FR2531555A1 - Method of coding a card for an access authorisation system, and system using this method. - Google Patents

Abstract

The invention relates to systems for control of the doors of premises with restricted access. It consists in coding the magnetic cards of electronic locks which control these premises according to an identification area and an authorisation area comprising a set of bits each of which controls the opening of a door. All the electronic locks comprise a card reader 101, electronic logic 102, and a coder 106 which makes it possible to link them to a common electronic telephone exchange (PABX). The signalling device 107, linked to a centralised clock, makes it possible to carry out a day/night changeover. It makes it possible to have a decentralised access authorisation system with centralised monitoring.

Description

METHOD FOR CODING A SYSTEM CARD
ACCESS AUTHORIZATION SYSTEM AND USING THE SAME
The present invention relates to access authorization systems which allow a person with a credit card to open the door of a room whose access is reserved for certain people.

 So-called electronic locks are known which allow a door to be opened by inserting a magnetic card into this lock, sometimes known as a badge, which is of the type commonly used for credit cards. These cards are standardized under the reference ISO 2894.

This standard defines not only the dimensions, but also the characteristics of a certain number of magnetic tracks, and a coding allowing the recording of digital characters on these tracks. The person who wishes to open the door inserts his card into the electronic lock, and the latter reads the magnetic characters carried by the card. If these characters correspond to the code memorized in the lock, the latter controls the opening of the door.

 Such a device obviously requires as many cards as there are doors to open, and does not allow monitoring of successive door openings. If these characteristics are admissible in the case of the door of a particular building, they are annoying in the case of a business with a large number of doors, whose access is restricted to different people and for which it is necessary to monitor and memorize the inputs and outputs in the premises they control.

 To allow the use of a single card, the invention proposes a method of coding a magnetic card for an access authorization system, mainly characterized in that a set of characters is recorded on a magnetic strip of this card. numeric divided into an identification zone allowing the card to be identified, and an authorization zone comprising a determined number of bits each of which allows access to a determined room for a determined period.

Other features and advantages of the invention will appear clearly in the following description presented by way of nonlimiting example and made with reference to the appended figures which represent:
- Figure 1, the block diagram of one of the stations of the access authorization system;
FIG. 2, the diagram of an exemplary embodiment of the reader logic 102 of FIG. 1.

 FIG. 1 shows the local device for controlling the opening of a door, in its maximum configuration. The simplified versions are obtained by deleting part of the organs of this device, and the organs which can be thus deleted will be indicated as the device is described.

 This local device, or station, includes a card reader 101, of the motorized type, in which the card is inserted into a slot 110 indicated by an inscription "INTRODUISEZ YOUR BADGE". This card is automatically swallowed and the reader reads on its track 2, referenced ABA, forty numerical characters of four useful bits written with a density of 75 bpi.

 In an alternative embodiment, a manual reader may be used. As this only allows about half of this information to be read, track 3 is then preferably used. This makes it possible to read 50 characters and therefore to extend the authorization area described below by 10 characters of 4 bits.

 After reading and decoding, the card is returned and one of the two lamps 103 or 104 lights up.

The lamp 103 is red and surmounts the inscription "ACCESS NO
AUTHORIZED ". The lamp 104 is green and overcomes the inscription -" PASS ".

 The forty characters written on the track read are divided into a first identification zone, and a second authorization zone.

 The first zone is made up of nine numeric characters which identify the owner of the card according to an arbitrary code available to the system operator.

 The following thirty-one characters, corresponding to the authorization zone, provide the 124 bits which can each have a "1" or "0" state. Each of these bits is assigned to a room to which we want to authorize access. If the bit is at "1", Access will be authorized, and if it is at "O", it will be refused. We could of course use reverse coding.

 Each card holder is authorized to enter one or more premises, and when his card is coded to be assigned to him, the bits corresponding to the premises to which access is permitted are entered at "1".

 The same room can have several entrance doors each controlled by a local station, and in this case the same bit will be assigned to it and each of these stations will decode this. bit for opening the door it controls.

 The forty characters, ie 160 bits, thus read by the reader 101, are transmitted in series to a reader logic 102 which comes to decode the bit corresponding to the gate which it controls. The reading of this particular bit was programmed by the hardware installer, for example by positioning a determined strap in the circuits of logic 102.

 Depending on the result of this decoding, the logic 102 sends a YES signal or a NO signal respectively on two separate connections to the badge reader 101. The YES signal turns on the lamp 104 and controls the return of the card. The NO signal also controls the return of the card and lights the lamp 103.

 When access is authorized, a separate signal is sent to the door control device after a time delay T1 adjustable by the installer and during a time T2 also adjustable by the installer.

