We considered the inverse coefficient problem for the geoelectric equation. For the purpose of research of the conditional stability of the inverse problem solution, we used integral formulation of the inverse geoelectric problem. By implementing the relevant norms and using the close system of Volterra integral equations, we managed to estimate the conditional stability of the solution of inverse problem or rather lower changes in input data imply lower changes in the solution (of the numerical method). When determining the additional information the device errors are possible. That is why this research is important for experimental studies with usage of ground penetrating radars.
1. Introduction
Inverse problems for hyperbolic equations, in particular for the acoustics and geoelectrics, were investigated by many authors; notably, a detailed bibliography is given in the monography of Kabanikhin [1]. We will present the main scientific results on this problem. Blagoveshchenskii applied Gelfand-Levitan method for proving the uniqueness of the solution of the inverse acoustic problem [2]. Romanov proved a comparable theorem for the following equation [3]:
(1)wtt(x,t)=wxx(x,t)-q(x)w(x,t),
which is consolidated from the acoustic equation with well-known transformation (see [4]):
(2)w(x,t)=u(x,t)exp{-12lnσ(x)},q(x)=-12[lnσ(x)]′′+14[σ′(x)σ(x)]2.
Romanov and Yamamoto [5] obtained the estimation of conditional stability in L2 for getting a multidimension analog of the inverse problem (1).
Numerical algorithm of inverse acoustic problem solving in the discrete case was given in work [6] for the first time.
Bamberger and his coauthors used a conjugate gradient method to define the acoustic impedance [7, 8].
He and Kabanikhin used the optimization method to solve the inverse problem for three-dimension acoustic equation [9].
Azamatov and Kabanikhin studied the conditional stability of the solution to Volterra operator equation in L2 [10].
Problems of uniqueness of the inverse problem solution and set of numerical methods for solving the geoelectric equation were given in the monograph of Romanov and Kabanikhin [11].
For solving inverse acoustic problem in integral case formulation the estimation of the conditional stability in H1 was obtained in the work of Kabanikhin et al. [12].
Further, in works [13, 14] for minimizing purposes they built and investigated a special form of the composite functional that allowed proving the following theorems in the space L2: the local correctness theorem, the correctness theorem of the inverse problem for small amount of data, and the correctness theorem in the envelope of the exact solution in L2.
Bukhgeim and Klibanov suggested using the method of Carleman estimates when proving uniqueness theorems of the coefficient inverse problems [15]. A broad overview on the use of Carleman estimates in the theory of multidimension coefficient inverse problems is given in the work [16].
The problem of uniqueness of inverse problem solution for determination of the coefficients of the permittivity and conductivity for Maxwell’s equation system is considered in the work [17].
Approbation of the globally convergent numerical algorithm with the use of experimental radar data for determination of the permittivity is given in work [18]. They presented an analysis of convergence of the method and it has been shown that the computed and real values of permittivity were in enough agreement. A wide range of globally convergent algorithms of solving a class of problems is described in work [19].
Comparative analysis of the classical equation methods and globally convergent numerical method of solving the coefficient inverse problems was given in work [20]. These comparisons were performed for both computationally simulated and experimental data.
In the work [21] continuation problem from the time-like surface for the 2D Maxwell’s equation was considered. The gradient method for the continuation and coefficient inverse problem was explained. The results of computational experiment were presented.
In this research, following the methods which were described in the work [12], we obtained the estimation results of the conditional stability of the geoelectric equation in H1.
Herein after the second paragraph there is the conclusion of the main equations which were derived from the system of Maxwell’s equations [11].
In the third paragraph we had amplified the inverse problem for the geoelectric equation with data on characteristics. It allows us to obtain a close system of integral equations.
Finally, in the fourth paragraph, the implementation of the relevant class of input data functions and the class of solutions of the inverse problem allowed us to estimate the conditional stability of the inverse problem solution for the geoelectric equation.
2. Statement of the Problems
The propagation process of electromagnetic waves in a medium is described by Maxwell’s equations [11]:
(3)ε∂∂tE-rotH+σE+jcm=0,x3≠0,(x1,x2,x3)∈R3,μ∂∂tH+rotE=0,t>0.
Here E=(E1,E2,E3)* and H=(H1,H2,H3)* are the electric and magnetic fields intensity vectors; ε is dielectric permittivity of the medium; μ is magnetic permeability of the medium; σ is conductivity of the medium; jcm is source of external currents.
