Plant health is increasingly threatened by environmental stressors,improper irrigation practices,and animal interference,leading to decreased growth and vitality.Current solutions often fail to integrate autonomous ir...Plant health is increasingly threatened by environmental stressors,improper irrigation practices,and animal interference,leading to decreased growth and vitality.Current solutions often fail to integrate autonomous irrigation with effective deterrent mechanisms in a single system.This paper presents the Intelligent Sapling Shield,an innovative device designed to enhance plant protection and optimize growth conditions.The system features an autonomous soil moisture regulation mechanism to optimize water usage,reducing wastage and irrigation costs,while a vibrational deterrent system mitigates animal interference,preventing crop damage.Constructed from plastic mesh,the device ensures proper sunlight exposure,airflow,and shade,with an integrated waterproof LED strip for night-time illumination.Results demonstrate that the system maintains optimal soil moisture levels,reducing water consumption compared to traditional irrigation methods.Additionally,automated plant care minimizes labour requirements,ensuring consistent hydration and protection while enhancing crop resilience and yield.The design emphasizes affordability,portability,and ease of installation,making it suitable for both small-scale urban gardening and large-scale agricultural deployment.Its modular structure allows for customization depending on plant type and environmental conditions,further extending its applicability.By integrating irrigation efficiency,protective deterrence,and energy-efficient illumination,the Intelligent Sapling Shield creates a holistic solution that addresses multiple challenges faced in plant cultivation.By promoting cost-effective,resource-efficient,and sustainable agricultural practices,the Intelligent Sapling Shield contributes to urban greening initiatives and biodiversity conservation,supporting long-term ecological sustainability and offering significant potential for future smart farming innovations.展开更多
This research presents an ultra-wideband (UWB) textile antenna designfor body-centric applications. The antenna is printed on a 1 mm thick denim substrate with a 1.7 relative permittivity. The jeans substrate is sandw...This research presents an ultra-wideband (UWB) textile antenna designfor body-centric applications. The antenna is printed on a 1 mm thick denim substrate with a 1.7 relative permittivity. The jeans substrate is sandwiched between apartial ground plane and a radiating patch with a Q-shaped slot. The slotted radiating patch is placed above the substrate and measures 27.8 mm × 23.8 mm. In freespace, the antenna covers the ultra-wideband spectrum designated by the FederalCommunication Commission (FCC). Various parameters of the antenna designwere changed for further performance evaluation. Depending on the operating frequency, the antenna's realized gain varied from 2.7 to 5 dB. The antenna achievedhigh radiation efficiency with an omnidirectional radiation pattern. A parametricstudy was performed in research on varying antenna substrates and other components of the antenna. The three outermost layers of the human body are used tomodel a human phantom for on-body simulation. After that, the antenna wasplaced at five different distances from the phantom. The findings demonstrate thatat close distances to the phantom, the antenna's gain and efficiency at lower frequencies are reduced. The antenna's radiation efficiency and gain were muchhigher at higher frequencies for distances greater than 6 mm. Compared to freespace, the antenna's radiation pattern was more omnidirectional, especially athigher frequencies. This antenna is novel, compact and has an ultra wide bandwidth, a maximum of 94.60% radiation efficiency and a 5 dBi gain that will makeit a good candidate for body-centric communications.展开更多
Nowadays,deepfake is wreaking havoc on society.Deepfake content is created with the help of artificial intelligence and machine learning to replace one person’s likeness with another person in pictures or recorded vid...Nowadays,deepfake is wreaking havoc on society.Deepfake content is created with the help of artificial intelligence and machine learning to replace one person’s likeness with another person in pictures or recorded videos.Although visual media manipulations are not new,the introduction of deepfakes has marked a breakthrough in creating fake media and information.These manipulated pic-tures and videos will undoubtedly have an enormous societal impact.Deepfake uses the latest technology like Artificial Intelligence(AI),Machine Learning(ML),and Deep Learning(DL)to construct automated methods for creating fake content that is becoming increasingly difficult to detect with the human eye.Therefore,automated solutions employed by DL can be an efficient approach for detecting deepfake.Though the“black-box”nature of the DL system allows for robust predictions,they cannot be completely trustworthy.Explainability is thefirst step toward achieving transparency,but the existing incapacity of DL to explain its own decisions to human users limits the efficacy of these systems.Though Explainable Artificial Intelligence(XAI)can solve this problem by inter-preting the predictions of these systems.This work proposes to provide a compre-hensive study of deepfake detection using the DL method and analyze the result of the most effective algorithm with Local Interpretable Model-Agnostic Explana-tions(LIME)to assure its validity and reliability.This study identifies real and deepfake images using different Convolutional Neural Network(CNN)models to get the best accuracy.It also explains which part of the image caused the model to make a specific classification using the LIME algorithm.To apply the CNN model,the dataset is taken from Kaggle,which includes 70 k real images from the Flickr dataset collected by Nvidia and 70 k fake faces generated by StyleGAN of 256 px in size.For experimental results,Jupyter notebook,TensorFlow,Num-Py,and Pandas were used as software,InceptionResnetV2,DenseNet201,Incep-tionV3,and ResNet152V2 were used as CNN models.All these models’performances were good enough,such as InceptionV3 gained 99.68%accuracy,ResNet152V2 got an accuracy of 99.19%,and DenseNet201 performed with 99.81%accuracy.However,InceptionResNetV2 achieved the highest accuracy of 99.87%,which was verified later with the LIME algorithm for XAI,where the proposed method performed the best.The obtained results and dependability demonstrate its preference for detecting deepfake images effectively.展开更多
文摘Plant health is increasingly threatened by environmental stressors,improper irrigation practices,and animal interference,leading to decreased growth and vitality.Current solutions often fail to integrate autonomous irrigation with effective deterrent mechanisms in a single system.This paper presents the Intelligent Sapling Shield,an innovative device designed to enhance plant protection and optimize growth conditions.The system features an autonomous soil moisture regulation mechanism to optimize water usage,reducing wastage and irrigation costs,while a vibrational deterrent system mitigates animal interference,preventing crop damage.Constructed from plastic mesh,the device ensures proper sunlight exposure,airflow,and shade,with an integrated waterproof LED strip for night-time illumination.Results demonstrate that the system maintains optimal soil moisture levels,reducing water consumption compared to traditional irrigation methods.Additionally,automated plant care minimizes labour requirements,ensuring consistent hydration and protection while enhancing crop resilience and yield.The design emphasizes affordability,portability,and ease of installation,making it suitable for both small-scale urban gardening and large-scale agricultural deployment.Its modular structure allows for customization depending on plant type and environmental conditions,further extending its applicability.By integrating irrigation efficiency,protective deterrence,and energy-efficient illumination,the Intelligent Sapling Shield creates a holistic solution that addresses multiple challenges faced in plant cultivation.By promoting cost-effective,resource-efficient,and sustainable agricultural practices,the Intelligent Sapling Shield contributes to urban greening initiatives and biodiversity conservation,supporting long-term ecological sustainability and offering significant potential for future smart farming innovations.
