In theoretical mechanics field, solution methods for nonlinear differential equations are very important because many problems are modelled using such equations. In particular, large deflection of a cantilever beam under a terminal follower force and nonlinear pendulum problem can be described by the same nonlinear differential equation. Therefore, in this work, we propose some approximate solutions for both problems using nonlinearities distribution homotopy perturbation method, homotopy perturbation method, and combinations with Laplace-Padé posttreatment. We will show the high accuracy of the proposed cantilever solutions, which are in good agreement with other reported solutions. Finally, for the pendulum case, the proposed approximation was useful to predict, accurately, the period for an angle up to 179.99999999∘ yielding a relative error of 0.01222747.
1. Introduction
Solving nonlinear differential equations is an important issue in science because many physical phenomena are modelled using such equations. During last century, the approximate solution of such equations was a task performed by hand using methods like the perturbation method. Nowadays, symbolic software like Maple or Mathematica allow researchers to calculate highly accurate approximate solutions using new methods like the homotopy perturbation method (HPM) [1–38]. The HPM method is one of the most famous analytic techniques for nonlinear differential equations, which is widely applied in science and engineering.
In [28, 39] was reported the nonlinearities distribution homotopy perturbation method (NDHPM) as an extended version of HPM that allows the distribution of the nonlinearities between the different iterations of HPM method. The main advantage of this process is the increase in the number of possible iterations by constructing easier to solve linear equations for HPM procedure. Additionally, several works reported that a Laplace-Padé posttreatment [40–49] of power series solutions obtained by HPM can improve accuracy and convergence to the exact solution. Therefore, in this work, we propose the use of the aforementioned methods to obtain approximate solutions for two nonlinear problems, related by to same nonlinear differential equation. The first one is the large deflection of a cantilever beam under a terminal follower force [50–55]. This kind of structures arises in marine riser and other practical applications of civil engineering. The mathematical formulation of such a problem yields a nonlinear two-point boundary-value problem, which usually can be solved by numerical methods [50]. The second one is the nonlinear pendulum problem [56–58], which is modelled by the same equation of the Cantilever’s case study. The pendulum or systems containing the pendulums are well-studied complex phenomen [59]. For both problems, the results exhibited high accuracy using our proposed solutions, which are in good agreement to the results reported by other works. In particular, for the pendulum case, we succeeded to predict, accurately, the period until an initial angle up to 179.99999999° achieving a relative error of 0.01222747.
This paper is organized as follows. In Section 2, the basic idea of the HPM method is provided. We give an introduction to NDHPM method in Section 3. In Section 4, the basic concept of Padé approximants is explained. The Laplace-Padé coupling with NDHPM and HPM methods is presented in Section 5. In Sections 6 and 7, the cantilever and pendulum problems are solved, respectively. In addition, a discussion on the results is presented in Section 8. Finally, a brief conclusion is given in Section 9.
2. Basic Concept of HPM
It can be considered that a nonlinear differential equation can be expressed as
(1)A(u)-f(r)=0,wherer∈Ω,
having boundary condition as
(2)B(u,∂u∂η)=0,wherer∈Γ,
where A is a general differential operator, f(r) is a known analytic function, B is a boundary operator, Γ is the boundary of domain Ω, and ∂u/∂η denotes differentiation along the normal drawn outwards from Ω [50]. The A operator, generally, can be divided into two operators, L and N, which are linear and nonlinear operators, respectively. Hence, (1) can be rewritten as
(3)L(u)+N(u)-f(r)=0.
Now, a possible homotopy formulation is
(4)H(v,p)=(1-p)[L(v)-L(u0)]+p(L(v)+N(v)-f(r))=0,p∈[0,1],
where u0 is the initial approximation for (3) which satisfies the boundary conditions and p is known as the perturbation homotopy parameter.
For the HPM method [4–7], we assume that the solution for (4) can be written as a power series of p(5)v=p0v0+p1v1+p2v2+⋯.
Considering that p→1, results that the approximate solution of (1) is
(6)u=limp→1v=v0+v1+v2+⋯.
The series (6) is convergent on most cases as reported in [4, 7, 20, 21].
3. HPM Method with Nonlinearities Distribution
Recent reports [28, 39] have introduced the NDHPM method, which eases the searching process of solutions for (3) and reduces the complexity of solving differential equations. As first step, a modified homotopy is introduced:
(7)H(v,p)=(1-p)[L(v)-L(u0)]+p(L(v)+N(v,p)-f(r,p))=0,p∈[0,1].
