Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]

Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]

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Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]

Message from the author

๐Ÿ”Š Author Introduction: Graduate from a 985 university, researcher and developer in the field of MATLAB;

๐Ÿš… Motto: A journey of a thousand miles begins with a single step.

โœ… Research Scope: Complete code, paper reproduction, program customization, journal writing, research collaboration

๐Ÿ† Code Acquisition Method: Method to obtain MATLAB code for the “Sea Godโ€™s Light”

For more MATLAB signal processing simulation content, click below๐Ÿ‘‡

MATLAB Signal Processing (Advanced Version)

MATLAB Signal Processing Radar Communication (Milk Tea Price Version)

Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]

Introduction

๐Ÿ“‹๐Ÿ“‹๐Ÿ“‹ The table of contents is as follows: ๐ŸŽ๐ŸŽ๐ŸŽ

Table of Contents

๐Ÿ’ฅ1 Overview

๐Ÿ“š2 Code and Running Steps

๐ŸŽ‰3 Running Results

๐ŸŒˆ4 MATLAB Version and References

๐Ÿ”Ž5 Code Acquisition Method

๐Ÿ…6 Simulation Consultation

Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]

1 Overview

See CSDN Sea Godโ€™s Light with the same title

**1 Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication** The millimeter-wave frequency band (30-300GHz) has high bandwidth advantages in 5G communication but is easily affected by obstacles such as the human body. Human blockage can lead to signal attenuation, multipath effects, and link interruptions. The analysis principle is based on the following core mechanisms: **Electromagnetic Wave Propagation Characteristics** The free-space path loss formula for millimeter waves is: $$ L_{fs} = 92.4 + 20 ext{log}_{10}(f) + 20 ext{log}_{10}(d) $$ where $f$ is the frequency (GHz) and $d$ is the distance (km). The absorption attenuation of millimeter waves by the human body can reach 20-40dB, depending on the frequency and angle of incidence. **Scattering and Diffraction Model** The roughness of the human body surface causes non-specular reflection, and the Knife-edge diffraction model is commonly used to calculate diffraction loss: $$ L_{diff} = 6.9 + 20 ext{log}_{10}( ext{sqrt}((v-0.1)^2 +1) + v -0.1) $$ where $v$ is the Fresnel zone parameter, related to the height and position of the obstacle. **2 Human Blockage Analysis Process** **Data Collection Phase** Channel parameters are obtained through ray tracing simulation or actual measurement: – Use 3D laser scanning to establish a human geometric model – Vector network analyzer measures S parameters in the 28/60GHz frequency band – Dynamic capture system records pedestrian movement trajectories **Modeling and Simulation Phase** A hybrid modeling approach is adopted: – Determine the dielectric constant of human body materials ($ ext{ฮต}_r=3-50$, $ ext{ฯƒ}=0.5-15$S/m) – Simulate crowd density based on time-varying Poisson processes – Use Monte Carlo methods to evaluate blockage probability: $$ P_{block} = 1 – e^{- ext{ฮป} A_{shadow}} $$ where $ ext{ฮป}$ is the human density per unit area and $A_{shadow}$ is the shadow area. **Performance Evaluation Metrics** – Interruption probability: The proportion of time the received signal is below the threshold (typically -85dBm) – Spatial availability: The percentage of the coverage area that meets QoS requirements – Delay spread: The maximum delay difference of multipath components (typical values 5-20ns) **3 Mitigation Strategy Verification** **Beam Switching Optimization** A fast beam switching algorithm based on blockage prediction, with a switching delay of less than 100ms. Beamforming weight calculation: $$ extbf{w} = ext{arg} ext{max}_{ extbf{w}} ext{||H extbf{w}||}^2 $$ where $ extbf{H}$ is the channel matrix. **Intelligent Reflective Surface Deployment** The phase adjustment formula for RIS units: $$ heta_n = ext{mod}igg(- rac{2 ext{ฯ€}}{ ext{ฮป}}(d_{n}^{tx} + d_{n}^{rx}), 2 ext{ฯ€}igg) $$ where $d_{n}^{tx}$ and $d_{n}^{rx}$ are the distances to the transmitter and receiver, respectively. **Machine Learning Prediction** The input to the LSTM network includes: – Historical channel state information (CSI) – Pedestrian movement speed (0-1.5m/s) – Base station height (3-10m) The output blockage probability prediction error can be controlled within 8%.

Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]

2 Code and Running Steps

2.1 Partial Code2.2 Running Steps

(1) Directly run main.m to generate the graph with one click

Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]

3Running Results

Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]

4MATLAB Version and References

1 MATLAB Version

2019b

2 References

[1] Ni Yiyang, Zhu Hongbo, Wang Yuxi. Overview of Millimeter-Wave D2D Communication Technology for 5G [J]. Modern Electronic Technology. 2019

[2] Wan Yuan, Li Xingguo, Wang Hong. Application of Channel Coding Technology in Millimeter-Wave Communication [J]. Journal of Ordnance and Guidance. 2006

3 Note

This section is excerpted from the internet for reference only. If there is any infringement, please contact for removal.

Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]

Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]

5 Code Acquisition Method

๐Ÿ†CodeAcquisitionMethod:Method to obtain MATLAB code for the “Sea Godโ€™s Light”

Analysis of Human Blockage in Urban Millimeter-Wave Cellular Communication Based on MATLAB (Including Calculation of User Device Blockage Probability in Urban Areas) [Includes MATLAB Source Code]

6 Simulation Consultation

**๐Ÿ… Simulation Consultation

1 Various intelligent optimization algorithms improvement and application**

1.1 PID Optimization

1.2 VMD Optimization

1.3 Distribution Network Reconstruction

1.4 Three-Dimensional Packing

1.5 Microgrid Optimization

1.6 Layout Optimization

1.7 Parameter Optimization

1.8 Cost Optimization

1.9 Charging Optimization

1.10 Scheduling Optimization

1.11 Price Optimization

1.12 Departure Optimization

1.13 Distribution Optimization

1.14 Coverage Optimization

1.15 Control Optimization

1.16 Inventory Optimization

1.17 Routing Optimization

1.18 Design Optimization

1.19 Location Optimization

1.20 Absorber Optimization

1.21 Site Selection Optimization

1.22 Operation Optimization

1.23 Assignment Optimization

1.24 Combination Optimization

1.25 Workshop Scheduling

1.26 Production Scheduling

1.27 Economic Scheduling

1.28 Assembly Line Scheduling

1.29 Reservoir Scheduling

1.30 Cargo Position Optimization

1.31 Bus Scheduling Optimization

1.32 Container Ship Loading Optimization

1.33 Pump Combination Optimization

1.34 Medical Resource Allocation Optimization

1.35 Visual Base Station and Drone Site Selection Optimization

**2 Machine Learning and Deep Learning Classification and Prediction**

**2.1 Machine Learning and Deep Learning Classification**

2.1.1 BiLSTM Bidirectional Long Short-Term Memory Neural Network Classification

2.1.2 BP Neural Network Classification

2.1.3 CNN Convolutional Neural Network Classification

2.1.4 DBN Deep Belief Network Classification

2.1.5 DELM Deep Learning Extreme Learning Machine Classification

2.1.6 ELMAN Recurrent Neural Network Classification

2.1.7 ELM Extreme Learning Machine Classification

2.1.8 GRNN General Regression Neural Network Classification

2.1.9 GRU Gated Recurrent Unit Classification

2.1.10 KELM Hybrid Kernel Extreme Learning Machine Classification

