Vehicular Ad-hoc Networks (VANETs) are integral to the fabric of Intelligent Transportation Systems (ITSs), facilitating essential vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I) communications. However, the rising prevalence of jamming attacks, characterized by the intentional disruption of communications through interference signals, presents a significant challenge to the security of VANETs and, consequently, public safety. This emerging threat highlights a critical research gap in the development of sophisticated, AI-driven security solutions for VANETs. In response to this challenge, our study introduces an innovative artificial intelligence (AI) model, meticulously engineered to detect jamming attacks in VANETs. This model represents a synergistic integration of an array of machine learning (ML) and deep learning (DL) classifiers, meticulously analyzing signal characteristics within VANET communication channels. Its primary aim is the effective identification of anomalous patterns signaling the presence of jamming attacks. Extensive simulations were conducted to rigorously test the model’s efficacy, which yielded encouraging results. Initially, we assessed the detection accuracy of 14 different ML classifiers and 4 DL classifiers. Subsequently, we proposed a voting-based ensemble AI classifier combining the most accurate ML and DL classifiers, namely Random Forest (RF), Extra Tree (ET), and fine-tuned Convolutional Neural Network (CNN). This ensemble classifier, RF+ET+CNN, achieved the highest detection accuracy, outperforming the individual classifiers. Specifically, the CNN algorithm demonstrated an exceptional detection accuracy of 99.133%, while the RF and ET classifiers were the most accurate among the ML algorithms tested, with accuracy rates of 97.4359% and 97.4357%, respectively. Notably, the proposed RF+ET+CNN ensemble classifier achieved an impressive detection accuracy of 99.8125%. These findings underscore the superiority of our propos...