It can be noticed that the homotopy function (7) is essentially the same as (4), except for the nonlinear operator N and the nonhomogeneous function f, which embeds the homotopy parameter p. The arbitrary introduction of p within the differential equation is a strategy to redistribute the nonlinearities between the successive iterations of the HPM method and, thus, increase the probabilities of finding the sought solution.
Again, we establish that
(8)v=∑i=0∞vipi.
Considering that p→1 turns out that the approximate solution for (1) is
(9)u=limp→1v=∑i=0∞vi.
The convergence of the NDHPM method is exposed in [28].
4. Padé Approximants
A rational approximation to f(x) on [a,b] is the quotient of two polynomials PN(x) and QM(x) of degrees N and M, respectively. We use the notation RN,M(x) to denote this quotient. The RN,M(x) Padé approximations to a function f(x) are given by [49, 60]
(10)RN,M=PN(x)QM(x),fora≤x≤b.
The method of Padé requires that f(x) and its derivative should be continuous at x=0. The polynomials used in (10) are
(11)PN(x)=p0+p1x+p2x2+⋯+pN(x),QM(x)=q0+q1x+q2x2+⋯+qM(x).
The polynomials in (11) are constructed so that f(x) and RN,M(x) agree at x=0 and their derivatives up to N+M agree at x=0. For the case where Q0(x)=1, the approximation is just the Maclaurin expansion for f(x). For a fixed value of N+M the error is the smallest when PN(x) and QM(x) have the same degree or when PN(x) has a degree higher than QM(x).
Notice that the constant coefficient of QM is q0-1. This is permissible because it can be noted that 0 and RN,M(x) are not changed when both PN(x) and QM(x) are divided by the same constant. Hence, the rational function RN,M(x) has N+M+1 unknown coefficients. Assume that f(x) is analytic and has the Maclaurin expansion
(12)f(x)=a0+a1x+a2x2+⋯+akxk+⋯.
And, from the difference f(x)QM(x)-PN(x)=Z(x)(13)⌈∑i=0∞aixi⌉⌈∑i=0Mqixi⌉-⌈∑i=0Npixi⌉=⌈∑i=N+M+1∞cixi⌉.
The lower index j=N+M+1 in the summation at the right side of (13) is chosen because the first N+M derivatives of f(X) and RN,M(x) should agree at x=0.
When the left side of (13) is multiplied out and coefficients of the powers of xi are set equal to zero for k=0,1,2,…,N+M, this results in a system of N+M+1 linear equations:
(14)a0-p0=0,q1a0+a1-p1=0,q2a0+q1a1+a2-p2=0,q3a0+q2a1+q1a2+a3-p3=0,qMaN-M|qM-1aN-M-1|aN-pN=0,(15)qMaN-M+1+qM-1aN-M+2+⋯+q1aN+aN+2=0,qMaN-M+2+qM-1aN-M+3+⋯+q1aN+1+aN+3=0,⋮qMaN+qMaN+1+⋯+q1aN+M+1+aN+M=0.
Notice that in each equation the sum of the subscripts on the factors of each product is the same, and this sum increases consecutively from 0 to N+M. The M equations in (15) involve only the unknowns q1,q2,…,qM and must be solved first. Then, the equations in (14) are successively used to find p1,p2,…,pN [49].
5. Laplace-Padé Posttreatment of Power Series Solutions
The coupling of Laplace transform and Padé approximant [40] is used to deal with the lost information of truncated power series [41–49]. The process can be summarized as follows.
First, Laplace transformation is applied to a power series solution obtained by HPM or NDHPM methods.
Next, 1/t is written in place of s.
Afterwards, we convert the transformed series into a meromorphic function by forming its Padé approximant of order [N/M]. N and M are arbitrarily choses, but they should be smaller than the power series order. In this step, the Padé approximant extends the domain of the truncated series solution to obtain better accuracy and convergence.
Then, 1/s is written in place of t.
Finally, by using the inverse Laplace s transformation, we obtain the modified approximate solution.
The Laplace-Padé posttreatment of HPM and NDHPM methods will be referred throughout the rest of this paper as LPHPM and LPNDHPM, respectively.
