FR2927495A1 - Safe transaction system, has logic, arithmetic and electronic units detect proximity degree of user device with respect to terminal from analysis of electronic signals provided by antennas that receive radio signals emitted on channel - Google Patents

Abstract

The system has a radio terminal (BR) comprising two radio antennas arranged at positions near to each other. The antennas provide radio signals with different amplitudes, when a user device (DU) i.e. portable telephone, is placed near to the antennas. Logic, arithmetic and logic units detect a proximity degree of the user device with respect to the terminal from an analysis of electrical signals provided by the antennas. The antennas receive the radio signals emitted by the user device on a transmission channel (KR). The portable telephone is equipped with a Java(RTM: object-oriented programming language) virtual machine.

Description

PROVIDING SECURE TRANSACTIONS OF 2.4 GHz PROXIMITY WITH A DEVICE SUCH AS A PORTABLE RADIO TERMINAL

The present invention relates to the realization of secure, proximity and radio-based transactions over UHF frequency bands and beyond, using existing and low-cost user terminals, for example mobile telephones with communication functions. the Bluetooth (registered trademark) standard.

The context of the present is as follows: a) Secure local transactions can now be realized simply and economically with so-called Rfid equipment operating at the frequency of 13.56 Mhz (for example: selective access control such as the Navigo (registered trademark) system of RATP (registered trademark) Paris transport) b) There is currently no simple and economical way of carrying out such transactions with frequencies in the UHF frequency bands or beyond ( and in particular ISM free-use frequency bands such as 868 Mhz, 902 to 928 Mhz, 2.4 Ghz), c) It is not currently possible to use a mobile phone, with or without a communication option to the Bluetooth standard) to carry out such transactions d) Many research exist to incorporate Rfid devices operating in the band of 13.56 MHz in telephone to make such transactions with mobile phones e) such incorporation 13.56 Mhz devices in mobile phones has no technical difficulty, but is very heavy economically since to allow a large number of people to be able to achieve such transactions, it is necessary to change, or at least to adapt all the mobile phones used by these people.

The present invention aims to enable the realization of such transactions with user devices (the devices used by customers or end users) currently existing and already widely distributed. For this purpose, the subject of the invention is a system of transactions, of proximity and carried out by radio on the UHF frequency bands and beyond, and comprising: a) a user device (DU), manipulated by the user ( U), provided with electronic, arithmetic and logic means (LU), a user interface (UI), as well as radio communication means (RU) b) a radio terminal (BR) comprising radio communication means (RR) ) and electronic, arithmetic and logic means (LR) c) a bidirectional radio transmission channel (KR) over a UHF frequency band and beyond between the user device (DU) and the radio terminal (BR) characterized in that that the radio terminal (BR) further comprises at least two radio antennas (AT1) and (AT2) connected to the radio communication means (RR) of said terminal, said at least two antennas being: - arranged at very close positions l one of the other, - able to provide radio signals with amplitudes significantly different when the user device (DU) is also very close to at least two radio antennas (AT1) and (AT2), the electronic, arithmetic and logic means (LR) being able to detect the degree of proximity of the user device (DU) with respect to the radio terminal (BR) from the analysis of the electrical signals supplied by the at least two antennas (AT1) and (AT2) following reception of the radio signals transmitted by the user device (DU) on the transmission channel (KR) Thus, only the terminals (the proximity devices that interact with the user terminals) used in the context of the present invention are specific to the invention, and are cost and ease of use comparable to the existing terminals. It will be noted that the number of terminals to be installed for a general public application (selective access for transport, payment or micro payment device) is of the order of thousands or tens of thousands for a general public application. This number must be compared to the number of terminals to provide or adapt so that the general public can use the application: the latter number is of the order of one million or tens of millions. In particular: - the number of mobile phones in existence worldwide is several hundred million - in OECD countries, the rate of equipment of the population in mobile phones is of the order of 80%, and the percentage of mobile phones equipped with a Bluetooth connection is increasing and already in the order of 60% PRESENTATION OF FIGURES Other features and advantages of the invention will become apparent from the following description, given as a non-limiting example, with reference to the appended figures in which: Figure 1 shows the main elements involved in the invention.

Figure 2 details the components of the device handled by the user. Figure 3 details the components of the radio terminal. Figure 4 details the elements making up the radio portion of the radio terminal. Figure 5 details the elements showing the importance of using more than one antenna in the radio terminal.

