FR2907928A1 - Autonomous user authentication device for access control system of e.g. building, has storage unit, and reading unit arranged such that unit converts mechanical work of action into electrical energy when action is exerted on reading unit - Google Patents

Abstract

The device (100) has an authentication sensor i.e. finger print reading unit (110), arranged with respect to a solar/thermoelectrical type converting unit (120) e.g. electromagnetic transducer, so that the unit (120) converts mechanical work of mechanical action into electrical energy when the action is exerted on the unit (110). A microcontroller (140) compares characteristics of finger prints for determining whether the action exerted on the reading unit is authorized by a user, and an energy storage unit (130) i.e. capacitor, stores the electrical energy.

Description

The invention relates to an authentication device in a

  access control system, in particular a building, a garage or a vehicle.

  Such a system generally comprises two parts. The purpose of the first part is to identify a user who wants to access the building, the garage or the vehicle and the second part is to operate a mobile means of authorizing or prohibiting access to the building. garage or vehicle. Preferably, the communication between these two parts is done by wireless means for example radio means which avoids wiring. As a result each part must be powered by a different energy source. As the second part requires a large amount of energy, it is preferentially connected to the sector and is used for example energy conversion means for example of the solar or thermoelectric type into electrical energy. However, the use of this type of means requires that we have relatively large energy storage means insofar as the periods of energy need do not always coincide with the periods of energy supply and in the as the power of the energy inputs is generally much lower than the power of the needs. EP 1 306 817, US 6,861,785, EP 1,312,171, EP 1 324 468 or US 6,700,310 are known from autonomous transmitters. In addition, various authentication means such as keys, card readers or biometric means are known. MS \ 2. S649.12FR.574.dpt. The object of the invention is to provide an authentication device that overcomes the problems mentioned above and improves the known devices of the prior art. In particular, the authentication device according to the invention allows the use of electrical energy storage means of very low capacity. Such energy storage means are therefore not very bulky. The authentication device according to the invention makes it possible to group together in a single action of the user the various actions necessary for the energization of the device and the authentication, which presents a great advantage of simplicity in ergonomics. The autonomous authentication device according to the invention comprises an authentication sensor and a means for converting mechanical energy into electrical energy. It is characterized in that the authentication sensor 15 is a fingerprint reading means arranged with respect to the energy conversion means so that, when a mechanical action is exerted on the reading means of the fingerprint, the mechanical work of this mechanical action is converted into electrical energy by the energy conversion means. The fingerprint reading means may be mounted on the energy conversion means. The mechanical action may comprise a translation of the finger in front of the fingerprint reading means. The mechanical action may include finger pressure on the fingerprint reading means. The authentication device may include a fingerprint feature storage memory, MS \ 2 means. S649.12FR.574. Fingerprint characteristics comparison to determine whether an action on the authentication sensor is performed by an authorized user and means to issue control commands accordingly. In this case, the command commands that the authentication device transmits can be encrypted or contain an identifier of its address. The access control system according to the invention comprises a mobile element operating device and an autonomous authentication device defined above. The appended drawing represents, by way of example, an embodiment of an access control system according to the invention. Figure 1 is a diagram of an embodiment of an access control system according to the invention. Figure 2 is a flowchart of an embodiment of such an access control system. Fig. 3 is a diagram detailing an embodiment of combined elements of Fig. 1.