6. Solution of Cantilever Problem
Beams subjected to follower load arise in many problems of structural engineering like lumbar spine in biomechanics, smart structures applications, and loads applied to structural components by cables in tension, among others. The governing equations of such structures involve the effects of nonlinearities due to large deformations and material properties [50–55].
In this work, we study the large-deflection problem of a cantilever beam under a tip-concentrated follower force as depicted in Figure 1. The angle α of inclination of the force with respect to the deformed axis of the beam remains unchanged during deformation. We assume that the center of the Cartesian system (x,y) is located at the fixed end and θ is the local angle of inclination of the centroidal axis beam. Therefore, the mathematical formulation of this problem yields the following nonlinear two-point boundary-value problem:
(16)θ′′+λsin[θ+α-θ(0)]=0,θ′(0)=0,θ(1)=0,
where prime denotes differentiation with respect to η. Additionally, the related dimensionless quantities are defined as
(17)η=sl,ξ=xl,ζ=yl,λ=l2PEl,
where l represents the length of the originally straight elastic cantilever beam, El is the flexural rigidity, s is the arc length measured from the tip, and P is the terminal follower force with constant angle α.
A cantilever beam under terminal follower force.
In [50] is reported that (16) can be reduced to an initial-value problem by the following transformation:
(18)ϕ(η)=θ(η)+α-θ(0),
resulting in the following initial value problem:
(19)ϕ′′+λsin(ϕ)=0,ϕ(0)=α,ϕ′(0)=0,
with the extra condition:
(20)ϕ(1)-α+θ(0)=0,
where the slope of θ(η) can be obtained by using (18) and (20), resulting in the following:
(21)θ(η)=ϕ(η)-ϕ(1).
Finally, the deformed curve of beam axis can be calculated from solution of the slope θ(η) as
(22)ξ(η)=∫η1cos(θ)dη~,ζ(η)=∫η1sin(θ)dη~.
6.1. Solution Obtained by Using NDHPM Method
In order to circumvent difficulties due to the nonlinear sin term of (19), we propose to use a seventh-order Taylor series expansion, resulting in the following:
(23)ϕ′′+λ(ϕ-16ϕ3+1120ϕ5-15040ϕ7)=0,ϕ(0)=α,ϕ′(0)=0,
and by using (7) and (23), we establish the following homotopy equation:
(24)(1-p)(L(v)-L(ϕ0))+p(v′′+λ(v-16v3+1120v5p-15040v7p2))=0,
where homotopy parameter p has been arbitrarily embedded into the power series of Taylor’s expansion, and linear operator L is
(25)v′′+λv,
and trial function ϕ0 is
(26)ϕ0=αcos(λη).
Substituting (8) into (24) and reordering and equating terms with the same p powers, we obtain the following linear set of differential equations:
(27)p0:v0′′+λv0=0,v0(0)=α,v0′(0)=0,p1:v1′′+λv1-16λv03=0,v1(0)=0,v1′(0)=0,p2:v2′′+λv2+1120λv05-12λv02v1=0,v2(0)=0,v2′(0)=0,p3:v3′′+λv3-12λv0v12-15040λv07+124λv04v1-12λv02v2=0,v3(0)=0,v3′(0)=0.
By solving (27), we obtain
(28)v0=αcos(λ^η),v1=-148α3(-cos(λ^η)+cos3(λ^η)-3sin(λ^η)λ^η),v2=115360α5(λ^223cos(λ^η)-60cos2(λ^η)sin(λ^η)λ^η+15sin(λ^η)λ^η-35cos3(λ^η)+12cos5(λ^η)-30cos(λ^η)λ^2η2),v3=-15160960α7(λ^2-593cos(λ^η)+1148cos3(λ^η)-609sin(λ^η)λ^η-735cos5(λ^η)+1365cos(λ^η)λ^2η2+180cos7(λ^η)-1260sin(λ^η)×λ^ηcos7(λ^η)x+2100cos2(λ^η)×sin(λ^η)λ^η+210sin(λ^η)λ^3η3-1890λ^2cos3(λ^η)η2),
where λ^=λ.
Substituting solutions (28) into (8) and calculating the limit when p→1 results in the third-order approximation:
(29)ϕ(η)=limp→1(∑i=03vipi)=v0+v1+v2+v3.
6.2. Solution Calculated by Using HPM and LPHPM Methods
By using (4) and (23), we establish the following homotopy equation:
(30)(1-p)(L(v)-L(ϕ0))+p(v′′+λ(v-16v3+1120v5-15040v7))=0,
where linear operator L is
(31)v′′,
and trial function ϕ0 is
(32)ϕ0=α.