Consider geophysical model of the medium consisting of two half spaces: R-3={x∈R3,x3<0}—air; R+3={x∈R3,x3>0}—earth.
Let the external current source take the following form:
(4)jcm=(0,1,0)*g(x1)δ(x3)θ(t),
where g(x1) is the function which describes the transversal dimension of the source; δ(x3) is Dirac delta function; and θ(t) is Heaviside function.
Setting the external current in the form (4) makes it an instantaneous inclusion current, parallel to the axis x2 at time scales of 10–50 ns (nanoseconds).
Using the definition of the curl we get finally from Maxwell’s equations
(5)ε∂∂tE1+σE1=∂∂x2H3-∂∂x3H2,ε∂∂tE2+σE2=-∂∂x1H3+∂∂x3H1+γ2,ε∂∂tE3+σE3=∂∂x1H2-∂∂x2H1,μ∂∂tH1=-∂∂x2E3+∂∂x3E2,μ∂∂tH2=-∂∂x1E3-∂∂x3E1,μ∂∂tH3=-∂∂x1E2-∂∂x2E1.
Assuming that the coefficients of Maxwell’s equations do not depend on the variable x2 and are of the special choice of the source in the form (4), the system will retain only three nonzero components E2, H1, and H3 [11]. Excluding the last two components, the final equations are written such that
(6)ε∂2∂t2E2+σ∂∂tE2=∂∂x1(1μ∂∂x1E2)+∂∂x3(1μ∂∂x3E2)+g(x1)η(x3)θ′(t),x3>0,t>0,(7)E2|t>0=0,(8)E2|x3=+0=φ(1)(x1,t),(9)(1μ∂∂x3E2)|x3=+0=∂∂tφ(2)(x3,t).
Particular attention has aggravated conditions (8) and (9).
Condition (8) is taken as additional information (the response of the medium).
Condition (9) is unknown, but it is necessary for solving direct and inverse problems in a half space {x3>0} (earth).
In this situation we proceed as shown in [11], in the half space {x3≤0} where σ=0 we solve the direct problem by the known data ε, μ:
(10)ε∂2∂t2E2=∂∂x1(1μ∂∂x1E2)+∂∂x3(1μ∂∂x3E2)ε∂2∂t2E2+g(x1)η(x3)θ′(t),x3<0,t>0,(11)E2|t<0=0,(12)E2|x3=+0=φ(1)(x1,t).
In the last system we consider known additional information (8) as a boundary condition for solving the direct problem in the area {x3<0} (air). This fact enables us to restrict the numerical solution of the inverse problem for the minimum possible size of the area in the plane {x3>0}.
If the coefficients of (10) do not depend on the variable x1 [11] then applying the Fourier transform Fx1[·] to (10)–(12) and similar to (6)–(9), we write the final statement of the problem.
In the air domain {x3<0} we have the following statement of the direct problem:
(13)ευ~tt=1μυ~x3x3-λ2μυ~+g~λη(x3)θ′(t),x3<0,υ~|t<0=0,υ~t|t<0=0,υ~(0,t)=f(1)(t).
In the earth domain {x3>0} we have the following statement of the direct problem:
(14)υ~tt+σευ~t=1μευ~x3x3-λ2μεg~λδ(x3,t),x3>0,x3∈R1,(15)υ~|t<0=0,υ~t|t<0=0,(16)1μυ~x3(0,t)=f(2)(t),(17)υ~(0,t)=f(1)(t).
Here λ is a Fourier parameter and υ~(x,t)=Fx1[E2(x1,0,x3,t)]; f(1)(t)=Fx1[φ(1)(x1,t)]; and f(2)(t)=Fx1[(∂/∂t)φ(2)(x1,t)] are Fourier images.
Direct Problem. By the known values of ε, μ, and σ find υ~(x3,t) as the solution of the mixed problem (14)–(16).
Inverse Problem. Find σ(x3) and υ~(x3,t) from (14) to (16) for given f(1)(t) with fixed λ=λ0.
To study conditional stability of the inverse geoelectric problem, it is convenient to use the integral formulation.
Now we introduce the following notations: b(x3)=1/με(x3) and a(x3)=σ(x3)/ε(x3) and change the variables and functions:
(18)z=z(x3)=∫0x3με(ξ)dξ,x3=ω(z);a(z)=σ(ω(z))ε(ω(z)),b(z)=1με(ω(z)),u(z,t)=υ(ω(z),t),j0=-g(λ)με(0).
