2.1. Indirect approaches

Fikke et al. (Reference Fikke, Ronsten, Heimo, Kunz, Ostrozlik, Persson, Sabata, Wareing, Wichura, Chum, Laakso, Säntti and Makkonen2007) listed the available prototypes of ice detectors in the market. External weather parameters, such as temperature and humidity, combined with deterministic models, can be utilized to predict icing events indirectly (Molinder et al., Reference Molinder, Körnich, Olsson, Bergström and Sjöblom2018). Deterministic models require several parameters which must be provided as inputs in order to characterize the beginning or end of all types of icing events (wind, humidity, precipitation, etc.) (Wei et al., Reference Wei, Yang, Zuo and Zhong2020). Unfortunately, such parameters are not always measured in a standard way for icing risk assessment, especially in older-generation wind turbines (which may or may not have sensors for detecting such external parameters). Nevertheless, it may be possible to use weather forecasting models to derive an approximation of these values (Fikke et al., Reference Fikke, Ronsten, Heimo, Kunz, Ostrozlik, Persson, Sabata, Wareing, Wichura, Chum, Laakso, Säntti and Makkonen2007; Kreutz et al., Reference Kreutz, Alla, Lütjen, Ohlendorf, Freitag, Thoben, Zimnol and Greulich2023). However, dependence on approximations derived from such weather forecasting models (often based on numerical simulations) makes the operations and maintenance (O&M) process more complex, expensive, and not entirely reliable.

Despite the prevalence of existing sensor-based systems, there are still no industry standards in place which clearly define the values of the parameters for the tools—such as the threshold ratio for icing. Others have a coarse accuracy, which makes such sensors unstable for measuring light icing events. Pivotal measured parameters for detecting ice on the rotor blades are commonly used, like the droplet size distribution (Cattin et al., Reference Cattin, Heikkilä, Bourgeois, Raupach and Storck2016). In summary, most existing studies on indirect approaches have outlined that all systems have their shortcomings under specific conditions. In summary, and to our understanding, none of the existing ice detectors mentioned here have leveraged intelligent algorithms for detecting icing events.

2.2. Direct approaches

Direct ice detection techniques analyse changes in physical parameters caused by icing and can depend on (amongst others) inductance or optic systems (Battisti, Reference Battisti2015; Fakorede et al., Reference Fakorede, Feger, Ibrahim, Ilinca, Perron and Masson2016; Wei et al., Reference Wei, Yang, Zuo and Zhong2020). The latter are able to accomplish this on a thermal (heated wires) or optical (laser scanning) basis (Cattin, Reference Cattin2012). The main drawback of thermal solutions is that they are either very expensive or not able to derive the measurements automatically. Additionally, there can be large uncertainties depending on the utilized approach (Cattin, Reference Cattin2012). Another recent direct approach is the use of optical cameras to detect icing on the blades of a wind turbine. A camera is mounted on the spinner of the rotor, so that the camera is rotating and always pointing to the rotor blades. However, a key disadvantage of this approach is that the camera is strongly exposed to the external weather and the view angle to the blade is very flat. This makes it highly challenging to monitor the icing status on the tip of the blades (Wallenius and Lehtomäki, Reference Wallenius and Lehtomäki2016).

Previous studies (Zhang et al., Reference Zhang, Liu, Wang and Omariba2018; Liu et al., Reference Liu, Cheng, Kong, Wang and Cui2019; Yuan et al., Reference Yuan, Wang, Luo, Jiang, Long, Yu and Liu2019; Jiang and Jin, Reference Jiang and Jin2021; Kreutz et al., Reference Kreutz, Alla, Varasteh, Ohlendorf, Lütjen, Freitag and Thoben2021; Kemal et al., Reference Kemal, Başağa, Yavuz and Karimi2022) have utilized image data from automated optical cameras to train machine learning models (e.g., decision trees) as well as leveraged DL techniques for ice detection. They have all demonstrated near-perfect accuracy with regards to the degree of detecting ice, including near and far views of a blade, ice density, and light (Alvela Nieto et al., Reference Alvela Nieto, Gelbhardt, Ohlendorf, Thoben, Valle, Lehmhus, Gianoglio, Ragusa, Seminara, Bosse, Ibrahim and Thoben2023). However, it is integral to note that the characteristics of a wind park are unique. In the case where a neural model has been developed from a single scenario, the model compatibility with all scenarios (e.g., all rotor blade types) is not always implied.