2.1.11 KNN Classification

2.1.12 LSSVM Least Squares Support Vector Machine Classification

2.1.13 LSTM Long Short-Term Memory Network Classification

2.1.14 MLP Multi-Layer Perceptron Classification

2.1.15 PNN Probabilistic Neural Network Classification

2.1.16 RELM Robust Extreme Learning Machine Classification

2.1.17 RF Random Forest Classification

2.1.18 SCN Stochastic Configuration Network Model Classification

2.1.19 SVM Support Vector Machine Classification

2.1.20 XGBOOST Classification

**2.2 Machine Learning and Deep Learning Prediction**

2.2.1 ANFIS Adaptive Neuro-Fuzzy Inference System Prediction

2.2.2 ANN Artificial Neural Network Prediction

2.2.3 ARMA Autoregressive Moving Average Model Prediction

2.2.4 BF Particle Filter Prediction

2.2.5 BiLSTM Bidirectional Long Short-Term Memory Neural Network Prediction

2.2.6 BLS Broad Learning System Prediction

2.2.7 BP Neural Network Prediction

2.2.8 CNN Convolutional Neural Network Prediction

2.2.9 DBN Deep Belief Network Prediction

2.2.10 DELM Deep Learning Extreme Learning Machine Prediction

2.2.11 DKELM Regression Prediction

2.2.12 ELMAN Recurrent Neural Network Prediction

2.2.13 ELM Extreme Learning Machine Prediction

2.2.14 ESN Echo State Network Prediction

2.2.15 FNN Feedforward Neural Network Prediction

2.2.16 GMDN Prediction

2.2.17 GMM Gaussian Mixture Model Prediction

2.2.18 GRNN General Regression Neural Network Prediction

2.2.19 GRU Gated Recurrent Unit Prediction

2.2.20 KELM Hybrid Kernel Extreme Learning Machine Prediction

2.2.21 LMS Least Mean Squares Algorithm Prediction

2.2.22 LSSVM Least Squares Support Vector Machine Prediction

2.2.23 LSTM Long Short-Term Memory Network Prediction

2.2.24 RBF Radial Basis Function Neural Network Prediction

2.2.25 RELM Robust Extreme Learning Machine Prediction

2.2.26 RF Random Forest Prediction

2.2.27 RNN Recurrent Neural Network Prediction

2.2.28 RVM Relevance Vector Machine Prediction

2.2.29 SVM Support Vector Machine Prediction

2.2.30 TCN Temporal Convolutional Network Prediction

2.2.31 XGBoost Regression Prediction

2.2.32 Fuzzy Prediction

2.2.33 Singular Spectrum Analysis Method SSA Time Series Prediction

**2.3 Machine Learning and Deep Learning Practical Application Prediction**

CPI index prediction, PM2.5 concentration prediction, SOC prediction, financial warning prediction, yield prediction, parking space prediction, pest prediction, strip steel thickness prediction, battery health status prediction, power load prediction, housing price prediction, corrosion rate prediction, fault diagnosis prediction, photovoltaic power prediction, trajectory prediction, aircraft engine life prediction, exchange rate prediction, concrete strength prediction, heating furnace temperature prediction, price prediction, traffic flow prediction, consumer price index prediction, air quality prediction, grain temperature prediction, temperature prediction, clean water value prediction, unemployment rate prediction, electricity consumption prediction, transportation volume prediction, manufacturing purchasing manager index prediction

