Balistokardiyografi sinyalleri ile derin öğrenme tabanlı hipertansiyon tespiti

Year 2023, Volume: 12 Issue: 3, 704 - 715, 15.07.2023

Salih Taha Alperen Özçelik , Hakan Uyanık , Abdülkadir Şengür

https://doi.org/10.28948/ngumuh.1257145

Abstract

Kan basıncı, damarlardaki kanın damar duvarlarına uyguladığı basınçtır. Bu basınç değerinin normal kabul edilen seviyelerin üzerinde seyir etmesi yüksek tansiyon (YT) veya hipertansiyon (HPT) olarak bilinir. Hayat kalitesini negatif yönde etkileyen, çoğu zaman organlarda çeşitli tahribatlara sebep olan ve ölümlere yol açabilen bu sağlık probleminin teşhisi oldukça önemlidir. Bu çalışmada, balistokardiyografi (BKG) sinyalleri kullanılarak HPT'nin otomatik teşhisine yönelik bir yöntem önerilmiştir. Bunun için BKG sinyalleri, sürekli dalgacık dönüşümü filtre bankası (SDDFB) yöntemi kullanılarak zaman-frekans domenine taşınmıştır. Bu işlemler yapılırken kullanılan dönüşüm yönteminde bazı parametre ayarları gerçekleştirilerek dönüşümün kalitesi arttırılmıştır. Daha sonra elde edilen görüntüler ResNet18, ResNet50, VGG16 ve AlexNet evrişimsel sinir ağlarıyla sınıflandırılmış ve elde edilen sonuçlar karşılaştırılmıştır. Önerilen yöntem ile ResNet18, ResNet50, VGG16 ve AlexNet mimarileri için sırasıyla %98,92, %99,34 ve %99,22 ve %98,07 sınıflandırma doğruluğu elde etmiştir. Elde edilen bu yüksek sınıflandırma sonuçları önerilen yöntemin hipertansiyon teşhisi için kullanılabileceğini ispatlar niteliktedir.

Keywords

Hipertansiyon, BKG sinyali, Derin Öğrenme, Sürekli Dalgacık Dönüşümü Filtre Bankası

Deep learning based hypertension detection with ballistocardiography signals

Abstract

Blood pressure is the pressure exerted by the blood in the vessels against the vessel walls. If this pressure value is above normal levels, it is known as high blood pressure (HBP) or hypertension (HPT). The diagnosis of this health problem, which negatively affects the quality of life, often causes various damage to organs and can lead to death, is very important. In this study, a method for automatic diagnosis of HPT using ballistocardiography (BCG) signals is proposed. For this, BCG signals are transferred to the time-frequency domain using the continuous wavelet transform filter bank (CWTFB) method. The quality of the conversion has been increased by making some parameter settings in the conversion method used while performing these operations. Then, the obtained images were classified with ResNet18, ResNet50, VGG16 and AlexNet convolutional neural networks and the obtained results were compared. With the proposed method, classification accuracy of 98.92%, 99.34%, 99.22% and 98.07% was obtained for ResNet18, ResNet50, VGG16 and AlexNet architectures, respectively. These high classification results obtained prove that the proposed method can be used for the diagnosis of hypertension.

Keywords

Hypertension, BCG signals, Deep learning, Continuous wavelet transform filter bank

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