Linear seismic inversion
is a mathematical technique where the objective is to determine the physical properties of the subsurface of an earth region that has produced a given seismogram. Cooke and Schneider defined it as calculation of the earth's structure and physical parameters from some set of observed seismic data. The underlying assumption in this method is that the collected seismic data are from an earth structure that matches the cross-section computed from the inversion algorithm. Some common earth properties that are inverted for include acoustic velocity, formation and fluid densities, acoustic impedance, Poisson's ratio, formation compressibility, shear rigidity, porosity, and fluid saturation.
The method has long been useful for geophysicists and can be categorized into two broad types: Deterministic and stochastic inversion. Deterministic inversion methods are based on comparison of the output from an earth model with the observed field data and continuously updating the earth model parameters to minimize a function, which is usually some form of difference between model output and field observation. As such, this method of inversion to which linear inversion falls under is posed as an minimization problem and the accepted earth model is the set of model parameters that minimizes the objective function in producing a numerical seismogram which best compares with collected field seismic data.
On the other hand, stochastic inversion methods are used to generate constrained models as used in reservoir flow simulation, using geostatistical tools like kriging. As opposed to deterministic inversion methods which produce a single set of model parameters, stochastic methods generate a suite of alternate earth model parameters which all obey the model constraint. However, the two methods are related as the results of deterministic models is the average of all the possible non-unique solutions of stochastic methods. Since seismic linear inversion is a deterministic inversion method, the stochastic method will not be discussed beyond this point.
Linear inversion
The deterministic nature of linear inversion requires a functional relationship which models, in terms of the earth model parameters, the seismic variable to be inverted. This functional relationship is some mathematical model derived from the fundamental laws of physics and is more often called a forward model. The aim of the technique is to minimize a function which is dependent on the difference between the convolution of the forward model with a source wavelet and the field collected seismic trace. As in the field of optimization, this function to be minimized is called the objective function and in convectional inverse modeling, is simply the difference between the convolved forward model and the seismic trace. As earlier mentioned, different types of variables can be inverted for but for clarity, these variables will be referred to as the impedance series of the earth model. In the following subsections we will describe in more detail, in the context of linear inversion as a minimization problem, the different components that are necessary to invert seismic data.Forward model
The centerpiece of seismic linear inversion is the forward model which models the generation of the experimental data collected. According to Wiggins, it provides a functional relationship between the model parameters and calculated values for the observed traces. Depending on the seismic data collected, this model may vary from the classical wave equations for predicting particle displacement or fluid pressure for sound wave propagation through rock or fluids, to some variants of these classical equations. For example, the forward model in Tarantola is the wave equation for pressure variation in a liquid media during seismic wave propagation while by assuming constant velocity layers with plane interfaces, Kanasewich and Chiu used the brachistotrone model of John Bernoulli for travel time of a ray along a path. In Cooke and Schneider, the model is a synthetic trace generation algorithm expressed as in Eqn. 3, where R is generated in the Z-domain by recursive formula. In whatever form the forward model appears, it is important that it not only predicts the collected field data, but also models how the data is generated. Thus, the forward model by Cooke and Schneider can only be used to invert CMP data since the model invariably assumes no spreading loss by mimicking the response of a laterally homogeneous earth to a plane-wave source- where t is ray travel time, x, y, z are depth coordinates and vi is the constant velocity between interfaces i − 1 and i.
where represent bulk modulus, density, the source of acoustic waves, and the pressure variation.
Objective function
An important numerical process in inverse modeling is to minimize the objective function, which is a function defined in terms of the difference between the collected field seismic data and the numerically computed seismic data. Classical objective functions include the sum of squared deviations between experimental and numerical data, as in the least squares methods, the sum of the magnitude of the difference between field and numerical data, or some variant of these definitions. Irrespective of the definition used, numerical solution of the inverse problem is obtained as earth model that minimize the objective function.In addition to the objective function, other constraints like known model parameters and known layer interfaces in some regions of the earth are also incorporated in the inverse modeling procedure. These constraints, according to Francis 2006, help to reduce non-uniqueness of the inversion solution by providing a priori information that is not contained in the inverted data while Cooke and Schneider reports their useful in controlling noise and when working in a geophysically well-known area.
