In Nepal, air pollution is a serious public health concern, especially in cities like Kathmandu where particulate matter (PM2.5 and PM10) has a major influence on respiratory health and air quality. The Air Quality Index (AQI) is predicted in this work using a Random Forest Regressor, and the model's predictions are interpreted using SHAP (SHapley Additive exPlanations) analysis. With the lowest Testing RMSE (0.23) and flawless R2 scores (1.00), CatBoost performs better than other models, demonstrating its greater accuracy and generalization which is cross validated using a nested cross validation approach. NowCast Concentration and Raw Concentration are the most important elements influencing AQI values, according to SHAP research, which shows that the machine learning results are highly accurate. Their significance as major contributors to air pollution is highlighted by the fact that high values of these characteristics significantly raise the AQI. This study investigates the Hydrogen-Alpha (HA) biodegradable filter as a novel way to reduce the related health hazards. With removal efficiency of more than 98% for PM2.5 and 99.24% for PM10, the HA filter offers exceptional defense against dangerous airborne particles. These devices, which are biodegradable face masks and cigarette filters, address the environmental issues associated with traditional filters' non-biodegradable trash while also lowering exposure to air contaminants.

Abstract: This study offers a revolutionary strategy to developing wheelchairs based on the Brain-Computer Interface (BCI) that incorporates Artificial Intelligence (AI) using a The device uses electroencephalogram (EEG) data to mimic wheelchair navigation. Five different models were trained on a pre-filtered dataset that was divided into fixed-length windows using a sliding window technique. Each window contained statistical measurements, FFT coefficients for different frequency bands, and a label identifying the activity carried out during that window that was taken from an open-source Kaggle repository. The XGBoost model outperformed the other models, CatBoost, GRU, SVC, and XGBoost, with an accuracy of 60%. The CatBoost model with a major difference between training and testing accuracy shows overfitting, and similarly, the bestperforming model, with SVC, was implemented in a tkinter GUI. The wheelchair movement could be simulated in various directions, and a Raspberry Pi-powered wheelchair system for braincomputer interface is proposed here. Keywords: Brain Computer Interfacing, FFT (Fast Fourier Transform), Raspberry-pi, electroencephalogram 1. Introduction Brain-Computer Interfaces (BCIs) represent a cutting-edge technology that facilitates direct communication between the human brain and external devices. In recent years, BCIs have been widely explored for assisting individuals with mobility impairments. This paper focuses on a novel BCI-based wheelchair control system that leverages EEG signals associated with control using various movements related dataset. The system incorporates various machine learning models with various optimization techniques for hyper-parameter tuning and finally, shows an attention mechanism for enhancing the performance of Bi-directional Long Short-Term Memory (Bi-LSTM) networks, which are employed for EEG signal classification. To integrate the braincomputer interface (BCI) for the wheelchair, an analysis of brain activity is necessary-based on modern technology. The signs of brain activity can be obtained using a variety of techniques [1]. In order to help people with severe disabilities live their daily lives, new aids, gadgets, and assistive technologies are required, as demonstrated by the pandemic emergency of the coronavirus illness 2019 (COVID-19). Brain-Computer Interfaces (BCIs) that use electroencephalography (EEG) can help people who experience major health issues become more independent and participate in activities more easily. This can improve their general well-being and prevent deficits [2].