DE2218323C3 - Data sampling and decoding apparatus - Google Patents

Description

The invention relates to a data scanning and decoding device with a scanner having several scanning points by means of which the binary information (L, 0) present on a recording medium in the form of surfaces of different sizes, for example color strips, are scanned during a relative movement between the scanner and the recording medium.

In a data sampling and decoding device known for example from FR-PS 15 37 810 Record carriers used on which binary r> 5 Data are represented by wide and narrow white stripes that are interposed between them black lines are separated from each other. The data recorded in this way are processed by a hand-held scanning device that uses two bundles of optical fibers to receive reflected light and contains a bundle for listening to light. With this device two Recording areas on the recording medium are scanned with different widths when the device is moved parallel to the strip widths. The two fiber optic bundles for reception of reflected light work together with two corresponding photosensitive elements, the in turn are connected to an evaluation circuit.

This known device has the disadvantage that to achieve correct operation when

of the scanning device via the calibration Only very small tests parallel to the strip width Deviations are permitted.

Furthermore, the scanning device must not be rotated, as this would lead to incorrect reading can.

From the IBM Technical Disclosure Bul'ctin Vol. 13 No. 8, January 1971 _1st page 221! a scanning device is known which does not have the disadvantages mentioned above. This device contains a total of four scanning points, of which three scanning points are arranged at the corner points of an equilateral triangle and one scanning point is arranged in the center. In this device, it is disadvantageous that four scanning points must be used, which results in high manufacturing costs.

It is the object of the invention to provide a data sampling and decoding device in which the from Hand-moved scanning device is not moved over the recording medium in such an exact direction must be and which requires less than four sampling points.

The invention is characterized in that the scanner has three equally spaced scanning points whose dimensions in relation to the areas of adjacent widths and narrow strips are set so that the centers of the sampling points are all within a wide strip, however not all lie within a narrow strip and that never two adjacent strips at the same time can be completely covered by the centers.

The invention is illustrated in detail using an exemplary embodiment with the aid of drawings described. In these shows

F i g. 1 a recording medium in the form of a label,

2 shows an enlarged illustration of the on the Label according to fig. 1 encoded data shown,

F i g. 3 is a schematic representation of a manually operable scanning device for scanning the Label according to Fig. 1, ·

4 along an enlarged sectional view of lines 4-4 in FIG. 3,

F i g. FIG. 5 shows the areas on the label which are produced by the device in FIG. 3 are scanned,

F i g. 6 is a schematic representation of the scanning process, the hand-held scanning device in different Shows positions above the recording medium,

F i g. 7 is a block diagram of the decoding circuit.

In Fig. 1 shows a recording medium in the form of a label 10 which is attached to the various Items of sale of a retail store can be attached. On label 10 are in encoded form data 11 containing z. B. an article number, the number of the point of sale and can represent other relevant data. The label 10 may also contain human readable indicia 12 which with the encoded data 11 are identical.

The type of coding is shown below with reference to FIGS. 2 explained. In Fig. 2 are two decimal digits in binary coded. The elements of the binary code are black and white stripes arranged in an alternating sequence. Each strip has one of two possible widths. Strips 22, 25, 26, 28 and 30 are wide stripes and strips 20, 21, 23, 24, 27 and 29 are narrow strips. The wide stripes each represent a binary one 1 and the narrow stripes each represent a binary 0.

where it is immaterial. whether the stripes swore / or are white.

The white stripes can e.g. B. formed by the background of the label JO on which the ι black stripes only have to be printed on. Instead of the black and white stripes Stripes with two other colors can also be used, which have different reflective properties. have properties.

ίο Starting from left to right in the direction of the Arrow 35, the first strip represents a narrow black strip 20, which is a binary 0 represents. The next stripe is a narrow white stripe 21 through which a binary 0

is displayed. The following wide black one

Stripe 22 represents a binary 1. Above the stripe is the binary value assigned to them is given in each case.

The decimal digits 9 and 5 in FIG. 2 are thus

by the binary digit groups 1001 and 0101

jo shown. In each binary digit group, the weights 2 °, 2 ¹ , 2 ² and 2 ^{J are} assigned to the individual binary digits in a known manner.

The first strip from the left in FIG. 2, which represents a binary 0, is used as start information A. The last bit on the right-hand side, which is represented by a wide black stripe and represents a binary 1, is used as final information B. From the information A and B , it is possible to recognize the direction in which the label is scanned. In the label used here, the first and the last stripe is a blackened stripe, since a white stripe could not be recognized from the label background. In order to ensure that the aforementioned condition can be met, a parity bit P is provided in the form of a narrow white strip 21, by means of which the number of bits on the recording medium can be made odd. If the number of bits is already odd, the parity bit P can be suppressed.

