This invention relates to coding security threads for bank notes and other security documents.

It is well known to provide a security thread in a bank note or security paper. The thread, which may be of thread form but is usually in the form of an elongate strip, is usually though not necessarily in the form of an elongated carrier such as a plastics film which supports a metallic member in the form of a continuous or discontinuous strip. It is known to use magnetic material for the strip and it is also known to provide a repetitive coding on the strip. The coding may comprise a binary code of a particular word length. It is preferable to define a bit length, that is to say the length occupied by each bit in the binary code, and to render the bit length substantially constant for the whole length of the strip. The word segments may alternate with the termination segments.

Although the coding of security threads, in the particular case of a magnetic thread, has been known for a long time from, for example GB-1127043, it has proved particularly difficult to provide a security thread which can be reliably detected by a reading machine. It has also proved difficult to provide threads which can yield a sufficient number of codes to enable unique identification of a particular denomination of note or type of note within a given format.

A security thread, usually with its carrier, would normally be manufactured in great lengths so as to be incorporated into paper in a continuous paper making process. The thread may be made from a web and thereafter be slit into narrow strips at least one of which is incorporated at a given place in a continuous roll of security paper so that eventually it extends across the shorter dimension of each of a multiplicity of bank notes printed on the web. It is not usually possible or even desirable to achieve exact register of each bank note with the longitudinal coding on the magnetic thread.

The present invention is particularly concerned with providing an improved format for security threads which are used or intended to be used in bank notes or other similar forms of security document. The main object of the invention is to provide a format which is extremely resistant to false readings and versatile in its variety of codes.

According to one aspect of the invention, a method of coding a security thread for bank notes or security paper comprises applying binary coding to the thread in word segments each comprising a multiplicity of bit lengths of substantially constant length dimension and providing termination segments alternating with the word segments, each termination segment being in length equal to or greater than a first plurality of bit lengths and the word segments each consisting of a second plurality, greater than the first plurality, of bit lengths, the bit lengths of the termination segments having coding of one and the same binary value, and at least the first and last bit lengths in

each word segment being of the other binary value, and the maximum sequence of bit lengths within a word segment having the said one binary value being less than the first plurality.

Owing to the relationship between the length of the termination segment and the said maximum sequence of bit lengths in the word segment, the reading of a plurality of bits taken partly from one word and partly from another is prevented. This restriction reduces the total number of different codes which can be provided by a bit sequence consisting of the second plurality of bits but different codes may be provided by varying a multiplicity of parameters while still retaining the same general format. For example, the bit length of the word can be varied, the format being sufficient to avoid any confusion of a word of end bits with a word of other than end bits. The termination length may be varied. The restriction on the bit sequence length may be varied and of course the individual bit lengths may be varied.

The thread may be a discontinuous thread and the said one binary value may be denoted by an absence of thread. The thread may be magnetic.

Accordingly the invention also provides a security thread for bank notes or security paper comprising a thread which has a binary code composed of bit lengths of substantially constant length, the code being constituted by termination segments and word segments which alternate, each termination segment consisting of a first plurality of bit lengths and each word segment consisting of a second

plurality, greater than the first plurality, of bit lengths, the termination segment having coding of one and the same binary value and at least the first and last bit lengths in the word segment being of the other binary value, and wherein the maximum bit sequence within a word segment of bit lengths which have said one binary value is less than the first plurality.

The termination segments need not be an integral number of bit lengths, and according to another aspect of the invention there is provided a bank note or other security document having running across it within its thickness a thread which has a binary code composed of termination segments and word segments which alternate, each word segment consisting of a predetermined plurality of bit lengths, the first and last bit lengths in each word segment being of a particular binary value, each termination segment being longer in length than a maximum sequence of bit lengths of the other binary value within a word segment, and there being at least one complete word segment and two complete termination segments across the said dimension of the bank note or security document.

According to this aspect of the invention there is also provided a method of coding a security thread for bank notes or security paper, comprising applying binary code into the thread in word segments each comprising a multiplicity of bit lengths of substantially constant length and providing termination segments alternating with the word segments, the word segment consisting of a predetermined plurality of bit lengths, of which at least the first and last bit lengths are of a particular binary value, each termination segment

being in length greater than a maximum sequence of bit lengths of the other binary value within a word segment and formed of portions corresponding to the binary value of the opposite sense to that of the first and last bit lengths in the word segment.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 illustrates diagramatically one form of magnetic security thread according to the inventions.