Then (14)–(16) can be written in the form
(19)utt(z,t)=uzz(z,t)-a(z)ut(z,t)-b′(z)b(z)uz(z,t)-(λb(z))2u(z,t),(20)u|t<0=0,ut|t<0=0,(21)1μuz(0,t)=f(2)(t),(22)u(0,t)=f(1)(t).
In the future, we will get (19) without the derivative uz; for this we assume that
(23)u(z,t)=G(z)v(z,t).
Now we calculate derivatives as follows:
(24)uz=G′v+Gvz,uzz=G′′v+2G′vz+Gvzz,ut=Gvt,utt=Gvtt.
Substituting (24) into (19), we obtain
(25)Gvtt=G′′v+2G′vz+Gvzz-a(z)Gvt-b′b(G′v+Gvz)-(λb)2Gv.
Grouped together, we obtain
(26)vtt=vzz+(2G′G-b′b)vz-a(z)vt+(G′′G-b′bG′G-(λb)2)v.
Put that
(27)2G′G-b′b=0,(28)g(z)=G′′G-b′bG′G-(λb)2.
Finally, we have
(29)vtt=vzz-a(z)vt+g(z)v,v|t<0=0,vt|t<0=0,1μvz(0,t)=f(2)(t),v(0,t)=f(1)(t).
From (27) we have
(30)G′G=b′2b;(lnG)′=(lnb)′,lnG=lnb+lnS(0),S(0)=1,G(z)=b(z).
Thus, the function g(z) is uniquely determined from (28) by the formula (30).
3. Statement of the Problem with the Data on the Characteristics
In the domain Δ(l)={(z,t)|0<|z|<t<l} we consider the inverse problem with data on the characteristics [11]:
(31)vtt(z,t)=vzz(z,t)-Pv(z,t),(z,t)∈Δl,(32)v(z,z)=S(z),0≤z≤l,(33)v(0,t)=f(t),0≤t≤2l,(34)vz(0,t)=φ(t),0≤t≤2l.
Here
(35)Pv(z,t)=a(z)vt(z,t)+g(z)v(z,t),f(t)=f(1)(t),φ(t)=μf(2)(t).
We deem that a(z) is an unknown function and the function g(z) is to be known.
Function S(z) is a solution to Volterra integral equation of the second kind:
(36)S(z)=12γ0-12∫0za(ξ)S(ξ)dξ,z∈(0,l).
Inverting the operator (∂2/∂t2)-(∂2/∂z2) in (31) and taking into account (33) and (34), we obtain
(37)v(z,t)=Φ(z,t)+At,z[Pv],(z,t)∈Δ(l).
Here we use the following notations:
(38)Φ(z,t)=12[f(t+z)+f(t-z)]+12∫t-zt+zφ(ξ)dξ,At,z[v]=12∫0z∫t-z+ξt+z-ξv(ξ,τ)dτdξ.
Differentiating (37) with respect to t we obtain
(39)vt(z,t)=Φt(z,t)+12∫0z[Pv(ξ,t+z-ξ)-Pv(ξ,t-z+ξ)]dξ.
Put t=z+0 in (37) and use condition (32); then we have
(40)S(z)=Φ(z,z+0)+Az+0,z[Pv].
Differentiating both sides of the resulting equality with respect to z gives
(41)S′(z)=Φ′(z,z+0)+∫0zPv(ξ,2z-ξ)dξ.
It is not difficult to see that the function q(z)=[S(z)]-1 satisfies Volterra integral equation of the second kind:
(42)q(z)=γ-1+12∫0za(ξ)q(ξ)dξ,γ=γ02.
Taking this into account and the relation a(z)=2S′(z)/S(z), we get
(43)a(z)=2[Φ′(z,z+0)+∫0zPv(ξ,2z-ξ)dξ]·[γ-1+12∫0za(ξ)q(ξ)dξ].
Thus, we obtain a closed system of integral equations (37), (39), (42), and (43).