Mathematical analysis of generalized linear inversion procedure
The objective of mathematical analysis of inverse modeling is to cast the generalized linear inverse problem into a simple matrix algebra by considering all the components described in previous sections. viz; forward model, objective function etc. Generally, the numerically generated seismic data are non-linear functions of the earth model parameters. To remove the non-linearity and create a platform for application of linear algebra concepts, the forward model is linearized by expansion using a Taylor series as carried out below. For more details see Wiggins, Cooke and Schneider.Consider a set of seismic field observations, for and a set of earth model parameters to be inverted for, for. The field observations can be represented in either or, where and are vectorial representations of model parameters and the field observations as a function of earth parameters. Similarly, for representing guesses of model parameters, is the vector of numerical computed seismic data using the forward model of Sec. 1.3. Taylor's series expansion of about is given below.
On linearization by dropping the non-linear terms, the equation becomes
Considering that has components and and have components, the discrete form of Eqn. 5 results in a system of linear equations in variables whose matrix form is shown below.
Solution algorithm
is computed from the forward model, while is the experimental data. Thus, is a known quality. On the other hand, is unknown and is obtained by solution of Eqn. 10. This equation is theoretically solvable only when is invertible, that is, if it is a square matrix so that the number of observations is equal to the number of unknown earth parameters. If this is the case, the unknown corrector vector, is solved for as shown below, using any of the classical direct or iterative solvers for solution of a set of linear equations.The error is given by
or or of given by or.
The generalized procedure for inverting any experimental seismic data for or, using the mathematical theory for inverse modeling, as described above, is shown in Fig. 1 and described as follows.
An initial guess of the model impedance is provided to initiate the inversion process. The forward model uses this initial guess to compute a synthetic seismic data which is subtracted from the observed seismic data to calculate the difference vector.
- An initial guess of the model impedance is provided to initiate the inversion process.
- A synthetic seismic data is computed by the forward model, using the model impedance above.
- The difference vector is computed as the difference between experimental and synthetic seismic data.
- The sensitivity matrix is computed at this value of the impedance profile.
- Using and the difference vector from 3 above, the corrector vector is calculated. A new impedance profile is obtained as
- The or norm of the computed corrector vector is compared with a provided tolerance value. If the computed norm is less than the tolerance, the numerical procedure is concluded and the inverted impedance profile for the earth region is given by from Eqn. 14. On the other hand, if the norm is greater than the tolerance, iterations through steps 2-6 are repeated but with an updated impedance profile as computed from Eqn. 14. Fig. 2 shows a typical example of impedance profile updating during successive iteration process. According to Cooke and Schneider, use of the corrected guess from Eqn. 14 as the new initial guess during iteration reduces the error.
Parameterization of the earth model space
Considering that inverse modeling problem is only theoretically solvable when the number of discrete intervals for sampling the properties is equal to the number of observation in the trace to be inverted, a high-resolution sampling will lead to a large matrix which will be very expensive to invert. Furthermore, the matrix may be singular for dependent equations, the inversion can be unstable in the presence of noise and the system may be under-constrained if parameters other than the primary variables inverted for, are desired. In relation to parameters desired, other than impedance, Cooke and Schneider gives them to include source wavelet and scale factor.
Finally, by treating constraints as known impedance values in some layers or discrete intervals, the number of unknown impedance values to be solved for are reduced, leading to greater accuracy in the results of the inversion algorithm.
Inversion examples
Temperature inversion from Marescot (2010)
We start with an example to invert for earth parameter values from temperature depth distribution in a given earth region. Although this example does not directly relate to seismic inversion since no traveling acoustic waves are involved, it nonetheless introduces practical application of the inversion technique in a manner easy to comprehend, before moving on to seismic applications. In this example, the temperature of the earth is measured at discrete locations in a well bore by placing temperature sensors in the target depths. By assuming a forward model of linear distribution of temperature with depth, two parameters are inverted for from the temperature depth measurements.The forward model is given by
The objective of this inversion algorithm is to find, which is the value of that minimizes the difference between the observed temperature distribution and those obtained using the forward model of Eqn. 15. Considering the dimension of the forward model or the number of temperature observations to be, the components of the forward model is written as
- so that