DE1180178B - Device for character recognition - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Boarding school Class: G06f

German KL: 43 a - 41/03

Number: 1180 178

File number: J 20747IX c / 43 a

Filing date: October 30, 1961

Opening day: October 22, 1964

The invention relates to a device for character recognition with a scanner for section-by-section Character scanning and with a pattern memory in which signals of pattern characters are stored in an organization operation preceding the actual recognition operation are used to set the device to a certain type of character.

A device for character recognition has already become known in which in one of the actual recognition operation scanned and stored a pattern of the character type to be recognized will. A magnetic drum serves as a memory, on the circumference of which the pattern characters one after the other to be recorded. Then, during the recognition operation, the scanned characters and the pattern characters read from the drum are fed to a comparison device which, during the determination a match delivers a recognition signal. This device requires a control device for exact synchronization between the character scanning and the extraction of the sample characters from the pattern memory.

It is also known in character recognition devices for a specific type of character are trained to use sequential circuits that are characteristic of the characters to be recognized Partial signals are supplied staggered in time. These devices use as a recognition criterion the lengths of the lines recorded in the form of pulses. The by point-by-point sampling obtained character signals are fed to a presorting circuit, which is in connection with counting circuits signals for the identification of short, medium-length or long characters or spacing generated. These signals are temporarily stored in a shift register arrangement. Signal combinations are compiled from the memories in a switching matrix, which are fed to the follow-up circuits together with height-indicative values. For each characters to be recognized, such a sequential circuit is provided as a rigid combination of AND, OR and inverse circuits is constructed.

In a sequential circuit, the instantaneous output signal is not just a function of the instantaneous Input signals, but also the history of the inputs. It is the use a table, a so-called flow table, for recording the sequence of these earlier ones Input states and for the definition of the we-device for character recognition

Applicant:

International Business Machines Corporation,
New York, NY (V. St. A.)

Representative:

Dipl.-Ing. HE Böhmer, patent attorney,
ίο Böblingen (Württ), Sindelfinger Str. 49

Named as inventor:
Edward John Skiko, Poughkeepsie, NY,
Paul Revere Low, Palo Alto, Calif. (V. St. A.)

Claimed priority:

V. St. ν. America October 31, 1960

(66 299)

k way of the desired circuit has been proposed. It is essential that the river or the switching sequence runs downwards in a table comprising several rows of boxes that are separated by the Crossing horizontal and vertical lines are formed. The usual sequence switching mechanism derives conclusions from the previous history at every point during operation, represents an instantaneous State represented by a line and saves one possibility of several future ones States. The choice of the future status depends on the current status and the input signal depending on the row and column input. The flow chart illustrates the prehistory by numbering; usually one has a steady state for each line or period of history and a switching or unstable state between two stable states. This so-called flow table logic provides a technique for practicing a logic circuit in a physical one Matrix form, which is directly analogous to the flow table form and of the usual form of links differs from AND, OR and inversion circuits. Because of this technique are logical Circuits easy to design and inexpensive to manufacture. Applications of the flow chart logic for sequential circuits, especially for counting circuits are known. More information about the structure and the applications of flow table logic in data processing technology are, for example, in

409 708/204

the book by S. H. Caldwell, “Switching Cir- gen of a White Part of the Sign in the Correspond and Logical Design ”, New York, 1958. See the corresponding column. The line above the reference

The main object of the invention is what chen denotes the complement or "not an automatically organizing device function". For example, Ύ is “not X”, and ΎΥΖ for character recognition in a simple way under Ver. 5 the combination of signals means “not X”. Reversal of the principles explained above and "not Y" with "Z".

to develop the flow chart logic. This is achieved during the initial organizational period

This is because sequential circuits in the form of processing devices are provided one after the other which have a flow table matrices, which inputs A, B marking the sequence of characters and scanning signals via lines of a matrix io matched partial pattern inputs, such as ζ. Β. Ύ Y ~ Z, XYZ coordinates for step-by-step advancement of one and XYZ, of organizational level 4. Pre-defined switching status are supplied that processing signals indicate a first pattern. A memory switch elements at the crossing points of the river level and an associated pattern flow table level board matrices memory elements of the pattern memory or matrix are assigned to this pattern by preparation, which characterisie the characters to be recognized during the organization for a line of the cable 13 and organization operation - tion photoconductors 14, which are grouped around each organization circuit in the flow table matrices setting- luminous element 15, assigned, and that luminesce with predetermined lines of the output lines connected to the intersection of the other matrix coordinates luminesce and make lines for display serve that the supplied 20 selected organization photoconductor 14 conductive to th input signals have corresponded to a set switching path corresponding memory light elements 16 in the. To light up memory level 5.