Substituting (5) into (30) and reordering and equating terms with the same p powers, we obtain the following set of linear differential equations:
(33)p0:v0′′=0,v0(0)=α,v0′(0)=0,p1:v1′′-15040λv07-16λv03+λv0+1120λv05=0,v1(0)=0,v1′(0)=0,p2:v2′′+124λv04v1+λv1-12λv02v1-1720λv06v1=0,v2(0)=0,v2′(0)=0,⋮
By solving (33), we obtain
(34)v0=α,v1=(110080λα7+112λα3-12λα-1240λα5)η2,v2=(-11209600λ2α11-11890λ2α7+1180λ2α5+411451520λ2α9-136λ2α3+124λ2α+187091200λ2α13)η4,⋮
where the subsequent iterations are calculated using Maple CAS software.
Substituting solutions (34) into (5) and calculating the limit when p→1, we can obtain the 18th-order approximation:
(35)ϕ(η)=limp→1(∑i=018vipi).
Expression (35) is too long to be written here; nevertheless, it can be simplified if we consider a particular case. For instance, when α=π/2, it results in the following:
(36)u(η)=-5.0091602×10-5η10λ5-3.7265881×10-5η4λ2+0.004184205840η6λ3+7.200012957×10-17η36λ18-0.4999215505η2λ+3.48692001×10-9η16λ8-4.36006×10-12η26λ13-1.4×10-15η34λ17-3.618364186×10-7η12λ6+7.89×10-14η30λ15-2.448310334×10-12η24λ12+2.455105652×10-10η22λ11+0.0000008161908993η14λ7-1.686×10-15x32λ16-1.409132166×10-8η18λ9+4.567238741×10-11η20λ10+7.07×10-14η28λ14+1.570796327-7.024412×10-6η8λ4.
By using (36) and (21) we can calculate, approximately, the deflection angle θ(0); nevertheless, accuracy can be increased applying the Laplace-Padé posttreatment. First, Laplace transformation is applied to (36); then, 1/η is written in place of s. Afterwards, Padé approximant [8/8] is applied and 1/s is written in place of η. Finally, by using the inverse Laplace s transformation, we obtain the modified approximate solution. For instance, for λ=13.75, the result of LPHPM is
(37)u(η)=-0.1295812455566806×10-3exp(-5.536309139671352η)×cos(14.54887311024889η)+0.3532982009243434×10-4exp(-5.536309139671352η)×sin(14.54887311024889η)-0.2686099209980136×10-1cos(8.783120641372600η)+1.597916481385812×cos(3.150018868129787η)-0.1295812455566806×10-3exp(5.536309139671352η)×cos(14.54887311024889η)-0.3532982009243434×10-4exp(5.536309139671352η)×sin(14.54887311024889η).
On one side, for λ=13.75, the exact result is θ(0)=180° [51]. On the other side, by using (21), we can calculate the deflection angle using (36) and (37) approximations, resulting in 240146° and 179.1119°, respectively. Therefore, for this case, the Laplace-Padé posttreatment was relevant in order to deal with the HPM truncated power series, resulting a notorious increase of accuracy (see Table 1).
Terminal slope θ(0) of cantilever beam under normal follower forces (α=π/2).
λ
θ(0)° [51]
S.M. [53]
NDHPM (29)
HPM (35)
LPHPM (37)
NDHPM (41)
LPNDHPM (43)
HPM [50]
0.7010
20
19.50
20.0016
19.9981
19.9981
19.998
19.9981
19.9981
1.4195
40
39.03
39.9784
39.9957
39.9958
39.9487
39.9957
39.9976
2.1755
60
58.61
59.9681
59.9964
59.9975
56.1523
59.9959
60.0066
2.9941
80
78.25
79.9905
79.9947
80.0057
−36.9334
79.9934
80.0233
3.9117
100
98.00
100.0498
99.9943
100.0610
−2104.49
99.9999
100.0504
4.9872
120
117.88
120.1375
120.001
120.2963
−33644.8
120.0574
120.0812
6.3339
140
137.93
140.2400
140.57
141.1245
−523001
140.3214
140.1092
8.2421
160
158.27
160.2464
221.529
163.5890
-1.13840e+07
161.2001
160.1172
13.7500
180
179.97
178.7521
240146
179.1119
-5.39274e+09
180.0345
179.8075
6.3. Power Series Solution by Using NDHPM and Laplace-Padé Posttreatment
By using (7) and (23), we establish the following homotopy equation:
(38)(1-p)(L(v)-L(u0))+p(v′′+λ(v-16v3p+1120v5p2-15040v7p3))=0,
where homotopy parameter p has been arbitrarily embedded into the power series of Taylor expansion, linear operator L, and trial function ϕ0 are taken from (31) and (32), respectively.