**3 Image Processing Aspects**

**3.1 Image Edge Detection**

**3.2 Image Processing**

**3.3 Image Segmentation**

**3.4 Image Classification**

**3.5 Image Tracking**

**3.6 Image Encryption and Decryption**

**3.7 Image Retrieval**

**3.8 Image Registration**

**3.9 Image Stitching**

**3.10 Image Evaluation**

**3.11 Image Denoising**

**3.12 Image Fusion**

**3.13 Image Recognition**

3.13.1 Dial Recognition

3.13.2 Lane Line Recognition

3.13.3 Vehicle Counting

3.13.4 Vehicle Recognition

3.13.5 License Plate Recognition

3.13.6 Parking Space Recognition

3.13.7 Size Detection

3.13.8 Answer Sheet Recognition

3.13.9 Appliance Recognition

3.13.10 Fall Detection

3.13.11 Animal Recognition

3.13.12 QR Code Recognition

3.13.13 Invoice Recognition

3.13.14 Clothing Recognition

3.13.15 Chinese Character Recognition

3.13.16 Traffic Light Recognition

3.13.17 Iris Recognition

3.13.18 Fire Detection

3.13.19 Disease Classification

3.13.20 Traffic Sign Recognition

3.13.21 Card Number Recognition

3.13.22 Mask Recognition

3.13.23 Crack Detection

3.13.24 Target Tracking

3.13.25 Fatigue Detection

3.13.26 Flag Recognition

3.13.27 Grass Recognition

3.13.28 Face Recognition

3.13.29 Renminbi Recognition

3.13.30 ID Card Recognition

3.13.31 Gesture Recognition

3.13.32 Digit and Letter Recognition

3.13.33 Palm Recognition

3.13.34 Leaf Recognition

3.13.35 Fruit Recognition

3.13.36 Barcode Recognition

3.13.37 Temperature Detection

3.13.38 Defect Detection

3.13.39 Chip Detection

3.13.40 Behavior Recognition

3.13.41 CAPTCHA Recognition

3.13.42 Medicinal Material Recognition

3.13.43 Coin Recognition

3.13.44 Postal Code Recognition

3.13.45 Playing Card Recognition

3.13.46 Fingerprint Recognition

**3.14 Image Restoration**

**3.15 Image Compression**

**3.16 Image Steganography**

**3.17 Image Enhancement**

**3.18 Image Reconstruction**

**4 Path Planning Aspects**

**4.1 Traveling Salesman Problem (TSP)**

4.1.1 Single Traveling Salesman Problem (TSP)

4.1.2 Multiple Traveling Salesman Problem (MTSP)

**4.2 Vehicle Routing Problem (VRP)**

4.2.1 Vehicle Routing Problem (VRP)

4.2.2 Capacitated Vehicle Routing Problem (CVRP)

4.2.3 Capacitated + Time Window + Distance Vehicle Routing Problem (DCTWVRP)

4.2.4 Capacitated + Distance Vehicle Routing Problem (DCVRP)

4.2.5 Distance-Constrained Vehicle Routing Problem (DVRP)

4.2.6 Vehicle Routing Problem with Charging Stations + Time Windows (ETWVRP)

4.2.3 Vehicle Routing Problem with Multiple Capacities (MCVRP)

4.2.4 Distance-Constrained Multi-Vehicle Routing Problem (MDVRP)

4.2.5 Simultaneous Pickup and Delivery Vehicle Routing Problem (SDVRP)

4.2.6 Vehicle Routing Problem with Time Windows + Capacities (TWCVRP)

4.2.6 Vehicle Routing Problem with Time Windows (TWVRP)

**4.3 Multimodal Transport Problem**

**4.4 Robot Path Planning**

4.4.1 Obstacle Avoidance Path Planning

4.4.2 Maze Path Planning

4.4.3 Grid Map Path Planning

**4.5 Delivery Path Planning**

4.5.1 Cold Chain Delivery Path Planning

4.5.2 Takeout Delivery Path Planning

4.5.3 Mask Delivery Path Planning

4.5.4 Medicine Delivery Path Planning

4.5.5 Delivery Path Planning with Charging Stations

4.5.6 Chain Supermarket Delivery Path Planning

4.5.7 Vehicle Collaborative Drone Delivery Path Planning

**4.6 Drone Path Planning**

4.6.1 Aircraft Simulation

4.6.2 Drone Flight Operations