With the device according to the invention, the optical coupling and feedback

both a synchronization between characters from the memory light element 16 to the memory photo-scanning and pattern memory as well as a comparison 35 conductor 17 becomes the memory latch circuit 18 set between scanned characters and sample characters. This includes the light element 16 with superfluous. In addition, the arrangement enables positive feedback to the photoconductor 17 and to them Utilization of the ordered, optically coupled, related elements belonging to the flow table matrices Advantages by having a simple design of the circuit input and output adjusting photoconductors 19 and even for the complicated types of characters as well as a 30 20 for the transfer and locking convenience, circuit easily accessible for rationalization. The memory latch circuit 18 Manufacturing is achievable. is only shown in detail once, otherwise it is as

Further features of the invention are drawn from the large diamond.

To see claims. The following is an off The memory latch circuit works like

Management example of the invention on the basis of drawing 35 follows: The luminous element 16, which is a neon lamp descriptions. It shows or a conventional lamp or one with

F i g. 1 is a block diagram of a flow-speaking voltages and frequencies operated blackboard logic working character recognition system, electroluminescent lamp, will be short-

F i g. 2 a logical diagram for the timely light. This takes place under the pattern identification 40 control of the processing device 12 assigned to the processing device via the connected photoconductor 14-1, which in turn is represented by FIG. 3 a the scanning process of an arbitrary the luminous element 15 is exposed. As a result of the pattern, brief lighting up of the luminous element 16, F i g. 3 b the partial pattern sequence for the arbitrary photoconductor 17 briefly exposed. The photo-selected pattern, 45 conductor 17, conducts fairly quickly, while an-Fig. 3c a logical flow chart for the recognizer side the conductive state slowly decays, sequence of the arbitrarily chosen pattern.Through this slow decay, even if the Fig Example pattern, for + V through the photoconductor 17 to the Leuchtele-F i g. 5 a 50 element 16 organized for the example pattern in order to bring it to the lighting storage level for the second time. The second time it lights up, F i g. 6 that of the memory level of FIG. 5 to the photoconductor 17 exposed, so that the original, ordered and brief exposure for recognizing the example pattern is continued, so that the organized pattern flow table level. second flash into a continuous glow

55 passes. The continuous glow keeps the

F i g. 1 - Flow table logic pattern recognition interlock circuit and exposes the assigned

Device General Description Associated actuation photoconductors 19

and 20 for transmission and locking

The scanner 11 and processing device 12 circuitry extending into the flow table. If during the detection time a sequence of 60 of the photoconductor 19 is dark, it interrupts the logic signals (functions of X, Y and Z), electric circuit. If he is exposed, he connects the characters scanned to him, which represent the successive partial patterns of the assigned element as a transmission circuit. The signals X, Y in order to transmit the stable state to the associated one or Z indicate the presence of a black interlock circuit, since the part of the character in an associated column area included in the setting photoconductor 20 for the actuation of this keying also indicates, and AB circuit is exposed.

indicate the order of the partial pattern scans.

again. The signals Ύ, Y or Z show the presence matrix either form interlocking circuits

or transmission circuits. Each latch circuit maintains a steady state; every Transmission circuit transmits a steady state from one latch circuit to one other.

A transmission circuit can connect two interlock circuits around many consecutive Steps are separated, thereby skipping steps; she can also reverse the order and go back several steps, after which the steps can then be repeated. However, for this flexible order is special treatment in the flow table logic with automatic organization is necessary.

In practice, a flow table matrix comprises a number of horizontal ones (e.g. 26, 36, 42 and 45) and vertical (e.g. 30, 31, 32 and 33) conductors arranged in a checkerboard or grid pattern. The vertical conductors are isolated from the horizontal ones. The vertical conductors correspond to the columns in the river table; the horizontal ladder corresponds to the rows of the river table. In the figures the conductors end in small diamonds that can be thought of as isolated connections.

