To enhance the Generative Adversarial Networks (GAN) used in the High Energy Physics (HEP) community for fast event simulation with Quantum Circuit Born Machine (QCBM), a versatile and efficient quantum generative model, to sample the prior (latent space). The quantum enhanced architecture, Quantum Circuit Associative Adversarial Network (QC-AAN), was shown previously to not only have similar performance as DCGAN but also have practical quantum advantages such as greater training stability on MNIST [1]. Instabilities of the training caused by diverging gradient and vanishing gradient are a major practical concern, especially for the HEP community*[2]. So, if a QC-AAN can make the training for GANs more robust, we would expect it to have practical value for the HEP community. We plan to build upon CaloGAN [3], a popular architecture to generate HEP detector responses and use vanilla CaloGAN as a baseline for comparison.
* To overcome the training instability, HEP community often uses Wasserstein GANs. Due to time constraints, we plan to investigate a quantum enhanced Wassertein GANs in the future.
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Construct QC-AAN with QCBM and CaloGAN
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Run experiments on partial ECal Shower dataset [4] and compare QC-ANN against vanilla CaloGAN with the metrics in the next section
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Optimize multi-basis QCBM
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Run experiments on full ECal Shower dataset and compare QC-ANN against vanilla CaloGAN with the metrics in the next section
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If time permits, repeat the experiments and compare it against
- Wasserstein CaloGAN
- Restricted Boltzmann Machine (RBM) based AAN
- Inception score
- HEP based similarity score
- 1-D showering statistics
- Energy flow polynomials (EFPs)
- Training stability
- Mode (energy) diversity
For a non-techinical overview, please refer to this slides.
[1] M. S. Rudolph, N. B. Toussaint, A. Katabarwa, S. Johri, B. Peropadre, and A. Perdomo-Ortiz, Generation of High-Resolution Handwritten Digits with an Ion-Trap Quantum Computer, (2020).
[2] A. Butter and T. Plehn, Generative Networks for LHC Events, ArXiv:2008.08558 [Hep-Ph] (2020).
[3] M. Paganini, L. de Oliveira, and B. Nachman, CaloGAN: Simulating 3D High Energy Particle Showers in Multi-Layer Electromagnetic Calorimeters with Generative Adversarial Networks, Phys. Rev. D 97, 014021 (2018).
[4] Nachman, Benjamin; de Oliveira, Luke; Paganini, Michela (2017), “Electromagnetic Calorimeter Shower Images”, Mendeley Data, V1, doi: 10.17632/pvn3xc3wy5.1