NO830802L - FLAT BASED DIGITAL CAPACITY INFORMATION STORES AND PROCEDURES FOR READING AND CODING CODES - Google Patents

Description

The invention relates to a surface-bound information store and a method for reading and recoding the same.

Several forms of surface-bound information stores are well known, e.g. magnetic, optical and conductor paths. They can all be read by placing them in a reading unit which is either stationary in relation to the information store or which requires relative movement. Low costs are a common feature, however, unauthorized changes to the stored information are not sufficiently difficult. Digital information stores based on a capacitive principle are well known, e.g. UK patent 1,037,633 which describes a construction based on a line matrix. In most cases, a galvanic connection to the information storage is required, however, US patent 3,604,900 describes a capacitive connection to a multilayer information storage, which includes electronic circuits. However, measures have not been taken for authorized coding of the information store after encapsulation. DOS 26 00 289 mentions, in rather vague terms, a capacitive information storage which has metal areas separated by a dielectric, where the content of the information unit is expressed as the value of the formed capacitor, and where coding is performed by destroying the capacitor's dielectric using a high voltage supplied capacitively to the unity capacitor. None of the capacitive information stores with capacitive connection known to date can be used in areas where there is limited access to power for the reader and recoding unit.

It is an object of the invention to provide a digital, capacitive information storage which has a low production price, which is easy to read with low energy consumption in the reading device, which can be effectively recoded using the device with low energy consumption, and which is difficult to recode for unauthorized persons. This has been achieved according to the invention by allowing the conductive areas of the unit capacitors to only partially overlap each other.

Claim 2 states that one of the conductive areas can be shared by several capacitor units.

Claim 3 states that a unit capacitor can have a weak link in the connection with the capacitor.

Claim 4 states that the reading of a capacitor takes place by means of electrodes placed only on one side of the information storage.

Claim. 5 indicates that recoding of a capacitor unit takes place by means of a high-voltage pulse applied to electrodes placed on only one side of the information storage.

Claim 6 states that recoding a capacitor unit in case it has a weak link takes place in accordance with claim 5, however the mechanism is different.

The invention will be described in more detail below with reference to the drawing, where

fig. 1 shows a plan view of four capacitor units according to the invention,

fig. 2 shows a side view of the capacitor units,

fig. 3 shows a plan and side view of a construction according to claim 2, and

fig. 4 shows a plan view of capacitor units according to claim 3,

fig. 5 shows a plan and side view of an embodiment of the invention which makes it particularly suitable for use in transactions during which the value of the information store, represented by the encoded information, is to be written down during the transaction,

fig. 6 shows the arrangement of electrodes (not to scale) which are used in connection with the methods according to claims 4, 5 and 6,

fig. 7 shows the basic structure of the equipment to be connected to the electrodes shown in fig. 6 to carry out the method according to claim 4, and

fig. 8 shows the basic structure of the equipment to be connected to the electrodes shown in fig. 6 to carry out the method according to claims 5 and 6.

Fig. 1 shows four capacitors out of a large number, which together make up the information store. The capacitor a consists of a first conductive area (1) which is separated from a second conductive area (2) by means of dielectric (3) as shown in fig. 2. The value of the capacitors is one of two values, the capacitive storage being digital. As the distance between conductive areas is constant and provided that the dielectric is also constant, the value of the condensate burn-up only depends on the overlap of the two areas. If appropriate consideration is given to the mutual influence between adjacent capacitors, these can be classified according to size and determine certain information-bearing discrete values. In connection with the description of the equipment's operation as shown in fig. 6 and 8, it will be seen that it will be practical to have a certain information area that cannot be recoded. This has been achieved by placing certain capacitors at a distance from the surface that is greater than that of certain other capacitors. Fig. 3 shows a structure which enables coding of partial information in the same horizontal line, i.e. information which naturally belongs together with regard to the further information processing. This is achieved by letting the first conductive layer of each capacitor be a continuous layer (5) separated from the second conductive layer by a thin dielectric (3). Use of a continuous layer establishes the possibility of using an oxide layer on the surface of the continuous layer (5) as a dielectric using an otherwise well-known technique. Thereby, the advantage of a very thin and stable layer is achieved which, however, has a well-defined breakdown field strength. Fig. 4 shows a structure which is completely analogous to fig. 3, but where a narrowing has been established in the part of the second conductive area (8,8',8") which does not overlap the first conductive area (5,). The application of this structure is explained in connection with fig. 8. Fig. 5 shows a structure analogous to Fig. 3, but where the carrier for the information storage is a stable insulator sheet (D). It is also shown how a varying degree of overlap indicates whether the logical value '■' 1 1 corresponding to large overlap or '0' corresponding to small overlap, shall be associated with the special capacitor unit. It is shown that the partial information defined by the conductive area (5) and the conductive areas (2<n>) indicates a binary number with h bit It is obvious that several degrees of overlap can be used, which is why the resolution of the information will depend on the discrimination of the equipment and the material uniformity of the capacitors.