A flow table logic interlock circuit is a stable circuit such as B. a positive feedback Interlock circuit connected to the assigned column conductor and row conductor to their cut die Rules are:

1. Each pattern must have a continuous black track in the scanning direction, e.g. B. from left to right, included.

2. There must be a noticeable white gap between the patterns; consecutive Patterns must not overlap or, in the worst cases, skewed tracing do not cause simultaneous sampling of "black". Overlapping patterns can be treated as uniform patterns that adhere to the rules.

3. The processing device must itself fill the gap between the patterns, between the words and each longer gap differ. For all but the gaps between the patterns all subscriber lines including XYZ (I) must be briefly switched off to enable the Delete sample flow table levels. Special pattern recognition circuits for the short and long gaps are possible.

4. There must be a gap to the left of the first pattern.

At the beginning of the recognition cycles, the photoconductor 25 (Fig. 1), prepared by the Luminous element 63 (Fig. 2), ground potential on the Row ladder 26. Any other stable state will

point and in the flow chart block for
the stable state is arranged. The interlocking 30 excluded during an interval ZYZ (I), processing circuit used depending on the selected as ^{still m} connection with Fig. 2 is explained. The component of the self ^{-locking properties s} P ^old "no-part-pattern" is XYZ and (T).
or the positive feedback to either of two other pairs of pattern storage planes and

stable states, which are referred to here as high and low pattern flow table levels (ζ. B. the N-th pattern storage potential, to be assumed and maintained at 35 chereplane 27 and the N-th pattern flow table matrix 28), and holds the associated row conductor are so organized that they have the remaining patterns in the appropriate potential.

The luminous element 21 and the photoconductor 22 constitute a transmission circuit for the stable

State to the luminous element 23 and to the photo line 40 12 encrypted and all flow tables parallel to 24 of the associated interlocking circuit. When transmitting a partial pattern sequence of a river. This interlock circuit is for
Takeover and maintenance of the stable state effective when the memory latch circuit 18 assigned to it is set; otherwise 45
it is found at rest, with its photoconductor branch being an open circuit. The organization is controlled by the processing device
via the organization and storage levels. One

Memory latch circuitry is for each pair of 5 "work equipment 12 during a particular one, for of idle and belonging together, each pattern corresponds to the planned organization time

Recognize writing. At the end of the organization time, the samples are scanned by the scanner 11, in partial pattern sequences by the processing device

table matrix (e.g. 6), this flow table leads their pattern recognition signal via the recognition line (e.g. 29) back to the processing device.

The organization for the pattern XYZ-XYZ is shown in the abbreviated flow chart of FIG.

Before the start of the detection time, the

some transmission and locking circuits provided; when set, actuates the Memory latch circuit the pair of circuits assigned to it.

A column "no sub-pattern" stores between successive sub-pattern scans the stable state of the sequential circuit between two partial scans of the sequence. In the illustrative series of partial pattern signals (functions of X, Y and Z generated by the processing device) and order mark signals A, B and so on. For the sequence ΧΥΖ-ΎΥΖ given as an example, the partial pattern XY ¹ Z and the sequence marker A set the assigned memory latch circuit A in the memory level 5. A moment later make the partial pattern

In the th preferred embodiment, column 60 ~XY ~Z and the order marker B are the associated lines for possible partial pattern functions of the nete memory latch circuit B. Other X, Y and Z provided as well as the column line memory planes, such as. B. the Nth pattern memory "no-sub-pattern" for logic function level 27 are also used during subsequent XYZ (T). Set with a simple set of regular organizational cycles. Each of the settings is thereby obtained a variable number of 65 th memory latch circuits A and B be partial patterns per character, as it is e.g. B. in the case of bookers, the associated transmission and rods I and M in the usual antiquated printing of the interlocking circuits at the appropriate points. in the first sample flow table level 6.

