Your search keyword '"Barry, Abdoul Aziz"' showing total 5 results

1. Machine learning techniques applied to dimensionality reduction for digital predistortion linearizers

Author

Barry, Abdoul Aziz, Universitat Politècnica de Catalunya. Departament de Teoria del Senyal i Comunicacions, and Gilabert Pinal, Pere Lluís

Subjects

Artificial satellites, Satèl·lits artificials -- Informàtica, Digital predistortion linearization, Machine learning, Aeronàutica i espai::Astronàutica::Enginyeria aeroespacial [Àrees temàtiques de la UPC]

Abstract

Over the past half century, the improvements in spacecraft technology have been primarily in the areas of microelectronics for on-board processing, high frequency electronic devices, and integrated circuits for communications and navigation, solar cells and batteries for on-board power generation and storage among many others. Despite the fact that energy-storage technologies have advanced dramatically over the past years, the power consumption of on-board communications, sensors and digital signal processing systems is of paramount importance in battery or solar powered systems such as small satellites, HAPs or UAVs (drones). There is multiple applications that involves the use of these systems, e.g., Earth observation applications, surveillance, broadcast communications, scientific research, etc. In wireless communications, the power amplifier is a critical subsystem in the transmitter chain. Not only because it is one of the most power hungry devices that accounts for most of the direct current power consumption, but also because it is the main source of nonlinear distortion in the transmitter. Amplitude and phase modulated communications signals presenting high peak-to-average power ratio have a negative impact in the transmitter's power efficiency, because the PA has to be operated at high power back-off levels to avoid introducing nonlinear distortion. Digital predistortion (DPD) linearization is the most common and spread solution to cope with power amplifiers (PA) inherent linearity versus efficiency trade-off. When considering wide bandwidth signals, such as Doherty PAs, envelope tracking PAs or outphasing transmitters, the number of parameters required in the DPD model to compensate for both nonlinearities and memory effects can be very high. This has a negative impact in the DPD ceofficients extraction, because increases the computational complexity and drives to over-fitting and uncertainty. However, by applying dimensionality reduction techniques we can both avoid the numerical ill-conditioning of the estimation and reduce the number of coefficients of the DPD function, which ultimately impacts the baseband processing computational complexity and power consumption. In this Project, several dimensionality reduction techniques will be described and compared in terms of model order reduction capabilities and evaluation performance. In particular, some of the machine learning techniques for dimensionality reduction will be studied.

Published

2021

2. Machine learning techniques applied to dimensionality reduction for digital predistortion linearizers

Author

Universitat Politècnica de Catalunya. Departament de Teoria del Senyal i Comunicacions, Gilabert Pinal, Pere Lluís, Barry, Abdoul Aziz, Universitat Politècnica de Catalunya. Departament de Teoria del Senyal i Comunicacions, Gilabert Pinal, Pere Lluís, and Barry, Abdoul Aziz

Abstract

Over the past half century, the improvements in spacecraft technology have been primarily in the areas of microelectronics for on-board processing, high frequency electronic devices, and integrated circuits for communications and navigation, solar cells and batteries for on-board power generation and storage among many others. Despite the fact that energy-storage technologies have advanced dramatically over the past years, the power consumption of on-board communications, sensors and digital signal processing systems is of paramount importance in battery or solar powered systems such as small satellites, HAPs or UAVs (drones). There is multiple applications that involves the use of these systems, e.g., Earth observation applications, surveillance, broadcast communications, scientific research, etc. In wireless communications, the power amplifier is a critical subsystem in the transmitter chain. Not only because it is one of the most power hungry devices that accounts for most of the direct current power consumption, but also because it is the main source of nonlinear distortion in the transmitter. Amplitude and phase modulated communications signals presenting high peak-to-average power ratio have a negative impact in the transmitter's power efficiency, because the PA has to be operated at high power back-off levels to avoid introducing nonlinear distortion. Digital predistortion (DPD) linearization is the most common and spread solution to cope with power amplifiers (PA) inherent linearity versus efficiency trade-off. When considering wide bandwidth signals, such as Doherty PAs, envelope tracking PAs or outphasing transmitters, the number of parameters required in the DPD model to compensate for both nonlinearities and memory effects can be very high. This has a negative impact in the DPD ceofficients extraction, because increases the computational complexity and drives to over-fitting and uncertainty. However, by applying dimensionality reduction techniques we can

