r n o f f e w r e s e a r c h e r s i n t h e f i e l d o f g e o t e c h n i c a l e a r t h q u a k e e n g i n e e r i n g d u r i n g r e c e n t d e c a d e s. T h i s p a p e r p r e s e n t s t h e s e i s m i c b e a r i n g c a p a c i t y f a c t o r s، $ {b f N_{g a m m a}}$،$ {b f N_{q}}$ a n d $ {b f N_{c}}$، o f a r i g i d s t r i p f o u n d a t i o n r e s t i n g a d j a c e n t t o t h e t o p o f a s l o p e، o b t a i n e d b y t h e s t r e s s c h a r a c t e r i s t i c m e t h o d، c o m m o n l y r e f e r r e d t o a s t h e s l i p-l i n e m e t h o d. T h e e f f e c t s o f e a r t h q u a k e s o n b o d y f o r c e s، a s w e l l a s o n o v e r b u r d e n e d s u r c h a r g e s a r e i n c o r p o r a t e d. I t i s a s s u m e d t h a t t h e s o i l b e h a v e s a s r i g i d p e r f e c t l y p l a s t i c a n d o b e y s t h e w e l l k n o w n M o h r-C o u l o m b f a i l u r e c r i t e r i a u n d e r p l a n e s t r a i n c o n d i t i o n s. I t i s a s s u m e d t h a t t h e s t a t e o f s t r e s s e v e r y w h e r e i n t h e n e i g h b o r h o o d o f t h e f o u n d a t i o n i s a t f a i l u r e. I t i s a l s o a s s u m e d t h a t e v e r y w h e r e a l o n g t h e s u r f a c e o f t h e f o u n d a t i o n، t h e r a t i o o f s h e a r t o n o r m a l s t r e s s i s e q u a l t o t h e h o r i z o n t a l e a r t h q u a k e a c c e l e r a t i o n c o e f f i c i e n t ($ {b f k_{h}}$). T h e $ {b f N_{g a m m a}}$ p a r a m e t e r w a s c a l c u l a t e d b a s e d o n t h e b o t h-s i d e s f a i l u r e m e c h a n i s m، w h e r e a s t h e $ {b f N_{q}}$ a n d $ {b f N_{c}}$ p a r a m e t e r s w e r e c a l c u l a t e d b a s e d o n t h e s i n g l e-s i d e f a i l u r e m e c h a n i s m. T h e $ {b f N_{c}}$ p a r a m e t e r f o r c o h e s i v e m e d i a w a s c a l c u l a t e d u s i n g t h e r u l e o f e q u i v a l e n t s t a t e s. S o m e g r a p h s a n d t a b l e s a r e p r e s e n t e d t h a t c o u l d b e u s e d i n o r d e r t o a s s e s s t h e s e i s m i c b e a r i n g c a p a c i t y f a c t o r s o f f o u n d a t i o n s r e s t i n g a d j a c e n t t o t h e t o p o f a s l o p e، e v a l u a t e d b y t h e s t r e s s c h a r a c t e r i s t i c m e t h o d. I t i s s h o w n t h a t a l l s e i s m i c b e a r i n g c a p a c i t y f a c t o r s r e d u c e c o n s i d e r a b l y w i t h a n i n c r e a s e i n e i t h e r g r o u n d i n c l i n a t i o n o r i n $ {b f k_{h}}$. I t i s a l s o s h o w n t h a t i n w e i g h t y m e d i a، t h e s e i s m i c b e a r i n g c a p a c i t y o f a f o u n d a t i o n a d j a c e n t t o t h e t o p o f a s l o p e i s l e s s c o m p a r e d t o t h e o n e r e s t i n g o n a s i m i l a r i n f i n i t e s l o p e، w h e r e a s، i n w e i g h t-l e s s m e d i a، i t i s e q u a l. T h e v a l u e s o f t h e s e i s m i c b e a r i n g c a p a c i t y f a c t o r s c a l c u l a t e d b y t h e s t r e s s c h a r a c t e r i s t i c m e t h o d a r e c o m p a r e d w i t h t h o s e o b t a i n e d b y t h e u p p e r b o u n d t h e o r e m r e p o r t e d i n t h e l i t e r a t u r e. I t i s o b s e r v e d t h a t t h e s t r e s s c h a r a c t e r i s t i c m e t h o d g i v e s l o w e r v a l u e s o f s e i s m i c b e a r i n g c a p a c i t y f a c t o r s t h a n t h o s e e s t i m a t e d b y t h e u p p e r b o u n d t h e o r e m.