DE1809049A1 - Device for reading multiple signals of different duration - Google Patents

Description

Device for reading multiple signals of different duration The invention refers to a device for reading multiple signals of different duration, from multiple signal sources, preferably from the probes of tape readers, It is known that band-shaped carriers to be used to store digital data. Usually these stripes have a Number of data tracks that are on along the length of the strip and at the same time extend in the direction of movement of the strip 0 of each data track a probe head is assigned which is able to determine markings on these tracks0 ?; if a binary code is used, for example form a binary decimal code all markings across the strip, i.e. all in one perpendicular to the longitudinal direction the row of marks, a number, a letter or any other character, The density of characters on such tape-shaped carriers is mainly due to the limited accuracy when adjusting the probes restricted. This is especially true when using film strips on which the markings of transparent and opaque areas are formed and in which the scanning with the aid of light-sensitive elements, for example Phototransistors takes place. Because of the difficulties in mechanical and optical Alignment, the density of digital data on such filmstrips is not special hochO That is why light point scanners and magnetic tape devices are often used when a high data density is required0 In some applications, in which as well However, high data density is desired, the use of such devices is either not possible because of their costs or for other reasons inherent in the system0 Especially for such cases there is a need for an apparatus sum reading multiple signals of different durations, which are essentially the same in which the signals are very short in time and follow one another closely can without the risk of erroneous reading, the invention lies consequently the object of the invention is to provide such an improved device. In particular, a reader is to be created by the invention with which it it is possible to read out the data from film strips with high data density without errors.

This object is achieved according to the invention in that with the Signal sources a gate circuit is connected which supplies a first control signal, if a signal is fed to it from any of the signal sources, that continues a bistable element is connected to each of the signal waves, a first or assumes a second state, depending on whether the output signal of the associated Signal source falls below or exceeds a certain value that continues a first circuit arrangement responds to the trailing edge of the first control signal, which defines a first period of time for sampling the states of the bistable elements, and that finally a second circuit arrangement; Is seen that on the end of the responds to the first period of time and resets the bistable elements to the first state.

In the circuit according to the invention, the bistable elements have the task of the output signals of the signal sources, in particular the phototransistors of a film tape reader to temporarily store each character duration 0 With a data density of 40 bit / cm, the bit or character duration is equal to the time which is required to guide the film strip 1/49 cm past the read head that which contains phototransistors. The gate circuit speaks during each character duration on the output signals of the phototransistors. The trailing edge of the from the first Gate circuit supplied control signal indicates that all character bits are scanned have been. During the triggered by the trailing edge of the first control signal all bistable elements can then be scanned at the same time, which avoids the risk of an @incorrect readout, in one of the first The bistable elements are all in the period following the second period of time same first state postponed and thereby prepared to come back on address the output signals of the phototransitors if they have a following character scan.

Further details and configurations of the invention. are the The following description can be found in which the invention is based on the in the drawing illustrated embodiment is described and explained in more detail. The the description and the features to be taken from the drawing can be used in other embodiments of the invention individually or in any combination Combination find application. 1 shows the block diagram of a device according to the invention, Fig. 2 shows a section of a filmstrip as it is in the device is used according to Fig. 1, Fig. 3 is a diagram of the output signals of the various light-sensitive sensor of the device according to Fig. 1 and Fig. 4 and 5 further diagrams to explain the invention.

The device shown in Fig. 1 has a light source 12, which directs its light onto a diffuser 14 which is at a distance from a reading head 16 is arranged. A film strip is located between the diffuser 14 and the reading head 16 20, assumed from the set that it can be moved perpendicular to the plane of the image. A Section of the film strip ao, which is assumed for the purpose of explanation, that it has five data channels, and the side opposite the diffuser 14 of the reading head 16 are illustrated in FIG.

The reading head 16 is provided with five windows D1 to D5 on the in 2 sections of the film 20 shown are four each comprising five bits Characters C1 to C4 available. The bit "1" is represented by a transparent part of the The film is reproduced while the bit "0" is reproduced through an opaque area Opaque areas of the film are indicated in FIG. 2 by hatching The four characters C1 to C4 represent the binary numbers 11100, 00100, 11010 and 00001 represents.

As can be seen from FIG. 1, 16 phototransistors are used in the reading head PT1 to PT5 carried, which are assigned to the windows D1 to D50 The output signal of the phototransistor T1 is fed to an input of a reader amplifier A1, whose other input is connected to a terminal 22 to which a reference voltage V'ref is connected. Accordingly, the phototransistors PT2 to PT5 are respectively connected to an input of one of the reader amplifiers A2 to A5, each one have a second output connected to terminal 22.

