Complex-valued signals encode both amplitude and phase, yet most deep models treat attention as real-valued correlation, overlooking interference effects. We introduce the Holographic Transformer, a physics-inspired architecture that incorporates wave interference principles into self-attention. Holographic attention modulates interactions by relative phase and coherently superimposes values, ensuring consistency between amplitude and phase. A dual-headed decoder simultaneously reconstructs the input and predicts task outputs, preventing phase collapse when losses prioritize magnitude over phase. We demonstrate that holographic attention implements a discrete interference operator and maintains phase consistency under linear mixing. Experiments on PolSAR image classification and wireless channel prediction show strong performance, achieving high classification accuracy and F1 scores, low regression error, and increased robustness to phase perturbations. These results highlight that enforcing physical consistency in attention leads to generalizable improvements in complex-valued learning and provides a unified, physics-based framework for coherent signal modeling. The code is available at https://github.com/EonHao/Holographic-Transformers.

Deep convolutional image classifiers progressively transform the spatial variability into a smaller number of channels, which linearly separates all classes. A fundamental challenge is to understand the role of rectifiers together with convolutional filters in this transformation. Rectifiers with biases are often interpreted as thresholding operators which improve sparsity and discrimination. This paper demonstrates that it is a different phase collapse mechanism which explains the ability to progressively eliminate spatial variability, while improving linear class separation. This is explained and shown numerically by defining a simplified complex-valued convolutional network architecture. It implements spatial convolutions with wavelet filters and uses a complex modulus to collapse phase variables. This phase collapse network reaches the classification accuracy of ResNets of similar depths, whereas its performance is considerably degraded when replacing the phase collapse with thresholding operators. This is justified by explaining how iterated phase collapses progressively improve separation of class means, as opposed to thresholding non-linearities.