基金support from Taif University Researchers Supporting Project(TURSP-2020/214),Taif University,Taif,Saudi Arabia.
文摘This research presents an ultra-wideband (UWB) textile antenna designfor body-centric applications. The antenna is printed on a 1 mm thick denim substrate with a 1.7 relative permittivity. The jeans substrate is sandwiched between apartial ground plane and a radiating patch with a Q-shaped slot. The slotted radiating patch is placed above the substrate and measures 27.8 mm × 23.8 mm. In freespace, the antenna covers the ultra-wideband spectrum designated by the FederalCommunication Commission (FCC). Various parameters of the antenna designwere changed for further performance evaluation. Depending on the operating frequency, the antenna's realized gain varied from 2.7 to 5 dB. The antenna achievedhigh radiation efficiency with an omnidirectional radiation pattern. A parametricstudy was performed in research on varying antenna substrates and other components of the antenna. The three outermost layers of the human body are used tomodel a human phantom for on-body simulation. After that, the antenna wasplaced at five different distances from the phantom. The findings demonstrate thatat close distances to the phantom, the antenna's gain and efficiency at lower frequencies are reduced. The antenna's radiation efficiency and gain were muchhigher at higher frequencies for distances greater than 6 mm. Compared to freespace, the antenna's radiation pattern was more omnidirectional, especially athigher frequencies. This antenna is novel, compact and has an ultra wide bandwidth, a maximum of 94.60% radiation efficiency and a 5 dBi gain that will makeit a good candidate for body-centric communications.
基金Princess Nourah bint Abdulrahman University Researchers Supporting Project number(PNURSP2022R193)Princess Nourah bint Abdulrahman University,Riyadh,Saudi Arabia.Taif University Researchers Supporting Project(TURSP-2020/26),Taif University,Taif,Saudi Arabia.
文摘Nowadays,deepfake is wreaking havoc on society.Deepfake content is created with the help of artificial intelligence and machine learning to replace one person’s likeness with another person in pictures or recorded videos.Although visual media manipulations are not new,the introduction of deepfakes has marked a breakthrough in creating fake media and information.These manipulated pic-tures and videos will undoubtedly have an enormous societal impact.Deepfake uses the latest technology like Artificial Intelligence(AI),Machine Learning(ML),and Deep Learning(DL)to construct automated methods for creating fake content that is becoming increasingly difficult to detect with the human eye.Therefore,automated solutions employed by DL can be an efficient approach for detecting deepfake.Though the“black-box”nature of the DL system allows for robust predictions,they cannot be completely trustworthy.Explainability is thefirst step toward achieving transparency,but the existing incapacity of DL to explain its own decisions to human users limits the efficacy of these systems.Though Explainable Artificial Intelligence(XAI)can solve this problem by inter-preting the predictions of these systems.This work proposes to provide a compre-hensive study of deepfake detection using the DL method and analyze the result of the most effective algorithm with Local Interpretable Model-Agnostic Explana-tions(LIME)to assure its validity and reliability.This study identifies real and deepfake images using different Convolutional Neural Network(CNN)models to get the best accuracy.It also explains which part of the image caused the model to make a specific classification using the LIME algorithm.To apply the CNN model,the dataset is taken from Kaggle,which includes 70 k real images from the Flickr dataset collected by Nvidia and 70 k fake faces generated by StyleGAN of 256 px in size.For experimental results,Jupyter notebook,TensorFlow,Num-Py,and Pandas were used as software,InceptionResnetV2,DenseNet201,Incep-tionV3,and ResNet152V2 were used as CNN models.All these models’performances were good enough,such as InceptionV3 gained 99.68%accuracy,ResNet152V2 got an accuracy of 99.19%,and DenseNet201 performed with 99.81%accuracy.However,InceptionResNetV2 achieved the highest accuracy of 99.87%,which was verified later with the LIME algorithm for XAI,where the proposed method performed the best.The obtained results and dependability demonstrate its preference for detecting deepfake images effectively.
