Capacity analysis of power line communication point‐to‐point and relay channels M Sheikh‐Hosseini, GA Hodtani, M Molavi–Kakhki Transactions on Emerging Telecommunications Technologies 27 (2), 200-215, 2016 | 22 | 2016 |
Connectivity and coverage constrained wireless sensor nodes deployment using steepest descent and genetic algorithms M Sheikh-Hosseini, SRS Hashemi Expert Systems with Applications 190, 116164, 2022 | 15 | 2022 |
Linear precoder design for peak‐to‐average power ratio reduction of generalized frequency division multiplexing signal using gradient descent methods M Sheikh‐Hosseini, M Hasheminejad, F Rahdari Transactions on Emerging Telecommunications Technologies 34 (2), e4698, 2023 | 3 | 2023 |
On the capacity of additive white mixture Gaussian noise channels M Sheikh-Hosseini, GA Hodtani Transactions on Emerging Telecommunications Technologies, 2019 | 3 | 2019 |
Frequency-domain equalization for orthogonal and quasi-orthogonal STBCs over frequency-selective wireless and power-line channels M Sheikh-Hosseini, M Molavi-Kakhki, GA Hodtani Wireless personal communications 71, 2445-2461, 2013 | 3 | 2013 |
Single carrier transmission in power line channels using time and frequency domain decision feedback equalizations M Sheikhhosseini, M Molavi Kakhki International Journal of Tomography & Statistics 12, 2009 | 3 | 2009 |
Modelling and Optimization of Channel Allocation for Power Line Communications Access Networks in the Presence of In-Line and In-Space Interference M Sheikh Hosseini, SM Nosratabadi Journal of Electrical and Computer Engineering Innovations (JECEI) 9 (1 …, 2020 | 1 | 2020 |
Evolution of power line communications: From a fixed telephone system to telecommunication technology of smart energy grid M Sheikh-Hosseini Iranian Journal of Engineering Education 20 (80), 71-96, 2019 | 1 | 2019 |
Transceiver design for STBC transmission over MIMO multiple‐access SC‐FDE systems M Sheikh‐Hosseini Transactions on Emerging Telecommunications Technologies 29 (6), e3304, 2018 | 1 | 2018 |
Linear precoder design for peak-to-average power ratio reduction of generalized frequency division multiplexing signal using gradient descent methods | 1* | 2021 |
Nonlinear symbolic regression for bit error rate prediction of NOMA systems in 5G cellular communications F Rahdari, M Sheikh-Hosseini Engineering Applications of Artificial Intelligence 127, 107344, 2024 | | 2024 |
Performance analysis of OFDM and GFDM techniques over additive white impulsive noise channels M Sheikh-Hosseini, S Ahmadi 2022 6th International Conference on Millimeter-Wave and Terahertz …, 2022 | | 2022 |
Target and Areas Coverage in Wireless Sensor Networks Using Analytical and Evolutionary Algorithms M Sheikh-Hosseini, SR Samareh Hashemi Computational Intelligence in Electrical Engineering 13 (1), 39-54, 2022 | | 2022 |
Modeling and Analyzing Human and Revelation Communications from the Telecommunications Engineering Perspective HM SHEIKH, M MONEMIZADEH, A Oliyayi ANDISHE-E-NOVIN-E-DINI 15 (59001095), 63-76, 2020 | | 2020 |
Performance Improvement of FFT-OFDM for Impulsive Noise Communications Channels Using Wavelet Transforms and Noise Mitigation Methods M Sheikh-Hosseini, S Ebrahimi Meymand Iranian journal of Marine technology 6 (2), 14-25, 2019 | | 2019 |
On the Design of Coherent Zero-Forcing Receiver for the Flat Fading MIMO Multiple-Access Channels M Sheikh-Hosseini Journal of Electrical and Computer Engineering Innovations (JECEI) 7 (2 …, 2019 | | 2019 |
Single-Carrier Frequency-Domain Equalization for Orthogonal STBC over Frequency-Selective MIMO-PLC Channels G Abed Hodtani, M Molavi-Kakhki, M Sheikh-Hosseini Journal of Communication Engineering 1 (1), 1-17, 2016 | | 2016 |
Comparison of OFDM and Single Carrier Transmission in Power Line Communications M Sheikhhosseini, M Molavi Kakhki Tenth International Symposium on Communication Theory and Applications, 2009 | | 2009 |
Comparison of OFDM and Single Carrier Transmission in Power Line Communications M Molavi, M Sheikh-Hosseini | | |
Linear Precoder Design for PAPR Reduction of GFDM Signals Using Gradient Descent Methods | | |