 The time T1 makes it possible to recover the badge and to go to the door, which is more or less distant from the local device, without a person who during this time waiting in front of the door being able to fraudulently cross it. Time T2 allows the authorized person to go through the door alone.

 The lamps go out one second after the card is retrieved.

 In order to allow the identity of the person requesting the opening and the authorization or refusal of this opening to be transmitted to the central monitoring station, the card reader may not swallow another card until it has been reset by an INIT signal transmitted by logic 102.

 Logic 102 retransmits, for the needs of system monitoring, the nine characters of the identification zone, and the prohibition or authorization bit, to a buffer memory 105 of the FIFO type which allows, in the event that transmission lines are congested, allowing faster access to premises in case of crowds. This buffer memory can be deleted, in the case for example where it is wished to ensure stricter monitoring of entries into the room.

In either case, the 37 bits are transmitted to a communication interface 106, which is for example an encoder of the type
Q23, which retransmits the 10 characters corresponding to a PABX telephone exchange, which processes this information in the desired manner, for example by storing it, or by retransmitting it to a guard station. It is known in fact that current private electronic exchanges allow a wide variety of processing of the signals which arrive to them on the subscriber lines.

 The communication interface 106 proceeds, in a known manner, to call the central, and to transmit the information when the latter has established the communication. When the information is transmitted, the interface 106 hangs up the line with the exchange, which then allows it to transmit the initialization signal INIT to the reader logic 102. In the case where buffer buffer 105 is used this INIT signal is transmitted to this memory to receive the next 37 bits, and this memory itself generates the INIT signal intended for logic 102 when it has memorized a 37 bit signal and there is room for it memorize the next.

 There are several types of encoder making it possible to produce the communication interface 106, and in addition to the type Q23 mentioned above, the type V24 will also be mentioned.

 Authorization to access premises is commonly differentiated according to the time of day, in particular between day and night. In such a case, the authorization zone will be subdivided into two distinct 62-bit sub-zones, one corresponding to the day and the other to the night. The accesses of the same room will be assigned a bit in each sub-area, and the logic 102 will switch to recognize one or the other of these bits according to the chosen moment. When registering the card, one or the other of the two bits, or even both, will be 'grounded'. This is the case, for example, for an employee authorized to enter a room during administrative working hours, the bit corresponding to this room in the zone affected by the day will be "1", and that in the zone affected by the night will be "0". However, for a person from the security service , which can be brought in day or night in this same room, the two bits will be "1".

 To switch the logic 102, a signaling interface 107 is used, which in the example shown is integrated into the logic 102. This interface is connected by a pair 108 to a central clock which sends the switching signals at the scheduled times. Advantageously, for this pair 108, the second pair of the connection cable dp- the interface 106 to the local exchange will be used. It is known in fact that the connection cables for telephone sets commonly take two pairs, only one of which is used for telephone communication proper, and the other of which can be used for special needs such as for example connecting the doorbell in the case of parallel posts. The special need here will be the day / night switch command.

An improvement consists in also connecting the pair 108 to a guard post provided with a key making it possible to force the switching day / night in special cases, for example in the event of any alert requiring either to limit access or on the contrary to extend it
In the case of a simple day-night switchover, the control can be done by a simple switch which establishes a loop on the pair 108. The detection of this loop causes the switching of a relay in the reader logic, which replaces the strap corresponding to the control of the day bit by the strap corresponding to the control of the night bit
It is also possible to increase the number of authorization states. In fact, it is not very interesting to continue subdividing the authorization zone into sub-zones of identical dimensions, since this very quickly reduces the number of separate accessible rooms.

On the other hand, it is interesting to assign a limited number of bits to exceptional cases. This is how we can assign the front, last bit to a position called "strike", and the last bit to a position called "fire". Thus in the event of a strike, the reader logic will be switched to decode the penultimate bit, and only a small number of authorized persons will be able to access the premises. In the event of a fire, the reader logic will be switched to decoding the last bit, and the firefighters will be able to access the premises to which they did not normally have access.

 It is clear that we can no longer be satisfied with a simple loop detection on the pair 108 and that it is necessary to send separate signals, which presents no difficulty.

FIG. 2 represents a simple embodiment of the reader logic 102, and of the signaling interface 107. The 160-bit signal, coming from the reader, is applied to a first monostable 201, which delivers a slot whose duration T3 is 160 steps from a clock
H at the same frequency as that of the signal from the card reader.