Published

2021

3. Development of an updated global land in situ‐based data set of temperature and precipitation extremes: HadEX3

Author

Barcelona Supercomputing Center, Dunn, Rober J. H., Alexander, Lisa V., Donat, Markus, Zhang, Xuebin, Bador, Margot, Herold, Nicholas, Lippmann, Tanya, Allan, Rob, Aguilar, Enric, Barry, Abdoul Aziz, Brunet, Manola, Caesar, John, Chagnaud, Guillaume, Cheng, Vincent, Cinco, Thelma, Durre, Imke, Guzman, Rosaline, de, Htay, Tin Mar, Wan Ibadullah, Wan Maisarah, Ibrahim, Muhammad Khairul Izzat Bin, Khoshkam, Mahbobeh, Kruger, Andries, Kubota, Hisayuki, Leng, Tan Wee, Lim, Gerald, Li‐Sha, Lim, Marengo, Jose, Mbatha, Sifiso, McGree, Simon, Menne, Matthew, Skansi, Maria de los Milagros, Ngwenya, Sandile, Nkrumah, Francis, Oonariya, Chalump, Pabon‐Caicedo, Jose Daniel, Panthou, Gérémy, Pham, Cham, Rahimzadeh, Fatemeh, Ramos, Andrea, Salgado, Ernesto, Salinger, Jim, Sané, Youssouph, Sopaheluwakan, Ardhasena, Srivastava, Arvind, Sun, Ying, Timbal, Bertrand, Trachow, Nichanun, Trewin, Blair, Schrier, Gerard, van der, Vazquez‐Aguirre, Jorge, Vasquez, Ricardo, Villarroel, Claudia, Vincent, Lucie, Vischel, Theo, Vose, Russ, Yussof, Mohd Noor'Arifin Bin Hj, Barcelona Supercomputing Center, Dunn, Rober J. H., Alexander, Lisa V., Donat, Markus, Zhang, Xuebin, Bador, Margot, Herold, Nicholas, Lippmann, Tanya, Allan, Rob, Aguilar, Enric, Barry, Abdoul Aziz, Brunet, Manola, Caesar, John, Chagnaud, Guillaume, Cheng, Vincent, Cinco, Thelma, Durre, Imke, Guzman, Rosaline, de, Htay, Tin Mar, Wan Ibadullah, Wan Maisarah, Ibrahim, Muhammad Khairul Izzat Bin, Khoshkam, Mahbobeh, Kruger, Andries, Kubota, Hisayuki, Leng, Tan Wee, Lim, Gerald, Li‐Sha, Lim, Marengo, Jose, Mbatha, Sifiso, McGree, Simon, Menne, Matthew, Skansi, Maria de los Milagros, Ngwenya, Sandile, Nkrumah, Francis, Oonariya, Chalump, Pabon‐Caicedo, Jose Daniel, Panthou, Gérémy, Pham, Cham, Rahimzadeh, Fatemeh, Ramos, Andrea, Salgado, Ernesto, Salinger, Jim, Sané, Youssouph, Sopaheluwakan, Ardhasena, Srivastava, Arvind, Sun, Ying, Timbal, Bertrand, Trachow, Nichanun, Trewin, Blair, Schrier, Gerard, van der, Vazquez‐Aguirre, Jorge, Vasquez, Ricardo, Villarroel, Claudia, Vincent, Lucie, Vischel, Theo, Vose, Russ, and Yussof, Mohd Noor'Arifin Bin Hj