Substituting (8) into (38), reordering and equating terms with the same p powers, we obtain the following set of linear differential equations:
(39)p0:v0′′=0,v0(0)=α,v0′(0)=0,p1:v1′′+λv0=0,v1(0)=0,v1′(0)=0,p2:v2′′-16λv03+λv1=0,v2(0)=0,v2′(0)=0.⋮
Solving (39), we obtain
(40)v0=α,v1=-12λαη2,v2=124λ2αη4+112λα3η2,⋮
where the subsequent iterations are calculated using Maple CAS software.
Substituting solutions (40) into (8) and calculating the limit when p→1, we can obtain the 18th-order approximation:
(41)ϕ(η)=limp→1(∑i=018vipi).
Expression (41) is too long to be written here; nevertheless, it can be simplified considering a particular case. For instance, a terminal follower normal angle α=π/2, resulting
(42)ϕ(η)=4.222646520×10-42λ18η36+1.140293002×10-24λ17η34+4.131839790×10-17λ16η32+1.098177235×10-12λ15η30+7.059044113×10-10λ14η28+5.042078503×10-8λ13η26+8.416343250×10-7λ12η24+4.617471554×10-6λ11η22+9.600210952×10-6λ10η20+7.77303550×10-6λ9η18+2.32539526×10-6λ8η16+1.0311191×10-6λ7η14-3.576556×10-7λ6η12-5.00915992×10-5λ5η10-7.024403934×10-6η8λ4+4.184205821×10-3η6λ3-3.726587×10-5λ2η4-0.4999215505λη2+1.570796327.
In order to increase accuracy of θ(0), (42) is transformed by the Padé approximation and Laplace transformation. First, Laplace transformation is applied to (42) and then 1/η is written in place of s. Then, Padé approximant [8/8] is applied and 1/s is written in place of η. Finally, by using the inverse Laplace s transformation, we obtain the modified approximate solution. For example, given λ=13.75, the resultant LPNDHPM approximation is
(43)u(η)=-0.1295804634×10-3exp(-5.536309145η)×cos(14.54887309η)+0.3532927940×10-4exp(-5.536309145η)×sin(14.54887309η)-0.2686099338×10-1cos(8.783120717η)+1.597916481cos(3.150018864η)-0.1295804634×10-3exp(5.536309145η)×cos(14.54887309η)-0.3532927940×10-4exp(5.536309145η)×sin(14.54887309η).
Now, by using (21), we can calculate θ(0) for (42) and (43) approximations. Results for NDHPM and LPNDHPM are -5.39274e(+9)° and 180.0345°, respectively (see Table 1). In fact, for λ=13.75, the exact result is θ(0)=180°; therefore, the Laplace-Padé after-treatment was a key factor to increase accuracy of NDHPM truncated power series.
7. Solution of Nonlinear Pendulum
The pendulum [56–58] of Figure 2 can be modelled by (19). Nevertheless, we need to redefine the variables and parameters of (19), resulting in the following:
(44)ϕ′′+λsin(ϕ)=0,ϕ(0)=α,ϕ′(0)=0,
considering
(45)λ=gL,
where prime denotes differentiation with respect to time t, L is the length of the pendulum, g is acceleration due to gravity, and α is the initial angle of displacement ϕ.
A nonlinear pendulum.
Taking into account the above considerations and substituting η=t into (29), results that the approximate solution (29) obtained by using NDHPM can be considered, also, as the solution ϕ(t) of the nonlinear pendulum problem (44).
