Публикация:Михайлова 2020 Universal ranging code generator of GLONASS and GPS open navigation signals — различия между версиями

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<includeonly>{{Статья|PageName = Публикация:Михайлова 2020 Universal ranging code generator of GLONASS and GPS open navigation signals
   |автор =  Ilya V. Korogodin
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   |автор =  Olga K. Mikhaylova
   |автор2 = Olga K. Mikhaylova
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   |автор2 = Ilya V. Korogodin
 
   |автор3 = Ivan V. Lipa
 
   |автор3 = Ivan V. Lipa
 
   |автор4 =  
 
   |автор4 =  
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   |страницы = 1-5
 
   |doi = 10.1109/REEPE49198.2020.9059133
 
   |doi = 10.1109/REEPE49198.2020.9059133
   |url = https://ieeexplore.ieee.org/document/9059133
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  |url статьи = https://ieeexplore.ieee.org/document/9059133
 
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   |язык = english
 
   |язык = english
 
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}}</includeonly><noinclude>{{Статья|BibtexKey = mikhaylova2020REEPE
   |автор =  Ilya V. Korogodin
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   |автор =  Olga K. Mikhaylova
   |автор2 = Olga K. Mikhaylova
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   |автор2 = Ilya V. Korogodin
 
   |автор3 = Ivan V. Lipa
 
   |автор3 = Ivan V. Lipa
 
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   |автор4 =  
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   |doi = 10.1109/REEPE49198.2020.9059133
 
   |doi = 10.1109/REEPE49198.2020.9059133
   |url = https://ieeexplore.ieee.org/document/9059133
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   |url =
  |url статьи =
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  |url статьи = https://ieeexplore.ieee.org/document/9059133
 
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== Аннотация ==  
 
== Аннотация ==  
  
atellite navigation  systems  are  used  to  de-termine the position and synchronization of users of thesesystems.  Each  system  includes  a  satellite  constellation  inorbit,  broadcasting  navigation  information  and  signals.By  estimating  the  travel  time  of  signals  from  differentsatellites to  receiver,  the  user’s  location  can  be  calculate.Signals  include  ranging  codes  to  measure  propagationdelay.Navigation systems such as GPS and GLONASS includeabout  30  satellites.  Each  satellite  transmits  up  to  10different signals. And each signal has its own ranging code.In  this  paper,  the  universal  ranging  code  generator  ofopen navigation signals is presented. This structure allowsthe generation  of  ranging  codes  for  about  75%  of  allopen GLONASS  and  NAVSTAR  GPS  navigation  signals.Ranging codes generation methods for the existing GNSSsare considered.  Initialization  parameters  to  configure  theuniversal generator are also found. In addition, we receiveddifferent types of navigation signals using the FPGA-basedreceiver that includes the universal ranging code generatormodule.  As  a  result,  correlation  functions  of  differentsignals are  obtained.  
+
Satellite navigation  systems  are  used  to  determine the position and synchronization of users of thesesystems.   
 +
Each  system  includes  a  satellite  constellation  in orbit,  broadcasting  navigation  information  and  signals.
 +
By  estimating  the  travel  time  of  signals  from  different satellites to  receiver,  the  user’s  location  can  be  calculated.  
 +
Signals  include  ranging  codes  to  measure  propagationdelay.
 +
Navigation systems such as GPS and GLONASS includeabout  30  satellites.   
 +
Each  satellite  transmits  up  to  10 different signals.  
 +
And each signal has its own ranging code.
 +
In  this  paper,  the  universal  ranging  code  generator  of open navigation signals is presented.  
 +
This structure allows the generation  of  ranging  codes  for  about  75%  of  all open GLONASS  and  NAVSTAR  GPS  navigation  signals.
 +
Ranging codes generation methods for the existing GNSSs are considered.   
 +
Initialization  parameters  to  configure  the universal generator are also found.  
 +
In addition, we receive ddifferent types of navigation signals using the FPGA-based receiver that includes the universal ranging code generator module.   
 +
As  a  result,  correlation  functions  of  different signals are  obtained.
  
 
== Галерея ==
 
== Галерея ==

Текущая версия на 12:22, 26 апреля 2020

Olga K. Mikhaylova, Ilya V. Korogodin, Ivan V. Lipa Universal ranging code generator of GLONASS and GPS open navigation signals // 2020 International Youth Conference on Radio Electronics, Electrical and Power Engineering (REEPE). — 2020. — Pp. 1-5.

BibTeX:
 @article{mikhaylova2020REEPE,
   author = "Olga K. Mikhaylova and Ilya V. Korogodin and Ivan V. Lipa",
   title = "Universal ranging code generator of GLONASS and GPS open navigation signals",
   journal = "2020 International Youth Conference on Radio Electronics, Electrical and Power Engineering (REEPE)",
   pages = "1-5",
   url = "https://ieeexplore.ieee.org/document/9059133",
   doi = "10.1109/REEPE49198.2020.9059133",
   year = "2020",
   language = english
 }

[править] Аннотация

Satellite navigation systems are used to determine the position and synchronization of users of thesesystems. Each system includes a satellite constellation in orbit, broadcasting navigation information and signals. By estimating the travel time of signals from different satellites to receiver, the user’s location can be calculated. Signals include ranging codes to measure propagationdelay. Navigation systems such as GPS and GLONASS includeabout 30 satellites. Each satellite transmits up to 10 different signals. And each signal has its own ranging code. In this paper, the universal ranging code generator of open navigation signals is presented. This structure allows the generation of ranging codes for about 75% of all open GLONASS and NAVSTAR GPS navigation signals. Ranging codes generation methods for the existing GNSSs are considered. Initialization parameters to configure the universal generator are also found. In addition, we receive ddifferent types of navigation signals using the FPGA-based receiver that includes the universal ranging code generator module. As a result, correlation functions of different signals are obtained.

[править] Галерея

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