Abstract

We present the second update to a data set of gridded land‐based temperature and precipitation extremes indices: HadEX3. This consists of 17 temperature and 12 precipitation indices derived from daily, in situ observations and recommended by the World Meteorological Organization (WMO) Expert Team on Climate Change Detection and Indices (ETCCDI). These indices have been calculated at around 7,000 locations for temperature and 17,000 for precipitation. The annual (and monthly) indices have been interpolated on a 1.875°×1.25° longitude‐latitude grid, covering 1901–2018. We show changes in these indices by examining ”global”‐average time series in comparison with previous observational data sets and also estimating the uncertainty resulting from the nonuniform distribution of meteorological stations. Both the short and long time scale behavior of HadEX3 agrees well with existing products. Changes in the temperature indices are widespread and consistent with global‐scale warming. The extremes related to daily minimum temperatures are changing faster than the maximum. Spatial changes in the linear trends of precipitation indices over 1950–2018 are less spatially coherent than those for temperature indices. Globally, there are more heavy precipitation events that are also more intense and contribute a greater fraction to the total. Some of the indices use a reference period for calculating exceedance thresholds. We present a comparison between using 1961–1990 and 1981–2010. The differences between the time series of the temperature indices observed over longer time scales are shown to be the result of the interaction of the reference period with a warming climate. The gridded netCDF files and, where possible, underlying station indices are available from www.metoffice.gov.uk/hadobs/hadex3 and www.climdex.org., Robert Dunn was supported by the Met Office Hadley Centre Climate Programme funded by BEIS and Defra (GA01101) and thanks Nick Rayner and Lizzie Good for helpful comments on the manuscript. Lisa Alexander is supported by the Australian Research Council (ARC) Grants DP160103439 and CE170100023. Markus Donat acknowledges funding by the Spanish Ministry for the Economy, Industry and Competitiveness Ramón y Cajal 2017 Grant Reference RYC‐2017‐22964. Mohd Noor'Arifin Bin Hj Yussof and Muhammad Khairul Izzat Bin Ibrahim thank the Brunei Darussalam Meteorological Department (BDMD). Ying Sun was supported by China funding agencies 2018YFA0605604 and 2018YFC1507702. Fatemeh Rahimzadeh and Mahbobeh Khoshkam thank I.R. of Iranian Meteorological Organization (IRIMO) and the Atmospheric Science and Meteorological Organization Research Center (ASMERC) for Data and also sharing their experiences, especially Abbas Rangbar. Jose Marengo was supported by the National Institute of Science and Technology for Climate Change Phase 2 under CNPq Grant 465501/2014‐1, FAPESP Grants 2014/50848‐9 and 2015/03804‐9, and the National Coordination for High Level Education and Training (CAPES) Grant 88887.136402‐00INCT. The team that worked on the data in West Africa received funding from the UK's National Environment Research Council (NERC)/Department for International Development DFID) Future Climate For Africa programme, under the AMMA‐2050 project (Grants NE/M020428/1 and NE/M019969/1). Data from Southeast Asia (excl. Indonesia) was supported by work on using ClimPACT2 during the Second Workshop on ASEAN Regional Climate Data, Analysis and Projections (ARCDAP‐2), 25–29 March 2019, Singapore, jointly funded by Meteorological Service Singapore and WMO through the Canada‐Climate Risk and Early Warning Systems (CREWS) initiative. This research was supported by Thai Meteorological Department (TMD) and Thailand Science Research and Innovation (TSRI) under Grant RDG6030003. Daily data for Mexico were, Peer Reviewed, Postprint (published version)

Published

2020

4. Development of an Updated Global Land In Situ-Based Data Set of Temperature and Precipitation Extremes: HadEX3

Author

Universitat Rovira i Virgili, Dunn, Robert J. H.; Alexander, Lisa, V; Donat, Markus G.; Zhang, Xuebin; Bador, Margot; Herold, Nicholas; Lippmann, Tanya; Allan, Rob; Aguilar, Enric; Barry, Abdoul Aziz; Brunet, Manola; Caesar, John; Chagnaud, Guillaume; Cheng, Vincent; Cinco, Thelma; Durre, Imke; de Guzman, Rosaline; Htay, Tin Mar; Ibadullah, Wan Maisarah Wan; Bin Ibrahim, Muhammad Khairul Izzat; Khoshkam, Mahbobeh; Kruger, Andries; Kubota, Hisayuki; Leng, Tan Wee; Lim, Gerald; Li-Sha, Lim; Marengo, Jose; Mbatha, Sifiso; McGree, Simon; Menne, Matthew; de los Milagros Skansi, Maria; Ngwenya, Sandile; Nkrumah, Francis; Oonariya, Chalump; Daniel Pabon-Caicedo, Jose; Panthou, Geremy; Cham Pham; Rahimzadeh, Fatemeh; Ramos, Andrea; Salgado, Ernesto; Salinger, Jim; Sane, Youssouph; Sopaheluwakan, Ardhasena; Srivastava, Arvind; Sun, Ying; Timbal, Bertrand; Trachow, Nichanun; Trewin, Blair; van der Schrier, Gerard; Vazquez-Aguirre, Jorge; Vasquez, Ricardo; Villarroel, Claudia; Vincent, Lucie; Vischel, Theo; Vose, Russ; Yussof, Mohd Noor'Arifin Bin Hj, Universitat Rovira i Virgili, and Dunn, Robert J. H.; Alexander, Lisa, V; Donat, Markus G.; Zhang, Xuebin; Bador, Margot; Herold, Nicholas; Lippmann, Tanya; Allan, Rob; Aguilar, Enric; Barry, Abdoul Aziz; Brunet, Manola; Caesar, John; Chagnaud, Guillaume; Cheng, Vincent; Cinco, Thelma; Durre, Imke; de Guzman, Rosaline; Htay, Tin Mar; Ibadullah, Wan Maisarah Wan; Bin Ibrahim, Muhammad Khairul Izzat; Khoshkam, Mahbobeh; Kruger, Andries; Kubota, Hisayuki; Leng, Tan Wee; Lim, Gerald; Li-Sha, Lim; Marengo, Jose; Mbatha, Sifiso; McGree, Simon; Menne, Matthew; de los Milagros Skansi, Maria; Ngwenya, Sandile; Nkrumah, Francis; Oonariya, Chalump; Daniel Pabon-Caicedo, Jose; Panthou, Geremy; Cham Pham; Rahimzadeh, Fatemeh; Ramos, Andrea; Salgado, Ernesto; Salinger, Jim; Sane, Youssouph; Sopaheluwakan, Ardhasena; Srivastava, Arvind; Sun, Ying; Timbal, Bertrand; Trachow, Nichanun; Trewin, Blair; van der Schrier, Gerard; Vazquez-Aguirre, Jorge; Vasquez, Ricardo; Villarroel, Claudia; Vincent, Lucie; Vischel, Theo; Vose, Russ; Yussof, Mohd Noor'Arifin Bin Hj