Generative AI models such as CycleGAN have shown immense success toward synthetic data generation in multiple domains (including safety-critical areas) like healthcare (Sandfort et al., Reference Sandfort, Yan, Pickhardt and Summers2019; Motamed et al., Reference Motamed, Rogalla and Khalvati2021), remote sensing for wildfire detection (Park et al., Reference Park, Tran, Jung and Park2020), flood event detection (Pouyanfar et al., Reference Pouyanfar, Tao, Sadiq, Tian, Tu, Wang, Chen and Shyu2019), road surface detection for autonomous vehicles (Choi et al., Reference Choi, Heo and Ahn2021) and so forth. Particularly, the utilization of CycleGAN was helpful to make models from a single satellite compatible with all the satellites of the constellation. GANs have also been used for condition monitoring of various types of wind turbine gearboxes (Zhang et al., Reference Zhang, Wu, He, Lou and Gao2020).

In our study, the automated camera was mounted on the nacelle catching the blade by motion detection when it moves through the image. This approach has the advantage that it is not necessary to put a hole into the spinner, the camera is less exposed and the view angle toward the blade is more steep, that is, it is possible to see the whole blade in perspective. Further, this paper focuses on a different strand of research compared to existing studies. The use of algorithms based on generative AI detects icing on different blades from the RGB-camera images automatically—while most previous studies rely on manual analysis. The generation of synthetic data facilitates better compatibility of DL models originally developed for one specific wind turbine (i.e., rotor blades of a single turbine) to any other wind turbines.

4.1. CycleGAN for unpaired image-to-image translation

Image-to-image translation (Liu et al., Reference Liu, Breuel and Kautz2017) is a popular computer vision task that aims to automatically map images in one domain onto corresponding images in another domain. Conventional image-to-image translation relies on supervised learning models requiring labeled pairs of images between the source and target domains, which is rarely available in many real-world practical problems. This includes the wind industry in which there is often a lack of historically paired images across different scene representations (e.g., image of the same wind turbine rotor blade in summer and winter, day and night). Owing to this challenge, unsupervised image-to-image translation models are recently gaining prominence—as they do not require a paired dataset of images or additional domain expertise and can simply leverage existing unlabelled datasets (Hoyez et al., Reference Hoyez, Schockaert, Rambach, Mirbach and Stricker2022).

CycleGANs (Zhu et al., Reference Zhu, Park, Isola and Efros2017) are a type of generative adversarial network (GAN) model that can be used for unpaired image-to-image translation. They rely on unsupervised learning to automatically map patterns between images from two different domains—and thus learn to translate the images from one domain to the style of the other domain. The CycleGAN is based on the typical GAN architecture consisting of:

1. 1. Generator: The generator is a deep neural network (DNN) that aims to generate new (fake) images which would match the style of the target domain images, while preserving the underlying content of the source domain images. It achieves this by receiving continuous feedback from the discriminator as described next.

2. 2. Discriminator: The discriminator is another DNN that checks whether the new image generated by the generator is actually a real image (i.e., a copy of the original target domain images), or a truly novel (fake) image that modifies the source domain image to the style of the target domain. It acts as a basic classification model that aims to distinguish between real and fake images generated by the generator.

