This comprehensive report, "Quantum Circuit Input Beyond QML," examines the diverse methods for providing input parameters to non-Quantum Machine Learning (QML) quantum circuits as of September 2025. It highlights a core distinction between problem-structure encoding for non-QML, where a problem's inherent mathematical definition is mapped onto quantum hardware, and data-feature encoding used in QML for embedding large datasets. The report categorizes non-QML input mechanisms into three main families: Hamiltonian-based encoding (for simulation and optimization), direct state preparation (for linear algebra problems like HHL), and algorithmic circuit synthesis (for algorithms like Shor's). A central theme is the "data loading bottleneck," which manifests as different resource overheads—exponential complexity for arbitrary state preparation, substantial qubit and gate costs for Hamiltonian block encoding, and significant compilation costs for circuit synthesis—all presenting major challenges to achieving practical quantum advantage. The analysis emphasizes that future advancements rely on exploiting inherent problem structure, co-designing algorithms and hardware, and integrating with quantum error correction.

Some equations were not properly rendered by the second stage AI, which is handling the hosts. Attempting to verbally describe quantum computing math is far from ideal and the AI was not trained for that. The written research reports are always superior, but audio podcasts stay convenient.

Research done with the help of artificial intelligence, and presented by two AI-generated hosts.

Note: “qubit” was incorrectly pronounced as “kwibit” instead of “cue-bit” (the standard pronunciation). This issue arises from phonetic handling, and it cannot be easily corrected because the second-stage AI is not reading from a fixed script but generating new dialogue from the research report. As a result, all the episodes on Quantum Computing were affected by this error.