  The access control system 1 represented in FIG. 1 comprises two parts: an authentication device 100 and an operating device 200. The system makes it possible, in particular, to control access to a building, a garage or a vehicle. by controlling an actuating actuator of a movable element, in particular a door, a barrier or a lock. MS \ 2. The authentication device 100 preferably contains at least one fingerprint reading means 110, a means for converting mechanical energy into electrical energy 120, a means of energy storage 130, a microcontroller 140, a non-volatile memory 150 and a wireless command transmitter 160. The authentication device 100 may be mounted at a fixed location or be part of a nomadic element. The fingerprint reading means is arranged with respect to the energy conversion means, so that when a user presses his finger on the fingerprint reading means, this action activates the data conversion means. energy and generates sufficient electrical energy to enable the reading of a fingerprint, the comparison of this fingerprint with other fingerprints stored in memory and the eventual transmission of a motion control command of the element mobile as a result of this comparison. Different types of fingerprint reading means can be used. They can in particular be optical, capacitive, electronic, electromagnetic, or else include a CCD (coupled charge device). The means for converting mechanical energy into electrical energy may in particular be a piezoelectric element and / or an electromagnetic transducer. The energy conversion means may include additional circuits such as in particular a rectifier. The fingerprint reading means can be mounted directly on the energy conversion means. It can also be mounted on a button which is connected to the energy conversion means. Finally, the fingerprint reading means 30 may contain a mechanical element MS \ 2. S649.12FR.574.dp.doc.doc.doc 269/249 EN which is activated during the pressing of the finger, this element being associated with the energy conversion means. The energy storage means is preferably a capacitor.

5 The use of a rechargeable battery could also be imaginable. The operating device 200 preferably contains at least one wireless command receiver 210 and an actuator 220. The actuator 220 is intended to provide the opening and closing operations of the movable element. The authentication device 100 is activated during an authentication process by the user. According to the information gathered during this process, the authentication device 100 transmits wireless control commands to the control device 200 by radio frequency signals 300.

One embodiment of an authentication method used by an authentication device according to the invention is described with reference to the flowchart of FIG. 2.

In a first step 400, the authentication method is initiated. In a second step 410, the user acts on the authentication device 100, by pressing his finger on the fingerprint reading means 110.

Since the fingerprint reading means 110 is associated with the energy conversion means 120 (for example, the reading means is mounted on the conversion means as seen above), in a step 420, the action of the finger of the finger the user activates the conversion means which provides the energy necessary for the operation of the authentication device. MS \ 2. S 649.12FR. 74. dept. In a step 430, the energy in excess of that consumed instantly is stored in an energy storage means.

In a step 440, the fingerprint reading means acquires data defining characteristics of the fingerprint on the reading means. In a test step 450, the data acquired in step 440 is compared with data stored in memory and defining the fingerprint characteristics of the users authorized to control a move of the movable member. If the data acquired corresponds to the characteristics of a fingerprint stored in memory and belonging to an authorized user, a step 470 is taken in which the command transmitter 160 issues a control command to the operating device. This control command may include the address of the authentication device and may be encrypted. Upon receipt of the control command by the receiver 20 the operating device acts on the movable member to move it. In a step 500, the authentication method is completed. If the acquired data does not correspond to any of the characteristics of a fingerprint stored in memory and belonging to an authorized user, step 500 is proceeded to. The result of the test step 450 can be notified to the user. thanks to a visual or acoustic signal.

Steps 420 to 440 may take place in another order and in particular take place in parallel. Indeed, it is sufficient that the stored energy MS \ 2. S649.12FR. 574. dpt. in the storage means is sufficient to start the acquisition process, and the energy storage can take place during the entire duration of this acquisition, or even during a continuation of the user action while the acquisition is finished. According to the identification technique, the comparison with the data in memory of step 450 can also begin before the acquisition step 440 is completed.

The communication between the command transmitter and the command receiver can be unidirectional or bidirectional, as represented by the double arrow denoting the radio frequency signals 300 in FIG. 1. Thanks to the structure of the authentication device according to FIG. In the invention and the authentication method described above, it is noted that the electrical energy storage capacity can be greatly reduced compared to that required in the autonomous devices known from the prior art. This reduction in the electrical energy storage capacity is also accompanied by a reduction in the dimensions of the electrical energy storage means. This is due in particular to the fact that the electrical energy is produced at the moment when it is consumed. Performing the comparison step 450 at the authentication device and not sending the data defining the characteristics of the fingerprint read reduces the power consumption. It is important to size the energy converting means so that a complete action thereon, for example a fulcrum causing a complete stroke of a displaceable member thereof, produces sufficient energy to allow reading of an MS \ 2. S 649.12FR. 74. dept. The digital fingerprint, the comparison of the characteristics of this fingerprint with those of other fingerprints stored in memory and the possible issuance of a motion control command of the movable element as a result of this comparison.