While the traditional GAN only has a single generator and a discriminator, the CycleGAN consists of two generators and two discriminators. It uses them to compute the cyclic-consistency loss—a loss metric that is used when translating images from domain A to B (or vice versa) by leveraging a mapping function G and mapping the translated image back to A (or vice versa) by utilizing a different mapping function F to quantify how close the generated (fake) image is to the original (real) image. The CycleGAN aims to learn a mapping $ G:\mathrm{Domain}\hskip0.35em A\to \mathrm{Domain}\hskip0.35em B $ during its training process to ensure that the probabilistic distribution of the images obtained with the function $ G(X) $ is identical to the probabilistic distribution of domain B images based on an adversarial loss (Zhu et al., Reference Zhu, Park, Isola and Efros2017). The model also learns an inverse mapping $ F:\mathrm{Domain}\;B\to \mathrm{Domain}\;A $ and computes the cyclic-consistency loss $ {\mathrm{\mathcal{L}}}_{\mathrm{cyc}}\left(G,F\right) $ :

(1) $$ {\displaystyle \begin{array}{l}{\mathrm{\mathcal{L}}}_{\mathrm{cyc}}\left(G,F\right)={E}_{x\sim {p}_{\mathrm{data}}(x)}\left[\parallel F\left(G(x)\right)-x{\parallel}_1\right]\\ {}\hskip8.7em +{E}_{y\sim {p}_{\mathrm{data}}(y)}\left[\parallel G\left(F(y)\right)-y{\parallel}_1\right],\end{array}} $$

wherein, $ x $ represents the images in training data for domain A ( $ x\hskip0.35em \in \hskip0.35em A $ ), $ y $ represents the images for domain B ( $ y\hskip0.35em \in \hskip0.35em B $ ) and $ E $ represents the expected values to ensure that $ F\left(G(X)\right)\approx X $ (or vice versa) by minimizing the value of the cyclic-consistency loss. We propose to utilize the CycleGAN model for learning to translate plain rotor blade images in domain A (without ice, as obtained during the summers) to rotor blade images with icing (as evident in the winter) in domain B. Figure 1 describes the proposed framework, wherein, CycleGAN is used as a generative AI model. Note that for simplicity, only one part of the CycleGAN is shown in this figure with one generator and one discriminator—there would be another similar generator and discriminator that would learn to translate from domain B to A. For more details on the generic model architecture of CycleGAN, the interested reader is referred to Liu et al. (Reference Liu, Breuel and Kautz2017) and Sinha (Reference Sinha2021).

Figure 1. Framework for leveraging CycleGAN for translating plain rotor blade images (without ice) into rotor blade images (with icing)—CycleGAN generic model architecture.

4.2. Neural style transfer algorithm

Neural style transfer with CNNs (Gatys et al., Reference Gatys, Ecker and Bethge2015; Jing et al., Reference Jing, Yang, Feng, Ye, Yu and Song2020) is a more traditional method of facilitating domain adaptation in computer vision tasks. The algorithm employs an optimization technique in a pretrained CNN (e.g., based on weights from VGG-16, VGG-19) to transform a content image to the style of a reference style image—while ensuring that the weighted sum of the content loss and style loss functions computed across the content, style and generated stylized images are minimized (Ganegedara, Reference Ganegedara2020; Jing et al., Reference Jing, Yang, Feng, Ye, Yu and Song2020). The weighted sum is represented as:

(2) $$ L=\alpha {L}_{\mathrm{content}}+\beta {L}_{\mathrm{style}}, $$

where $ {L}_{\mathrm{content}} $ represents the content loss, $ {L}_{\mathrm{style}} $ represents the style loss and $ \alpha $ , $ \beta $ are user-specified hyper-parameters during the CNN training process.

Note that while the CycleGAN does not require a corresponding style image to generate stylized images as it directly learns transferable representations from the content image, we observed that the CycleGAN generated suboptimal results for our problem compared to the neural style transfer algorithm. For our study, we used a combination of two different approaches for synthetic image generation with the neural style transfer algorithm:

1. 1. A VGG-19 model architecture (Simonyan and Zisserman, Reference Simonyan and Zisserman2014; Kavitha et al., Reference Kavitha, Dhanapriya, Vignesh and Baskaran2021), originally pretrained with weights from ImageNet for image classification.

2. 2. A pretrained fast style transfer model leveraging arbitrary image stylization (Ghiasi et al., Reference Ghiasi, Lee, Kudlur, Dumoulin, Shlens, Kim, Zafeiriou, Brostow and Mikolajczyk2017) (no fine-tuning required).