4.6.3 Drone Trajectory Tracking

4.6.4 Drone Swarm Simulation

4.6.5 Three-Dimensional Path Planning for Drones

4.6.6 Drone Formation

4.6.7 Drone Collaborative Tasks

4.6.8 Drone Task Allocation

**5 Speech Processing**

**5.1 Speech Emotion Recognition**

**5.2 Sound Source Localization**

**5.3 Feature Extraction**

**5.4 Speech Coding**

**5.5 Speech Processing**

**5.6 Speech Separation**

**5.7 Speech Analysis**

**5.8 Speech Synthesis**

**5.9 Speech Encryption**

**5.10 Speech Denoising**

**5.11 Speech Recognition**

**5.12 Speech Compression**

**5.13 Speech Hiding**

**6 Cellular Automata Aspects**

**6.1 Cellular Automata Virus Simulation**

**6.2 Cellular Automata Urban Planning**

**6.3 Cellular Automata Traffic Flow**

**6.4 Cellular Automata Gas**

**6.5 Cellular Automata Personnel Evacuation**

**6.6 Cellular Automata Forest Fire**

**6.7 Cellular Automata Game of Life**

**7 Signal Processing Aspects**

**7.1 Fault Signal Diagnosis Analysis**

7.1.1 Gear Damage Identification

7.1.2 Asynchronous Motor Rotor Broken Bar Fault Diagnosis

7.1.3 Rolling Element Inner and Outer Ring Fault Diagnosis Analysis

7.1.4 Motor Fault Diagnosis Analysis

7.1.5 Bearing Fault Diagnosis Analysis

7.1.6 Gearbox Fault Diagnosis Analysis

7.1.7 Three-Phase Inverter Fault Diagnosis Analysis

7.1.8 Diesel Engine Fault Diagnosis

**7.2 Radar Communication**

7.2.1 FMCW Simulation

7.2.2 GPS Anti-Jamming

7.2.3 Radar LFM

7.2.4 Radar MIMO

7.2.5 Radar Angle Measurement

7.2.6 Radar Imaging

7.2.7 Radar Positioning

7.2.8 Radar Echo

7.2.9 Radar Detection

7.2.10 Radar Digital Signal Processing

7.2.11 Radar Communication

7.2.12 Radar Phased Array

7.2.13 Radar Signal Analysis

7.2.14 Radar Early Warning

7.2.15 Radar Pulse Compression

7.2.16 Antenna Radiation Pattern

7.2.17 Radar Clutter Simulation

**7.3 Bioelectric Signals**

7.3.1 Electromyography (EMG)

7.3.2 Electroencephalography (EEG)

7.3.3 Electrocardiography (ECG)

7.3.4 Heart Simulation

**7.4 Communication Systems**

7.4.1 DOA Estimation

7.4.2 LEACH Protocol

7.4.3 Encoding and Decoding

7.4.4 Variational Mode Decomposition

7.4.5 Ultra-Wideband Simulation

7.4.6 Multipath Fading Simulation

7.4.7 Cellular Networks

7.4.8 Pipeline Leakage

7.4.9 Empirical Mode Decomposition

7.4.10 Filter Design

7.4.11 Analog Signal Transmission

7.4.12 Analog Signal Modulation

7.4.13 Digital Baseband Signals

7.4.14 Digital Channels

7.4.15 Digital Signal Processing

7.4.16 Digital Signal Transmission

7.4.17 Digital Signal Denoising

7.4.18 Underwater Acoustic Communication

7.4.19 Communication Simulation

7.4.20 Wireless Transmission

7.4.21 Bit Error Rate Simulation

7.4.22 Modern Communication

7.4.23 Channel Estimation

7.4.24 Signal Detection

7.4.25 Signal Fusion

7.4.26 Signal Recognition

7.4.27 Compressed Sensing

7.4.28 Noise Simulation

7.4.29 Noise Interference

**7.5 Drone Communication**

**7.6 Wireless Sensor Localization and Layout**

7.6.1 WSN Localization

7.6.2 Altitude Estimation

7.6.3 Filter Tracking

7.6.4 Target Localization

7.6.4.1 Dv-Hop Localization

7.6.4.2 RSSI Localization

7.6.4.3 Intelligent Algorithm Optimization Localization

7.6.5 Integrated Navigation

**8 Power System Aspects**

Microgrid Optimization, Reactive Power Optimization, Distribution Network Reconstruction, Energy Storage Configuration

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