Automatic signal classification is utilized in various medical and industrial applications, particularly in schizophrenia (SZ) diagnosis, one of the most prevalent chronic neurological diseases. SZ is a significant mental illness that negatively affects a person’s behavior by causing things like speech impairment and delusions. In this study, electroencephalography (EEG) signals, a non-invasive diagnostic technique, are being investigated to distinguish SZ patients from healthy people by proposing a pyramidal spatial-based feature attention network (PSFAN). The proposed PSFAN consists of dilated convolutions to extract multiscale deep features in a pyramidal fashion from 2-dimensional images converted from 4-sec EEG recordings. Then, each level of the pyramid includes a spatial attention block (SAB) to concentrate on the robust features that can identify SZ patients. Finally, all the SAB feature maps are concatenated and fed into dense layers, followed by a Softmax layer for classification purposes. The performance of the PSFAN is evaluated on two datasets using three experiments, namely the subject-dependent, subject-independent, and cross-dataset. Moreover, statistical hypothesis testing is performed using Wilcoxon’s Rank-Sum test to signify the model performance. Experimental results show that the PSFAN statistically defeats 11 contemporary methods, proving its effectiveness for medical industrial applications. Source code: https://github.com/KarnatiMOHAN/PSFAN-Schizophrenia-Identification-using-EEG-signals.