At the beginning of the detection time, the photoconductor 25 is exposed and thus applies ground potential to the row conductor 26. The first partial pattern is probably a space or "no-partial pattern", namely XYZ (T). A + V "no-sub-pattern" signal appears on column line 30; the column lines 31, 32 and 33 maintain ground potential. The light element 34, the only one in the flux table connected between + V and earth, lights up. The optical coupling with the photoconductor 35 forms a locking circuit which holds the row conductor 26 at ground potential, so that a circuit from + V to ground via the luminous element 34 is maintained as long as gaps ΎΎΎ, (T) appear.

After several gaps, the signal XY2 appears as + V on the XYZ column line 32. The XYT, (T) column line 30 goes back to earth potential and thus darkens the luminous element 34. However, as the conductivity of the photoconductor 35 decays, the earth potential rises the first row conductor 26 is maintained long enough to illuminate the luminous element 21 which has been identified by the memory latch circuit 18 for transmission. The photoconductor 22, which is responsive to the lighting up of the luminous element 21, grounds the row conductor 36 long enough to cause the interlocking luminous element 23, which is connected to the + V potential through the XYZ column line 32, to light up.

By lighting up the locking light element 23, the photoconductor 24 is exposed to form the optical interlock circuit and the Maintain ground potential on row conductor 36 for the remainder of the sub-pattern interval.

At the end of the partial pattern interval, the column line XYT, (T) receives the potential + V, and the column line XYT. receives ground potential in preparation for the second partial pattern scan. The transmission light-emitting element 37 lights up during the decay of the conductivity of the photoconductor 24, as a result of which the photoconductor 38 is briefly exposed and the row conductor 42 is grounded. The interlock light 40 illuminates and forms an optical interlock with the photoconductor 41, thereby maintaining the ground potential on the row conductor 42 for the remainder of the "no-subpattern" interval. In the following partial pattern scan, the XYZ (T) column line 30 is returned to ground potential while the XYZ column line 31 is prepared. The transmission luminous element 43 lights up during the decay of the conductivity of the photoconductor 41, whereby the transmission photoconductor 44 is briefly exposed to ground the row conductor 45 for a short time. The interlock luminous element 46 illuminates and forms with the photoconductor 47 an optical interlock circuit which maintains the ground potential on the row conductor 45 during the remainder of the sampling interval.

At the end of the sampling interval, the ΎΥΤ, (T) column line 30 is prepared, while the XYZ column line 31 is again given ground potential. As the conductivity of the photoconductor 47 decays, the transmission luminous element 48 lights up and thereby briefly illuminates the photoconductor 49 in order to send a ground potential detection signal via the detection line 29 and the cable 50 to the processing device 12. More complex pattern flow tables require additional associated flow table logic transfer and latches for the XYZ (T) column and additional rows of sub-pattern flow table logic twin circuits along with associated memory latches. The paired sub-pattern circuits for transmission and locking are

ίο complementary to the circuit pairs »no partial pattern« arranged. A continuous stable state moves through from the starting position corresponding consequences of switching: interlocking "no partial pattern", transmission and interlocking switch pairs for partial pattern, transmission and interlocking circuit "no partial pattern" etc., to a final recognition state. For partial patterns that are not in the Define the pattern contained in the flow table matrix, the stable state is lost when a partial pattern input signal appears where an idle pair of circuits is in the corresponding Partial sample column and row is located.

When assigning each column of the flow chart to a different one of the sub-patterns that may be can form the pattern, thus the recognition consists in the movement of the stable state through the correct path of the river table. If one or more of the sub-patterns that are being scanned are not resemble the corresponding partial pattern of the desired pattern, the stable state does not follow the correct orbit, and no recognition is achieved.

F i g. 2 - pattern identification circuits

Certain patterns can be entirely contained in others, e.g. B. P in R, O in Q and I in B, D, E, F, H, K, L, M, N, P, R and T. The signal on line 29 is therefore a detection signal, but still no final identification signal. If P is in R and O is in Q, they are different Flow charts through the rightmost vertical sub-patterns; but the I is more difficult because it appears early in some signs, late in T and twice in H, M and N. By having a "No partial pattern" scanning is required as the final process of pattern recognition the identity can be established. However, the column "No partial pattern" does not differentiate between a "no-sub-pattern" scan and the "no-scan". The processing device can easily be from the recognition on the identification by applying the logical AND condition to XYZ (T) and toggle »detection«.