In Fig. 3, a handheld scanner 150 is shown with which the label described above can be scanned. This contains a housing 160 in which three bundles of light guides 165, 166, 167 are arranged. These run in the housing from point 169 up to point 168. At point 169, the light guides divide into three bundles 170, 171 and 172 as well as into the three bundles 180, 181 and 182. The bundles 165, 166 and 167 are held in the housing 160 by support mats rial 183 fixed and held, as can be seen from the sectional view in FIG. Bundles 170, 171 and 172 are led to a light source 184 in which a lamp 185 and a lens 186 are arranged. the Bundles 180, 181 and 182 cooperate with photo elements 190, 191 and 192, which are connected to the Decoding circuit in Fig.7 are connected. The light comes through the bundles 170,171 and 172 and 165,166,167 from Λ r Lamp 185 via a focusing lens 194 on the "reiche 40,4i and 42 dss label 10 steered u id that from these light reflected the photo elements 19C, 191 and 192 via the light guide bundles 165,166,167 and 180, 181, 182 supplied. The front end 195 of the handheld scanner adjacent to the lens 194 contacts during the scanning process the recording medium

f, ₅ ger. The in F i g. 3 can also be modified so that the light source 184 and / or the photosensitive elements 190, 191 and 192 are arranged in the housing 160.

The three areas 40, 41 and 42 on the recording medium 10 are shown in FIG. 5 in plan view shown. The centers of these areas form a triangle, the sides D of which are of equal length.

The relative size of the width 51 of the narrow strips and the width 52 of the wide strips and the side length D of the equilateral triangle depend on the following conditions:

1. Points 70, 71 and 72 must never all lie within a narrow strip;

2. the points 70, 71, 72 must never completely cover two adjacent narrow strips;

3. Points 70, 71, 72 must never completely cover a wide strip.

In addition, the possible deviation in the scanning of the label 10 with the hand-held scanning device 150 to the vertical must be taken into account. If the maximum deviation is Φη «, *, the following must be used Maximum conditions for the value 51 and the following minimum conditions for 51 and 52 observed will:

SI

d 2 (cos

· Sl _n

d ( _C os4> _maz ) S2 _m

Points 1 to 3 above are taken into account in these conditions.

The reading and decoding process is described below with reference to FIGS. 6 and 7 and Table 1. FIG. 6 shows 13 different positions which the hand-held scanning device can assume. Each position is represented by an equilateral triangle 70, 71, 71, the tips of which are marked with X, Y, Z.

In the decoding circuit of FIG. 7, flip-flops are used, the states of which are designated as set and not set. Each flip-flop has an input T via which the control pulses are applied, each of which causes the flip-flop to switch. The flip-flops can be reset from the set to the unset state via the R input. Each flip-flop also has an output for set and an output for not set. The opposite information appears at these outputs.

The decoding circuit F i g. 7 has an input terminal 210X connected to photosensitive element 190 (Fig. 3). An amplifier 21IX is connected to the terminal 21OX. A circuit 212X is connected to the output of the amplifier 211 <Y and is activated by the photosensitive element 190 when a set pulse occurs for each color transition (e.g. change from black to white or from white to black). In practice, the photosensitive element 190 will detect such a transition whenever the center of the area 40 crosses the boundary between two adjacent strips. The output of the circuit 212X is connected to an AND gate 213X, the output of which is connected to an OR gate 214X. The output of the OR element 214X is connected to the trigger input T of a Fläp-FJops 215X, which has two outputs Xn- \ and Xn- \ at which the set or not-set signals occur. The not-set output Xn-t is connected to the input of an AND-Glicdes213X.

The set output Xn- ι is connected to the input of an AND element 218X, at whose second input the output signals via a conductor 219X

ίο be applied by the circuit 212X. The exit of the AND gate 218X is connected to the trigger input of a flip-flop 220X.

The flip-flop 220X for its part has a set output X / v and a not-set output Xn. The output Xn is connected to the input of an AND element 230 via a conductor 225X and to the input of an AND element 227X via a conductor 226X . The output of 227X is connected to the input of the Od'r element 214X.

The output of an OR element 235X is connected to the reset input of the flip-flop 220X first input is connected to a reset input 201, the function of which will be discussed later with the reset input of a flip-flop 215X

is discussed.

A similar arrangement of gates and flip-flops is for the photosensitive element

191 in the V branch and for the photosensitive element

192 in the Z branch, so that a detailed Explanation of these two circles can be dispensed with. For the V branch, the flip-flops are 215 V and 220 V and the flip-flops 215Z and 220Z for the Z branch intended.