We write this system in vector form as follows:
(44)Υ=F+K(Υ),
where
(45)Υ(z,t)=(Υ1,Υ2,Υ3,Υ4)T,F(z,t)=(F1,F2,F3,F4)T,K(Υ)=(K1(Υ),K2(Υ),K3(Υ),K4(Υ))T,Υ1(z,t)=v(z,t),Υ2(z,t)=vt(z,t),Υ3(z)=q(z),Υ4(z)=a(z).F1(z,t)=Φ(z,t),F2(z,t)=Φt(z,t),F3=γ0-1,F4(z)=χ(z),
where χ(z)=2γ-1Φ′(z,z+0),
(46)K1(Υ)=12∫0z∫t-z+ξt+z-ξPΥ(ξ,τ)dτdξ,(z,t)∈Δ(l),K2(Υ)=12∫0z[PΥ(ξ,t+z-ξ)-PΥ(ξ,t-z+ξ)]dξ,K3(Υ)=12∫0zΥ4(ξ)Υ3(ξ)dξ,K4(Υ)=Φ′(z,z+0)∫0zΥ4(ξ)Υ3(ξ)dξK4(Υ)=+2∫0zPΥ(ξ,2z-ξ)dξK4(Υ)=·(γ-1+12∫0zΥ4(ξ)Υ3(ξ)dξ).
Here
(47)PΥ(z,t)=Υ4(z)·Υ2(z,t)-g(z)Υ1(z,t).
We deem that Υ=(Υ1,Υ2,Υ3,Υ4)∈L2(l), if
(48)Υj(z,t)∈L2(Δ(l)),j=1,2;Υj(z)∈L2(0,l),j=3,4.
Let Υ(j)=(Υ1(j)(z,t),Υ2(j)(z,t),Υ3(j)(z),Υ4(j)(z))T, j=1,2.
We define the scalar product and the norm as follows:
(49)〈Υ(1),Υ(2)〉=∑k=12∫0l∫z2l-zΥk(1)(z,t)Υk(2)(z,t)dtdz+∑k=34∫0lΥk(1)(z)Υk(2)(z)dz,∥Υ∥2=〈Υ,Υ〉.
Inverse Problem. Find vector Υ∈L2(l) from (44) for given F∈L2(l).
4. Conditional Stability
Studying H1, conditional stability is similar to that in [12] where it was done for the inverse acoustic problem.
We suppose ∥a∥L2(0,l)2=M1, ∥f∥L2(0,l)2+∥f′∥L2(0,l)2=M2, ∥φ∥L2(0,l)2=M3, and ∥g∥L2(0,l)2≤M4 to be known.
We define ∑(l,M1,a*) as the class of possible solutions of the inverse problem; namely, a(z)∈∑(l,M1,a*) if a(z) satisfies the following conditions:
a(z)∈H1(0,l)∩C1(0,l),
∥a∥H1(0,l)≤M1,
0<a*≤a(z),x∈(0,l).
We also define F(l,M2,M3,M4,k0) as the class of possible initial data; namely, f∈F(l,Q,k0) if f satisfies the following conditions:
f∈H1(0,2l),
∥f∥H1(0,2l)≤M2,
f(+0)=k0, ∥φ∥H1(0,2l)≤M3.
Suppose that for f(1),f(2)∈F(l,M2,M3,M4,k0) there exist a(1) and a(2) from ∑(l,M1,a*) which solve the inverse problem:
(50)vtt(j)(z,t)=vzz(j)(z,t)-Pv(j)(z,t),(z,t)∈Δ(l),v(j)(z,z)=S(j)(z),0≤z≤l,v(j)(0,t)=f(j)(t),vz(0,t)=φ(j)(t),0≤t≤2l,
for j=1,2, respectively.
Here
(51)Pv(j)(z,t)=a(j)(z)vt(j)(z,t)+g(z)v(j)(z,t),f(j)(t)=f(1)(j)(t),φ(j)(t)=μf(2)(j)(t).
We deem that the function g(z) is known and a(j)(z) is unknown, j=1,2. We write the early resulting closed system in the vector form as follows:
(52)Υ(j)=F(j)+K(Υ(j)),j=1,2,
where
(53)Υ(j)=(Υ1(j),Υ2(j),Υ3(j),Υ4(j))T;Υ1(j)(z,t)=v(j)(z,t),Υ2(j)(z,t)=vt(j)(z,t),(54)Υ3(j)(z)=q(z),Υ4(j)(z)=a(j)(z);F(j)=(F1(j),F2(j),F3(j),F4(j))T,j=1,2;F1(j)(z,t)=Φ(j)(z,t),F2(j)(z,t)=Φt(j)(z,t),F3=j-1,F4(z)=χ(j)(z),j=1,2;(55)K1(Υ(j))=12∫0z∫t-z+ξt+z-ξPΥ(j)(ξ,τ)dτdξ,(z,l)∈Δ(l),K2(Υ(j))=12∫0z[PΥ(j)(ξ,t+z-ξ)-PΥ(j)(ξ,t-z+ξ)]dξ,K3(Υ(j))=12∫0zΥ4(j)Υ3(j)dξ,K4(Υ(j))=Φ′(j)(z,z+0)∫0zΥ4(j)(ξ)Υ3(j)(ξ)dξ+2∫0zPΥ(j)(ξ,2z-ξ)dξ·(γ-1+12∫0zΥ4(j)(ξ)Υ3(j)(ξ)dξ).