Fig. 2 shows a space counter 51 which counts spaces (partial pattern gate and ΎΥΤ) for the use desired by the processing device. The AND circuit 52 provides count input signals. The inversion circuit 53 resets the counter at the end of each series of spaces by the output signal YYT (any sub-pattern other than "XYT").
At the first gap count, the XYZ (T) column line is turned off by the inverter 54 and the AND circuit 55, which turn the power stage 56 off. As a result, all model flow tables lose their stable state, and the

ίο

Completion of a partial pattern by the first part of the following pattern is prevented. The line XYZ (T) is always prepared during the recognition with the exception of the ZYZ (^ -counting of the first scanned gap between the characters and the actual partial pattern scans.

The gap count 1 also prepares an input to the identification AND circuit 60; the other input receives the pattern recognition signal on line 29, which is brought to the operating voltage for the AND circuit by the inverter 61. Even if the light-emitting element 48 (FIG. 1) goes out when the XYZ (T) line is grounded, the decay of the conductivity of the photoconductor 49 produces a signal which lasts long enough to generate the logical 1st output

Operate circuit and provide an identification signal for the corresponding pattern to the processing device.

The AND circuit 55 forwards the signal XYZ (T) ao to the flip-flop 62, which is the lighting element

63 feeds. The luminous element grounds the first series switch of each of the sample flow table levels an associated photoconductor (e.g. 25 in Figure 1). Likewise, at the beginning of the organization time fm, the processing device sets the flip-flop for each pattern

64 “Do not delete”, which the light element 65 “Do not delete” constantly during detection feeds. The "non-erasure" luminous element continuously exposes the photoconductor 66 (FIG. 5) of the pattern storage plane.

The foreign pattern flip-flop 67, which is switched so that it is triggered by the leading edge of the signal gap count-1 is set is reset by the detection output of the inverter 61. The processing device has the option of not recognizing such an early notification record the place of the foreign sample and continue working. Albeit strange to other patterns it can step back and scan again to try the detection a second time, and if it is not recognized again, reorganize the pattern memory for another pattern. This reorganization can either be done by The sequence of signals for the detection is as follows:

ZYZ

XYZ XYZ

XYZ XYZ

XYZ XYZ

XYZ XYZ

Although there are no order mark signals, the order is changed during detection explained as follows (Fig. 3c):

XYZ

2 XYZ (2) XYZ 3. (A +) XYZ (3.) (B-) XYI 4 XYZ (4) Z YZ 5. (B +) XYZ (5.) (C-) XYZ 6 XYZ (6) XYZ 7. (C +) XYZ (7) (P-) XYZ 8 XYZ (S) XYZ 9. (D +) XYZ

(B)

(D)

recognition

The usual flow chart designations are shown in FIG. 3 c retained; the one surrounded by a circle Number is a stable point, and appropriate operator control or self-contained number is an unstable point, the repeated several times until the foreign pattern reaches the stable point with the corresponding number recognized or determined to be undetectable. leads.

As an alternative to the circuits described above, the identification problem can thereby

50

be simplified that a certain number, e.g. B. seven scans per pattern can be provided. All flow tables can then have a maximum of seven sub-pattern circuit pairs for transmission and interlocking to have; a foreign pattern is deduced if it is not recognized during scanning 7, while an output signal at scan 7 provides the identification directly.

F i g. 4 - organizational level

are separated as follows

F i g. 3 a to 3 c - random pattern

Figure 3a illustrates a random pattern which also refer to the other figures. Its sequence of organization signals is as follows (Fig. 3b):

A XYZ

B XYZ

C XYZ

D XYZ

60

65 organizational signals
created:

A XYZ

B XYZ

C XYZ

D XYZ

The order is not critical as long as the correct lines are prepared in pairs to prepare the light elements A, B, C and D. The processing device 12 applies the potential + V to the 1-terminal of the board 71, which it sends via the prepared 1-photoconductor to the corresponding terminals 72 (FIG. 5) in the memory plane. During the organization cycles for other patterns, terminals 2, 3, 4 or N are activated. The electrically opposite side of each photoconductor is associated with an associated one of the terminals 72 in FIG. 5 connected.