Figure 2 illustrates a magnetic thread having the same format as the thread shown in Figure 1 but with a different coding.

DETAILED DESCRIPTION

The security device shown in Figure 1 consists of a security thread 1 which may comprise, in this embodiment a carrier such as a plastic strip 2 which may be made of 'Melinex' or other suitable polyester. The surface of the strip 2 may be coated with a vacuum deposition of, for example, aluminium. Along the thread 1 is a discontinuous track 3 of magnetic material. For convenience of understanding, the track 3 is shown as divided into equally spaced bit lengths, those which are cross hatched denoting which bit lengths are constituted by material, and those bit lengths which are blank showing where material is omitted. This embodiment of a thread is preferred, but it is not the only form available. Other forms of coding using a continuous or discontinuous thread are intended to be within the scope of the invention.

The bit lengths or bit cells of the thread are of substantially equal length. Typically, each bit length may be 2 mm long. Of course, this is a parameter which can be varied without altering the same general format.

The magnetic thread or track is coded so that alternate segments 4 and 5 succeed each other along the length of thread. The segments 4 are termination segments which separate and define the beginning and end of two successive word segments. Each word segment 5 in a given magnetic thread has the same length. In the example shown the word length is eleven bits. Employing the convention that the presence of magnetic material in a bit length is to be denoted by a 1, and absence by a 0, the particular coding for each word length 5 in the embodiment in Figure 1 is 10100011111.

Each termination segment consists effectively of a plurality of bit lengths; that is to say, it occupies a length equal to an integral multiple of bit lengths. Each of the bit lengths in the termination segment contains no magnetic material, and is therefore a 0.

A first bit length 6 and a last bit length 7 in the word segment should be of the opposite binary value to those of the termination segment. Thus, in this embodiment, the first and last bit lengths of the word segment should be l's.

The format herein employed has one further restriction, namely a restriction on a continuous sequence 8 of 0's within each word, that is to say a sequence of binary digits

which have the same effective binary value as the (imaginary) bits in the termination segment. This restriction is employed in order to prevent the occurrence within a word of any sequence which might be confused with a termination segment.

In the example therefor the length of each termination segment 4 is four bit lengths, i.e. four 0's, and accordingly the maximum sequence of 0's in the word segments must be less than four.

Figure 2 illustrates diagramatically another security strip which has the same format and parameters as the strip shown in Figure 1 but with a different coding, the coding within , each word segment being 11011010001. This strip likewise has a maximum sequence of bits of coding corresponding to bits in the termination segment of one fewer than the bit length of the temination segment.

In the foregoing, all the words within a particular strip have the same length and coding. This is preferred but the repetition cycle could be greater than that shown.

The use of an 11 bit word with a 4 bit termination segment and a 3 bit restriction on the length of a sequence of 0's within each word is not, of course essential. One of the advantages of the invention is that the same general format can be used while the parameters of word length and so on can be varied. A greater restriction on the number of codes available is provided by varying the 0 sequence maximum length so that it is more than one bit length fewer than the length of the termination segment. This is more appropriate

for codings where the word length and termination length are substantially greater than as shown in the drawing.

Although the restriction on the maximum sequence of 0's within a word segment substantially reduces the different codes available, a great variety of different codes may be provided by varying the word length, the termination length and the bit length.

The tolerances adopted for the bit length are generally of the order of 15% of a bit length for any sequence of bits. Thus a 2 mm length may have a tolerance between 1.7 mm and 2.3 mm but a three bit length, corresponding to β mm, may have a tolerance of 5.7 mm to 6.3 mm. In this case the absolute tolerances are the same regardless of the length of the respective bit sequence.

The use of such a constant absolute tolerance rather than a fractional tolerance facilitates the provision of different codes which employ the same general format but employ a different bit length.

In the foregoing, the termination segment has a length equal to a plurality of bit lengths. This restriction is not essential. The termination segment must have a length greater than the longest permitted sequence of like-valued bits within a word and be such that a complete word length and its termination segments occupy less than the relevant dimension of a note across which the thread is disposed.

Security threads coded according to the present invention may be incorporated in security paper or bank notes

according to known techniques. In particular a laminated strip comprises a magnetic track sandwiched between two aluminised polyester films may be disposed within the thickness of the paper in accordance with known techniques. The security devices may be made in comparatively wide widths and then slit longitudinally to provide strips of an appropriate size (of the order of a millimeter in width) for incorporation into paper which will be printed to form bank notes and subsequently cut up to provide individual bank notes each of which has a security thread running across it, usually across the shorter dimension.