The outputs X _n i, Yn ι and Zn ι of the flip-flops 215X, 215 Y, 215Z are connected to the AND element 240, the output of which is applied to a pulse generator 242. This can e.g. B. consist of a monostable circuit. It generates a set pulse of a predetermined duration at its output when a set pulse is applied to its input. The output of the pulse generator 242 is connected to the inputs of the AND gates 227X. 227 Y and 227Z and connected via an inverter 243 and a line 246 to the inputs of the AND gates 213X, 213 Y and 213Z. The output of the pulse generator 242 is also connected to a shift register 250 and via a delay device 252 with the OR gates 235X. 235V and 235Z connected.

The output of the AND element 230 is via a data input 254 with the first stage 261 of the register 250 connected. The reset input 201 is connected to the reset input 256 of the shift register 250.

The output of shaping circuits 212X, 212 Y, and

212Z are with the control circuit 270 of the shift register

250 connected. There is also a connection

between the second stage 262 of the shift register

and the control circuit 270.

The following is how the decoder works circle in Fig. 7 described.

At the beginning, a reset pulse is applied to the reset input 201, by means of which all flip-flops 215X, 215 Y, 215Z, 220X, 220 Y and 220Z are switched to their state not set. All stages of the shift register 250 are also switched to the O state.

It is now assumed that the hand-held scanner is in position 1 in FIG. 6 and in position 2 is moved. In the initial / .state should be first

it can be determined whether the output of the pulse generator 242 has a non-set level, so that the AND gates 213A, 213 V and 213Z can be driven by the inverter 243. The AND elements 227A, 227 Y and 227Z, on the other hand, must not be activated. The AND gates 218A, 218 V and 218Z cannot be switched through either, since the outputs Xn- \. Yn-i and Z _n - \ of the flip-flops 215A, 215V and 215Z have a non-set level. When the point 70 crosses the leading edge 301 of the first strip 20, a set pulse is generated which appears at the output of the circuit 212A and is applied to the trigger input of the flip-flop 215A via the AND gate 213 A and the OR gate 214A will. The inputs of the AND gate 213A "are set via the line 246 and via the line 216A. The flip-flop 21 5X is set via the circuit 212A by the pulse generated by the trailing edge of the strip. When the point 71 crosses the guide line 301 , the flip-flop 215 V is set by the trailing edge of the pulse generated by the circuit 212 V. Next, the point 70 crosses the limit 303. whereby a pulse via the line 219A and the AND gate 218A to the flip-flop 220A " which is thereby set and in turn causes the flip-flop 215A to be driven. The flip-flop 215X is not switched by this pulse, since the AND gate 213A is kept blocked via the line 216A. Its output Xn 1 is not set. Next, point 71 crosses line 303, which sets flip-flop 220V. During this time the flip-flops are 215A. 215 Y. 220A and 220 VaIIe set.

Next, point 72 crosses boundary 301, setting flip-flop 215Z. Now the outputs Xn \ .Yn l Zn ι are all set, so that the AND element 240 is opened and the pulse generator 242 is activated. This initiates the decoding operation. At this point in time, the inputs to the AND gate 230 are through the outputs X _n . Yn, Z _n of flip-flops 220A, 220 V and 220Z not set. The AND gate 230 is therefore closed, and a non-set pulse is applied to the input 254 of the shift register 250 so that the pulse generated by the pulse generator 242 causes on line 248 that a 0 of the first stage 261 Shift register 250 is stored. It goes without saying. that if a set pulse is applied to input 254, a binary 1 would be input to the first stage of the shift register. The output of the pulse generator 242 assumes a set level, whereby the AND gates 227A. 227 V and 227Z can be made effective, so that signals depending on the reset outputs Xn, Yn, Zn of the flip-flops 220A. 220 V and 220Z are applied to flip-flops 5S, 215A ", 215 V and 215Z. This leaves flip-flops 215A and 215 V in their set state, while flip-fop 215Z is switched to the non-set state, so that the AND element 240 is blocked by the signal fio appearing at the output Z / vi. The output of the delay element 252 can now switch the flip-flops 220A, 220 V and 220Z to their non-set state the duration of the pulse generated by the pulse generator 242 is shorter than the pulses generated by the fts circuits 212A, 212 V, 212Z trigger.

