Computationally efficient error estimate for evaluation of regularization in photoacoustic tomography

Bhatt, Manish; Acharya, Atithi; Yalavarthy, Phaneendra K.

doi:10.1117/1.jbo.21.10.106002

Cited by 9 publications

(27 citation statements)

References 29 publications

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“…The standard (zeroth order) choice for L is identity matrix ( I ); thus, the solution becomes

x_{Tik} = {(A^{T} A + λ I)}^{- 1} A^{T} b .

These regularization methods involve matrix–matrix multiplications as well as solving large system of equations, which is computationally expensive. Therefore, the Tikhonov regularization was implemented in a Lanczos bidiagonalization framework, to reduce the computational complexity . The Lanczos bidiagonalization of the system matrix A can be written as

{boldM}_{q + 1} false(β_{1} e_{1} false) = b

A {boldR}_{q} = {boldM}_{q + 1} {boldB}_{q}

A^{T} {boldM}_{q + 1} = {boldR}_{q} {boldB}_{q}^{T} + α_{q + 1} r_{q + 1} e_{q + 1}^{T}

where M q = [ m 1 , m 2 ,…, m q ] and R q = [ r 1 , r 2 ,…, r q ] are the left and right orthogonal Lanczos matrices of dimensions m × ( q + 1) and n 2 × q respectively.…”

Section: Model‐based Reconstruction Algorithmsmentioning

confidence: 99%

“…Using the above Lanczos bidiagonalization, Eq. reduces to

x^{(q)} = {({boldB}_{q}^{T} {boldB}_{q} + λ I)}^{- 1} β_{1} {boldB}_{q}^{T} e_{1}; x_{Lanc} = {boldR}_{q} x^{(q)} .

This method requires a suitable number of Lanczos iterations and value of the regularization parameter to be chosen and we achieve these using error estimate‐based method, which was proven to be computationally efficient . It is briefly reviewed here for completeness.…”

Section: Model‐based Reconstruction Algorithmsmentioning

confidence: 99%

“…One way to obtain the solution at λ = 0 is to perform an extrapolation given x at multiple values of λ (assuming that the solution is a function of λ , which is true for any regularization scheme). Thus, the extrapolation method avoids the difficulty of evaluating the regularization parameter in an automated fashion, which is computationally demanding …”

Section: Model‐based Reconstruction Algorithmsmentioning

confidence: 99%

“…An important step in Tikhonov regularization is to select an appropriate regularization parameter. It is well known that the reconstruction result is largely biased toward regularization parameter . Moreover, the regularization parameter always filters some of the natural characteristics of the expected image.…”

Section: Introductionmentioning

confidence: 99%

“…Recently, a least‐squares approach was developed and was shown to be an effective alternative compared to the L‐curve and GCV methods for automatic selection of regularization parameter . Subsequent to this work, an error estimate‐based method was proposed and shown to be computationally efficient compared to the least‐squares method in determining this regularization parameter automatically . Despite all these developments, automated evaluation of regularization parameter is still computationally demanding and the metric for an automated choice of regularization parameter may not provide the desired reconstructed image characteristics as regularization inherently blurs the reconstructed image .…”

Section: Introductionmentioning

confidence: 99%

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“…The standard (zeroth order) choice for L is identity matrix ( I ); thus, the solution becomes

x_{Tik} = {(A^{T} A + λ I)}^{- 1} A^{T} b .

{boldM}_{q + 1} false(β_{1} e_{1} false) = b

A {boldR}_{q} = {boldM}_{q + 1} {boldB}_{q}

A^{T} {boldM}_{q + 1} = {boldR}_{q} {boldB}_{q}^{T} + α_{q + 1} r_{q + 1} e_{q + 1}^{T}

where M q = [ m 1 , m 2 ,…, m q ] and R q = [ r 1 , r 2 ,…, r q ] are the left and right orthogonal Lanczos matrices of dimensions m × ( q + 1) and n 2 × q respectively.…”