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You can adjust the values in the designedPHY and existingPHY arrays to match your actual data. The code creates a bar graph with blue bars representing the range achieved by the designed PHY layer and red bars representing the range achieved by existing PHY layers. The x-axis represents distance, and the y-axis represents range.


Energy Efficiency Comparison Graph

% Energy Efficiency Comparison Graph

% Data for existing PHY layers in the IEEE 802.11 standard
existingPHY_energy = [5.0 4.5 4.2 3.8 3.5]; % in Joules/bit

% Data for the designed PHY layer
designedPHY_energy = [3.0 2.5 2.3 2.0 1.8]; % in Joules/bit

% X-axis data (different scenarios)
x_data = 1:5;

% Create bar graph
bar(x_data, [existingPHY_energy; designedPHY_energy]');

% Set axis labels and title
xlabel('Scenario');
ylabel('Energy Efficiency (Joules/bit)');
title('Energy Efficiency Comparison');

% Set legend
legend('Existing PHY Layers', 'Designed PHY Layer');

You can modify the existingPHY_energy and designedPHY_energy arrays to input your own data for the energy efficiency measurements in different scenarios. The code will create a bar graph comparing the energy efficiency of the existing PHY layers and the designed PHY layer. The x-axis will show the different scenarios, and the y-axis will show the energy efficiency in Joules/bit. The legend will indicate which data corresponds to the existing PHY layers and which data corresponds to the designed PHY layer.
Interpreting the results of the research, the designed PHY layer outperformed the existing PHY layers in terms of data rate, range, and energy efficiency. These findings suggest that the designed PHY layer has the potential to improve the performance of wireless communication systems using the IEEE 802.11ay standard.
The implications of these findings are significant, as higher data rates and improved energy efficiency are critical for a wide range of applications, including high-speed data transfer, multimedia streaming, and IoT. The increased range of the designed PHY layer could also be useful for applications such as wireless backhaul, where longer-range communication links are required.
The results are not unexpected, given that the designed PHY layer was specifically optimized to meet the requirements of the IEEE 802.11ay standard. The simulations and experimental studies confirmed that the design was successful in achieving the desired performance characteristics.
Overall, these findings demonstrate the potential for continued innovation in wireless communication technologies and highlight the importance of ongoing research in this field to meet the growing demands for faster and more efficient wireless communication.
There are several limitations to this study that should be acknowledged. First, the simulations were conducted using idealized models that may not accurately reflect real-world conditions. The effects of interference, multipath propagation, and other environmental factors were not considered in the simulations, which could have impacted the performance of the PHY layer in practice.
Second, the experimental studies were conducted in a limited range of environments and may not be representative of all possible scenarios. The experiments were conducted in an open field, and the results may not apply to more complex indoor or urban environments.
Third, the sample size of the experimental studies was relatively small, with only two SDRs used in the experiments. While the results showed good agreement with the simulations, further studies with larger sample sizes would be needed to confirm these findings.
Finally, the study focused on the PHY layer of the IEEE 802.11ay standard and did not consider other aspects of the standard, such as the MAC layer or the overall system performance. Future research could investigate the performance of the complete IEEE 802.11ay system, including both PHY and MAC layers, and in a wider range of environments.
In comparison to prior research, our study contributes to the field by designing a PHY layer that meets the requirements of the IEEE 802.11ay standard, which is an emerging standard for high-speed wireless communication. While prior research has focused on optimizing existing PHY layers in the IEEE 802.11 standard, our study takes a step forward by designing a new PHY layer that meets the specific requirements of the IEEE 802.11ay standard.
Our study also validates the performance of the designed PHY layer through extensive simulations and experimental studies, which is a crucial step in the development of any new wireless communication technology. Additionally, our study compares the performance of the designed PHY layer with existing PHY layers in the IEEE 802.11 standard, which provides a benchmark for future research in this area.
Overall, our study contributes to the field by designing a new PHY layer that meets the requirements of the IEEE 802.11ay standard and by validating its performance through simulations and experimental studies.


Based on the findings of this study, the following recommendations are provided for future research in the field:

  1. Further investigate the performance of the designed PHY layer in more complex environments, such as indoor settings, to assess its robustness and reliability.

  2. Conduct research on the integration of the designed PHY layer with other layers in the IEEE 802.11ay standard, such as the MAC layer, to evaluate the overall performance of the standard.

  3. Investigate the potential for further improving the energy efficiency of the designed PHY layer, for example, by exploring the use of advanced power-saving techniques.

  4. Explore the possibility of implementing the designed PHY layer on low-power devices, such as IoT devices, to assess its suitability for use in low-power applications.

  5. Investigate the potential for implementing the designed PHY layer on hardware platforms other than SDRs, such as field-programmable gate arrays (FPGAs) or application-specific integrated circuits (ASICs), to evaluate its scalability and commercial viability.

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