7.1. Solution Obtained by Using HPM and Laplace-Padé Posttreatment
Although approximate solutions (35) and (41) possess good accuracy for cantilever problem, we need to increase the order of Taylor expansion for the sin term in (23) to obtain a highly accurate solution for pendulum problem, compared to other reported solutions [50–55]. Therefore, we propose to use a 22th-order Taylor series expansion of sin term, resulting in the following:
(46)P(ϕ)=ϕ′′+λ(ϕ-16ϕ3+1120ϕ5-15040ϕ7+1362880ϕ9-139916800ϕ11+16227020800ϕ13-11307674368000ϕ15+1355687428096000ϕ17-1121645100408832000ϕ19+151090942171709440000ϕ21)=0,
where initial conditions are ϕ(0)=α and ϕ′(0)=0.
A homotopy formulation that can generate a power series solution for this problem is
(47)(1-p)(L(v)-L(ϕ0))+p(P(v))=0,
where linear operator L and trial function ϕ0 are taken from (31) and (32), respectively.
Substituting (5) into (47) and reordering and equating terms with the same p-powers, we obtain the following set of linear differential equations:
(48)p0:v0′′=0,v0(0)=α,v0′(0)=0,p1:v1′′+λ(v0-16v03+1120v05-15040v07+1362880v09-139916800v011+16227020800v013-11307674368000v015+1355687428096000v017-1121645100408832000v019+151090942171709440000v021)=0,v1(0)=0,v1′(0)=0,⋮
by solving (48), we obtain
(49)v0=α,v1=(-12α+112α3-1240α5+110080α7-1725760α9+179833600α11-112454041600α13+12615348736000α15-1711374856192000α17+1243290200817664000α19-1102181884343418880000α21)λt2,⋮
where the subsequent iterations are calculated by using Maple CAS software.
Substituting solutions (49) into (5) and calculating the limit when p→1, we can obtain the 12th-order approximation:
(50)ϕ(t)=limp→1(∑i=012vipi).
Expression (50) is too large to be written here; nevertheless, it can be simplified considering particular cases. For example, if we consider α=1° and λ=1, we get the following results:
(51)ϕ(t)=0.0174532925200-0.00872620321865t2+0.000727072847969t4-2.42099213449×10-5t6+4.28299598028×10-7t8-4.35845271451×10-9t10+5.75330823834×10-12t12+1.31315973780×10-12t14-5.55443572871×10-14t16+1.62530684769×10-15t18-3.65740303058×10-17t20+6.06029996445×10-19t22-5.08850528365×10-21t24.
Now, (51) is transformed by the Laplace-Padé posttreatment. First, Laplace transformation is applied to (51) and then 1/t is written in place of s. Then, Padé approximant [4/4] is applied and 1/s is written in place of t. Finally, by using the inverse Laplace s transformation, we obtain the modified approximate LPHPM solution:
(52)ϕ(t)=-2.76933314632×10-8cos(2.99987437966t)+0.0174533202134cos(0.999980961654t).
Equation (52) is more compact and computationally efficient than power series solution (51). Thus, (52) can be used when accurate and handy expressions are needed. This process can be repeated for different values of α and λ.
We can express pendulum period in terms of
(53)T=41λK(ϵ),ϵ=sin(α2),
where K is the complete elliptic function of the first kind formulated as
(54)K(ϵ)=∫0π/211-ϵ2sin2θdθ,0≤ϵ<1.
For comparison purposes, we will normalize the value of T to
(55)T^=λ4T=K(ϵ).
Finally, T^ is calculated for some values of α in Tables 3 and 4.
8. Numerical Simulation and Discussion8.1. Cantilever Problem
Structures subjected to follower forces have been reported by several researchers [50, 55]. In this work, we propose the solution for large deflections of a cantilever beam subjected to a follower force reported in [55]. Therefore, by using approximate solution (29) and (21), we show in Figure 3 the relationship between terminal slope θ(0) and load parameter λ for some values of deflection angle in the range α∈(0°,180°). Flutter instability occurs, and the maximum value of terminal slope is approximately θ(0)=2α as reported in [50, 55].
Terminal slope versus follower force for various angles of inclination α.
On one side, considering a fixed value for α=π/4, we show in Figure 4 the deformed curves of a beam under different values of load parameter λ. First, the cantilever beam is a straight line, and it is deformed gradually as the amplitude of the end-concentrated follower force increases, until the curvature of the beam is notorious for λ=24. Additionally, when the load parameter is larger than the flutter load, the beam deforms towards the opposite direction as reported in [50]. On the other side, we consider a fixed value for load parameter λ=16 and different values of α as shown in Figure 5, resulting that the deflection and terminal slope θ(0) are influenced by the angle α of follower force producing a notorious bending as α increases reaching the extreme case at α=π/2.