In particular, as shown in FIG. 3, the ACT action on the displaceable element can have two components, a first displacement component ACT1 caused by the simple support of the finger, and a second displacement component ACT2, substantially perpendicular. to the first displacement component caused by a translation movement of the finger in support. The second displacement component has an amplitude preferably greater than the first.

For the user, it is a single action in appearance, while it can implement simultaneously or successively two different energy converters, for example a piezoelectric type converter 121 for the recovery of the compression energy W1 due to the first displacement component ACT1, and an electromagnetic type converter, having a coil 122 and a set of alternating magnetic poles 123, for the recovery of the translation energy W2 due to the second component of ACT2 displacement. The energy storage means 130 then comprises two inputs. Internal diodes make it possible to avoid the passage of current from one converter to the other. The use of a translational movement component is particularly advantageous if the finger has to move in front of an optical strip 111 of the CCD type for reading line-to-line imprints. The bar 111 has a main axis perpendicular to the MS \ 2. S 649.12FR. 74. dept. The direction of optical reading is represented by a double arrow. Preferably, the finger presses on a transparent surface 121 and 5 protected against soiling, this surface being guided in translation above the CCD bar and in a direction substantially perpendicular to the main axis of this bar. The transparent surface 121 is for example made of piezoelectric polymer PVDF type. It is disposed on a transparent movable plate 113, sliding on supports 114 arranged on a frame 112 and comprising for example rollers or sliding pads to facilitate the movement of the movable plate. The set of alternating magnetic poles 123 is connected to the movable plate 113. The translation of the movable plate thus causes the passage of alternating magnetic poles in the coil 122, which is fixed relative to the frame (link not shown). Alternatively, the supports 114 are connected to the movable plate 113 by hinges. The action ACT causes a bending of the supports and the energy converters are then arranged on the supports. In this case, the supports may be integrally made of piezoelectric material.

It is possible to limit the action and the energy conversion to a single displacement component if the energy dimensioning allows it. In any case, the invention allows a completely transparent use for the user and thus simplifies the usability of the autonomous authentication device. MS \ 2. S 649.12FR. 74. dept. doc

Claims (7)

claims   : 1. Autonomous authentication device (100) comprising an authentication sensor (110) and a means (120) for converting mechanical energy into electrical energy, characterized in that the authentication sensor is a reading means fingerprint arrangement arranged with respect to the energy conversion means so that, when a mechanical action is exerted on the fingerprint reading means, the mechanical work of this mechanical action is converted into electrical energy by the energy conversion means.   2. Authentication device according to claim 1, characterized in that the fingerprint reading means is mounted on the energy conversion means.   3. Authentication device according to claim 1 or 2, characterized in that the mechanical action comprises a translation of the finger in front of the fingerprint reading means.   4. Authentication device according to claim 1 or 2, characterized in that the mechanical action comprises a finger pressure on the fingerprint reading means. 25   5. Authentication device according to one of the preceding claims, characterized in that it comprises a memory (150) for storing fingerprint characteristics, means (140) for comparison of fingerprint characteristics to determine if an action on the authentication sensor 30 is performed by an authorized user and means (160) for issuing control commands accordingly. MS \ 2. S649.12FR.574. dept. doc 10 5 2907928 11   6. Authentication device according to claim 5, characterized in that the control commands that it emits are encrypted or contain an identifier of its address.   An access control system (1) comprising a mobile element operating device (200) and an autonomous authentication device (100) according to one of the preceding claims. 1.0 MS \ 2. S 649.12FR.574.dpt. doc