If the movie 20 is in the Pig. 2 direction indicated by arrow 25 is moved, comes every time a transparent part of the film at a of the openings of the reading head 16, light from the diffuser 14 slides through the transparent one Silence of the film and the corresponding opening to the phototransistor0 The phototransistor produced in turn an output signal that corresponds to the received light is proportional. When the output of the l-hototransistor is equal to or greater than is Vref than the reference voltage, the amplifier produces a TRUE output signal, which is characteristic of the bit "1", on the other hand an opaque one Film position, which represents a bit "0", passes an opening, the light is attached to it prevented from getting to the phototransistor ZU. As a result, its output signal lies below the reference voltage Vref so that the sense amplifier will output a FALSE generated which is characteristic of the bit "0"; When in the one shown in FIG Embodiment the character Ci passes the read head 16, deliver the read amplifiers A1, A2 and A3 TRUE output signals while sense amplifiers A4 and A5 FASSCH; Deliver output signals. All output signals together give the binary number 11100 again If, on the other hand, the character C4 is read, only the output of the Amplifier A5 true because the character C4 is formed from the binary number 00001. This type of operation for optical tape readers is known.

It is also known that the data density at which such Reader device can still be operated with security is limited. The limitations are mostly due to fluctuations in the response time and the conversion factor the various phototransistors as well as difficulties in the mechanical and optical adjustment conditional. Even with an ideal alignment and the like The different conversion factors or sensitivities can still be addressed of the phototransistors can lead to reading errors. The difficulties that exist can it can best be explained with reference to Figo 3, in which it is an idealized diagram Output signals of the phototransistors PT1, PT2 and PT3 when reading out the character Cl acts. The differences in the amplitudes correspond to the assumed different ones Sensitivities of the phototransistor A minimum sensitivity has been set for the phototransistor PT1 assumed, while the phototransistor PT2 about twice and the phototransistor PT3 has eight times the sensitivity. The reference voltage Vref has been set to 75% of the Lowest output signal of a phototransistor to be expected is set, such as it Fig. 3 shows.

The phototransistors PT4 and PT5 do not generate any significant output signals, because the windows D4 and D5 assigned to them are opaque areas of the film face when the character C1 is read.

The output signals of the sense amplifiers A1 to A5 as a function of the output signals of the phototransistors PT1 to PT5 when reading out the character C1 are shown in FIG. Although each of the sense amplifiers Al, A2 and A3 is a Provides TRUE output to represent an i are the lengths the TRUE output signals of the amplifiers A1 to A3 are different because the conversion factors or sensitivities of the phototransistors PT1 to PT3 differ from one another, as Fig. 3 shows.

The amplifier A1 generates the output signal with the shortest duration It is this difference in the duration of the read amplifier outputs that does it is difficult to read the characters accurately. This applies in particular to high data densities, where the character duration is very short. For example, at a density of 40 bit / cm, the character duration is equal to the time it takes to make the film strip to move 1/40 = 0.025 cm.

To overcome these difficulties, the invention provides that, as shown in? igO 1, the outputs of the amplifiers A1 to A5 each with the S-input of a bistable element assigned to it is connected to the device According to Fig. 1, flip-flops FF1 to FF5 are provided. Also the outputs the five amplifiers are fed to the five inputs of an OR gate 25, the TRUE output signal of which is used to control a first monoflop 26. The output of the first Monoflop 26 is used to control a second monoflop 27 and to control a gate 28 to which the Q outputs of the flip-flops are connected. The output signal of the second monoflop 27 is fed to the R inputs of all flip-flops FFX to FF5 The output pulse of the first monoflop 26 becomes this used that Open gate 28 so that there is a transfer of the states of the flip-flops that are passed through their Q output signals are reproduced to evaluation devices not shown in detail allows, whereas the output pulse of the second monoflop 27 is used to all Reset flip-flops FF1 to FF5 The mode of operation of the device according to the invention can best be described with reference to FIG. 5, in which the pulses 30, 31 and 32 the output pulses of the OR gate 25, the first monoflop 26 and the second Show monoflop 27 in their correct time allocation.It is assumed that c'aB during operation the flip-flops are in a zero position before reading each character are located. When reading a character, the TRUE output signal causes a any of the amplifiers use the OR gate 25 of FIG. 1 for delivering a pulse 30. The leading edge coincides with the leading edge of the first TRUE output signal together supplied by any one of the amplifiers, while the trailing edge occurs when the output signals of all sense amplifiers have decreased to the FALSE level i.e. that the trailing edge of pulse 30 coincides with the trailing edge of the last TRUE pulse coincides. In the example given here, the duration of the pulse is 30 The duration of the TRUE output signal of amplifier A3 (Fig. 4) is the same. So are of the TRUE output signals of the reader amplifiers all assigned Flip-flops have been set before the trailing edge of the output pulse 30 of the OR gate 25 appears.

The trailing edge of the output pulse 30 of the gate 25 hits the first Monoflop 26 so that it generates a pulse 31 of a certain duration during which the Gate 28 is open. During this time, the states of the flip-flops FF1 to FF5 can be read out. In the case of the character Cl, it is determined during the pulse 31, that the flip-flops FF1, FF2 and FF3 are set, whereas the flip-flops FF4 and FF5 assume their zero state, so that it can be seen that C1 is the binary number 11100 represents. Accordingly, the reading takes place during a clearly defined time instead, which is determined by the duration of the pulse 31.