Deflection curves of a cantilever beam axis under several follower forces, considering α=π/4.
Deflection curves beam axis under follower force λ=16 for various angles of inclination α.
Considering a normal angle α=π/2, we show in Table 1 the terminal slope θ(0) (using (21)) versus different values of load parameter λ. In such table, we compare the proposed solutions (29), (35), (41), LPHPM/LPNDHPM approximations (see (37), and (43)) to exact solution [51], a shooting method solution [53], and HPM solution reported in [50]. Our proposed approximate solutions are in good agreement with the other reported approximations. In particular, (29) and LPNDHPM approximations (see (43)) exhibited the best accuracy of all proposed solutions of this work, with a similar accuracy compared to the results reported in [50]. Furthermore, we showed in Table 2, the terminal slope θ(0) and coordinates [ξ(0),ζ(0)] (see (22)) of cantilever beam under normal follower forces (α=π/2), resulting that our proposed solution (29) exhibited an accuracy in good agreement with the values obtained by a direct method (D.M.) [55] and the results reported in [50]. For this work, the cantilever beam is considered elastic and ideal; then, Figures 4 and 5 present an ideally deformed beam. Further work should be performed in order to include nonideal effects due to material characteristics of cantilever.
Terminal slope θ(0) and coordinates [ξ(0),ζ(0)] of cantilever beam under normal follower forces (α=π/2).
Method
D.M. [55]
NDHPM (29)
HPM [50]
D.M. [55]
NDHPM (29)
HPM [50]
D.M. [55]
NDHPM (29)
HPM [50]
λ
θ(0)°
θ(0)°
θ(0)°
ξ(0)
ξ(0)
ξ(0)
ζ(0)
ζ(0)
ζ(0)
2.00
55.48
55.44
55.48
0.7674
0.7677
0.7673
0.5738
0.5735
0.5739
4.00
101.78
101.84
101.84
0.3428
0.3419
0.3420
0.7862
0.7866
0.7864
8.00
157.94
158.20
158.06
−0.0739
−0.0765
−0.0749
0.6336
0.6323
0.6330
13.75
180.00
178.75
179.81
0.0000
0.0104
0.0019
0.4570
0.4577
0.4566
16.00
177.56
176.27
177.22
0.0910
0.1009
0.0938
0.4212
0.4215
0.4206
24.00
140.04
141.94
141.16
0.4348
0.4310
0.4320
0.1588
0.1732
0.1664
36.00
55.64
54.20
54.51
0.2855
0.2726
0.2740
−0.4546
−0.4619
−0.4608
Numerical comparison for T^ of nonlinear pendulum. Considering λ=1.
α∘
T^ (55)
HPM (50)
LPHPM
NDHPM (29)
1.00000000
1.5708262330620782
1.5708262330620789
1.5708262328912635
1.5708262330620782
10.00000000
1.5737921309247680
1.5737921309137186
1.5737904171285648
1.5737921309298985
50.00000000
1.6489952184785310
1.6489951818036827
1.6478388934763048
1.6489966814551095
100.00000000
1.9355810960047220
1.9356331885927838
1.9133053425965654
1.9345771658441948
120.00000000
2.1565156474996432
2.1562170331637955
2.1071446302159819
2.1435695247049310
130.00000000
2.3087867981671961
2.3080949709723178
2.2390737258149828
2.2708015298391809
140.00000000
2.5045500790016340
2.5047278166695662
2.4091002654586270
2.4052794658306813
150.00000000
2.7680631453687676
2.7723737183655317
2.6410091037967786
2.5354467979775911
160.00000000
3.1533852518878388
3.1570008973230000
2.9887412725547848
—
170.00000000
3.8317419997841462
3.8074862454595039
3.6247866486947020
—
175.00000000
4.5202232749476581
4.5078737329373597
4.2924790748606028
—
177.00000000
5.0298609371127860
5.0733536048198848
4.79490944850198683
—
179.00000000
6.127778824526868
4.631673755961933
5.88740406465829867
—
179.90000000
8.430255141254121
—
8.18871358260360318
—
179.99999000
17.64055690983073
—
17.3989702100090882
—
179.99999999
24.548351581120853
—
24.2491870075566718
—
Relative error (RE) comparison for T^ of nonlinear pendulum (see Table 3).