DETAILED DESCRIPTION OF THE INVENTION In the various figures, the same references have been retained to designate identical or similar elements. Figure 1 depicts a typical use situation of the invention: - the user (U) manipulates a user device (DU) - the user device (DU) communicates by means of a bidirectional transmission channel (KR) with a radio terminal (BR) The transmission channel (KR) is bidirectional and uses frequencies in the UHF frequency bands or beyond (and in particular the so-called ISM free frequency bands such as 868 Mhz, 902 to 928 MHz, 2.4 GHz). Figure 2 details the elements of the user device (DU). - radio means (RU) - electronic, arithmetic and logical means (LU) - a user interface (UI) As an example of a user device (DU), mention may be made of: - a mobile phone with an option of communication to the Bluetooth standard and a Java virtual machine (registered trademark) - a specialized device of the radio remote control type, communicating in one of the ISM radio bands between 868 Mhz and 2.4 Ghz Figure 3 details the elements of the terminal radio (BR): - radio means (RR) - electronic, arithmetic and logical means (LR) Figure 4 details the key elements of the radio means (RR) of the radio terminal (BR): 20 - at least two antennas (AT1) and (AT2) - a radio transceiver (ERT) adapted to manage the at least two antennas (AT1) and (AT2) - (advantageously) an attenuator (TN1) and (TN2) for each of the at least two antennas (AT1) and (AT2) The presence of the at least two antennas (AT1) and (AT2) is u an essential element of the present invention. For aspects other than the presence of at least two antennas (AT1) and (AT2) and their management by the radio transceiver (ERT), the radio terminal (BR) according to the invention has no particular specificity by report to radio terminals according to the state of the art. The object of the invention is to enable the realization of secure, proximity and radio transactions. For this, the following characteristics must be met: a) the transaction must be able to be performed only by the user (U) wishing to perform the transaction b) any observer who can listen to communications on the transmission channel (KR) must not be able to obtain information enabling it to perform transactions of the type performed by the user (U)

Point b) above is managed by conventional means: - radio communications on the transmission channel (KR) are encrypted, for example using the 128-bit AES algorithm which is implemented on components or modules managing communications on the 2.4 Ghz frequency band (for example: Chipcon CC2420 components, Xbee modules - registered trademarks) - the information transmitted by the user device (DU) takes into account risks transmitted by the radio terminal (BR ) to present themselves a random character For example, the following communication protocol makes it possible to respond to point b) above: i. The radio terminal (BR) sends to the user device (DU) a hazard (A) in an encrypted message ii. The user device (DU) decrypts the message and recovers the hazard (A) iii. The user device (DU) gives a random character to the information (I) that it wishes to send to the radio terminal (BR) by performing an EXCLUSIVE OR between the data (A) and (D), which generates the data (X) iv. The user device (DU) transmits the data (X) to the radio terminal in an encrypted message v. The radio terminal (BR) decrypts the message and retrieves the data (X) vi. The radio terminal (BR) retrieves the information (I) by performing an EXCLUSIVE OR between the data (X) and (D) the hazard (A). The point a) above is managed by means of the at least two antennas (AT1) and (AT2) as follows: - the at least two antennas (AT1) and (AT2) are arranged very close to one another, typically a few centimeters from each other. the other, in order to be less than half a wavelength away from the frequencies used on the transmission channel (KR) 20 - under these conditions they are intended to receive an identical signal - to be able to receive signals from amplitude significantly different, the user device (DU) must necessarily be very close to at least two antennas (AT1) and (AT2)

FIG. 5 makes it possible to appreciate how this proximity is necessary so that the signals received by the at least two antennas (AT1) and (AT2) are of significantly different amplitude: a) Two antennas (AT1) and (AT2) are placed on the right (DA) and perpendicular thereto, the point (A) being located in the middle of (AT1) and (AT2), and the axis (AX) is perpendicular to the right (DA) b) a point (P) is located on the right (DP), parallel to the right (DA), the point (0) being located at the intersection of the line (DP) and the axis (AX), the distance between the point (A) and (AT1) or (AT2) is equal to xc) the distance between the points (A) and (0) is equal to D, the distance between the points (0) and (P) is equal to xd) the angles (NP1) and (NP2) are the angles existing between the line (DP) on the one hand, and the lines ((P), (AT1)) and ((P), (AT2)) of e) the angles (NA1) and (NA2) are the angles between the line (DA) on the one hand, and the lines (( P), (AT1)) and ((P), (AT2)) on the other hand It is noted that the cotangentes of the angles (NA1) and (NA2), the angles under which the point (P) is seen by the antennas (AT1) and (AT2), are the following: Cotg (NAl) = (X + d) / D = (X / D) + (d / D) Cotg (NA2) = (Xd) / D = (X / D) - (d / D) One recalls that Cotg (90 °) = 0, the function Cotg is linear close to 90 °, and Cotg (0 °) = infinite. A typical case of use of the invention is: d = 5 mm D = 5 cm to 20 cm It is thus seen that if X is of the same order of magnitude as D, then the angles (NA1) and (NA2) are very neighbors, and that is all the more true since D is large. If, on the contrary, X is of the same order of magnitude as d, then the angles (NA1) and (NA2) are close to 0 °.