Here we denote PΥ(j)(z,t)=Υ4(z)Υ2(z,t)-g(z)Υ1(z,t).
Theorem 1.
Suppose that, for F(j)∈L2(l), j=1,2, there exist Υ(j)∈L2(Δ(l)) as the solution of the inverse problem as follows:
(56)Υ(j)(z,t)=F(j)(z,t)+K(Υ(j)),j=1,2,(z,t)∈Δ(l).
Then
(57)∥Υ(1)-Υ(2)∥2≤C∥f(1)-f(2)∥H1(0,2l)2,
where
(58)C=C(l,M1,M2,M3,M4,k0).
Proof.
We introduce
(59)Υ~(x,t)=(Υ~1(z,t),Υ~2(z,t),Υ~3(z),Υ~4(z))=Υ(1)(z,t)-Υ(2)(z,t),F~(z,t)=F(1)(z,t)-F(2)(z,t).
Then from (52) it follows that
(60)Υ~(z,t)=F~(z,t)-K(Υ~),(z,t)∈Δ(l).
In the vector equation (60) we estimate each component separately taking into account the obvious inequalities as follows:
(61)(a+b+c)2≤3(a2+b2+c2),(a+b)2≤2a+2b,
for a≥0, b≥0.
We obtain the chain of the inequalities:
(62)|Υ~1(z,t)|≤|F~1(z,t)|+12∫0z|Υ~3(ξ)|2dξ|Υ~1(z,t)|×[∫0z|Υ1(1)(ξ,t+z-ξ)|2dξ|Υ~1(z,t)|1111111+∫0z|Υ1(1)(ξ,t-z+ξ)|2dξ]|Υ~1(z,t)|+12∫0z|Υ3(2)(ξ)|2dξ|Υ~1(z,t)|×[∫0z|Υ~1(ξ,t+z-ξ)|2dξ|Υ~1(z,t)|1111111+∫0z|Υ~2(ξ,t-z+ξ)|2dξ].
Using the obvious inequality we get
(63)|Υ~1(z,t)|2≤3|F~1(z,t)|2+32∫0z|Υ~3(ξ)|2dξ×∫0z[|Υ1(1)(ξ,t+z-ξ)|2+|Υ1(1)(ξ,t-z+ξ)|2]dξ+32∫0z|Υ3(2)(ξ)|2dξ×∫0z|Υ~1(ξ,t+z-ξ)|2+|Υ~1(2)(ξ,t-z+ξ)|2dξ.
Turning to the earlier introduced norms we have
(64)∥Υ~1∥L2(Δ(l,z))2≤3∥F~1∥L2(Δ(l,z))T2+32∫0z∫ξ2l-ξ{∫0ξ|Υ~3(ξ′)|2dξ′≤1113∥F~1∥(Δ(l,z))2×∫0ξ[|Υ1(1)(ξ′,τ+ξ-ξ′)|21111111111111111111+|Υ1(1)(ξ′,τ-ξ+ξ′)|2]dξ′≤1113∥F~1∥(Δ(l,z))2+∫0ξ|Υ32(ξ′)|2dξ′≤1113∥F~1∥(Δ(l,z))2×∫0ξ[|Υ~1(ξ′,τ+ξ-ξ′)|21111111111111111111+|Υ~1(2)(ξ′,τ-ξ+ξ′)|2]dξ′∫0ξ|Υ32(ξ′)|2dξ′}dτdξ≤3∥F~1∥L2(Δ(l,z))2+12Υ*2∫0z∫0ξ|Υ~3(ξ′)|2dξ′dξ+12Υ*2∫0z∥Υ~1∥L2(Δ(l,ξ))dξ.
Here
(65)Υ*=max{∥Υ(1)∥,∥Υ(2)∥}.