We leveraged images from the source domain that represent the ice texture on the rotor blades as style images. Note that the icing characteristics on wind turbine rotor blades are domain-invariant irrespective of rotor blade designs in the different wind parks—we aimed to reproduce this characteristic in our study. The goal is to modify the plain rotor blade images of the target domain (content images) with the icing characteristics of the source domain, to improve the generalizability of the model.

We realized that directly modifying the content images led to distorted background as well. To specifically modify the parts of the source image which contain the rotor blade, we followed an overlaying process—wherein, a mask is applied to the content image and a reverse mask is applied to the generated stylized image. The overlayed images are preprocessed (as discussed in Section 5) and finally utilized for training the CNN models for generalized ice detection. Figure 2 depicts the complete process of the proposed approach. It is integral to highlight that with the above process, the source domain images are only utilized for acquisition of the ice textures to modify the target domain plain rotor blade images. In simple terms, we have cropped-out the ice textures from source domain images before using them as style images, which is based on the foundation that ice textures will be same in both the source as well as target domains and are independent of wind park locations. Additionally, the above method ensures that we are not modifying the whole target domain image, but only the segment of the plain rotor blade (without ice) since the background is removed beforehand with the masking/overlaying process.

Figure 2. Framework for generalized ice detection with neural style transfer. Plain rotor blades in the target domain (B) are styled with ice from the source domain (A).

5.1. CycleGAN

For generating synthetic data with the CycleGAN, we experimented by considering three different scenarios:

• 1. Training CycleGAN with wind park A plain rotor blade images as source domain, wind park A rotor blade with ice images as target domain, wind park B plain rotor blade images as test data during inference. The goal here is to transform the plain rotor blade images of wind park B to rotor blade with ice images.

• 2. Training CycleGAN with wind park B plain rotor blade images as source domain, wind park B rotor blade with ice images as target domain, wind park A plain rotor blade images as test data during inference. The goal here is to transform the plain rotor blade images of wind park A to rotor blade with ice images.

• 3. Using a pretrained Summer2Winter Yosemite model,Footnote ¹ with (a) wind park A and (b) wind park B plain rotor blade images as test data during inference.

For CycleGAN modeling strategies (1) and (2), we used 200 images for the background class and 400 images for every other class to train the models. An initial learning rate of 0.0002 was used for the CycleGAN. The number of training samples was the same for both wind parks. While for Wind park A the remaining 200 images per class were used as a test set, for wind park B the remaining 800 images per class were incorporated as a test set. The class containing plain rotor blades that were modified to show ice characteristics in the training set consisted of 50 unique modified plain rotor blade images that were augmented using random rotation to an amount of 400 images.

We used CycleGAN’s resize and crop method for preprocessing the images for all three strategies—with a load size of 256 and crop size of 256 to prevent losing out on the original image segments (particularly the rotor blade) during training. For all strategies, the models were trained for a total of 200 epochs (100 epochs with the initial learning rate  $ + $  100 epochs with a step-based decay in learning rate). A batch size of 16 was used during training. For all other hyper-parameters, default values were used as in Zhu et al. (Reference Zhu, Park, Isola and Efros2017). Note that the same train-test splits of the dataset are used in both the CycleGAN and the neural style transfer algorithm (described below) for fair comparison.

5.2. Neural style transfer algorithm

For neural style transfer, we leveraged the intermediate layers (without the classification head) of the VGG-19 model and applied the Adam optimizer with the following hyper-parameters: a learning rate of 0.02, beta_1 = 0.99 and epsilon = 0.1 to train the model for 40 epochs with 100 steps per epoch and modify the content with the style from our preprocessed images. As the generation of the images at this stage leads to high-frequency artifacts and significant variation loss, a denoising process for further optimization of the images over 40 epochs with 100 steps per epoch and a total variation weight of 30 was used. Default hyperparameter values for the fast style transfer model (Ghiasi et al., Reference Ghiasi, Lee, Kudlur, Dumoulin, Shlens, Kim, Zafeiriou, Brostow and Mikolajczyk2017) were applied. Fifty rotor blade images of the target domain are style-transferred to generate 200 additional synthetic images for the ice class with the previously described techniques.