When the handheld scanner reaches position 3 (Fig. 6), point 72 crosses line 303 and points 70 and 71 have already reached line 305. When the point 72 crosses the line 303, a pulse is applied to the flip-flop 215Z via the AND gate 213Z, which switches it to its set state. The flip-flops 215A and 215 V are not switched by crossing points 70 and 71 of line 305, since the AND gates 213X and 213 V are kept blocked by the signals at the outputs Xn- \ and Yn- \. Thus, the flip-flops 215A, 215V and 215Z are in their law state, whereby a new decode operation is initiated. At this time, flip-flops 220A, 220 V via lines 219A, 219 V and AND gates 218A, 218 V were also set as a result of the crossing of points 70 and 71 via line 305. This results in a not set signal at the output of the AND element 230. that is, a binary 0 is shifted into shift register 250. The information previously stored in the first stage 261 was previously shifted to the next stage, ie to_left_. The non-set outputs X _n , Yn, Z _{n of} the flip-flops 220A, 220 V, 220Z are again applied to the trigger inputs of the flip-flops 215A :, 215 V, 215Z, so that the flip-flops 215A and 215 V remain in their set state while the flip-flop 215Z is reset. The flip-flops 220A, 220V, 220Z are reset again by the signal appearing at the output of the delay device 252.

When the handheld scanner reaches position 4, point 72 has crossed line 305, however, points 70 and 71 have not yet reached line 307 because the handheld scanner is above a wide strip is located. By crossing point 72 of line 305, a set pulse is sent to the Flip-flop 215Z is applied via the AND gate 213Z, so that this flip-flop is set. Now will be another Decoding operation initiated as flip-flops 215A, 215 V, 215Z are back in their set state condition. When crossing line 305 through point 72, flip-flop 220Z is not reset because at that time the AND element 218Z was not conductive. It was made through the Z / v-i output of flip-flop 215Z kept locked. Thus, at this point in the decode operation, all of the flip-flops are 220A. 220V, 220Z set so that a signal is produced at the output of the AND element 230 which indicates the binary value 1 and the is input to the shift register 250.

In summary, it can be said that the decoding circuit operates in such a way that when all three flip-flops 215A, 215V, 215Z are set, a decoding operation is initiated. The decoding is performed by checking the states of the flip-flops 220A, 220V, 220Z. If all of the last mentioned flip-flops are not set, the hand-held scanner will be over a wide strip, which will detect a binary 1. Otherwise, a binary 0 is recognized, indicating that the handheld scanner is over a narrow strip. After each decoding operation initiated, at least one of the flip-flops 215X to 215Znichl will be set so that the AND element 240 remains blocked until the Xn- ι to Z / v-ι are all set to not, so that a new decoding operation can be initiated.

709 624/171

The following table shows how all in F ί g. 6 scanned and decoded circles will:

Hand-scooping 13th Flip flops I. 215 Z 22OX 220K 220Z Decoding position I. 0 0 0 0 tes 215 X: I. I. 1 1 0 bit 1 I. 0 0 0 0 _ 2 (a) I. 1 1 1 0 0 (A) (b) 215 Y ) 0 0 0 0 3 (a) 0 0 I. I. 0 0 0 0 (P) (b) 1 1 I. 0 0 0 0 4 (a) 1 1 I. I. 1 1 0 1 (b) 1 1 I. 0 0 0 0 5 (a) ι ι I. 1 0 1 0 0 (b) 1 1 ) 0 0 0 0 6 (a) 0 ( I. 1 0 0 0 0 (b) ι; 3 0 0 0 0 7 (a) 1 ! I. 1 0 0 0 1 (b) l: I. 0 0 0 0 8 (a) ο: 1 1 0 1 0 1 (b) 1 3 0 0 0 0 9 (a) 0 ( 1 1 0 0 0 0 (b) 1 : 1 0 0 0 0 10 (a) 0 ( 1 1 0 1 0 1 (b) 1 D. 0 0 0 0 11 (a) 0 1 1 0 0 0 0 (b) I. 0 0 0 0 12 (a) 0 ( 1 0 0 0 l (B) (b) I. 0 I. I. 0 I. 1

The table shows the states of the flip-flops 215Λ " to 215Z and 220 * to 220Z in positions 1-13 (Fig. 6). The set state is with the binary value 1 and the not set status are identical to binary value 0. In each of the positions 2-12 at (a) the status of the flip-flops is displayed immediately after the setting of the flip-flops 2! 5.Y to 2i5Z, whereby the decoding operation is initiated, and at (b) the state of these flip-flops after the Coding was carried out, but before further boundary lines were crossed. From the table it can be seen that a binary 1 is recognized when all flip-flops 220A "to 220Z are set.

The last bit that is recognized (position 13) is one binary 1 derived from the background of the label. This 1 is not significant information and can be therefore be suppressed.