409 708/204

F i g. 5 - memory level

The + F signal at a terminal 72 causes the corresponding light element to light up. the Locking of the luminous element 16 and the photoconductor 17 has already been explained in connection with FIG been.

The luminous elements A, B, C and D interlock via associated photoconductors and thus form the memory interlock circuits A, B, C and D of the flow table matrix.

F i g. 6 - Pattern recognition flow chart level
or matrix

The operation of the random pattern recognition flow table level or matrix has already been explained in connection with FIG. 1 by the flow table logic circuit pair B for transmission and locking. Signals ΧΎΖ (Τ) -ΧΎΈ-ΧΥΖ-ΧΥΖ have moved ao the stable state to the interlock circuit B.

When the partial pattern input signal returned to XYZ (T), the circuit of FIG. 1 generates the detection signal. In the full ^a 5 flow chart of FIG. 6, however, the recognition process is continued in that the luminous element 48 lights up and exposes the photoconductor 49, which briefly grounds the row conductor 76. The brief grounding causes the luminous element 77 to light up, which interlocks with the photoconductor 78 in order to keep the row conductor 76 at ground potential during the interval B + C- between the scans.

The next partial pattern signal Z FZ causes the luminous element 79 of the transmission circuit to light up, as a result of which the photoconductor 80 is exposed in order to ground the row conductor 81. The ground potential on conductor 81 prepares the luminous element S2 (XY ^- Z still switched on), which is locked via photoconductor 83 and keeps conductor 81 at ground potential.

The stable state passes through the luminous element 84, C + and the photoconductor 85, around the conductor 86 for a short time to ground; then the stable state reaches the luminous element 87 (D—), which is located via the Photoconductor 88 latches and so the ground potential on conductor 86 during the no-part pattern interval is maintained between two samples.

The next partial pattern signal Z YZ causes the 5A luminous element 89 of the transmission circuit to light up, whereby the row conductor 91 (D-) is briefly earthed via the photo conductor 90. The ^v "; stable condition reaches the light-emitting element 92 (D-) of the latch circuit and to the photoconductor 93, the lock and so the row conductor 91 (D-) hold for the remaining part of the scan at ground potential.

At the end of the scan, the ZYZ φ column line 30 is prepared. The logical designation of this column line is XYZ, while the (I) simply means a "not reset" state. The luminous element 92 lights up and thereby briefly exposes the photoconductor 93 in order to generate a ground potential signal on the detection line 94. The detection signal arrives at the one shown in FIG. 2 where it is compared with a subsequent Z YZ (T) scan.

If there is the following space, identification is made; if the space is missing, further sub-pattern signals drive the steady state down out of the flow table of FIG. 6th out.

In the event of identification or non-identification, the subroutine of the ZYZ T cycle is followed. All lines for partial patterns and no partial patterns are switched off, and the luminous element 63 is exposed a photoconductor 25 in each pattern footer matrix. This will reset the matrices and brought into the starting position for the next detection attempt.

The invention as described herein used in the sample flow chart planes or matrices the photologics. Various other components can also be used, e.g. B. Relay, Semiconductors, superconductors and magnetic cores. Basic requirement of the component for a transmission circuit is that it is subjected to a column and a row input signal to generate an associated one To influence interlock circuit. The latch circuit must have a column input signal and the output signal associated with it Transmission circuit are supplied so that it assumes a measurable stable state and maintains it.

Likewise, other locking-enabling components can replace the optical locking circuits in the memory plane, and other switchable components can be the paired transfer and locking photoconductors substitute.

The flow table levels can be made more flexible by having two half memory latches between two adjacent row conductors in a given column, so that the one general flow table block corresponding circuit can be operated either as a transmission or as a locking circuit can.