We can see that if the antennas (AT1) and (AT2) are directional, especially in the vicinity of 0 °, then it is possible to: - appreciate the presence and position P of a nearby radio source antennas (AT1) and (AT2) or moving in the vicinity of these antennas by detecting a difference in the signals detected by the antennas (AT1) and (AT2), and in particular in the amplitude of these signals - not detecting significant difference in the signals detected by the antennas (AT1) and (AT2) if the point (P) is remote from the antennas (AT1) and (AT2), for example by a distance greater than 20 times the distance d existing between the antennas (AT1) and (AT2) The difference of the signals picked up by the antennas (AT1) and (AT2) can be done statically, that is to say with a point (P) stationary or moving very slowly, or on the contrary dynamically with a point (P) moving, preferably in the axis (DA) which connects the two antennas (AT1) and (AT2). A moving point (P) is particularly advantageous because it makes it possible to carry out numerous successive measurements and allows a better appreciation of the position of the point (P). A mobile point (P) corresponds for the user (U) to a particularly simple gesture, which consists in moving the user device (DU) a few centimeters in the vicinity of the antennas (AT1) and (AT2), a commonly designated gesture. by the term badger. It is also possible to use more than two antennas, in order to better estimate the position of the point (P) in the vicinity of the antennas. We also see that a transaction simulation by a radio source located far from the antennas (AT1) and (AT2) is doomed to failure, whatever the power of the radio signal used: indeed the proximity between the user device ( DU) and the radio terminal (BR) is discovered by comparing at least two electrical signals, which depend on the radiation pattern of the at least two antennas (AT1) and (AT2).

Furthermore, the at least two antennas (AT1) and (AT2) must have very restrictive characteristics to be adapted to the proper operation according to the invention: - they must have a significant directivity - they must have a weak coupling between them, despite their proximity, which is typically less than half a wavelength In the present invention, antenna antennas (AT1) and (AT2) will be referred to as any combination of antenna, ground plane, absorbent electric radio or conductive screen which results in obtaining antennas (AT1) and (AT2) with a directivity and low coupling between them adapted to the present invention. In particular, it will be possible to use antennas described in the patent application FR 0703297000 of 09/05/07. Moreover, given the proximity of the user device (DU) and the radio terminal (BR), it will be advantageous to connect the at least two antennas (AT1) and (AT2) to at least two attenuators (TN1) and ( TN2) (an attenuator connected to each antenna, for example to attenuate power by a factor of 100 or a factor of 1,000). This will allow the radio terminal (BR) to operate with electrical signals of a standard level, and also to make a first selection on the radio devices with which it can communicate.

An example of a user device (DU) is a mobile phone equipped with the following elements: - a communication function with the Bluetooth standard - a Java virtual machine (registered trademark) allowing to run programs and to have access to the function of communication with the Bluetooth standard - an application executed by the Java virtual machine dedicated to the management of communications with the radio terminal (BR), which could for example be downloaded

Claims (3)

1. A system of transactions, proximity, and radio over the UHF frequency bands and beyond, comprising: a) a user device (DU), manipulated by the user (U), provided with electronic, arithmetic means and logic (LU), a user interface (UI), and radio communication means (RU) b) a radio terminal (BR) comprising radio communication means (RR) and electronic, arithmetic and logical means (LR) c) a two-way radio transmission channel (KR) over a UHF frequency band and beyond between the user device (DU) and the radio terminal (BR) characterized in that the radio terminal (BR) comprises in addition to at least two radio antennas (AT1) and (AT2) connected to the radio communication means (RR) of said terminal, said at least two antennas being: - arranged at very close positions to each other, - apt to provide radio signals of significantly different amplitudes when e the user device (DU) is also located very close to at least two radio antennas (AT1) and (AT2), the electronic, arithmetic and logic means (LR) being able to detect the degree of proximity of the user device (DU ) with respect to the radio terminal (BR) from the analysis of the electrical signals supplied by the at least two antennas (AT1) and (AT2) following the reception of the radio signals transmitted by the user device (DU) on the channel transmission (KR) 2. System according to claim 1, in which the radio communications on the transmission channel (KR) are encrypted 3. System according to claims 1 and 2, in which the data transmitted by the user device (DU) on the transmission channel (KR) is of random character for an observer who is able to listen to radio communications on the transmission channel (KR) 15