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    This study validates a theoretical method for predicting optical radiation distribution by decomposing emitting source power. Practical and numerical examples demonstrate its effectiveness in single and multi-surface optical systems, ensuring traceability to the candela.

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    Area of Science:

    • Optical Engineering
    • Metrology
    • Radiometry

    Background:

    • Theoretical framework for predicting radiation distribution in optical systems was introduced in Part I.
    • This framework relies on decomposing emitting source power.
    • Experimental validation is crucial for theoretical models in optical engineering.

    Purpose of the Study:

    • To validate the theoretical method for predicting radiation distribution.
    • To demonstrate the practical application of source power decomposition in optical systems.
    • To assess the method's performance in both simple and complex optical setups.

    Main Methods:

    • A radiating source, calibrated for traceability to the candela (SI unit for luminous intensity), was used.
    • A single-surface optical system was employed for a practical validation example.
    • Numerical simulations were performed for a multi-surface optical system to assess performance.

    Main Results:

    • The practical example confirmed the validity of the source power decomposition method.
    • The numerical example demonstrated the method's capability in a more complex, multi-surface system.
    • Traceability to the candela ensures the reliability of the radiation measurements.

    Conclusions:

    • The source power decomposition method provides a valid approach for predicting radiation distribution in optical systems.
    • The method is applicable to both simple (single-surface) and complex (multi-surface) optical designs.
    • Experimental and numerical validation confirms the robustness and utility of the proposed theoretical background.