We estimate the second component of (60):
(66)|Υ~2(z)|≤12∫0z|Υ3(1)(ξ)Υ~2(ξ)|dξ+12∫0z|Υ2(2)(ξ)Υ~3(ξ)|dξ≤12∫0z|Υ3(1)(ξ)|2dξ∫0z|Υ~2(ξ)|2dξ+12∫0z|Υ2(2)(ξ)|2dξ∫0z|Υ~3(ξ)|2dξ.
Then we have
(67)∥Υ~2∥L2(0,z)2≤12Υ*2∫0z[∥Υ~2∥L2(0,ξ)2+∥Υ~3∥L2(0,ξ)2]dξ.
We estimate the third component of (60) and we have
(68)∥Υ~3∥L2(0,l)2≤14M2∫0z[∥Υ~3∥L2(0,ξ)2+M3∥Υ~4∥L2(0,ξ)2]dξ.
Finally, for the fourth component of (60) we get the estimate
(69)|Υ~4(z)|≤|F~4(z)|+∑i=14wi,w1(z)=2|(f(1))′(z)||K2(Υ(1))-K2(Υ(2))|,w2(z)=|K6(Υ(1))-K6(Υ(2))|,w3=|K2(Υ(1))|w2(z),w4=|K4(Υ(2))||K2(Υ(1))-K2(Υ(2))|,w5=|(f(1))′-(f(2))||K2(Υ(2))|,K6(Υ)=∫0zΥ3(ξ)Φ1(ξ,2z-ξ)dξ.
Estimating each term wi(z) and substituting into (69) and using the obvious inequality
(70)(∑k=14|bk|)2≤4∑k=14|bk|2,
we obtain
(71)∥Υ~4(z)∥L2(0,z)≤ν0∫0z[f′(2ξ)]2dξ+12ν1∥Υ~1∥L2(Δ(l,z))+∫0zν3(ξ)∥Υ~2∥L2(0,ξ)dξ+∫0zν3(ξ)∥Υ~3∥L2(0,ξ)dξ+∫0zν4(ξ)∥Υ~4∥L2(0,ξ)dξ.
Now we combine all the obtained estimates for the four components (60) and denote, for convenience,
(72)ψ1(z)=∥Υ~1∥L2(Δ(l,z))2,z∈(0,l),
and then
(73)ψ(z)=ψ1(z)+ψ2(z)+ψ3(z)+ψ4(z)
and for function ψ we obtain the following estimate:
(74)ψ(z)≤η+∫0z∑i=14γi(ξ)ψi(ξ)dξ,
where η=η(Υ*2,ν1,ν2,ν3,ν4).
Introduce a new function:
(75)ν(z)=η*+∫0z∑i=14γi(ξ)ψi(ξ)dξ,η<η*,
where η* is constant.
Then ψ(z)≤ν(z),
(76)ν′(z)=∑i=14γi(z)Υj(z)≤ν(z)∑i=14γi(z),ν′(z)ν(z)≤∑i=14γi(z).
Applying the Gronwall inequality we obtain
(77)ψ(z)≤ν(z)≤ν(0)exp{∫0z∑i=14γi(ξ)dξ},∫0z∑i=14γi(ξ)dξ≤25Υ*2×z+12Υ*2∥f(1)∥L2(0,2l)2+12Υ*4+12Υ*2(12+Υ*2·z).
Then from (77) we obtain
(78)∥Υ(1)-Υ(2)∥2≤N~∥f(1)-f(2)∥H1(0,2l),
where the constant C>0 is given by (58).
An explicit expression for the constant as a result of successive computations is given by
(79)C=[6l+6M1(4k02+Υ*4)(1+12Υ*2l)]×exp{Υ*2[24l+8M2(4k02+Υ*4)(M3+36Υ*2l)HHH++hhh+6M2Φ2+8M4Υ*4(4k02+Υ*4)]}.
5. Conclusions
The conditional stability of the inverse problem for the geoelectric equation has been investigated. For studying we consider the integral formulation of the inverse geoelectric problem. The estimation of the conditional stability of the inverse problem solution has been obtained or rather lower changes in input data imply lower changes in the solution (of the numerical method). When determining the additional information the device errors are possible. That is why this research is important for experimental studies with usage of ground penetrating radars. The inlet data belongs to the class F(l,M2,M3,M4,k0), while the solution belongs to the class ∑(l,M1,a*).
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
Acknowledgment
The work was supported by Ministry of Education and Science of the Republic of Kazakhstan (Grant no. 139 (69) ot 04.02.2014).
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