Due to the mechanical reinforcement of the information storage by means of the substrate (D), it can be handled, and taking into account the given recoding possibilities, it will be appropriate as a so-called "debit" card. A "debit" card represents a value and can be used to obtain benefits, e.g. the possibility of making calls from public payphones where it can represent a payment in line with coins. For each counting pulse, the value of the "debit" card must be written down until the total number of counting pulses has been used, after which it must be invalidated. The information store embedded in a "debit" card must have at least two functions, 1) part of the store must contain information: . which enables identification of the card. The bit pattern on this part must not be changed, as a change will invalidate the card, and 2) part of the storage must contain information about the card's current value. The bit pattern on this part of the information store changes as the card's value decreases. The card can be designed to have several separate tracks. Some tracks may contain information about the card's identity, other tracks may contain information about the card's value. Fig. 6 shows an arrangement of electrodes that can be used when measuring the pre-encoded capacitors and when recoding according to claims 4, 5 and 6. Each electrode, by its proximity, is only associated with one of the conductive areas that make up a capacitor. Thus, the electrode (10) is connected to conductive area (1) and the electrode (9) is connected to conductive area r(2). A different location of the electrode (10) is also shown, namely on the other side of the information storage (10' ). This must be considered to be within the limits of the state of the art, which has always prescribed a large degree of proximity between two electrodes that constitute what can be called coupling capacitors ^ ), (C^) >°9(in relation to the state of the art which is defined above) (C^<1>). As the electrodes are designed both for reading and for recoding, as shown in the figure, it must be possible to connect these to different equipment according to the intended use. This is shown with wire connections (11) to the electrode (10) and (12) to the electrode (9). Fig. 7 shows equipment to be connected to electrodes (9) and (10) to enable reading of the embedded information when the information storage is brought close to the plane of the electrodes. A high-frequency voltage from the generator (13) is supplied to the conductive area (2) through the coupling capacitor (C ), which is formed by part of the conductive area (2), the insulator (4), and the electrode (9), which can be called "generator head". The signal on conductive area (2) is transferred to conductive area (1) via the capacitor unit (C). From conductive area (1) the signal is transferred to electrode (10) via the coupling capacitor (C^) which is made up of part of the conductive area (1)/insulators (3) and (4), and the electrode (10) which can is called "detector head". From the detector head, the signal is fed to an amplifier (14) (fig. 7). The amplitude of the signal transmitted to the amplifier (14) depends on the values of the capacitors (C^), (C^) and (C^) which are effective in series. If (C^) and (C^) are considerably larger than (C), the amplitude of the transmitted signal will be mainly determined by the size of the information capacitor unit (C). In the event that the capacitor (C) exceeds a certain value, the output terminal (16) will receive a level detector (15) in an output signal corresponding to logical '1'. Otherwise, the output signal will correspond to logical '0'. The level detector (15) can also be arranged so that input signals within certain limits will correspond to logic<1>1<1>, while input signals within certain other limits will correspond to logic '0'. Input signals outside these intervals will give an output signal on the level detector's (15) second output terminal (17), which signal can be used to control e.g. rejection of the validity of the information. When used as a "debit" card, this may mean rejection

due to invalidity. Reading of the information storage can also take place by changing the connection between generator (13), amplifier (14) and electrodes (9) and (10). The generator and the detector heads can be movable as a unit,

a "read head" to come into contact with the relevant area of the information store, or the information store can be moved into a reader containing these heads in the correct position. Pulling means can be placed on the side that has the reinforcement base (D) to ensure sufficient mechanical contact.