The control circuit 270 generates an output signal if there are no more within a certain time Transitions can be determined on the label. At that time, all are recorded on the label Data has been read and decoded and is in shift register 250 as binary information. the Control circuit 270 sets the value of the binary information located in stage 262 of shift register 250 assigned to the last significant bit that was read. If this bit has the binary value 1 is indicated by the label in the forward direction and when it has the binary value 0 indicates that it was scanned in the reverse direction. The control circuit 270 is constructed so that it is in The sequence in which the stored in shift register 250 is determined as a function of the value of this bit Data can be output from this.

Another data input option is that the shift register has an input option at each end and a control circuit in Depending on the aforementioned bit, it is determined in which end the information is entered. In In this case it is possible to keep the information stored in the shift register always in the same direction to spend. Since the dispensing process is not directly part of the invention, it is not discussed in detail here described.

From Fig. 6 shows that an exact reading and Decoding is possible, although the hand-held scanning device is not exactly in the at right angles to the strips, but at an angle across the strips. Such a deviation can also occur if a boundary line has already been crossed when scanning in the forward direction and the hand scanner is moved in the reverse direction. A prerequisite is, however, that a Decoding operation was initiated before the gauge is crossed in the forward direction again. Scanning during a movement process backwards over a boundary line through the hand-held scanning device is created by the additional Triggering of the corresponding flip-flops 220A "to 220Z.

It will be understood that the data need not necessarily be recorded in an optically readable form. For example, the strips can also be made of a material that absorbs various microwaves reflected. Magnetic coding is also possible if, for. B. a scanner with one after Hall effect working device is used.

For this purpose 3 sheets of drawings

Claims (6)

Patent claims: 1. Data scanning and decoding device with a scanner having several scanning points by means of which the binary information (L, 0) present on a recording medium in the form of surfaces of different sizes, for example color strips, is scanned during a relative movement between scanner and recording medium, characterized in that that the scanner (150) has three equally spaced scanning points (40, 41, 42), the dimensions of which are determined in relation to the areas of adjacent wide (for example 25, 26) and narrow (for example 21, 24) strips are that the centers (70, 71, 72) of the scanning points (40, 41, 42) are all within a wide strip (for example 25), but not all within a narrow strip (for example 21) and that never two adjacent Strips (for example 23, 24) can be completely covered at the same time by the centers (70, 71, 72), 2. Device according to claim 1, characterized in that the first and / wide characteristic of the regions (20-30) is formed by a first and second spectral characteristic and that the scanner (150) includes a housing (160) in which means (170, 171, 172) for transferring Light onto the recording medium (10) and first, second and third means (180, 181, 182) for Returning the light reflected from the recording medium (10) are arranged. 3. Apparatus according to claim 2, characterized in that in the housing (160) three light guide bundles (165,166,167) are arranged, and that each The bundle consists of a set of light guides through which light reaches one of the three scanning points (40, 41, 42) is guided and from a further set of light guides through which the record carrier (10) reflected light is applied to three photosensitive elements (190,191,192). 4. Apparatus according to claim 3, characterized in that a decoding circuit (Fig.4) first, has second and third logic circles associated with the photosensitive elements (190, 191, 192) connected and since ii every logical circle first (/.B, 2I5X) and / wide (/.B. 220X) bistable Contains circuits and that the first bistable circuit (/.B. 2I5X) its circuit / ustand changes when there is a change in the area assigned to this circle (/. B. 40) and then the second bistable circuit (z. B. 220- *) their state changes when a change in the characteristic of the assigned area is detected and that thereby the first bistable circuit (z. B. 215X) is switched to its second state and a first Switching device (240) is arranged to generate a signal when the first bistable circuits (2ι4λ'-215Ζ) are all switched to their second state and that a second switching device (230) is connected to the second bistable circuits (220X-2202) and generates a signal, when all of the second bistable circuits (220X-220Z) are in their first state and that the output of the switching device (230) is connected to a memory (250) which is constructed so that when a control signal occurs, that which occurs at the output of the switching device (210) Signal that interprets a read image, takes in the memory (250). 5. The device according to claim 4, characterized in that each of the logic circuits are assigned switching devices (z. B. 227X, 214X) which, depending on the control signal, cause the first bistable circuit (215X) in the same state as the second bistable circuit (220X) remains, and that the control signal is then passed through a delay device (252) and causes the second bistable circuits (z. B. 220X) to be switched back to their first state. 6. Device according to claims 4 and 5, characterized in that the memory (250) consists of a shift register, in whose stages the scanned bits are entered step by step and that when the control signal occurs, the information input is stepped one step at a time is moved.