Rotation-scale equivariant steerable filters
Rotation-scale equivariant steerable filters
Incorporating either rotation equivariance or scale equivariance into CNNs has proved to be effective in improving models’ generalization performance. However, jointly integrating rotation and scale equivariance into CNNs has not been widely explored. Digital histology imaging of biopsy tissue can be captured at arbitrary orientation and magnification and stored at different resolutions, resulting in cells appearing in different scales. When conventional CNNs are applied to histopathology image analysis, the generalization performance of models is limited because 1) a part of the parameters of filters are trained to fit rotation transformation, thus decreasing the capability of learning other discriminative features; 2) fixed-size filters trained on images at a given scale fail to generalize to those at different scales. To deal with these issues, we propose the Rotation-Scale Equivariant Steerable Filter (RSESF), which incorporates steerable filters and scale-space theory. The RSESF
contains copies of filters that are linear combinations of Gaussian filters, whose direction is controlled by directional derivatives and whose scale parameters are trainable but constrained to span disjoint scales in successive layers of the network. Extensive experiments on two gland segmentation datasets demonstrate that our method outperforms other approaches,
with much fewer trainable parameters and fewer GPU resources required. The
code will be available soon
sasan, mahmoodi
Yang, Yilong
a0d162d2-c118-40be-b724-d2e03bffc026
Dasmahapatra, Srinandan
6716035c-8073-4e52-939f-c957bd3a5b7d
Mahmoodi, Sasan
91ca8da4-95dc-4c1e-ac0e-f2c08d6ac7cf
15 March 2023
Yang, Yilong
a0d162d2-c118-40be-b724-d2e03bffc026
Dasmahapatra, Srinandan
6716035c-8073-4e52-939f-c957bd3a5b7d
Mahmoodi, Sasan
91ca8da4-95dc-4c1e-ac0e-f2c08d6ac7cf
Yang, Yilong, Dasmahapatra, Srinandan and Mahmoodi, Sasan
(2023)
Rotation-scale equivariant steerable filters.
Oguz, Ipek
(ed.)
In International conference on Medical Imaging with Deep Learning.
21 pp
.
Record type:
Conference or Workshop Item
(Paper)
Abstract
Incorporating either rotation equivariance or scale equivariance into CNNs has proved to be effective in improving models’ generalization performance. However, jointly integrating rotation and scale equivariance into CNNs has not been widely explored. Digital histology imaging of biopsy tissue can be captured at arbitrary orientation and magnification and stored at different resolutions, resulting in cells appearing in different scales. When conventional CNNs are applied to histopathology image analysis, the generalization performance of models is limited because 1) a part of the parameters of filters are trained to fit rotation transformation, thus decreasing the capability of learning other discriminative features; 2) fixed-size filters trained on images at a given scale fail to generalize to those at different scales. To deal with these issues, we propose the Rotation-Scale Equivariant Steerable Filter (RSESF), which incorporates steerable filters and scale-space theory. The RSESF
contains copies of filters that are linear combinations of Gaussian filters, whose direction is controlled by directional derivatives and whose scale parameters are trainable but constrained to span disjoint scales in successive layers of the network. Extensive experiments on two gland segmentation datasets demonstrate that our method outperforms other approaches,
with much fewer trainable parameters and fewer GPU resources required. The
code will be available soon
Text
MIDL_Manuscript_Rivised17Feb23
More information
Published date: 15 March 2023
Keywords:
sasan, mahmoodi
Identifiers
Local EPrints ID: 476692
URI: http://eprints.soton.ac.uk/id/eprint/476692
PURE UUID: c1cb870f-acd0-4b13-b622-6056f80ca3f2
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Date deposited: 11 May 2023 16:44
Last modified: 18 Mar 2024 05:03
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Contributors
Author:
Yilong Yang
Author:
Srinandan Dasmahapatra
Author:
Sasan Mahmoodi
Editor:
Ipek Oguz
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