21 research outputs found
Joint-SRVDNet: Joint Super Resolution and Vehicle Detection Network
In many domestic and military applications, aerial vehicle detection and
super-resolutionalgorithms are frequently developed and applied independently.
However, aerial vehicle detection on super-resolved images remains a
challenging task due to the lack of discriminative information in the
super-resolved images. To address this problem, we propose a Joint
Super-Resolution and Vehicle DetectionNetwork (Joint-SRVDNet) that tries to
generate discriminative, high-resolution images of vehicles fromlow-resolution
aerial images. First, aerial images are up-scaled by a factor of 4x using a
Multi-scaleGenerative Adversarial Network (MsGAN), which has multiple
intermediate outputs with increasingresolutions. Second, a detector is trained
on super-resolved images that are upscaled by factor 4x usingMsGAN architecture
and finally, the detection loss is minimized jointly with the super-resolution
loss toencourage the target detector to be sensitive to the subsequent
super-resolution training. The network jointlylearns hierarchical and
discriminative features of targets and produces optimal super-resolution
results. Weperform both quantitative and qualitative evaluation of our proposed
network on VEDAI, xView and DOTAdatasets. The experimental results show that
our proposed framework achieves better visual quality than thestate-of-the-art
methods for aerial super-resolution with 4x up-scaling factor and improves the
accuracy ofaerial vehicle detection
Polarimetric Thermal to Visible Face Verification via Self-Attention Guided Synthesis
Polarimetric thermal to visible face verification entails matching two images
that contain significant domain differences. Several recent approaches have
attempted to synthesize visible faces from thermal images for cross-modal
matching. In this paper, we take a different approach in which rather than
focusing only on synthesizing visible faces from thermal faces, we also propose
to synthesize thermal faces from visible faces. Our intuition is based on the
fact that thermal images also contain some discriminative information about the
person for verification. Deep features from a pre-trained Convolutional Neural
Network (CNN) are extracted from the original as well as the synthesized
images. These features are then fused to generate a template which is then used
for verification. The proposed synthesis network is based on the self-attention
generative adversarial network (SAGAN) which essentially allows efficient
attention-guided image synthesis. Extensive experiments on the ARL polarimetric
thermal face dataset demonstrate that the proposed method achieves
state-of-the-art performance.Comment: This work is accepted at the 12th IAPR International Conference On
Biometrics (ICB 2019
Cross-Domain Identification for Thermal-to-Visible Face Recognition
Recent advances in domain adaptation, especially those applied to
heterogeneous facial recognition, typically rely upon restrictive Euclidean
loss functions (e.g., norm) which perform best when images from two
different domains (e.g., visible and thermal) are co-registered and temporally
synchronized. This paper proposes a novel domain adaptation framework that
combines a new feature mapping sub-network with existing deep feature models,
which are based on modified network architectures (e.g., VGG16 or Resnet50).
This framework is optimized by introducing new cross-domain identity and domain
invariance loss functions for thermal-to-visible face recognition, which
alleviates the requirement for precisely co-registered and synchronized
imagery. We provide extensive analysis of both features and loss functions
used, and compare the proposed domain adaptation framework with
state-of-the-art feature based domain adaptation models on a difficult dataset
containing facial imagery collected at varying ranges, poses, and expressions.
Moreover, we analyze the viability of the proposed framework for more
challenging tasks, such as non-frontal thermal-to-visible face recognition
Cross-Domain Identification for Thermal-to-Visible Face Recognition
Recent advances in domain adaptation, especially those applied to heterogeneous facial recognition, typically rely upon restrictive Euclidean loss functions (e.g., L2 norm) which perform best when images from two different domains (e.g., visible and thermal) are co-registered and temporally synchronized. This paper proposes a novel domain adaptation framework that combines a new feature mapping sub-network with existing deep feature models, which are based on modified network architectures (e.g., VGG16 or Resnet50). This framework is optimized by introducing new cross-domain identity and domain invariance loss functions for thermal-to-visible face recognition, which alleviates the requirement for precisely co-registered and synchronized imagery. We provide extensive analysis of both features and loss functions used, and compare the proposed domain adaptation framework with state-of-the-art feature based domain adaptation models on a difficult dataset containing facial imagery collected at varying ranges, poses, and expressions. Moreover, we analyze the viability of the proposed framework for more challenging tasks, such as non-frontal thermal-to-visible face recognition