α∘
T^ (55)
R.E. HPM (50)
R.E. LPHPM
R.E. NDHPM (29)
1.00000000
1.5708262330620782
-4.355e-16
1.087e-10
-3.247e-20
10.00000000
1.5737921309247680
7.021e-12
1.089e-06
-3.260e-12
50.00000000
1.6489952184785310
2.224e-08
0.0007012
-8.872e-07
100.00000000
1.9355810960047220
-2.691e-05
0.01151
0.0005187
120.00000000
2.1565156474996432
0.0001385
0.02289
0.006003
130.00000000
2.3087867981671961
0.0002996
0.03019
0.01645
140.00000000
2.5045500790016340
-7.097e-05
0.03811
0.03964
150.00000000
2.7680631453687676
-0.001557
0.0459
0.08404
160.00000000
3.1533852518878388
-0.001147
0.05221
—
170.00000000
3.8317419997841462
0.00633
0.05401
—
175.00000000
4.5202232749476581
0.002732
0.05038
—
177.00000000
5.0298609371127860
-0.86468e-2
0.4671132e-1
—
179.00000000
6.127778824526868
0.244151
0.3922706e-1
—
179.90000000
8.430255141254121
—
0.28651749e-1
—
179.99999000
17.64055690983073
—
0.1369703e-1
—
179.99999999
24.548351581120853
—
0.01222747
—
From above, we can conclude that the deflection and terminal slope are governed by the deflection angle and magnitude of the follower force. This means that the bending of the beam becomes more notorious as the deflection angle or the magnitude of the follower force increases [50].
8.2. Pendulum Problem
On one hand, in [56, 58] the authors achieve approximate solutions for pendulum period, with relative error <2% for α≤130°, and <1% for α≤150°, respectively. On the other hand, in Table 3 and Table 4 we show a comparison between T^, T/4 calculated using (29) and (50) and approximations calculated by LPHPM procedure explained in Section 7.1 (considering λ=1). The value T^ is obtained, applying Newton-Raphson method to equation ϕ(t)=0, that is, calculating the first crossing of ϕ(t) by zero since the initial angle ϕ(0). In Table 4, we show the relative error (RE) for the range of α∈(0°,180°), resulting that our proposed solutions are in good agreement with exact results. Furthermore, LPHPM solution can predict the T^ for α=179.99999999° exhibiting a RE of 0.01222747, which is highly accurate compared to the results obtained in [56, 58].
The coupling of Laplace-Padé and HPM method was a key factor to increase the accuracy range until ϕ(0) value is really close to 180°. Laplace-Padé posttreatment was able to deal with the truncate power series, in order to obtain better accuracy for angles close to α=180° although the behaviour was different for small values of α. However, in general terms, the Laplace-Padé posttreatment generates handy and computationally more efficient expressions (see (51) versus (52)). Furthermore, we can appreciate from Tables 3 and 4 that HPM and NDHPM methods do not present useful T^ values for α>150° and α>179°, due to numerical noise of the proposed approximations. Fortunately, LPHPM approximations achieve a good accuracy within the range 1°≤α≤179.99999999°. From the above discussion we can conclude that, as the initial angle of displacement α approximates to the vicinity 180°, the pendulum period increases notoriously.
Finally, further research should be done in order to obtain approximate solutions of the pendulum problem involving additional nonlinear effects like friction and mass, among others.
9. Conclusions
In this paper we presented the solution for two nonlinear problems related by the same differential equation. The first one was the large deflection of a cantilever beam under a terminal follower force. The second one was the nonlinear pendulum problem. We proposed a series of solutions obtained by NDHPM, HPM, and combinations with Laplace-Padé posttreatment. For both problems, results exhibited high accuracy, which are in good agreement with the results reported by other works. In particular, for the pendulum case, we succeeded to predict, accurately, the period for an initial angle up to 179.99999999°. By means of two case studies, we confirmed that NDHPM, HPM, LPNDHPM, and LPHPM are powerful and useful methods; all of them capable of generating highly accurate approximations for nonlinear problems.
Acknowledgments
The authors gratefully acknowledge the financial support provided by the National Council for Science and Technology of Mexico (CONACyT) through Grant CB-2010-01 no. 157024. The authors would like to express their gratitude to Rogelio-Alejandro Callejas-Molina and Roberto Ruiz-Gomez for their contribution to this paper.
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