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      The spectrum sensor detection algorithm can successfully detect the sensed frequency with probability PD and the noise variance can cause a false alarm3 with a probability of PF. The detection problem can be expressed as:

Schematic illustration of the single-threshold ROC model leading to false alarm and misdetection.

      Thus, the ROC model can calculate PD and PF as follows:

      3.9equation

      where Γ(a, x) is the incomplete gamma function and Lf and Lt are the associated Laguerre polynomials.

Graph depicts the different ROC curves for different SNIR.

      In addition to noise power estimation, a machine learning technique7 that uses the ROC model can leverage the following techniques to tune the decision threshold:

      1 Measure the success of its own decisions.8

      2 Take into consideration external variables such as emitter power, emitter distance to the sensor, terrain, rain, and fog that can affect SNIR.

      3 Increase accuracy by increasing the number of decision samples. Cooperative distributed DSA and centralized DSA techniques can be looking at more comprehensive information than a single node to make the ROC estimation more accurate.

      The purpose of using the above three techniques is to make the DSA system able to adapt the decision threshold to adhere to the same PD at the same given requirement of PF even with the increase of uncertainty.

      Example: Evaluation Metrics and ROC Design for Different Applications

      Equations (3.5) and (3.6) express the probability of detection and the probability of false alarm, respectively, for a single threshold ROC model. A third probability calculation could be the probability of misdetection.

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