Abstract

We present the second update to a data set of gridded land-based temperature and precipitation extremes indices: HadEX3. This consists of 17 temperature and 12 precipitation indices derived from daily, in situ observations and recommended by the World Meteorological Organization (WMO) Expert Team on Climate Change Detection and Indices (ETCCDI). These indices have been calculated at around 7,000 locations for temperature and 17,000 for precipitation. The annual (and monthly) indices have been interpolated on a1.875 degrees x1.25 degrees longitude-latitude grid, covering 1901-2018. We show changes in these indices by examining global-average time series in comparison with previous observational data sets and also estimating the uncertainty resulting from the nonuniform distribution of meteorological stations. Both the short and long time scale behavior of HadEX3 agrees well with existing products. Changes in the temperature indices are widespread and consistent with global-scale warming. The extremes related to daily minimum temperatures are changing faster than the maximum. Spatial changes in the linear trends of precipitation indices over 1950-2018 are less spatially coherent than those for temperature indices. Globally, there are more heavy precipitation events that are also more intense and contribute a greater fraction to the total. Some of the indices use a reference period for calculating exceedance thresholds. We present a comparison between using 1961-1990 and 1981-2010. The differences between the time series of the temperature indices observed over longer time scales are shown to be the result of the interaction of the reference period with a warming climate. The gridded netCDF files and, where possible, underlying station indices are available from and .

Published

2020

5. Development of an Updated Global Land In Situ‐Based Data Set of Temperature and Precipitation Extremes: HadEX3

Author

Dunn, Robert J. H., primary, Alexander, Lisa V., additional, Donat, Markus G., additional, Zhang, Xuebin, additional, Bador, Margot, additional, Herold, Nicholas, additional, Lippmann, Tanya, additional, Allan, Rob, additional, Aguilar, Enric, additional, Barry, Abdoul Aziz, additional, Brunet, Manola, additional, Caesar, John, additional, Chagnaud, Guillaume, additional, Cheng, Vincent, additional, Cinco, Thelma, additional, Durre, Imke, additional, Guzman, Rosaline, additional, Htay, Tin Mar, additional, Wan Ibadullah, Wan Maisarah, additional, Bin Ibrahim, Muhammad Khairul Izzat, additional, Khoshkam, Mahbobeh, additional, Kruger, Andries, additional, Kubota, Hisayuki, additional, Leng, Tan Wee, additional, Lim, Gerald, additional, Li‐Sha, Lim, additional, Marengo, Jose, additional, Mbatha, Sifiso, additional, McGree, Simon, additional, Menne, Matthew, additional, Milagros Skansi, Maria, additional, Ngwenya, Sandile, additional, Nkrumah, Francis, additional, Oonariya, Chalump, additional, Pabon‐Caicedo, Jose Daniel, additional, Panthou, Gérémy, additional, Pham, Cham, additional, Rahimzadeh, Fatemeh, additional, Ramos, Andrea, additional, Salgado, Ernesto, additional, Salinger, Jim, additional, Sané, Youssouph, additional, Sopaheluwakan, Ardhasena, additional, Srivastava, Arvind, additional, Sun, Ying, additional, Timbal, Bertrand, additional, Trachow, Nichanun, additional, Trewin, Blair, additional, Schrier, Gerard, additional, Vazquez‐Aguirre, Jorge, additional, Vasquez, Ricardo, additional, Villarroel, Claudia, additional, Vincent, Lucie, additional, Vischel, Theo, additional, Vose, Russ, additional, and Bin Hj Yussof, Mohd Noor'Arifin, additional

Published

2020