This clock is applied to an "AND" door 202, which is opened by the monostable 201. The 160 clock steps thus obtained are used to advance a shift register 203 comprising 124 stages. The 160 bit signal is also applied to the input of this shift register. After 160 clock steps, the register therefore contains the 124 bits of the authorization zone. The 124 stages of this register are connected to 124 connections, of which only the connections 160, 129, 69, and 37 have been shown. These connections lead to a set of terminals capable of being connected to another set of terminals by via removable straps. In the example shown, the authorization zone is divided into two sub-zones, day and night, and the door to be controlled is the one corresponding to bits 69 and 129. 1 A strap 204 connects the output of the stage corresponding to bit 69 at one of the input terminals of a two-position relay 206, and a strap 205 connects the stage corresponding to bit 129 to the other terminal of this relay.

 The coil 207 of the relay is connected to the pair 108 which receives the tilting signal, and the relay therefore realizes signaling interface 107.

Depending on the position of relay 206, one of bits 69 or 129 is applied to a direct input from an "AND" gate 208.

 The other inverting input of this gate 208 receives the output signal from the monostable 201, and it therefore opens when the 124 bits of the authorization zone fill the shift register, each in their place. Thus the authorization or refusal bits, selected by the straps 204 and 205, are delivered by the gate 208.

If it is a bit 1, giving the authorization to penetrate, it triggers a first monostable 209, with a duration of one second, which delivers the signal
YES applied to the card reader.

 This bit 1 also triggers a second monostable 210, adjustable, the duration of which corresponds to the time Tl of delay before the door is opened. This second monostable triggers, when it drops, a third monostable 211, also adjustable, which delivers the door opening signal for the duration T2.

 If it is a bit 0 indicating therefore the refusal to open, which comes out of the gate 208, it does not trigger the monostables 209 and 210 but it is inverted in an inverting amplifier 212 whose output is connected to a monostable 213 This is then triggered for a period of one second, and delivers the NO signal to the card reader.

 The output of the shift register 203 is applied to a gate, "OR" 214, which thus lets through the first 36 bits leaving the shift register during the last 36 of the 160 clock steps delivered by the gate 202. The other input of this door 214 is connected to a monostable 215, with a duration of 1 clock step, which is triggered by bit 1 leaving the "AND" gate 208. This monostable 215 therefore delivers, upon arrival of the authorization bit, a bit 1 just after the 36th bit leaving the shift register. This bit takes the place of the 37th bit of the signal from the reader, since at this time the register no longer advances because it no longer receives a clock signal. If the bit leaving gate 208 is a bit 4 the monostable 215 does not fire and its output remains at 0, which corresponds to a bit 0 added behind the 36th bit applied to the other input of gate 214. The output of this gate 214 therefore delivers the 37-bit signal, applied as appropriate to the buffer memory 105 or to the communication interface 106.

 In this exemplary embodiment, the signal INIT, allowing the card reader to read the next card which is presented to it, crosses the reader logic 102 without triggering an event. It is simply reset to the appropriate level for controlling the card reader, by an amplifier 216.

Claims (9)

 1. Method for coding a card for an access authorization system, characterized in that a set of digital characters is divided on this card divided into an identification zone making it possible to identify the card, and a zone authorization comprising a determined number of bits, each of which allows access to a given room for a given period.  2. Method according to claim I, characterized in that the authorization zone comprises two sub-zones comprising the same number of bits, the two sub-zones being assigned to two distinct determined periods.  3. Method according to any one of claims I and 2, characterized in that the authorization zone comprises at least one unmarked bit allowing access to certain premises under determined circumstances.  4. Method according to any one of claims 1 to 3, characterized in that the identification zone comprises 9 characters of 4 useful bits, and the authorization zone 31 characters of 4 bits.  5. Method according to any one of claims 1 to 4, characterized in that the card is a magnetic card comprising at least one magnetic strip.  6. Access authorization system using the method according to any one of claims 1 to 5, characterized in that it comprises a set of card reading stations assigned to a set of premises each provided with at least a door, each station controlling the opening of a door and the stations controlling the doors of the same room detecting the same bit of the card identification area, and an electronic telephone switchboard (BAPX) connected to each station for collect the information read on the cards; each station comprising at least one card reader (101), electronic logic (102) for decoding in the authorization zone the bit corresponding to the room controlled by the station, controlling according to the value of this bit the opening of the door , and form a message comprising the characters of the identification zone and said decoded bit, and a communication interface (106) for transmitting to the telephone switchboard the message formed by the logic.  7. System according to claim 6, characterized in that the electronic logic (102) makes it possible to decode in the authorization zone the two bits of the sub-zones and the unmarked bit, and that it also comprises a signaling interface to receive a batch switching control signal that is electronic on the decoding of one of these bits.  8. System according to any one of claims 6 and 7, characterized in that it further comprises a buffer memory (105) for storing the messages of the electronic logic (102) when the telephone switchboard (PABX) cannot receive these messages, and subsequently deliver these messages to the communication interface (106). Q23 or V24.  -9. System according to any one of Claims 6 to 8, characterized in that the communication interface (106) is an encoder of the type