The trailing edge of pulse 31, which marks the end of the reading period, is used to trigger the second monoflop 27 so that it generates the pulse 32 supplies. This pulse also has a certain duration during all flip-flops reset to their zero state for temporary storage a following character prepared Sindo Accordingly, the readout of the flip-flops takes place during impulse 31 and their setting back during impulse 32, There the read pulse 31 is triggered when the output signals of all reader amplifiers are wrong, a section of code is used that allows a return to zero, To this end, adjacent characters on the film 20 are opaque Stripes separated so that during part of the assigned to each character Time independent of the number of bits "1", i.e. the transparent places of the Character, all sense amplifiers deliver FLASCH output signals0 These are opaque Stripes are denoted by 40 in FIG. 2. The total duration of pulses 31 and 32 is shorter than the time that a strip 40 needs to the reading head 16 to happen. With a film strip with a data density of 40 bit / cm the width of each strip 40 is approximately 0.0025 cm. In summary, BK - @ accordingly the invention can be said to be in the application of a number of bistable elements (FF1 to FF5) that are added during the reading period assigned to each character is used to temporarily store the bits of the character to be read, On such a bistable element is either brought into the control state so that it represents a "1", or it remains in its zero state in which it represents a "0". Furthermore, an OR gate (25) is provided which has an output signal, its Trailing edge indicates that all bits have been read out 0 The trailing edge becomes this used to trigger a first unoflop (26) to create a first Period of time (Pulse 31) during which the states of the flip-flops are scanned0 At the end of the first period, a second ilonoflop (27) is triggered. This Monoflop in turn determines a second period of time (pulse 32) during which all Flip-flops reset to zero and therefore for temporary storage be prepared by bits of a following character to be read. Consequently are also when the duration of the TRUE outputs of the various sense amplifiers fluctuates, the bits of each character are read out simultaneously 0 This simultaneity contributes to a large extent to the accuracy when reading out characters that appear on a Filmstrips are arranged at a relatively high density0 It will be understood that the Invention is not limited to the illustrated embodiment, but Deviations from this are possible without departing from the scope of the invention. For example The teachings of the invention can also find use in tape readers that use make use of multi-track tapes with other than optical markings are provided0 In such a case, the phototransistors had to pass through elements be replaced; which are suitable for scanning the particular markings used are0

Claims (6)

Claims lo device for reading multiple signals of different Duration from several signal sources, preferably from the probes of tape readers, are delivered, characterized in that the signal sources (A1 to A5) a gate circuit (25) is connected which supplies a first control signal (30), when it receives a signal from any of the signal sources (A1 to A5) will that continue with each of the signal sources (A1 to A5) a bistable element (FF1 to FF5) is connected, which assumes a first or a second state, Depending on whether the output signal of the assigned signal source has a certain Value falls below or exceeds that continues on the trailing edge of the first Control signal (30) a first Schaltaaaordnung (26) responds, which a first.Zeitspanne defiaiert for scanning the states of the bistable elements (FF1 to FF5), and that finally a second circuit arrangement is provided which is connected to the end of the first Responds to the period of time and resets the bistable elements to the first state. 20 Device according to Claim 1, characterized in that the gate circuit (25) from an OR gate with one of the number of signal sources (A1 to A5) the same number of inputs, the first circuit arrangement (26) from one first monoflop, the first control pulse defining the first time period (31) supplies, and the second circuit arrangement (27) from a second monoflop is formed, which forms a reset signal forming second control pulse (32) supplies. 30 Device according to claim 1 or 2, characterized in that the bistable elements (FF1 to FF5) are formed by flip-flops and a gate circuit (28) is provided, the output signals characterizing the states of the flip-flops of the flip-flops and 'which are supplied during the by the first circuit arrangement (26) defined time span, in particular from the one supplied by the first monoflop (26) first control pulse (31) is opened to transmit the output signals, and that the flip-flops are supplied with a reset pulse by the second circuit arrangement (27) will. 4. Device according to one of the preceding claims, characterized in that that the signal sources (A1 to A5) are formed by amplifiers, each one lit each one light sensitive element (p si PT5) connected input and one second, with a common source a reference voltage (Vref) have connected input and provide a TRUE output signal when the level of the input signal supplied to them by the associated light-sensitive element does not read below the voltage reference (Vref), and a BOTTLE output if the level of the input signal supplied to them by the associated light-sensitive element below the reference voltage is that connected to the amplifiers (A1 to A5) bistable elements (FFfl to FF5) assume the first state when the output signal of the associated amplifier is "false", and the second state if the output signal of the associated amplifier is "true" and that the output signal of the gate circuit (25) is "true" as long as one of the output signals from the amplifiers is "true". 50 Device according to claim 4, characterized in that the light-sensitive Elements (PT1 to 1-T5) Part of a scanning head (16) for a film strip (20) with a number of tracks, each of which is one of the photosensitive elements (Pt1 to PT5) is assigned and each transparent and opaque places which form an optical code. 6. Device according to claims 2 and 5, characterized in that that the duration of the first and the second control pulse (31 or 32) together approximately is equal to one tenth of the duration required to scan a one associated with a character clear body is required 0