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GNSS Authentication and encryption: Difference between revisions

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The basic idea behind authentication and encryption is to ensure that a message is identical to the one transmitted at its origin and that it was generated by a trusted source. Encryption and authentication refer to two interrelated mechanisms to protect communications:  
The basic idea behind authentication and encryption is to ensure that a message is identical to the one transmitted at its origin and that it was generated by a trusted source. Encryption and authentication refer to two interrelated mechanisms to protect communications:  
* Communications may be encrypted (e.g. encoded) to keep them secret and make them unreadable to a third party.  
* Communications may be encrypted (e.g. encoded) to keep them secret and make them unreadable to a third party.  
Line 15: Line 16:
Different authentication techniques may be considered (unpredictable features at subcarrier or carrier level, as variable pulse shaping, frequency hopping, etc.), however the most promising ones are related to the authentication of the navigation messages.
Different authentication techniques may be considered (unpredictable features at subcarrier or carrier level, as variable pulse shaping, frequency hopping, etc.), however the most promising ones are related to the authentication of the navigation messages.


Most Navigation Message Authentication (NMA) techniques are based on the Timed Efficient Stream Loss-Tolerant Authentication (TESLA) protocol <ref>[I. Fernández-Hernández, V. Rijmen, G. Seco-Granados, J. Simon, I. Rodríguez, and J. David Calle, “A Navi-gation Message Authentication Proposal for the Galileo Open Service,” Navigation, Journal of The Institute of Navigation, vol. 63, no. 1, pp. 85-102]</ref>. Some variations and modifications have been proposed exploiting one or more signal components providing, in general, a high level of robustness against simplistic and intermediate spoofing attacks. This category of spoofing includes all the cases where the spoofer is able to generate asynchronous or synchronous counterfeit signals, but not to predict and/or a-priori generate valid NMA data. In fact, from a spoofer perspective, the cryptographically-protected data are not predictable a-priori and cannot be pre-computed by the spoofer. In this sense, a spoofer unable to generate valid cryptographic data can be easily detected by a receiver that implements the NMA algorithm.
Most Navigation Message Authentication (NMA) techniques are based on the Timed Efficient Stream Loss-Tolerant Authentication (TESLA) protocol <ref>I. Fernández-Hernández, V. Rijmen, G. Seco-Granados, J. Simon, I. Rodríguez, and J. David Calle, “A Navi-gation Message Authentication Proposal for the Galileo Open Service,” Navigation, Journal of The Institute of Navigation, vol. 63, no. 1, pp. 85-102</ref>. Some variations and modifications have been proposed exploiting one or more signal components providing, in general, a high level of robustness against simplistic and intermediate spoofing attacks. This category of spoofing includes all the cases where the spoofer is able to generate asynchronous or synchronous counterfeit signals, but not to predict and/or a-priori generate valid NMA data. In fact, from a spoofer perspective, the cryptographically-protected data are not predictable a-priori and cannot be pre-computed by the spoofer. In this sense, a spoofer unable to generate valid cryptographic data can be easily detected by a receiver that implements the NMA algorithm.


Up until now, the main operational GNSS systems which have considered including authentication capabilities are GPS and Galileo. In the case of GPS, a Chips-Message Robust Authentication (Chimera) approach, which is a hybrid NMA and spreading code authentication technique has been proposed for use within the new [[GPS Signal Plan|GPS L1C  signal]]. The NMA portion of this scheme is based on a well-established standard, the asymmetric elliptic curve digital signature algorithm (ECDSA) P-224, which simplifies the integration of the scheme into existing GNSS receivers.
Up until now, the main operational GNSS systems which have considered including authentication capabilities are GPS and Galileo. In the case of GPS, a Chips-Message Robust Authentication (Chimera) approach, which is a hybrid NMA and spreading code authentication technique has been proposed for use within the new [[GPS Signal Plan|GPS L1C  signal]]. The NMA portion of this scheme is based on a well-established standard, the asymmetric elliptic curve digital signature algorithm (ECDSA) P-224, which simplifies the integration of the scheme into existing GNSS receivers.


In the case of [[Galileo OS-NMA|Galileo OS-NMA]]; this feature consists in digitally signing the Open Service Navigation message in the E1 band, making use of forty reserved bits in the Galileo E1B data message and the TESTA protocol, thus keeping the rest of the navigation message unencrypted.
In the case of [[Galileo_Open_Service_Navigation_Message_Authentication|Galileo OS-NMA]]; this feature consists in digitally signing the Open Service Navigation message in the E1 band, making use of forty reserved bits in the Galileo E1B data message and the TESTA protocol, thus keeping the rest of the navigation message unencrypted.


==Notes==
==Notes==

Revision as of 07:42, 28 January 2021


FundamentalsFundamentals
Title GNSS Authentication and encryption
Edited by GMV
Level Basic
Year of Publication 2021
Logo GMV.png


The basic idea behind authentication and encryption is to ensure that a message is identical to the one transmitted at its origin and that it was generated by a trusted source. Encryption and authentication refer to two interrelated mechanisms to protect communications:

  • Communications may be encrypted (e.g. encoded) to keep them secret and make them unreadable to a third party.
  • Authentication is an additional mechanism in which communications are digitally signed to verify its authenticity.

In GNSS, authentication can be defined as the capability of a GNSS receiver to verify the authenticity of the GNSS information and of the entity transmitting it, to ensure that it comes from a trusted source. Authentication is an intrinsic GNSS capability remaining internal to the GNSS receiver.

Different authentication techniques may be considered (unpredictable features at subcarrier or carrier level, as variable pulse shaping, frequency hopping, etc.), however the most promising ones are related to the authentication of the navigation messages.

Most Navigation Message Authentication (NMA) techniques are based on the Timed Efficient Stream Loss-Tolerant Authentication (TESLA) protocol [1]. Some variations and modifications have been proposed exploiting one or more signal components providing, in general, a high level of robustness against simplistic and intermediate spoofing attacks. This category of spoofing includes all the cases where the spoofer is able to generate asynchronous or synchronous counterfeit signals, but not to predict and/or a-priori generate valid NMA data. In fact, from a spoofer perspective, the cryptographically-protected data are not predictable a-priori and cannot be pre-computed by the spoofer. In this sense, a spoofer unable to generate valid cryptographic data can be easily detected by a receiver that implements the NMA algorithm.

Up until now, the main operational GNSS systems which have considered including authentication capabilities are GPS and Galileo. In the case of GPS, a Chips-Message Robust Authentication (Chimera) approach, which is a hybrid NMA and spreading code authentication technique has been proposed for use within the new GPS L1C signal. The NMA portion of this scheme is based on a well-established standard, the asymmetric elliptic curve digital signature algorithm (ECDSA) P-224, which simplifies the integration of the scheme into existing GNSS receivers.

In the case of Galileo OS-NMA; this feature consists in digitally signing the Open Service Navigation message in the E1 band, making use of forty reserved bits in the Galileo E1B data message and the TESTA protocol, thus keeping the rest of the navigation message unencrypted.

Notes


References

  1. ^ I. Fernández-Hernández, V. Rijmen, G. Seco-Granados, J. Simon, I. Rodríguez, and J. David Calle, “A Navi-gation Message Authentication Proposal for the Galileo Open Service,” Navigation, Journal of The Institute of Navigation, vol. 63, no. 1, pp. 85-102