Dynamic Spectrum Access Decisions. George F. Elmasry

Dynamic Spectrum Access Decisions - George F. Elmasry


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or packets per second. The design has to also create metrics to evaluate the bird's eye view trade space. The reader can refer back to Chapter 1, Section 1.2 for the comprehensive DSA design aspects and see how the bird's eye view considerations can lead to creating metrics that evaluate this trade space, which may include the following:

      1 Measuring DSA decisions' rippling. This metric can measure how long a theater‐based DSA decision can last before another decision has to be made. A good centralized spectrum arbitrator should make DSA decisions that last.

      2 Adapting to traffic demand. If spectrum resources are allocated more where traffic demand is high, this will result in higher throughput efficiency of the heterogeneous networks and this higher throughput efficiency can be manifested in established network performance metrics such as packet or message completion ratio, packet delay, packet delay variation (jitter), and packet loss.

      3 Avoiding hidden nodes. A bird's eye view capability should overcome the hidden node phenomena and reduce the likelihood of mistakenly using a primary user's spectrum. This metric can be the measuring of the number of complaints from a primary user.example 2

      By the end of this chapter, the reader should realize that Figure 4.1 oversimplified the trade space areas in order to illustrate the most important aspects of this trade space. Other factors such as the used antennas' technologies, the use of licensed spectrum, unlicensed spectrum or a mix of both, and the interactions between the cognitive DSA process and other cognitive processes the system uses add more dimensions to this trade space.

Schematic illustration of the local decision fusion based on single-dimensional knowledge base.5

      Notice that to obtain such knowledge repository, the sensor has to have some sort of pre‐knowledge of the sensed signal characteristics. As explained earlier in this book, this can be achieved in both the case of same‐channel in‐band sensing and the case of an augmented sensor sensing the presence of a primary user signal with known cyclostationary characteristics. In the case of same‐channel in‐band sensing, signal marks allow for the differentiation between energy samples representing noise or noise plus interfering signal (left side of the decision threshold in Figure 4.2) and energy samples representing signal plus noise or signal plus noise plus interfering signal (right side of the decision threshold in Figure 4.2).3 In the case of an augmented sensor probing a frequency band for potential use, the signal cyclostationary characteristics will allow the sensor to collect energy samples representing noise (left side of the decision threshold in Figure 4.2) and energy samples representing signal plus noise (right side of the decision threshold in Figure 4.2).

      As scenarios 2 and 3 in Figure 4.2 show, when the noise power increases, the RSSI samples will tend to spread wider. Noise power can be due to pure AWGN or another secondary user overlaying its signal that has unknown characteristics. As scenario 3 in Figure 4.2 shows, a higher noise power will lead to the right side points and the left side points to encroach on each other. Note that higher noise power increases the standard deviation of the detected noise energy samples and the detected signal plus noise energy samples. With this case, the local decision fusion engine is able to hypothesize the presence or absence of a communications signal but clearly noise power increase can lead to either a higher probability of false alarm or a higher probability of misdetection depending on where the decision threshold is chosen.

Schematic illustration of the decision fusion based on two-dimensional knowledge base.

      This example is used to illustrate the importance of coordinating between decision fusion hierarchies. If the local decision fusion follows the approach depicted in Figure 4.2 to reduce computational complexity, the distributed or centralized decision fusion may need to create knowledge repositories equivalent to Figure 4.3 to reduce false alarm and misdetection probabilities. On the other hand, if the local decision fusion engine was able to hypothesize based on Figure 4.3, distributed and centralized decision fusion engines can focus on other DSA aspects, such as spatial location of interference and the creation of a more accurate spectrum utilization map.

      The trade space in Figure 4.1 illustrates some important aspects. In reality, there are more aspects in this trade space. For example, having a more detailed knowledge repository at the local node may not be achievable because of processing and power limitations.4,20 At a centralized arbitrator, processing power may not be a limiting factor. On the other hand, sending more detailed spectrum sensing information to a centralized arbitrator can have its own drawbacks to include the use of more bandwidth for DSA control traffic.