The information store's encoded information can be changed by

to change the physical properties of the dielectric (3) in the capacitor (C), whereby its value changes so that the reading as described above gives a different signal at level

the output terminals of the detector (15). The properties of the dielectric (3) are changed by applying a high voltage between the conductive areas (2) and (1) of the capacitor (C). Equipment as shown in fig. 8 is used for this, as a high-voltage or combined high-voltage and high-frequency generator (i.e. a pulse generator) (18) is connected to the electrode (9) and a fixed voltage, possibly an earth connection, to the electrode (10). The high-voltage generator (18) supplies a voltage pulse to the conductive area (2) via the capacitor (C ), and the conductive area (1) can be considered to be connected to earth with regard to short voltage pulses via the capacitor (C^).

As the capacitors (C ) and (C,) are assumed to be considered g r d

is greater than the capacitor (C), the electric field in the dielectric (3) will have the greatest field strength in the area between the part of the conductive areas (1) and (2) that make up the capacitor (C). With a suitably high field strength which is easy to determine by the person skilled in the art, the physical properties of the dielectric change so that the capacity and/or insulation resistance between the conductive areas (1) and (2) changes. This change can then be read as described above.

In the event that a configuration of conductive areas is used as shown in fig. 4, it will be possible to achieve a short current pulse in the narrowed part (8,8',8") so that it melts. In this case, the electrode for reading and recoding (9) must be placed close to the part (7, 7',7") furthest away from the conductive area (5), and the same conditions as above are assumed with respect to the relative values of the capacitors.

The preceding description is limited to small areas of an information store according to the invention. The example of the information store used as a "debit card" is an example of use where a flat structure is assumed. However, the information storage according to the invention is equally applicable in connection with single curved surfaces (cylindrical surfaces), and if the radius of curvature is sufficiently greater than the extent of the individual capacitors, or if curved reading and recoding electrodes are used, then double curved surfaces will also could use this information storage principle.

Claims (6)

1. Flat-bonded digital information storage with an insulating cover, in which the information is encoded as a combination of discrete capacitors, each consisting of a first conductive area and a second conductive area separated by a dielectric, characterized in that said first (1,. 1i', 1 " , ...) and said other (2 ,2 ' , 2 " ,...) conductive areas only partially overlap each other. 2. Information storage according to claim 1, characterized in that the first conductive area (5) is extended to cooperate with a number of other conductive areas (2,2', 2") 3. Information storage according to claim 1 or 2, characterized in that said second conductive areas consist of a part (6) which at least partially overlaps the first conductive area, a part (7) which does not overlap, and an intermediate part ( 8) which has a reduced cross-section compared to parts (6) and (7). 4. Method for reading a discrete information unit in an information store according to claim 1 or 3, the value of the capacitor being used as an indication of the information unit's content, characterized in that external electrodes (9) and (10) on the same side of the information store do not establish - galvanic (capacitive) contact with the capacitor's first and second conductive areas. 5. Method for recoding a discrete information unit in an information store according to claim 1, characterized in that external electrodes (9) and (10) on the same side of the information store establish non-galvanic (capacitive) contact with the capacitor's first and other conductive areas, whereby a short high-voltage pulse is applied between the electrodes (9) and (10) to achieve a breakdown of the dielectric (3) between the conductive areas (1) and (2). 6. Method for recoding a discrete information unit in an information store according to claim 3, characterized in that external electrodes (9) and (10) on the same side of the information store establish non-galvanic (capacitive) contact with the capacitor's first conductive area (5 ) and second conductive area (7), after which a short high-voltage pulse is applied between the electrodes to generate a current (I) which destroys the part (8) with a reduced cross-section.