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What possible result of radiant energy at low frequency to experiments specific answer? 

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Radiant energy at low frequencies can lead to intriguing outcomes in experiments. For instance, in a study on VLF radiation from a mobile ionospheric source, it was found that the intensity of signals received on the ground depends on the frequency shift and the source's location relative to the receiving point . Additionally, the EnergyPlus low temperature radiant model, validated through experiments, highlighted the sensitivity of the model to both construction and system parameters, emphasizing the accurate prediction of thermal comfort levels based on these parameters . Furthermore, a communication system utilizing highly directive low-frequency radiant energy demonstrated the generation of a low-frequency beam with a directivity pattern comparable to that of the high-frequency energies, particularly useful for sonic seabed examinations .

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The Nearfield Acoustical Holography technique can reveal non-radiating, circulating energy flow areas with large pressure or velocity amplitudes, correcting misconceptions about acoustic energy production at low frequencies.
The experimental validation of the EnergyPlus low-temperature radiant model showed sensitivity to construction and system parameters, highlighting the impact on predicted space comfort and energy consumption accuracy.
Radiant energy at low frequency in experiments is influenced by source location and frequency shift, impacting signal intensity received on the ground, as explained by the proposed model.
Low-frequency radiant energy in a degenerate electron gas exhibits a logarithmic singularity, contributing finitely to total energy, as shown analytically and numerically in the study.

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