Claims (12)

Patent claims: 1. Device for character recognition with a scanner for scanning characters in sections and with a pattern memory in which _ in one of the actual recognition operations' '' f signals of pattern characters are stored;. to adjust the device to a i "Mmmte type of character, characterized that sequential circuits in the form of , 1 ■ flow table matrices (6, 28) are provided, which Character scanning signals over lines (30 to 33) of the one matrix coordinate for stepwise Further switching of a defined switching state can be supplied that switching elements (21 to 24) at the crossing points of the flow table matrices memory elements (16) of the pattern memory assigned to the characters to be recognized during the organization operation Set characterizing switching paths in the flow table matrices, and that with predetermined Output lines (29) connected to lines (45) of the other matrix coordinate for display serve to ensure that the input signals supplied correspond to a set switching path to have. 2. Apparatus according to claim 1, characterized by an optical coupling on the one hand between the memory elements (16) of the pattern memory and the switching elements (21 to 24) the sequential circuits (6, 28) and / or on the other hand between the switching elements (15) one Setting matrix (4) and the storage elements of the sample memory. 3. Apparatus according to claim 1 or 2, characterized in that for each to be recognized A flow table matrix (6,28) is provided, the columns of which correspond to the various characters Parts of a character are assigned and the lines of which are assigned in pairs to the individual scans of the Character sections correspond to the order of the pairs of lines with the order of the samples coincides, and which has a preparation column that is used for intermediate storage a character segment recognition signal from the respective preceding character pair ao and is used to prepare the next pair of characters. 4. Device according to one of claims 1 to 3, characterized in that a flow table matrix (6, 28) at intersections of row conductors (26, 36, 42) and column conductors (30 to 33) a sequence of transmission circuits (21, 22) which alternates in the column direction and controls the excitation state of a row conductor of a row pair is transferred to the row conductor of the same row pair that is adjacent in the flow direction, and memory or latch circuits (23, 24) which the energization state to hold for the next change of the input signal. 5. Device according to one of claims 1 to 4, characterized in that in the flow direction following to a through the transmission and locking circuits (21 to 24) coupled Matrix line pair a transmission and latch circuit (37 to 41) in the Preparatory column is provided, which is a coupling to the adjacent matrix row pair manufactures. 6. Device according to one of claims 1 to 5, characterized in that the transmission circuits each of a lamp (21) connected to a column and a row conductor and each of a photoconductor illuminated by this (22), via which the row conductor adjacent in the flow direction is connected to ground is, and that the memory or latch circuits from each one with the column conductor and the adjacent row conductor connected lamp (23) and each illuminated by this Photoconductor (24), which connects the adjacent row conductor to ground. 7. Device according to one of claims 1 to 6, characterized in that in the connecting line the transmission and / or locking circuits (21 to 24) of a pair of lines A photoconductor (19, 20) is connected between ground and the relevant line conductor is, which is illuminated when an associated memory element (16) of the pattern memory is excited will. 8. Device according to one of claims 1 to 7, characterized in that the pattern memory for each flow table matrix (6,28) has a memory matrix (5, 27) whose memory elements (16) are in direct association with the transmission and / or Interlocking circuits (21 to 24) of the relevant dashboard matrix are located and which are selected one after the other for value recording during the organization operation. 9. Device according to one of claims 1 to 8, characterized in that the storage elements (16) of the pattern memory are light sources, which are generated after pulsed excitation keep energized via a photoconductor (17) and photoconductor (19,20) in the transmission and Control interlock circuits (21 to 24) of the flow table matrices. 10. Device according to one of claims 1 to 9, characterized in that for adjustment of the pattern memory a setting matrix (4) is provided, which is connected to a matrix coordinate the character parts scanned within the organization operation in the form of signals and the conductors assigned to the other matrix coordinate receives control signals marking the scans of the individual sections, and that at the crossing points of these conductors are switching elements (15) which correspond to the relevant Set the memory elements (16) assigned to the character part in the pattern memory. 11. The device according to claim 10, characterized in that the switching elements of the Switching matrix (4) are lamps that light up when their matrix conductor is excited and via photoconductors (14) control the setting of a memory element in the pattern memory. 12. Device according to one of claims 1 to 11, characterized in that the pattern memory is used to record the pattern of several fonts and that the follow-on formations (6, 28) can be set to a different font after an unsuccessful recognition operation, until one of the subsequent circuits emits an output signal. Considered publications: U.S. Patent No. 2,663,758; Austrian Patent No. 210 927; Canadian Patent No. 568,014; Calwell, "SWITCHING CIRCUITS AND LOGICAL DESIGN", New York, 1958, pp.453ff. For this purpose 2 sheets of drawings 409 708/204 10.54 © Bundeedruckerei BerUn